U s e r ’ s M a n u a l , V 2 . 1 , M a r c h 20 0 4 XC164-16 16-Bit Single-Chip Microcontroller with C166SV2 Core Volume 2 (of 2): Peripheral Units Microcontrollers N e v e r s t o p t h i n k i n g . Edition 2004-03 Published by Infineon Technologies AG, St.-Martin-Strasse 53, 81669 München, Germany © Infineon Technologies AG 2004. All Rights Reserved. Attention please! The information herein is given to describe certain components and shall not be considered as a guarantee of characteristics. Terms of delivery and rights to technical change reserved. We hereby disclaim any and all warranties, including but not limited to warranties of non-infringement, regarding circuits, descriptions and charts stated herein. Information For further information on technology, delivery terms and conditions and prices please contact your nearest Infineon Technologies Office (www.infineon.com). Warnings Due to technical requirements components may contain dangerous substances. For information on the types in question please contact your nearest Infineon Technologies Office. Infineon Technologies Components may only be used in life-support devices or systems with the express written approval of Infineon Technologies, if a failure of such components can reasonably be expected to cause the failure of that life-support device or system, or to affect the safety or effectiveness of that device or system. Life support devices or systems are intended to be implanted in the human body, or to support and/or maintain and sustain and/or protect human life. If they fail, it is reasonable to assume that the health of the user or other persons may be endangered. U s e r ’ s M a n u a l , V 2 . 1 , M a r c h 20 0 4 XC164-16 16-Bit Single-Chip Microcontroller with C166SV2 Core Volume 2 (of 2): Peripheral Units Microcontrollers N e v e r s t o p t h i n k i n g . XC164 Volume 2 (of 2): Peripheral Units Revision History: V2.1, 2004-03 Previous Version: V2.0, 2003-12 (Pre-Release) V1.1, 2002-02 (Draft Manual) V1.0, 2001-04 (Draft Manual) Page Subjects (major changes since last revision) all The layout of several graphics and text structures has been adapted to company documentation rules, obvious typographical errors have been corrected. 16-17 ADC reset calibration note added 19-17 IrDA pulse width table corrected Controller Area Network (CAN): License of Robert Bosch GmbH We Listen to Your Comments Any information within this document that you feel is wrong, unclear or missing at all? Your feedback will help us to continuously improve the quality of this document. Please send your proposal (including a reference to this document) to: [email protected] Template: mc_tmplt_a5.fm / 3 / 2003-09-01 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Table of Contents Page This User’s Manual consists of two Volumes, “System Units” and “Peripheral Units”. For your convenience this table of contents (and also the keyword index) lists both volumes, so you can immediately find the reference to the desired section in the corresponding document ([1] or [2]). 1 1.1 1.2 1.3 1.4 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1 [1] Members of the 16-bit Microcontroller Family . . . . . . . . . . . . . . . . . . . 1-3 [1] Summary of Basic Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-5 [1] Abbreviations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-9 [1] Naming Conventions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-10 [1] 2 2.1 2.1.1 2.1.2 2.1.3 2.1.4 2.1.5 2.1.6 2.2 2.3 2.4 2.5 2.6 2.7 Architectural Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-1 [1] Basic CPU Concepts and Optimizations . . . . . . . . . . . . . . . . . . . . . . . 2-2 [1] High Instruction Bandwidth / Fast Execution . . . . . . . . . . . . . . . . . . 2-4 [1] Powerful Execution Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-5 [1] High Performance Branch-, Call-, and Loop-Processing . . . . . . . . . 2-6 [1] Consistent and Optimized Instruction Formats . . . . . . . . . . . . . . . . 2-7 [1] Programmable Multiple Priority Interrupt System . . . . . . . . . . . . . . 2-8 [1] Interfaces to System Resources . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-9 [1] On-Chip System Resources . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-10 [1] On-Chip Peripheral Blocks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-14 [1] Clock Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-29 [1] Power Management Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-29 [1] On-Chip Debug Support (OCDS) . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-31 [1] Protected Bits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-32 [1] 3 3.1 3.2 3.3 3.4 3.5 3.6 3.7 3.8 3.9 3.9.1 3.9.2 3.9.3 3.9.4 3.9.5 3.9.6 Memory Organization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1 [1] Address Mapping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-3 [1] Special Function Register Areas . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-4 [1] Data Memory Areas . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-8 [1] Program Memory Areas . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10 [1] System Stack . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-12 [1] IO Areas . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-13 [1] External Memory Space . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-14 [1] Crossing Memory Boundaries . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-15 [1] The On-Chip Program Flash Module . . . . . . . . . . . . . . . . . . . . . . . . 3-16 [1] Flash Operating Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-18 [1] Command Sequences . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-19 [1] Error Correction and Data Integrity . . . . . . . . . . . . . . . . . . . . . . . . 3-25 [1] Protection and Security Features . . . . . . . . . . . . . . . . . . . . . . . . . 3-27 [1] Flash Status Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-32 [1] Operation Control and Error Handling . . . . . . . . . . . . . . . . . . . . . . 3-35 [1] User’s Manual I-1 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Table of Contents Page 3.10 3.10.1 3.10.2 3.11 3.11.1 3.11.2 3.11.3 3.11.4 The On-Chip Program Mask ROM . . . . . . . . . . . . . . . . . . . . . . . . . . Protection and Security Features . . . . . . . . . . . . . . . . . . . . . . . . . Command Sequences . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Program Memory Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Address Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Flash Memory Access . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . User ROM Access . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . IMB Control Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 4.1 4.2 4.2.1 4.2.2 4.2.3 4.3 4.3.1 4.3.2 4.3.3 4.3.4 4.4 4.5 4.5.1 4.5.2 4.6 4.7 4.7.1 4.7.2 4.7.3 4.7.4 4.7.5 4.8 4.8.1 4.8.2 4.8.3 4.9 4.9.1 4.9.2 4.9.3 4.9.4 4.9.5 4.9.6 4.9.7 Central Processing Unit (CPU) . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1 [1] Components of the CPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-4 [1] Instruction Fetch and Program Flow Control . . . . . . . . . . . . . . . . . . . . 4-5 [1] Branch Detection and Branch Prediction Rules . . . . . . . . . . . . . . . . 4-7 [1] Correctly Predicted Instruction Flow . . . . . . . . . . . . . . . . . . . . . . . . 4-7 [1] Incorrectly Predicted Instruction Flow . . . . . . . . . . . . . . . . . . . . . . . 4-9 [1] Instruction Processing Pipeline . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-11 [1] Pipeline Conflicts Using General Purpose Registers . . . . . . . . . . . 4-13 [1] Pipeline Conflicts Using Indirect Addressing Modes . . . . . . . . . . . 4-15 [1] Pipeline Conflicts Due to Memory Bandwidth . . . . . . . . . . . . . . . . 4-17 [1] Pipeline Conflicts Caused by CPU-SFR Updates . . . . . . . . . . . . . 4-20 [1] CPU Configuration Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-26 [1] Use of General Purpose Registers . . . . . . . . . . . . . . . . . . . . . . . . . . 4-29 [1] GPR Addressing Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-31 [1] Context Switching . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-33 [1] Code Addressing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-37 [1] Data Addressing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-39 [1] Short Addressing Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-39 [1] Long Addressing Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-41 [1] Indirect Addressing Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-45 [1] DSP Addressing Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-47 [1] The System Stack . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-53 [1] Standard Data Processing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-57 [1] 16-bit Adder/Subtracter, Barrel Shifter, and 16-bit Logic Unit . . . . 4-61 [1] Bit Manipulation Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-61 [1] Multiply and Divide Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-63 [1] DSP Data Processing (MAC Unit) . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-65 [1] Representation of Numbers and Rounding . . . . . . . . . . . . . . . . . . 4-66 [1] The 16-bit by 16-bit Signed/Unsigned Multiplier and Scaler . . . . . 4-67 [1] Concatenation Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-67 [1] One-bit Scaler . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-67 [1] The 40-bit Adder/Subtracter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-67 [1] The Data Limiter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-68 [1] The Accumulator Shifter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-68 [1] User’s Manual I-2 3-37 [1] 3-37 [1] 3-39 [1] 3-40 [1] 3-41 [1] 3-42 [1] 3-44 [1] 3-45 [1] V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Table of Contents Page 4.9.8 4.9.9 4.9.10 4.10 The 40-bit Signed Accumulator Register . . . . . . . . . . . . . . . . . . . . The MAC Unit Status Word MSW . . . . . . . . . . . . . . . . . . . . . . . . . The Repeat Counter MRW . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Constant Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 5.1 5.2 5.3 5.4 5.4.1 5.4.2 5.4.3 5.4.4 5.5 5.6 5.7 5.8 5.9 5.10 5.11 Interrupt and Trap Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1 [1] Interrupt System Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2 [1] Interrupt Arbitration and Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-4 [1] Interrupt Vector Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-10 [1] Operation of the Peripheral Event Controller Channels . . . . . . . . . . 5-18 [1] The PEC Source and Destination Pointers . . . . . . . . . . . . . . . . . . 5-22 [1] PEC Transfer Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-24 [1] Channel Link Mode for Data Chaining . . . . . . . . . . . . . . . . . . . . . . 5-26 [1] PEC Interrupt Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-27 [1] Prioritization of Interrupt and PEC Service Requests . . . . . . . . . . . . 5-29 [1] Context Switching and Saving Status . . . . . . . . . . . . . . . . . . . . . . . . 5-31 [1] Interrupt Node Sharing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-34 [1] External Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-35 [1] OCDS Requests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-40 [1] Service Request Latency . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-41 [1] Trap Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-43 [1] 6 6.1 6.1.1 6.1.2 6.1.3 6.1.4 6.1.5 6.1.6 6.1.7 6.2 6.2.1 6.2.2 6.2.3 6.2.4 6.2.5 6.2.6 6.3 6.3.1 6.3.2 6.3.3 6.3.4 General System Control Functions . . . . . . . . . . . . . . . . . . . . . . . . . 6-1 [1] System Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-2 [1] Reset Sources and Phases . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-3 [1] Status After Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-6 [1] Application-Specific Initialization Routine . . . . . . . . . . . . . . . . . . . 6-11 [1] System Startup Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-14 [1] Hardware Configuration in External Start Mode . . . . . . . . . . . . . . 6-18 [1] Default Configuration in Single-Chip Mode . . . . . . . . . . . . . . . . . . 6-23 [1] Reset Behavior Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-24 [1] Clock Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-26 [1] Oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-27 [1] Clock Generation and Frequency Control . . . . . . . . . . . . . . . . . . . 6-29 [1] Clock Distribution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-36 [1] Oscillator Watchdog . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-37 [1] Interrupt Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-37 [1] Generation of an External Clock Signal . . . . . . . . . . . . . . . . . . . . 6-38 [1] Central System Control Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-42 [1] Status Indication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-44 [1] Reset Source Indication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-45 [1] Peripheral Shutdown Handshake . . . . . . . . . . . . . . . . . . . . . . . . . 6-46 [1] Debug System Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-47 [1] User’s Manual I-3 4-69 [1] 4-70 [1] 4-72 [1] 4-74 [1] V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Table of Contents Page 6.3.5 6.4 6.4.1 6.4.2 6.4.3 6.5 6.6 Register Security Mechanism . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Reduction Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Reduction of Clock Frequencies . . . . . . . . . . . . . . . . . . . . . . . . . . Flexible Peripheral Management . . . . . . . . . . . . . . . . . . . . . . . . . . Watchdog Timer (WDT) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Identification Control Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 7.1 7.2 7.3 7.4 7.5 7.6 7.7 7.8 7.9 7.10 Parallel Ports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-1 [1] Input Threshold Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-2 [1] Output Driver Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-3 [1] Alternate Port Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-8 [1] PORT0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-9 [1] PORT1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-13 [1] Port 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-25 [1] Port 4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-38 [1] Port 5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-47 [1] Port 9 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-51 [1] Port 20 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-60 [1] 8 Dedicated Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8-1 [1] 9 9.1 9.2 9.2.1 9.2.1.1 9.2.1.2 9.2.2 9.2.2.1 9.2.2.2 9.2.2.3 9.2.2.4 9.2.2.5 9.2.2.6 9.2.3 9.3 9.3.1 9.3.2 9.3.3 9.3.4 9.3.5 9.3.6 9.3.6.1 The External Bus Controller EBC . . . . . . . . . . . . . . . . . . . . . . . . . . 9-1 [1] External Bus Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-3 [1] Timing Principles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-4 [1] Basic Bus Cycle Protocols . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-4 [1] Demultiplexed Bus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-5 [1] Multiplexed Bus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-6 [1] Bus Cycle Phases . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-7 [1] A Phase - CS Change Phase . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-7 [1] B Phase - Address Setup/ALE Phase . . . . . . . . . . . . . . . . . . . . . 9-7 [1] C Phase - Delay Phase . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-7 [1] D Phase - Write Data Setup/MUX Tristate Phase . . . . . . . . . . . . 9-7 [1] E Phase - RD/WR Command Phase . . . . . . . . . . . . . . . . . . . . . . 9-7 [1] F Phase - Address/Write Data Hold Phase . . . . . . . . . . . . . . . . . 9-8 [1] Bus Cycle Examples: Fastest Access Cycles . . . . . . . . . . . . . . . . . 9-8 [1] Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-10 [1] Configuration Register Overview . . . . . . . . . . . . . . . . . . . . . . . . . . 9-10 [1] The EBC Mode Register 0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-12 [1] The EBC Mode Register 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-14 [1] The Timing Configuration Registers TCONCSx . . . . . . . . . . . . . . 9-15 [1] The Function Configuration Registers FCONCSx . . . . . . . . . . . . . 9-16 [1] The Address Window Selection Registers ADDRSELx . . . . . . . . . 9-18 [1] Definition of Address Areas . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-18 [1] User’s Manual I-4 6-49 [1] 6-53 [1] 6-53 [1] 6-56 [1] 6-56 [1] 6-58 [1] 6-63 [1] V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Table of Contents Page 9.3.6.2 9.3.7 9.3.8 9.4 9.5 Address Window Arbitration . . . . . . . . . . . . . . . . . . . . . . . . . . . Access Control to TwinCAN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Shutdown Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . LXBus Access Control and Signal Generation . . . . . . . . . . . . . . . . . EBC Register Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-20 [1] 9-21 [1] 9-22 [1] 9-23 [1] 9-23 [1] 10 10.1 10.2 10.3 10.4 The Bootstrap Loader . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Entering the Bootstrap Loader . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Loading the Startup Code . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Exiting Bootstrap Loader Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Choosing the Baudrate for the BSL . . . . . . . . . . . . . . . . . . . . . . . . . 10-1 [1] 10-2 [1] 10-4 [1] 10-4 [1] 10-5 [1] 11 11.1 11.2 11.3 11.3.1 11.3.2 11.4 11.4.1 11.5 Debug System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Debug Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . OCDS Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Debug Events . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Debug Actions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Cerberus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Functional Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Emulation Device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11-1 [1] 11-1 [1] 11-2 [1] 11-3 [1] 11-5 [1] 11-6 [1] 11-7 [1] 11-7 [1] 11-9 [1] 12 Instruction Set Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12-1 [1] 13 Device Specification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13-1 [1] 14 14.1 14.1.1 14.1.2 14.1.3 14.1.4 14.1.5 14.1.6 14.1.7 14.2 14.2.1 14.2.2 14.2.3 14.2.4 14.2.5 14.2.6 14.2.7 14.2.8 The General Purpose Timer Units . . . . . . . . . . . . . . . . . . . . . . . . . 14-1 [2] Timer Block GPT1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14-2 [2] GPT1 Core Timer T3 Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14-4 [2] GPT1 Core Timer T3 Operating Modes . . . . . . . . . . . . . . . . . . . . . 14-8 [2] GPT1 Auxiliary Timers T2/T4 Control . . . . . . . . . . . . . . . . . . . . . 14-15 [2] GPT1 Auxiliary Timers T2/T4 Operating Modes . . . . . . . . . . . . . 14-18 [2] GPT1 Clock Signal Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14-27 [2] GPT1 Timer Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14-29 [2] Interrupt Control for GPT1 Timers . . . . . . . . . . . . . . . . . . . . . . . . 14-30 [2] Timer Block GPT2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14-31 [2] GPT2 Core Timer T6 Control . . . . . . . . . . . . . . . . . . . . . . . . . . . 14-33 [2] GPT2 Core Timer T6 Operating Modes . . . . . . . . . . . . . . . . . . . . 14-37 [2] GPT2 Auxiliary Timer T5 Control . . . . . . . . . . . . . . . . . . . . . . . . 14-40 [2] GPT2 Auxiliary Timer T5 Operating Modes . . . . . . . . . . . . . . . . . 14-42 [2] GPT2 Register CAPREL Operating Modes . . . . . . . . . . . . . . . . . 14-46 [2] GPT2 Clock Signal Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14-51 [2] GPT2 Timer Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14-54 [2] Interrupt Control for GPT2 Timers and CAPREL . . . . . . . . . . . . . 14-55 [2] User’s Manual I-5 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Table of Contents Page 14.3 Interfaces of the GPT Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14-56 [2] 15 15.1 15.2 15.3 15.3.1 15.3.2 15.3.3 15.4 Real Time Clock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15-1 [2] Defining the RTC Time Base . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15-2 [2] RTC Run Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15-5 [2] RTC Operating Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15-7 [2] 48-bit Timer Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15-10 [2] System Clock Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15-10 [2] Cyclic Interrupt Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15-11 [2] RTC Interrupt Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15-12 [2] 16 16.1 16.1.1 16.1.2 16.2 16.2.1 16.2.2 16.2.3 16.2.4 16.3 16.4 16.5 16.6 The Analog/Digital Converter . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-1 [2] Mode Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-3 [2] Compatibility Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-3 [2] Enhanced Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-5 [2] ADC Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-8 [2] Fixed Channel Conversion Modes . . . . . . . . . . . . . . . . . . . . . . . . 16-11 [2] Auto Scan Conversion Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-12 [2] Wait for Read Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-13 [2] Channel Injection Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-14 [2] Automatic Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-17 [2] Conversion Timing Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-18 [2] A/D Converter Interrupt Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-21 [2] Interfaces of the ADC Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-22 [2] 17 17.1 17.2 17.3 17.4 17.5 17.5.1 17.5.2 17.5.3 17.5.4 17.5.5 17.6 17.7 17.8 17.9 17.10 17.11 Capture/Compare Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17-1 [2] The CAPCOM Timers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17-4 [2] CAPCOM Timer Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17-9 [2] Capture/Compare Channels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17-10 [2] Capture Mode Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17-13 [2] Compare Mode Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17-14 [2] Compare Mode 0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17-15 [2] Compare Mode 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17-15 [2] Compare Mode 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17-18 [2] Compare Mode 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17-18 [2] Double-Register Compare Mode . . . . . . . . . . . . . . . . . . . . . . . . 17-22 [2] Compare Output Signal Generation . . . . . . . . . . . . . . . . . . . . . . . . 17-25 [2] Single Event Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17-27 [2] Staggered and Non-Staggered Operation . . . . . . . . . . . . . . . . . . . . 17-29 [2] CAPCOM Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17-34 [2] External Input Signal Requirements . . . . . . . . . . . . . . . . . . . . . . . . 17-36 [2] Interfaces of the CAPCOM Units . . . . . . . . . . . . . . . . . . . . . . . . . . . 17-37 [2] 18 Capture/Compare Unit 6 (CAPCOM6) . . . . . . . . . . . . . . . . . . . . . . 18-1 [2] User’s Manual I-6 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Table of Contents Page 18.1 18.1.1 18.1.2 18.1.3 18.1.4 18.1.5 18.2 18.2.1 18.2.2 18.3 18.4 18.5 18.5.1 18.5.2 18.5.3 18.5.4 18.6 18.7 18.8 18.9 18.10 18.11 Timer T12 Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-4 [2] Timer T12 Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-7 [2] T12 Compare Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-12 [2] Dead-Time Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-21 [2] T12 Capture Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-24 [2] Hysteresis-Like Control Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-28 [2] Timer T13 Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-29 [2] T13 Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-32 [2] T13 Compare Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-37 [2] Timer Block Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-41 [2] Multi-Channel Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-47 [2] Hall Sensor Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-50 [2] Hall Pattern Compare Logic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-51 [2] Sampling of the Hall Pattern . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-52 [2] Brushless DC-Motor Control with Timer T12 Block . . . . . . . . . . . 18-53 [2] Hall Mode Flags . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-55 [2] Trap Handling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-61 [2] Output Modulation Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-65 [2] Shadow Register Transfer Control . . . . . . . . . . . . . . . . . . . . . . . . . 18-69 [2] Interrupt Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-71 [2] Suspend Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-80 [2] Interfaces of the CAPCOM6 Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . 18-81 [2] 19 19.1 19.2 19.2.1 19.2.2 19.2.3 19.2.4 19.2.5 19.2.6 19.2.7 19.2.8 19.3 19.3.1 19.3.2 19.3.3 19.4 19.4.1 19.4.2 19.5 19.5.1 Asynchronous/Synchronous Serial Interface (ASC) . . . . . . . . . . 19-1 [2] Operational Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-3 [2] Asynchronous Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-5 [2] Asynchronous Data Frames . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-6 [2] Asynchronous Transmission . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-9 [2] Transmit FIFO Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-9 [2] Asynchronous Reception . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-12 [2] Receive FIFO Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-12 [2] FIFO Transparent Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-15 [2] IrDA Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-16 [2] RxD/TxD Data Path Selection in Asynchronous Modes . . . . . . . 19-17 [2] Synchronous Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-19 [2] Synchronous Transmission . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-20 [2] Synchronous Reception . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-20 [2] Synchronous Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-20 [2] Baudrate Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-22 [2] Baudrate in Asynchronous Mode . . . . . . . . . . . . . . . . . . . . . . . . . 19-22 [2] Baudrate in Synchronous Mode . . . . . . . . . . . . . . . . . . . . . . . . . 19-26 [2] Autobaud Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-27 [2] General Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-27 [2] User’s Manual I-7 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Table of Contents Page 19.5.2 19.5.3 19.5.4 19.6 19.7 19.8 19.9 Serial Frames for Autobaud Detection . . . . . . . . . . . . . . . . . . . . . Baudrate Selection and Calculation . . . . . . . . . . . . . . . . . . . . . . . Overwriting Registers on Successful Autobaud Detection . . . . . Hardware Error Detection Capabilities . . . . . . . . . . . . . . . . . . . . . . Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Interfaces of the ASC Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-28 [2] 19-29 [2] 19-33 [2] 19-34 [2] 19-35 [2] 19-39 [2] 19-56 [2] 20 20.1 20.2 20.2.1 20.2.2 20.2.3 20.2.4 20.2.5 20.2.6 20.2.7 20.2.8 20.3 High-Speed Synchronous Serial Interface (SSC) . . . . . . . . . . . . 20-1 [2] Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20-1 [2] Operational Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20-1 [2] Operating Mode Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20-3 [2] Full-Duplex Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20-8 [2] Half-Duplex Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20-11 [2] Continuous Transfers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20-12 [2] Baudrate Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20-12 [2] Error Detection Mechanisms . . . . . . . . . . . . . . . . . . . . . . . . . . . 20-14 [2] SSC Register Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20-16 [2] Port Configuration Requirements . . . . . . . . . . . . . . . . . . . . . . . . 20-17 [2] Interfaces of the SSC Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20-18 [2] 21 TwinCAN Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-1 [2] 21.1 Kernel Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-1 [2] 21.1.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-1 [2] 21.1.2 TwinCAN Control Shell . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-4 [2] 21.1.2.1 Initialization Processing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-4 [2] 21.1.2.2 Interrupt Request Compressor . . . . . . . . . . . . . . . . . . . . . . . . . 21-5 [2] 21.1.2.3 Global Control and Status Logic . . . . . . . . . . . . . . . . . . . . . . . . 21-6 [2] 21.1.3 CAN Node Control Logic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-7 [2] 21.1.3.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-7 [2] 21.1.3.2 Timing Control Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-9 [2] 21.1.3.3 Bitstream Processor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-11 [2] 21.1.3.4 Error Handling Logic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-11 [2] 21.1.3.5 Node Interrupt Processing . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-12 [2] 21.1.3.6 Message Interrupt Processing . . . . . . . . . . . . . . . . . . . . . . . . 21-13 [2] 21.1.3.7 Interrupt Indication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-13 [2] 21.1.4 Message Handling Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-15 [2] 21.1.4.1 Arbitration and Acceptance Mask Register . . . . . . . . . . . . . . . 21-16 [2] 21.1.4.2 Handling of Remote and Data Frames . . . . . . . . . . . . . . . . . . 21-17 [2] 21.1.4.3 Handling of Transmit Message Objects . . . . . . . . . . . . . . . . . . 21-18 [2] 21.1.4.4 Handling of Receive Message Objects . . . . . . . . . . . . . . . . . . 21-21 [2] 21.1.4.5 Single Data Transfer Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-23 [2] 21.1.5 CAN Message Object Buffer (FIFO) . . . . . . . . . . . . . . . . . . . . . . 21-24 [2] User’s Manual I-8 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Table of Contents Page 21.1.5.1 Buffer Access by the CAN Controller . . . . . . . . . . . . . . . . . . . 21.1.5.2 Buffer Access by the CPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.1.6 Gateway Message Handling . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.1.6.1 Normal Gateway Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.1.6.2 Normal Gateway with FIFO Buffering . . . . . . . . . . . . . . . . . . . 21.1.6.3 Shared Gateway Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.1.7 Programming the TwinCAN Module . . . . . . . . . . . . . . . . . . . . . . 21.1.7.1 Configuration of CAN Node A/B . . . . . . . . . . . . . . . . . . . . . . . 21.1.7.2 Initialization of Message Objects . . . . . . . . . . . . . . . . . . . . . . . 21.1.7.3 Controlling a Message Transfer . . . . . . . . . . . . . . . . . . . . . . . 21.1.8 Loop-Back Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.1.9 Single Transmission Try Functionality . . . . . . . . . . . . . . . . . . . . 21.1.10 Module Clock Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.2 TwinCAN Register Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.2.1 Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.2.2 CAN Node A/B Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.2.3 CAN Message Object Registers . . . . . . . . . . . . . . . . . . . . . . . . . 21.2.4 Global CAN Control/Status Registers . . . . . . . . . . . . . . . . . . . . . 21.3 XC164 Module Implementation Details . . . . . . . . . . . . . . . . . . . . . . 21.3.1 Interfaces of the TwinCAN Module . . . . . . . . . . . . . . . . . . . . . . . 21.3.2 TwinCAN Module Related External Registers . . . . . . . . . . . . . . . 21.3.2.1 System Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.3.2.2 Port Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.3.2.3 Interrupt Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21.3.3 Register Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 22.1 22.2 21-26 [2] 21-27 [2] 21-28 [2] 21-29 [2] 21-33 [2] 21-36 [2] 21-40 [2] 21-40 [2] 21-40 [2] 21-41 [2] 21-44 [2] 21-45 [2] 21-46 [2] 21-47 [2] 21-47 [2] 21-49 [2] 21-64 [2] 21-80 [2] 21-82 [2] 21-82 [2] 21-83 [2] 21-84 [2] 21-85 [2] 21-89 [2] 21-90 [2] Register Set . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22-1 [2] PD+BUS Peripherals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22-1 [2] LXBUS Peripherals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22-15 [2] Keyword Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . i-1 [1+2] User’s Manual I-9 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14 The General Purpose Timer Units The General Purpose Timer Unit blocks GPT1 and GPT2 have very flexible multifunctional timer structures which may be used for timing, event counting, pulse width measurement, pulse generation, frequency multiplication, and other purposes. They incorporate five 16-bit timers that are grouped into the two timer blocks GPT1 and GPT2. Each timer in each block may operate independently in a number of different modes such as gated timer or counter mode, or may be concatenated with another timer of the same block. Each block has alternate input/output functions and specific interrupts associated with it. Block GPT1 contains three timers/counters: The core timer T3 and the two auxiliary timers T2 and T4. The maximum resolution is fGPT/4. The auxiliary timers of GPT1 may optionally be configured as reload or capture registers for the core timer. These registers are listed in Section 14.1.6. • • • • • • fGPT/4 maximum resolution 3 independent timers/counters Timers/counters can be concatenated 4 operating modes: – Timer Mode – Gated Timer Mode – Counter Mode – Incremental Interface Mode Reload and Capture functionality Separate interrupt lines Block GPT2 contains two timers/counters: The core timer T6 and the auxiliary timer T5. The maximum resolution is fGPT/2. An additional Capture/Reload register (CAPREL) supports capture and reload operation with extended functionality. These registers are listed in Section 14.2.7. The core timer T6 may be concatenated with timers of the CAPCOM units (T0, T1, T7, and T8). The following list summarizes the features which are supported: • • • • • • fGPT/2 maximum resolution 2 independent timers/counters Timers/counters can be concatenated 3 operating modes: – Timer Mode – Gated Timer Mode – Counter Mode Extended capture/reload functions via 16-bit capture/reload register CAPREL Separate interrupt lines User’s Manual GPT_X41, V2.0 14-1 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.1 Timer Block GPT1 From a programmer’s point of view, the GPT1 block is composed of a set of SFRs as summarized below. Those portions of port and direction registers which are used for alternate functions by the GPT1 block are shaded. D ata R egiste rs C o ntrol R egisters Inte rru pt C ontrol T2 T2C O N T2IC O D P3 T3 T3C O N T3IC D P3 T4 T4C O N T4IC P3 SYSC O N 3 P ort R egisters E A LTSEL0P3 E P5 P5D ID IS Tx TxC O N TxIC SYSCON3 G P T 1 Tim er G P T 1 Tim er G P T 1 Tim er S ystem C trl. x R egister x C ontrol R egister x In terrupt C trl. R e g. R e g. 3 (P er. M gm t.) ODP3 DP3 P3 A LTS E L0P 3 P5 P 5D ID IS P ort P ort P ort P ort P ort P ort 3 3 3 3 5 5 O pen D rain C ontrol R egister D irection C ontrol R egister D ata R e gister A lterna te O utput S elect R eg. D ata R e gister D igital Inp ut D isable R eg. m c_ g p t0 1 0 0 _ re g iste rs.vsd Figure 14-1 SFRs Associated with Timer Block GPT1 All three timers of block GPT1 (T2, T3, T4) can run in one of 4 basic modes: Timer Mode, Gated Timer Mode, Counter Mode, or Incremental Interface Mode. All timers can count up or down. Each timer of GPT1 is controlled by a separate control register TxCON. Each timer has an input pin TxIN (alternate pin function) associated with it, which serves as the gate control in gated timer mode, or as the count input in counter mode. The count direction (up/down) may be programmed via software or may be dynamically altered by a signal at the External Up/Down control input TxEUD (alternate pin function). An overflow/underflow of core timer T3 is indicated by the Output Toggle Latch T3OTL, whose state may be output on the associated pin T3OUT (alternate pin function). The auxiliary timers T2 and T4 may additionally be concatenated with the core timer T3 (through T3OTL) or may be used as capture or reload registers for the core timer T3. The current contents of each timer can be read or modified by the CPU by accessing the corresponding timer count registers T2, T3, or T4, located in the non-bitaddressable SFR space (see Section 14.1.6). When any of the timer registers is written to by the CPU in the state immediately preceding a timer increment, decrement, reload, or capture operation, the CPU write operation has priority in order to guarantee correct results. User’s Manual GPT_X41, V2.0 14-2 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units The interrupts of GPT1 are controlled through the Interrupt Control Registers TxIC. These registers are not part of the GPT1 block. The input and output lines of GPT1 are connected to pins of ports P3 and P5. The control registers for the port functions are located in the respective port modules. Note: The timing requirements for external input signals can be found in Section 14.1.5, Section 14.3 summarizes the module interface signals, including pins. T3CON.BPS1 f GPT 2n: 1 Basic clock Interrupt Request (T2IRQ) Aux. Timer T2 T2IN T2EUD T2 Mode Control U/D Reload Capture Interrupt Request (T3IRQ) T3IN Toggle Latch T3 Mode Control Core Timer T3 T3OTL T3OUT U/D T3EUD Capture Reload T4IN T4EUD T4 Mode Control Aux. Timer T4 Interrupt Request (T4IRQ) U/D mc_gpt0101_bldiax1.vsd Figure 14-2 GPT1 Block Diagram (n = 2 … 5) User’s Manual GPT_X41, V2.0 14-3 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.1.1 GPT1 Core Timer T3 Control The current contents of the core timer T3 are reflected by its count register T3. This register can also be written to by the CPU, for example, to set the initial start value. The core timer T3 is configured and controlled via its bitaddressable control register T3CON. GPT12E_T3CON Timer 3 Control Register 15 14 T3 T3 R CH DIR DIR rh rwh 13 12 11 T3 ED GE BPS1 rwh rw SFR (FF42H/A1H) 10 9 8 7 T3 T3 T3 T3 OTL OE UDE UD rwh rw rw rw 6 Reset Value: 0000H 5 4 3 2 1 T3R T3M T3I rw rw rw 0 Field Bits Type Description T3RDIR 15 rh Timer T3 Rotation Direction Flag 0 Timer T3 counts up 1 Timer T3 counts down T3CHDIR 14 rwh Timer T3 Count Direction Change Flag This bit is set each time the count direction of timer T3 changes. T3CHDIR must be cleared by SW. 0 No change of count direction was detected 1 A change of count direction was detected T3EDGE 13 rwh Timer T3 Edge Detection Flag The bit is set each time a count edge is detected. T3EDGE must be cleared by SW. 0 No count edge was detected 1 A count edge was detected BPS1 [12:11] rw GPT1 Block Prescaler Control Selects the basic clock for block GPT1 (see also Section 14.1.5) 00 fGPT/8 01 fGPT/4 10 fGPT/32 11 fGPT/16 T3OTL 10 Timer T3 Overflow Toggle Latch Toggles on each overflow/underflow of T3. Can be set or reset by software (see separate description) User’s Manual GPT_X41, V2.0 rwh 14-4 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Field Bits Type Description T3OE 9 rw Overflow/Underflow Output Enable 0 Alternate Output Function Disabled 1 State of T3 toggle latch is output on pin T3OUT T3UDE 8 rw Timer T3 External Up/Down Enable1) 0 Input T3EUD is disconnected 1 Direction influenced by input T3EUD T3UD 7 rw Timer T3 Up/Down Control1) 0 Timer T3 counts up 1 Timer T3 counts down T3R 6 rw Timer T3 Run Bit 0 Timer T3 stops 1 Timer T3 runs T3M [5:3] rw Timer T3 Mode Control (Basic Operating Mode) 000 Timer Mode 001 Counter Mode 010 Gated Timer Mode with gate active low 011 Gated Timer Mode with gate active high 100 Reserved. Do not use this combination. 101 Reserved. Do not use this combination. 110 Incremental Interface Mode (Rotation Detection Mode) 111 Incremental Interface Mode (Edge Detection Mode) T3I [2:0] rw Timer T3 Input Parameter Selection Depends on the operating mode, see respective sections for encoding: Table 14-7 for Timer Mode and Gated Timer Mode Table 14-2 for Counter Mode Table 14-3 for Incremental Interface Mode 1) See Table 14-1 for encoding of bits T3UD and T3UDE. User’s Manual GPT_X41, V2.0 14-5 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Timer T3 Run Control The core timer T3 can be started or stopped by software through bit T3R (Timer T3 Run Bit). This bit is relevant in all operating modes of T3. Setting bit T3R will start the timer, clearing bit T3R stops the timer. In gated timer mode, the timer will only run if T3R = 1 and the gate is active (high or low, as programmed). Note: When bit T2RC or T4RC in timer control register T2CON or T4CON is set, bit T3R will also control (start and stop) the auxiliary timer(s) T2 and/or T4. Count Direction Control The count direction of the GPT1 timers (core timer and auxiliary timers) can be controlled either by software or by the external input pin TxEUD (Timer Tx External Up/Down Control Input). These options are selected by bits TxUD and TxUDE in the respective control register TxCON. When the up/down control is provided by software (bit TxUDE = 0), the count direction can be altered by setting or clearing bit TxUD. When bit TxUDE = 1, pin TxEUD is selected to be the controlling source of the count direction. However, bit TxUD can still be used to reverse the actual count direction, as shown in Table 14-1. The count direction can be changed regardless of whether or not the timer is running. Note: When pin TxEUD is used as external count direction control input, it must be configured as input (its corresponding direction control bit must be cleared). Table 14-1 GPT1 Timer Count Direction Control Pin TxEUD Bit TxUDE Bit TxUD Count Direction Bit TxRDIR X 0 0 Count Up 0 X 0 1 Count Down 1 0 1 0 Count Up 0 1 1 0 Count Down 1 0 1 1 Count Down 1 1 1 1 Count Up 0 User’s Manual GPT_X41, V2.0 14-6 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Timer 3 Output Toggle Latch The overflow/underflow signal of timer T3 is connected to a block named ‘Toggle Latch’, shown in the timer mode diagrams. Figure 14-3 illustrates the details of this block. An overflow or underflow of T3 will clock two latches: The first latch represents bit T3OTL in control register T3CON. The second latch is an internal latch toggled by T3OTL’s output. Both latch outputs are connected to the input control blocks of the auxiliary timers T2 and T4. The output level of the shadow latch will match the output level of T3OTL, but is delayed by one clock cycle. When the T3OTL value changes, this will result in a temporarily different output level from T3OTL and the shadow latch, which can trigger the selected count event in T2 and/or T4. When software writes to T3OTL, both latches are set or cleared simultaneously. In this case, both signals to the auxiliary timers carry the same level and no edge will be detected. Bit T3OE (overflow/underflow output enable) in register T3CON enables the state of T3OTL to be monitored via an external pin T3OUT. When T3OTL is linked to an external port pin (must be configured as output), T3OUT can be used to control external HW. If T3OE = 1, pin T3OUT outputs the state of T3OTL. If T3OE = 0, pin T3OUT outputs a high level (as long as the T3OUT alternate function is selected for the port pin). The trigger signals can serve as an input for the counter function or as a trigger source for the reload function of the auxiliary timers T2 and T4. As can be seen from Figure 14-3, when latch T3OTL is modified by software to determine the state of the output line, also the internal shadow latch is set or cleared accordingly. Therefore, no trigger condition is detected by T2/T4 in this case. 1 C ore Tim er O verflow / U nd erflow 1 Shadow Latch TxO TL T o g g le L a tch L o g ic 0 MUX TxO E S et/C lear (S W ) T xO U T T o P ort Logic T o A ux. Tim er Input Logic m c_ g p t0 1 0 6 _ o tl.vsd Figure 14-3 Block Diagram of the Toggle Latch Logic of Core Timer T3 User’s Manual GPT_X41, V2.0 14-7 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.1.2 GPT1 Core Timer T3 Operating Modes Timer 3 in Timer Mode Timer mode for the core timer T3 is selected by setting bitfield T3M in register T3CON to 000B. In timer mode, T3 is clocked with the module’s input clock fGPT divided by two programmable prescalers controlled by bitfields BPS1 and T3I in register T3CON. Please see Section 14.1.5 for details on the input clock options. T3IRQ fGPT Prescaler BPS1 fT3 T3I Count Core Timer T3 Toggle Latch T3OUT to T2/T4 T3R T3UD 0 =1 MUX 1 Up/Down T3EUD T3UDE MCB05391 Figure 14-4 Block Diagram of Core Timer T3 in Timer Mode User’s Manual GPT_X41, V2.0 14-8 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Gated Timer Mode Gated timer mode for the core timer T3 is selected by setting bitfield T3M in register T3CON to 010B or 011B. Bit T3M.0 (T3CON.3) selects the active level of the gate input. The same options for the input frequency are available in gated timer mode as in timer mode (see Section 14.1.5). However, the input clock to the timer in this mode is gated by the external input pin T3IN (Timer T3 External Input). To enable this operation, the associated pin T3IN must be configured as input, that is, the corresponding direction control bit must contain 0. T3IRQ fGPT Prescaler BPS1 Gate Ctrl. T3I fT3 Count Core Timer T3 Toggle Latch to T2/T4 T3R T3IN T3OUT T3UD 0 =1 MUX 1 Up/Down T3EUD T3UDE MCB05392 Figure 14-5 Block Diagram of Core Timer T3 in Gated Timer Mode If T3M = 010B, the timer is enabled when T3IN shows a low level. A high level at this line stops the timer. If T3M = 011B, line T3IN must have a high level in order to enable the timer. Additionally, the timer can be turned on or off by software using bit T3R. The timer will only run if T3R is 1 and the gate is active. It will stop if either T3R is 0 or the gate is inactive. Note: A transition of the gate signal at pin T3IN does not cause an interrupt request. User’s Manual GPT_X41, V2.0 14-9 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Counter Mode Counter Mode for the core timer T3 is selected by setting bitfield T3M in register T3CON to 001B. In counter mode, timer T3 is clocked by a transition at the external input pin T3IN. The event causing an increment or decrement of the timer can be a positive, a negative, or both a positive and a negative transition at this line. Bitfield T3I in control register T3CON selects the triggering transition (see Table 14-2). T3IRQ Edge Count T3IN Core Timer T3 Toggle Latch T3OUT Select T3I to T2/T4 T3R T3UD 0 =1 MUX Up/Down 1 T3EUD T3UDE MCB05393 Figure 14-6 Block Diagram of Core Timer T3 in Counter Mode Table 14-2 GPT1 Core Timer T3 (Counter Mode) Input Edge Selection T3I Triggering Edge for Counter Increment/Decrement 000 None. Counter T3 is disabled 001 Positive transition (rising edge) on T3IN 010 Negative transition (falling edge) on T3IN 011 Any transition (rising or falling edge) on T3IN 1XX Reserved. Do not use this combination For counter mode operation, pin T3IN must be configured as input (the respective direction control bit DPx.y must be 0). The maximum input frequency allowed in counter mode depends on the selected prescaler value. To ensure that a transition of the count input signal applied to T3IN is recognized correctly, its level must be held high or low for a minimum number of module clock cycles before it changes. This information can be found in Section 14.1.5. User’s Manual GPT_X41, V2.0 14-10 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Incremental Interface Mode Incremental interface mode for the core timer T3 is selected by setting bitfield T3M in register T3CON to 110B or 111B. In incremental interface mode, the two inputs associated with core timer T3 (T3IN, T3EUD) are used to interface to an incremental encoder. T3 is clocked by each transition on one or both of the external input pins to provide 2-fold or 4-fold resolution of the encoder input. T3IN Edge Count Core Timer T3 Toggle Latch T3OUT Select to T2/T4 T3R T3I T3 EDGE T3 RDIR _ >1 T3IRQ T3UD 0 =1 T3EUD MUX Change Detect T3UDE T3CH DIR 1 Phase Detect T3M T3M MCB05394 Figure 14-7 Block Diagram of Core Timer T3 in Incremental Interface Mode Bitfield T3I in control register T3CON selects the triggering transitions (see Table 14-3). The sequence of the transitions of the two input signals is evaluated and generates count pulses as well as the direction signal. So T3 is modified automatically according to the speed and the direction of the incremental encoder and, therefore, its contents always represent the encoder’s current position. The interrupt request (T3IRQ) generation mode can be selected: In Rotation Detection Mode (T3M = 110B), an interrupt request is generated each time the count direction of T3 changes. In Edge Detection Mode (T3M = 111B), an interrupt request is generated each time a count edge for T3 is detected. Count direction, changes in the count direction, and count requests are monitored by status bits T3RDIR, T3CHDIR, and T3EDGE in register T3CON. User’s Manual GPT_X41, V2.0 14-11 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Table 14-3 Core Timer T3 (Incremental Interface Mode) Input Edge Selection T3I Triggering Edge for Counter Increment/Decrement 000 None. Counter T3 stops. 001 Any transition (rising or falling edge) on T3IN. 010 Any transition (rising or falling edge) on T3EUD. 011 Any transition (rising or falling edge) on any T3 input (T3IN or T3EUD). 1XX Reserved. Do not use this combination. The incremental encoder can be connected directly to the XC164 without external interface logic. In a standard system, however, comparators will be employed to convert the encoder’s differential outputs (such as A, A) to digital signals (such as A). This greatly increases noise immunity. Note: The third encoder output T0, which indicates the mechanical zero position, may be connected to an external interrupt input and trigger a reset of timer T3 (for example via PEC transfer from ZEROS). Signal Conditioning Encoder Controller A A A B B B T0 T0 T0 T3Input T3Input Interrupt MCS04372 Figure 14-8 Connection of the Encoder to the XC164 For incremental interface operation, the following conditions must be met: • • • Bitfield T3M must be 110B or 111B. Both pins T3IN and T3EUD must be configured as input, i.e. the respective direction control bits must be 0. Bit T3UDE must be 1 to enable automatic external direction control. The maximum count frequency allowed in incremental interface mode depends on the selected prescaler value. To ensure that a transition of any input signal is recognized correctly, its level must be held high or low for a minimum number of module clock cycles before it changes. This information can be found in Section 14.1.5. User’s Manual GPT_X41, V2.0 14-12 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units As in incremental interface mode two input signals with a 90° phase shift are evaluated, their maximum input frequency can be half the maximum count frequency. In incremental interface mode, the count direction is automatically derived from the sequence in which the input signals change, which corresponds to the rotation direction of the connected sensor. Table 14-4 summarizes the possible combinations. Table 14-4 GPT1 Core Timer T3 (Incremental Interface Mode) Count Direction Level on Respective other Input Rising T3IN Input T3EUD Input Falling Rising Falling High Down Up Up Down Low Up Down Down Up Figure 14-9 and Figure 14-10 give examples of T3’s operation, visualizing count signal generation and direction control. They also show how input jitter is compensated, which might occur if the sensor rests near to one of its switching points. Forward Jitter Backward Jitter Forward T3IN T3EUD Contents of T3 Up Down Up Note: This example shows the timer behaviour assuming that T3 counts upon any transition on input, i.e. T3I = '011 B'. MCT04373 Figure 14-9 Evaluation of Incremental Encoder Signals, 2 Count Inputs User’s Manual GPT_X41, V2.0 14-13 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Forward Jitter Backward Jitter Forward T3IN T3EUD Contents of T3 Up Down Up Note: This example shows the timer behaviour assuming that T3 counts upon any transition on input T3IN, i.e. T3I = '001 B'. MCT04374 Figure 14-10 Evaluation of Incremental Encoder Signals, 1 Count Input Note: Timer T3 operating in incremental interface mode automatically provides information on the sensor’s current position. Dynamic information (speed, acceleration, deceleration) may be obtained by measuring the incoming signal periods. This is facilitated by an additional special capture mode for timer T5 (see Section 14.2.5). User’s Manual GPT_X41, V2.0 14-14 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.1.3 GPT1 Auxiliary Timers T2/T4 Control Auxiliary timers T2 and T4 have exactly the same functionality. They can be configured for timer mode, gated timer mode, counter mode, or incremental interface mode with the same options for the timer frequencies and the count signal as the core timer T3. In addition to these 4 counting modes, the auxiliary timers can be concatenated with the core timer, or they may be used as reload or capture registers in conjunction with the core timer. The start/stop function of the auxiliary timers can be remotely controlled by the T3 run control bit. Several timers may thus be controlled synchronously. The current contents of an auxiliary timer are reflected by its count register T2 or T4, respectively. These registers can also be written to by the CPU, for example, to set the initial start value. The individual configurations for timers T2 and T4 are determined by their bitaddressable control registers T2CON and T4CON, which are organized identically. Note that functions which are present in all 3 timers of block GPT1 are controlled in the same bit positions and in the same manner in each of the specific control registers. Note: The auxiliary timers have no output toggle latch and no alternate output function. GPT12E_T2CON Timer 2 Control Register 15 14 T2 T2 R CH DIR DIR rh rwh SFR (FF40H/A0H) 13 12 11 10 T2 ED GE T2 IR DIS - - T2 T2 T2 RC UDE UD rwh rw - - rw GPT12E_T4CON Timer 4 Control Register 15 14 T4 T4 R CH DIR DIR rh rwh 9 8 rw 7 rw 6 Reset Value: 0000H 5 4 12 11 10 9 8 T4 ED GE T4 IR DIS - - T4 T4 T4 RC UDE UD rwh rw - - rw rw 7 rw T2I rw rw rw 6 0 Reset Value: 0000H 5 4 3 2 1 T4R T4M T4I rw rw rw Bits Type Description TxRDIR 15 rh Timer Tx Rotation Direction 0 Timer x counts up 1 Timer x counts down 14-15 1 T2M Field User’s Manual GPT_X41, V2.0 2 T2R SFR (FF44H/A2H) 13 3 0 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Field Bits Type Description TxCHDIR 14 rwh Timer Tx Count Direction Change This bit is set each time the count direction of timer Tx changes. TxCHDIR must be cleared by SW. 0 No change in count direction was detected 1 A change in count direction was detected TxEDGE 13 rwh Timer Tx Edge Detection The bit is set each time a count edge is detected. TxEDGE must be cleared by SW. 0 No count edge was detected 1 A count edge was detected TxIRDIS 12 rw Timer Tx Interrupt Request Disable 0 Interrupt generation for TxCHDIR and TxEDGE interrupts in Incremental Interface Mode is enabled 1 Interrupt generation for TxCHDIR and TxEDGE interrupts in Incremental Interface Mode is disabled TxRC 9 rw Timer Tx Remote Control 0 Timer Tx is controlled by its own run bit TxR 1 Timer Tx is controlled by the run bit T3R of core timer 3, not by bit TxR TxUDE 8 rw Timer Tx External Up/Down Enable1) 0 Input TxEUD is disconnected 1 Direction influenced by input TxEUD TxUD 7 rw Timer Tx Up/Down Control1) 0 Timer Tx counts up 1 Timer Tx counts down TxR 6 rw Timer Tx Run Bit 0 Timer Tx stops 1 Timer Tx runs Note: This bit only controls timer Tx if bit TxRC = 0. User’s Manual GPT_X41, V2.0 14-16 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Field Bits Type Description TxM [5:3] rw Timer Tx Mode Control (Basic Operating Mode) 000 Timer Mode 001 Counter Mode 010 Gated Timer Mode with gate active low 011 Gated Timer Mode with gate active high 100 Reload Mode 101 Capture Mode 110 Incremental Interface Mode (Rotation Detect.) 111 Incremental Interface Mode (Edge Detection) TxI [2:0] rw Timer Tx Input Parameter Selection Depends on the operating mode, see respective sections for encoding: Table 14-7 for Timer Mode and Gated Timer Mode Table 14-2 for Counter Mode Table 14-3 for Incremental Interface Mode 1) See Table 14-1 for encoding of bits TxUD and TxUDE. Timer T2/T4 Run Control Each of the auxiliary timers T2 and T4 can be started or stopped by software in two different ways: • • Through the associated timer run bit (T2R or T4R). In this case it is required that the respective control bit TxRC = 0. Through the core timer’s run bit (T3R). In this case the respective remote control bit must be set (TxRC = 1). The selected run bit is relevant in all operating modes of T2/T4. Setting the bit will start the timer, clearing the bit stops the timer. In gated timer mode, the timer will only run if the selected run bit is set and the gate is active (high or low, as programmed). Note: If remote control is selected T3R will start/stop timer T3 and the selected auxiliary timer(s) synchronously. Count Direction Control The count direction of the GPT1 timers (core timer and auxiliary timers) is controlled in the same way, either by software or by the external input pin TxEUD. Please refer to the description in Table 14-1. Note: When pin TxEUD is used as external count direction control input, it must be configured as input (its corresponding direction control bit must be cleared). User’s Manual GPT_X41, V2.0 14-17 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.1.4 GPT1 Auxiliary Timers T2/T4 Operating Modes The operation of the auxiliary timers in the basic operating modes is almost identical with the core timer’s operation, with very few exceptions. Additionally, some combined operating modes can be selected. Timers T2 and T4 in Timer Mode Timer mode for an auxiliary timer Tx is selected by setting its bitfield TxM in register TxCON to 000B. fGPT fTx Prescaler BPS1 Count Auxiliary Timer Tx TxIRQ TxI TxR T3R 0 MUX 1 TxRC TxUD 0 =1 MUX 1 Up/Down TxEUD TxUDE x = 2, 4 MCB05395 Figure 14-11 Block Diagram of an Auxiliary Timer in Timer Mode User’s Manual GPT_X41, V2.0 14-18 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Timers T2 and T4 in Gated Timer Mode Gated timer mode for an auxiliary timer Tx is selected by setting bitfield TxM in register TxCON to 010B or 011B. Bit TxM.0 (TxCON.3) selects the active level of the gate input. Note: A transition of the gate signal at line TxIN does not cause an interrupt request. fGPT Prescaler BPS1 Gate Ctrl. fTx Count Auxiliary Timer Tx TxIRQ TxI TxIN TxM TxR T3R 0 MUX 1 TxRC TxUD 0 =1 MUX 1 Up/Down TxEUD TxUDE x = 2, 4 MCB05396 Figure 14-12 Block Diagram of an Auxiliary Timer in Gated Timer Mode Note: There is no output toggle latch for T2 and T4. Start/stop of an auxiliary timer can be controlled locally or remotely. User’s Manual GPT_X41, V2.0 14-19 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Timers T2 and T4 in Counter Mode Counter mode for an auxiliary timer Tx is selected by setting bitfield TxM in register TxCON to 001B. In counter mode, an auxiliary timer can be clocked either by a transition at its external input line TxIN, or by a transition of timer T3’s toggle latch T3OTL. The event causing an increment or decrement of a timer can be a positive, a negative, or both a positive and a negative transition at either the respective input pin or at the toggle latch. Bitfield TxI in control register TxCON selects the triggering transition (see Table 14-5). TxIN T3 Toggle Latch 0 Edge MUX Count 1 Auxiliary Timer Tx TxIRQ Select TxI.2 TxR T3R TxI 0 MUX 1 TxRC TxUD 0 =1 MUX 1 Up/Down TxEUD TxUDE x = 2, 4 MCB05397 Figure 14-13 Block Diagram of an Auxiliary Timer in Counter Mode Table 14-5 GPT1 Auxiliary Timer (Counter Mode) Input Edge Selection T2I/T4I Triggering Edge for Counter Increment/Decrement X00 None. Counter Tx is disabled 001 Positive transition (rising edge) on TxIN 010 Negative transition (falling edge) on TxIN 011 Any transition (rising or falling edge) on TxIN 101 Positive transition (rising edge) of T3 toggle latch T3OTL 110 Negative transition (falling edge) of T3 toggle latch T3OTL 111 Any transition (rising or falling edge) of T3 toggle latch T3OTL Note: Only state transitions of T3OTL which are caused by the overflows/underflows of T3 will trigger the counter function of T2/T4. Modifications of T3OTL via software will NOT trigger the counter function of T2/T4. User’s Manual GPT_X41, V2.0 14-20 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units For counter operation, pin TxIN must be configured as input (the respective direction control bit DPx.y must be 0). The maximum input frequency allowed in counter mode depends on the selected prescaler value. To ensure that a transition of the count input signal applied to TxIN is recognized correctly, its level must be held high or low for a minimum number of module clock cycles before it changes. This information can be found in Section 14.1.5. Timers T2 and T4 in Incremental Interface Mode Incremental interface mode for an auxiliary timer Tx is selected by setting bitfield TxM in the respective register TxCON to 110B or 111B. In incremental interface mode, the two inputs associated with an auxiliary timer Tx (TxIN, TxEUD) are used to interface to an incremental encoder. Tx is clocked by each transition on one or both of the external input pins to provide 2-fold or 4-fold resolution of the encoder input. TxIN Edge Count Auxiliary Timer Tx Tx Edge Tx RDIR Overflow Underflow Select TxI TxR T3R 0 MUX 1 TxRC & TxUD 0 =1 TxEUD MUX Change Detect TxUDE TxCH DIR 1 Phase Detect _ >1 TxIRQ TxM & TxM TxIRDIS MCB05398 Figure 14-14 Block Diagram of an Auxiliary Timer in Incremental Interface Mode The operation of the auxiliary timers T2 and T4 in incremental interface mode and the interrupt generation are the same as described for the core timer T3. The descriptions, figures and tables apply accordingly. User’s Manual GPT_X41, V2.0 14-21 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Timer Concatenation Using the toggle bit T3OTL as a clock source for an auxiliary timer in counter mode concatenates the core timer T3 with the respective auxiliary timer. This concatenation forms either a 32-bit or a 33-bit timer/counter, depending on which transition of T3OTL is selected to clock the auxiliary timer. • • 32-bit Timer/Counter: If both a positive and a negative transition of T3OTL are used to clock the auxiliary timer, this timer is clocked on every overflow/underflow of the core timer T3. Thus, the two timers form a 32-bit timer. 33-bit Timer/Counter: If either a positive or a negative transition of T3OTL is selected to clock the auxiliary timer, this timer is clocked on every second overflow/underflow of the core timer T3. This configuration forms a 33-bit timer (16-bit core timer + T3OTL + 16-bit auxiliary timer). As long as bit T3OTL is not modified by software, it represents the state of the internal toggle latch, and can be regarded as part of the 33-bit timer. The count directions of the two concatenated timers are not required to be the same. This offers a wide variety of different configurations. T3, which represents the low-order part of the concatenated timer, can operate in timer mode, gated timer mode or counter mode in this case. T3IRQ fGPT T3IN Operating Mode Control BPS1 TxIN 0 MUX TxI Count Core Timer T3 T3R T3OUT Auxiliary Timer Tx TxIRQ Up/Down Edge Count 1 Select TxI.2 Toggle Latch TxI TxR T3R 0 MUX Up/Down 1 TxRC x = 2, 4 MCA05399 Figure 14-15 Concatenation of Core Timer T3 and an Auxiliary Timer User’s Manual GPT_X41, V2.0 14-22 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Auxiliary Timer in Reload Mode Reload Mode for an auxiliary timer Tx is selected by setting bitfield TxM in the respective register TxCON to 100B. In reload mode, the core timer T3 is reloaded with the contents of an auxiliary timer register, triggered by one of two different signals. The trigger signal is selected the same way as the clock source for counter mode (see Table 14-5), i.e. a transition of the auxiliary timer’s input TxIN or the toggle latch T3OTL may trigger the reload. Note: When programmed for reload mode, the respective auxiliary timer (T2 or T4) stops independently of its run flag T2R or T4R. The timer input pin TxIN must be configured as input if it shall trigger a reload operation. T3IRQ fGPT T3IN Operating Mode Control BPS1 TxIN 0 MUX TxI Count T3R Edge 1 Core Timer T3 Toggle Latch T3OUT Up/Down Reload TxIRQ Select TxI.2 TxI Auxiliary Timer Tx x = 2, 4 MCA05400 Figure 14-16 GPT1 Auxiliary Timer in Reload Mode Upon a trigger signal, T3 is loaded with the contents of the respective timer register (T2 or T4) and the respective interrupt request flag (T2IR or T4IR) is set. Note: When a T3OTL transition is selected for the trigger signal, the interrupt request flag T3IR will also be set upon a trigger, indicating T3’s overflow or underflow. Modifications of T3OTL via software will NOT trigger the counter function of T2/T4. To ensure that a transition of the reload input signal applied to TxIN is recognized correctly, its level must be held high or low for a minimum number of module clock cycles, detailed in Section 14.1.5. The reload mode triggered by the T3 toggle latch can be used in a number of different configurations. The following functions can be performed, depending on the selected active transition: User’s Manual GPT_X41, V2.0 14-23 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units • • • If both a positive and a negative transition of T3OTL are selected to trigger a reload, the core timer will be reloaded with the contents of the auxiliary timer each time it overflows or underflows. This is the standard reload mode (reload on overflow/underflow). If either a positive or a negative transition of T3OTL is selected to trigger a reload, the core timer will be reloaded with the contents of the auxiliary timer on every second overflow or underflow. Using this “single-transition” mode for both auxiliary timers allows to perform very flexible Pulse Width Modulation (PWM). One of the auxiliary timers is programmed to reload the core timer on a positive transition of T3OTL, the other is programmed for a reload on a negative transition of T3OTL. With this combination the core timer is alternately reloaded from the two auxiliary timers. Figure 14-17 shows an example for the generation of a PWM signal using the “singletransition” reload mechanism. T2 defines the high time of the PWM signal (reloaded on positive transitions) and T4 defines the low time of the PWM signal (reloaded on negative transitions). The PWM signal can be output on pin T3OUT if T3OE = 1. With this method, the high and low time of the PWM signal can be varied in a wide range. Note: The output toggle latch T3OTL is accessible via software and may be changed, if required, to modify the PWM signal. However, this will NOT trigger the reloading of T3. User’s Manual GPT_X41, V2.0 14-24 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Auxiliary Timer T2 T2IN 0 Edge MUX 1 Reload T2IRQ Select T2I.2 T2I T3IRQ fGPT T3IN Operating Mode Control BPS1 T4IN 0 MUX T3I Count T3R Edge 1 Core Timer T3 Toggle Latch T3OUT Up/Down Reload T4IRQ Select T4I.2 T4I Auxiliary Timer T4 MCA05401 Figure 14-17 GPT1 Timer Reload Configuration for PWM Generation Note: Although possible, selecting the same reload trigger event for both auxiliary timers should be avoided. In such a case, both reload registers would try to load the core timer at the same time. If this combination is selected, T2 is disregarded and the contents of T4 is reloaded. User’s Manual GPT_X41, V2.0 14-25 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Auxiliary Timer in Capture Mode Capture mode for an auxiliary timer Tx is selected by setting bitfield TxM in the respective register TxCON to 101B. In capture mode, the contents of the core timer T3 are latched into an auxiliary timer register in response to a signal transition at the respective auxiliary timer’s external input pin TxIN. The capture trigger signal can be a positive, a negative, or both a positive and a negative transition. The two least significant bits of bitfield TxI select the active transition (see Table 14-5). Bit 2 of TxI is irrelevant for capture mode and must be cleared (TxI.2 = 0). Note: When programmed for capture mode, the respective auxiliary timer (T2 or T4) stops independently of its run flag T2R or T4R. T3IRQ fGPT T3IN Operating Mode Control BPS1 T3I Count T3R Edge TxIN Core Timer T3 Up/Down Toggle Latch T3OUT to Ty Capture TxIRQ Select TxI Auxiliary Timer Tx x = 2, 4 y = 4, 2 MCA05402 Figure 14-18 GPT1 Auxiliary Timer in Capture Mode Upon a trigger (selected transition) at the corresponding input pin TxIN the contents of the core timer are loaded into the auxiliary timer register and the associated interrupt request flag TxIR will be set. For capture mode operation, the respective timer input pin TxIN must be configured as input. To ensure that a transition of the capture input signal applied to TxIN is recognized correctly, its level must be held high or low for a minimum number of module clock cycles, detailed in Section 14.1.5. User’s Manual GPT_X41, V2.0 14-26 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.1.5 GPT1 Clock Signal Control All actions within the timer block GPT1 are triggered by transitions of its basic clock. This basic clock is derived from the system clock by a basic block prescaler, controlled by bitfield BPS1 in register T3CON (see Figure 14-2). The count clock can be generated in two different ways: • • Internal count clock, derived from GPT1’s basic clock via a programmable prescaler, is used for (gated) timer mode. External count clock, derived from the timer’s input pin(s), is used for counter mode. For both ways, the basic clock determines the maximum count frequency and the timer’s resolution: Table 14-6 Basic Clock Selection for Block GPT1 Block Prescaler1) BPS1 = 01B BPS1 = 00B2) BPS1 = 11B BPS1 = 10B Prescaling Factor for GPT1: F(BPS1) F(BPS1) =4 F(BPS1) =8 F(BPS1) = 16 F(BPS1) = 32 Maximum External Count Frequency fGPT/8 fGPT/16 fGPT/32 fGPT/64 Input Signal Stable Time 4 × tGPT 8 × tGPT 16 × tGPT 32 × tGPT 1) Please note the non-linear encoding of bitfield BPS1. 2) Default after reset. Internal Count Clock Generation In timer mode and gated timer mode, the count clock for each GPT1 timer is derived from the GPT1 basic clock by a programmable prescaler, controlled by bitfield TxI in the respective timer’s control register TxCON. The count frequency fTx for a timer Tx and its resolution rTx are scaled linearly with lower clock frequencies, as can be seen from the following formula: f GPT f Tx = -------------------------------------------<Txl> F ( BPS1 ) × 2 <Txl> ( BPS1 ) × 2 --------------------------------------------r Tx [ µs ] = F f GPT [ MHz ] (14.1) The effective count frequency depends on the common module clock prescaler factor F(BPS1) as well as on the individual input prescaler factor 2<TxI>. Table 14-7 summarizes the resulting overall divider factors for a GPT1 timer that result from these cascaded prescalers. Table 14-8 lists a timer’s parameters (such as count frequency, resolution, and period) resulting from the selected overall prescaler factor and the applied system frequency. Note that some numbers may be rounded. User’s Manual GPT_X41, V2.0 14-27 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Table 14-7 GPT1 Overall Prescaler Factors for Internal Count Clock Individual Prescaler for Tx Common Prescaler for Module Clock1) BPS1 = 01B BPS1 = 00B BPS1 = 11B BPS1 = 10B TxI = 000B 4 8 16 32 TxI = 001B 8 16 32 64 TxI = 010B 16 32 64 128 TxI = 011B 32 64 128 256 TxI = 100B 64 128 256 512 TxI = 101B 128 256 512 1024 TxI = 110B 256 512 1024 2048 TxI = 111B 512 1024 2048 4096 1) Please note the non-linear encoding of bitfield BPS1. Table 14-8 GPT1 Timer Parameters System Clock = 10 MHz Overall Divider Factor System Clock = 40 MHz Frequency Resolution Period 2.5 MHz 400 ns 26.21 ms 4 10.0 MHz 100 ns 6.55 ms 1.25 MHz 800 ns 52.43 ms 8 5.0 MHz 200 ns 13.11 ms 625.0 kHz 1.6 µs 104.9 ms 16 2.5 MHz 400 ns 26.21 ms 312.5 kHz 3.2 µs 209.7 ms 32 1.25 MHz 800 ns 52.43 ms 156.25 kHz 6.4 µs 419.4 ms 64 625.0 kHz 1.6 µs 104.9 ms 78.125 kHz 12.8 µs 838.9 ms 128 312.5 kHz 3.2 µs 209.7 ms 39.06 kHz 25.6 µs 1.678 s 256 156.25 kHz 6.4 µs 419.4 ms 19.53 kHz 51.2 µs 3.355 s 512 78.125 kHz 12.8 µs 838.9 ms 9.77 kHz 102.4 µs 6.711 s 1024 39.06 kHz 25.6 µs 1.678 s 4.88 kHz 204.8 µs 13.42 s 2048 19.53 kHz 51.2 µs 3.355 s 2.44 kHz 409.6 µs 26.84 s 4096 9.77 kHz 102.4 µs 6.711 s User’s Manual GPT_X41, V2.0 14-28 Frequency Resolution Period V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units External Count Clock Input The external input signals of the GPT1 block are sampled with the GPT1 basic clock (see Figure 14-2). To ensure that a signal is recognized correctly, its current level (high or low) must be held active for at least one complete sampling period, before changing. A signal transition is recognized if two subsequent samples of the input signal represent different levels. Therefore, a minimum of two basic clock periods are required for the sampling of an external input signal. Thus, the maximum frequency of an input signal must not be higher than half the basic clock. Table 14-9 summarizes the resulting requirements for external GPT1 input signals. Table 14-9 GPT1 External Input Signal Limits System Clock = 10 MHz Input Max. Input Min. Level Frequ. Frequency Hold Time Factor 1.25 MHz 400 ns 625.0 kHz 800 ns 312.5 kHz 1.6 µs 156.25 kHz 3.2 µs fGPT/8 fGPT/16 fGPT/32 fGPT/64 System Clock = 40 MHz GPT1 Input Divider Phase Max. Input Min. Level BPS1 Duration Frequency Hold Time 01B 4 × tGPT 5.0 MHz 100 ns 00B 8 × tGPT 2.5 MHz 200 ns 11B 16 × tGPT 1.25 MHz 400 ns 10B 32 × tGPT 625.0 kHz 800 ns These limitations are valid for all external input signals to GPT1, including the external count signals in counter mode and incremental interface mode, the gate input signals in gated timer mode, and the external direction signals. 14.1.6 GPT1 Timer Registers GPT12E_Tx Timer x Count Register 15 14 13 12 11 SFR (FE4xH/2yH) 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 Txvalue rwh Table 14-10 GPT1 Timer Register Locations Timer Register Physical Address 8-Bit Address T3 FE42H 21H T2 FE40H 20H T4 FE44H 22H User’s Manual GPT_X41, V2.0 14-29 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.1.7 Interrupt Control for GPT1 Timers When a timer overflows from FFFFH to 0000H (when counting up), or when it underflows from 0000H to FFFFH (when counting down), its interrupt request flag (T2IR, T3IR or T4IR) in register TxIC will be set. This will cause an interrupt to the respective timer interrupt vector (T2INT, T3INT or T4INT) or trigger a PEC service, if the respective interrupt enable bit (T2IE, T3IE or T4IE in register TxIC) is set. There is an interrupt control register for each of the three timers. GPT12E_T2IC Timer 2 Intr. Ctrl. Reg. SFR (FF60H/B0H) 15 14 13 12 11 10 9 - - - - - - - - - - - - - - GPT12E_T3IC Timer 3 Intr. Ctrl. Reg. 8 7 6 Reset Value: - - 00H 5 GPX T2IR T2IE rw rwh 4 3 14 13 12 11 10 9 - - - - - - - - - - - - - - GPT12E_T4IC Timer 4 Intr. Ctrl. Reg. 8 7 rw rw Reset Value: - - 00H 5 GPX T3IR T3IE rw rwh 4 3 14 13 12 11 10 9 - - - - - - - - - - - - - - 8 7 GPX T4IR T4IE rw rwh rw 1 0 GLVL rw rw rw 6 2 ILVL SFR (FF64H/B2H) 15 0 GLVL rw 6 1 ILVL SFR (FF62H/B1H) 15 2 Reset Value: - - 00H 5 4 3 2 1 0 ILVL GLVL rw rw Note: Please refer to the general Interrupt Control Register description for an explanation of the control fields. User’s Manual GPT_X41, V2.0 14-30 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.2 Timer Block GPT2 From a programmer’s point of view, the GPT2 block is represented by a set of SFRs as summarized below. Those portions of port and direction registers which are used for alternate functions by the GPT2 block are shaded. Data Registers Control Registers Port Registers Interrupt Control T5 T5CON T5IC ODP3 T6 T6CON T6IC DP3 CRIC P3 CAPREL SYSCON3 E ALTSEL0P3 E P5 P5DIDIS Tx CAPREL TxCON TxIC SYSCON3 GPT2 Timer x Register GPT2 Capture/Reload Register GPT2 Timer x Control Register GPT2 Timer x Interrupt Ctrl. Reg. System Ctrl. Reg. 3 (Per. Mgmt.) ODP3 DP3 P3 ALTSEL0P3 P5 P5DIDIS Port 3 Open Drain Control Register Port 3 Direction Control Register Port 3 Data Register Port 3 Alternate Output Select Reg. Port 5 Data Register Port 5 Digital Input Disable Reg. mc_gpt0107_registers.vsd Figure 14-19 SFRs Associated with Timer Block GPT2 Both timers of block GPT2 (T5, T6) can run in one of 3 basic modes: Timer Mode, Gated Timer Mode, or Counter Mode. All timers can count up or down. Each timer of GPT2 is controlled by a separate control register TxCON. Each timer has an input pin TxIN (alternate pin function) associated with it, which serves as the gate control in gated timer mode, or as the count input in counter mode. The count direction (up/down) may be programmed via software or may be dynamically altered by a signal at the External Up/Down control input TxEUD (alternate pin function). An overflow/underflow of core timer T6 is indicated by the Output Toggle Latch T6OTL, whose state may be output on the associated pin T6OUT (alternate pin function). The auxiliary timer T5 may additionally be concatenated with core timer T6 (through T6OTL). The Capture/Reload register CAPREL can be used to capture the contents of timer T5, or to reload timer T6. A special mode facilitates the use of register CAPREL for both functions at the same time. This mode allows frequency multiplication. The capture function is triggered by the input pin CAPIN, or by GPT1 timer’s T3 input lines T3IN and T3EUD. The reload function is triggered by an overflow or underflow of timer T6. Overflows/underflows of timer T6 may also clock the timers of the CAPCOM units. The current contents of each timer can be read or modified by the CPU by accessing the corresponding timer count registers T5 or T6, located in the non-bitaddressable SFR User’s Manual GPT_X41, V2.0 14-31 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units space (see Section 14.2.7). When any of the timer registers is written to by the CPU in the state immediately preceding a timer increment, decrement, reload, or capture operation, the CPU write operation has priority in order to guarantee correct results. The interrupts of GPT2 are controlled through the Interrupt Control Registers TxIC. These registers are not part of the GPT2 block. The input and output lines of GPT2 are connected to pins of Ports P3 and P5. The control registers for the port functions are located in the respective port modules. Note: The timing requirements for external input signals can be found in Section 14.2.6, Section 14.3 summarizes the module interface signals, including pins. T6CON.BPS2 f GPT 2n: 1 Basic clock Interrupt Request (T5IR) GPT2 Timer T5 T5IN T5EUD T5 Mode Control U/D Clear Capture CAPIN T3IN/ T3EUD CAPREL Mode Control GPT2 CAPREL Interrupt Request (CRIR) Reload Interrupt Request (T6IR) Clear Toggle FF GPT2 Timer T6 T6IN T6 Mode Control U/D T6OTL T6OUT T6OUF T6EUD mc_gpt0108_bldiax4.vsd Figure 14-20 GPT2 Block Diagram User’s Manual GPT_X41, V2.0 14-32 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.2.1 GPT2 Core Timer T6 Control The current contents of the core timer T6 are reflected by its count register T6. This register can also be written to by the CPU, for example, to set the initial start value. The core timer T6 is configured and controlled via its bitaddressable control register T6CON. GPT12E_T6CON Timer 6 Control Register 15 14 13 12 11 T6 T6 SR CLR - BPS2 rw - rw rw SFR (FF48H/A4H) 10 9 8 7 T6 T6 T6 T6 OTL OE UDE UD rwh rw rw rw 6 Reset Value: 0000H 5 4 3 2 1 T6R T6M T6I rw rw rw 0 Field Bits Type Description T6SR 15 rw Timer 6 Reload Mode Enable 0 Reload from register CAPREL Disabled 1 Reload from register CAPREL Enabled T6CLR 14 rw Timer T6 Clear Enable Bit 0 Timer T6 is not cleared on a capture event 1 Timer T6 is cleared on a capture event BPS2 [12:11] rw GPT2 Block Prescaler Control Selects the basic clock for block GPT2 (see also Section 14.2.6) 00 fGPT/4 01 fGPT/2 10 fGPT/16 11 fGPT/8 T6OTL 10 rwh Timer T6 Overflow Toggle Latch Toggles on each overflow/underflow of T6. Can be set or reset by software (see separate description) T6OE 9 rw Overflow/Underflow Output Enable 0 Alternate Output Function Disabled 1 State of T6 toggle latch is output on pin T6OUT T6UDE 8 rw Timer T6 External Up/Down Enable1) 0 Input T6EUD is disconnected 1 Direction influenced by input T6EUD User’s Manual GPT_X41, V2.0 14-33 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Field Bits Type Description T6UD 7 rw Timer T6 Up/Down Control1) 0 Timer T6 counts up 1 Timer T6 counts down T6R 6 rw Timer T6 Run Bit 0 Timer T6 stops 1 Timer T6 runs T6M [5:3] rw Timer T6 Mode Control (Basic Operating Mode) 000 Timer Mode 001 Counter Mode 010 Gated Timer Mode with gate active low 011 Gated Timer Mode with gate active high 100 Reserved. Do not use this combination. 101 Reserved. Do not use this combination. 110 Reserved. Do not use this combination. 111 Reserved. Do not use this combination. T6I [2:0] rw Timer T6 Input Parameter Selection Depends on the operating mode, see respective sections for encoding: Table 14-16 for Timer Mode and Gated Timer Mode Table 14-12 for Counter Mode 1) See Table 14-11 for encoding of bits T6UD and T6UDE. User’s Manual GPT_X41, V2.0 14-34 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Timer T6 Run Control The core timer T6 can be started or stopped by software through bit T6R (timer T6 run bit). This bit is relevant in all operating modes of T6. Setting bit T6R will start the timer, clearing bit T6R stops the timer. In gated timer mode, the timer will only run if T6R = 1 and the gate is active (high or low, as programmed). Note: When bit T5RC in timer control register T5CON is set, bit T6R will also control (start and stop) the Auxiliary Timer T5. Count Direction Control The count direction of the GPT2 timers (core timer and auxiliary timer) can be controlled either by software or by the external input pin TxEUD (Timer Tx External Up/Down Control Input). These options are selected by bits TxUD and TxUDE in the respective control register TxCON. When the up/down control is provided by software (bit TxUDE = 0), the count direction can be altered by setting or clearing bit TxUD. When bit TxUDE = 1, pin TxEUD is selected to be the controlling source of the count direction. However, bit TxUD can still be used to reverse the actual count direction, as shown in Table 14-11. The count direction can be changed regardless of whether or not the timer is running. Table 14-11 GPT2 Timer Count Direction Control Pin TxEUD Bit TxUDE Bit TxUD Count Direction X 0 0 Count Up X 0 1 Count Down 0 1 0 Count Up 1 1 0 Count Down 0 1 1 Count Down 1 1 1 Count Up User’s Manual GPT_X41, V2.0 14-35 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Timer 6 Output Toggle Latch The overflow/underflow signal of timer T6 is connected to a block named ‘Toggle Latch’, shown in the timer mode diagrams. Figure 14-21 illustrates the details of this block. An overflow or underflow of T6 will clock two latches: The first latch represents bit T6OTL in control register T6CON. The second latch is an internal latch toggled by T6OTL’s output. Both latch outputs are connected to the input control block of the auxiliary timer T5. The output level of the shadow latch will match the output level of T6OTL, but is delayed by one clock cycle. When the T6OTL value changes, this will result in a temporarily different output level from T6OTL and the shadow latch, which can trigger the selected count event in T5. When software writes to T6OTL, both latches are set or cleared simultaneously. In this case, both signals to the auxiliary timers carry the same level and no edge will be detected. Bit T6OE (overflow/underflow output enable) in register T6CON enables the state of T6OTL to be monitored via an external pin T6OUT. When T6OTL is linked to an external port pin (must be configured as output), T6OUT can be used to control external HW. If T6OE = 1, pin T6OUT outputs the state of T6OTL. If T6OE = 0, pin T6OUT outputs a high level (while it selects the timer output signal). As can be seen from Figure 14-21, when latch T6OTL is modified by software to determine the state of the output line, also the internal shadow latch is set or cleared accordingly. Therefore, no trigger condition is detected by T5 in this case. S et/C lear (S W ) 1 C ore Tim er O verflow / U nd erflow 1 Shadow Latch TxO TL T o g g le L a tch L o g ic 0 MUX TxO E T xO U T T o P ort Logic T o A ux. Tim er Input Logic m c_ g p t0 1 0 6 _ o tl.vsd Figure 14-21 Block Diagram of the Toggle Latch Logic of Core Timer T6 Note: T6 is also used to clock the timers in the CAPCOM units. For this purpose, there is a direct internal connection between the T6 overflow/underflow line and the CAPCOM timers (signal T6OUF). User’s Manual GPT_X41, V2.0 14-36 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.2.2 GPT2 Core Timer T6 Operating Modes Timer 6 in Timer Mode Timer mode for the core timer T6 is selected by setting bitfield T6M in register T6CON to 000B. In this mode, T6 is clocked with the module’s input clock fGPT divided by two programmable prescalers controlled by bitfields BPS2 and T6I in register T6CON. Please see Section 14.2.6 for details on the input clock options. T6IRQ fGPT Prescaler fT6 Count Core Timer T6 Toggle Latch T6OUT to T5/ BPS2 T6I CAPREL T6R T6OUF T6UD 0 =1 MUX 1 Up/Down T6EUD T6UDE MCB05403_X4 Figure 14-22 Block Diagram of Core Timer T6 in Timer Mode User’s Manual GPT_X41, V2.0 14-37 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Gated Timer Mode Gated timer mode for the core timer T6 is selected by setting bitfield T6M in register T6CON to 010B or 011B. Bit T6M.0 (T6CON.3) selects the active level of the gate input. The same options for the input frequency are available in gated timer mode as in timer mode (see Section 14.2.6). However, the input clock to the timer in this mode is gated by the external input pin T6IN (Timer T6 External Input). To enable this operation, the associated pin T6IN must be configured as input (the corresponding direction control bit must contain 0). T6IRQ fGPT Prescaler BPS2 Gate Ctrl. fT6 Count Core Timer T6 Toggle Latch T6OUT to T5, T6I T6R T6IN Clear CAPREL T6OUF T6UD 0 =1 MUX 1 Up/Down T6EUD T6UDE MCB05404_X4 Figure 14-23 Block Diagram of Core Timer T6 in Gated Timer Mode If T6M = 010B, the timer is enabled when T6IN shows a low level. A high level at this line stops the timer. If T6M = 011B, line T6IN must have a high level in order to enable the timer. Additionally, the timer can be turned on or off by software using bit T6R. The timer will only run if T6R is 1 and the gate is active. It will stop if either T6R is 0 or the gate is inactive. Note: A transition of the gate signal at pin T6IN does not cause an interrupt request. User’s Manual GPT_X41, V2.0 14-38 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Counter Mode Counter mode for the core timer T6 is selected by setting bitfield T6M in register T6CON to 001B. In counter mode, timer T6 is clocked by a transition at the external input pin T6IN. The event causing an increment or decrement of the timer can be a positive, a negative, or both a positive and a negative transition at this line. Bitfield T6I in control register T6CON selects the triggering transition (see Table 14-12). T6IRQ Edge Count T6IN Core Timer T6 Toggle Latch T6OUT Select to T5, T6R T6I Clear CAPREL T6OUF T6UD 0 =1 MUX 1 Up/Down T6EUD T6UDE MCB05405_X4 Figure 14-24 Block Diagram of Core Timer T6 in Counter Mode Table 14-12 GPT2 Core Timer T6 (Counter Mode) Input Edge Selection T6I Triggering Edge for Counter Increment/Decrement 000 None. Counter T6 is disabled 001 Positive transition (rising edge) on T6IN 010 Negative transition (falling edge) on T6IN 011 Any transition (rising or falling edge) on T6IN 1XX Reserved. Do not use this combination For counter mode operation, pin T6IN must be configured as input (the respective direction control bit DPx.y must be 0). The maximum input frequency allowed in counter mode depends on the selected prescaler value. To ensure that a transition of the count input signal applied to T6IN is recognized correctly, its level must be held high or low for a minimum number of module clock cycles before it changes. This information can be found in Section 14.2.6. User’s Manual GPT_X41, V2.0 14-39 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.2.3 GPT2 Auxiliary Timer T5 Control Auxiliary timer T5 can be configured for timer mode, gated timer mode, or counter mode with the same options for the timer frequencies and the count signal as the core timer T6. In addition to these 3 counting modes, the auxiliary timer can be concatenated with the core timer. The contents of T5 may be captured to register CAPREL upon an external or an internal trigger. The start/stop function of the auxiliary timers can be remotely controlled by the T6 run control bit. Several timers may thus be controlled synchronously. The current contents of the auxiliary timer are reflected by its count register T5. This register can also be written to by the CPU, for example, to set the initial start value. The individual configurations for timer T5 are determined by its bitaddressable control register T5CON. Some bits in this register also control the function of the CAPREL register. Note that functions which are present in all timers of block GPT2 are controlled in the same bit positions and in the same manner in each of the specific control registers. Note: The auxiliary timer has no output toggle latch and no alternate output function. GPT12E_T5CON Timer 5 Control Register 15 14 13 12 SFR (FF46H/A3H) 11 10 T5 T5 SC CLR CI T5 CC CT3 rw rw rw rw rw 9 8 7 T5 T5 T5 RC UDE UD rw rw rw 6 Reset Value: 0000H 5 4 3 2 1 T5R T5M T5I rw rw rw Field Bits Type Description T5SC 15 rw Timer 5 Capture Mode Enable 0 Capture into register CAPREL Disabled 1 Capture into register CAPREL Enabled T5CLR 14 rw Timer T5 Clear Enable Bit 0 Timer T5 is not cleared on a capture event 1 Timer T5 is cleared on a capture event CI [13:12] rw User’s Manual GPT_X41, V2.0 0 Register CAPREL Capture Trigger Selection (depending on bit CT3) 00 Capture disabled 01 Positive transition (rising edge) on CAPIN or any transition on T3IN 10 Negative transition (falling edge) on CAPIN or any transition on T3EUD 11 Any transition (rising or falling edge) on CAPIN or any transition on T3IN or T3EUD 14-40 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Field Bits Type Description T5CC 11 rw Timer T5 Capture Correction 0 T5 is just captured without any correction 1 T5 is decremented by 1 before being captured CT3 10 rw Timer T3 Capture Trigger Enable 0 Capture trigger from input line CAPIN 1 Capture trigger from T3 input lines T3IN and/or T3EUD T5RC 9 rw Timer T5 Remote Control 0 Timer T5 is controlled by its own run bit T5R 1 Timer T5 is controlled by the run bit T6R of core timer 6, not by bit T5R T5UDE 8 rw Timer T5 External Up/Down Enable1) 0 Input T5EUD is disconnected 1 Direction influenced by input T5EUD T5UD 7 rw Timer T5 Up/Down Control1) 0 Timer T5 counts up 1 Timer T5 counts down T5R 6 rw Timer T5 Run Bit 0 Timer T5 stops 1 Timer T5 runs Note: This bit only controls timer T5 if bit T5RC = 0. T5M [5:3] rw Timer T5 Mode Control (Basic Operating Mode) 000 Timer Mode 001 Counter Mode 010 Gated Timer Mode with gate active low 011 Gated Timer Mode with gate active high 1XX Reserved. Do not use this combination T5I [2:0] rw Timer T5 Input Parameter Selection Depends on the operating mode, see respective sections for encoding: Table 14-16 for Timer Mode and Gated Timer Mode Table 14-12 for Counter Mode 1) See Table 14-11 for encoding of bits T5UD and T5UDE. User’s Manual GPT_X41, V2.0 14-41 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Timer T5 Run Control The auxiliary timer T5 can be started or stopped by software in two different ways: • • Through the associated timer run bit (T5R). In this case it is required that the respective control bit T5RC = 0. Through the core timer’s run bit (T6R). In this case the respective remote control bit must be set (T5RC = 1). The selected run bit is relevant in all operating modes of T5. Setting the bit will start the timer, clearing the bit stops the timer. In gated timer mode, the timer will only run if the selected run bit is set and the gate is active (high or low, as programmed). Note: If remote control is selected T6R will start/stop timer T6 and the auxiliary timer T5 synchronously. 14.2.4 GPT2 Auxiliary Timer T5 Operating Modes The operation of the auxiliary timer in the basic operating modes is almost identical with the core timer’s operation, with very few exceptions. Additionally, some combined operating modes can be selected. Timer T5 in Timer Mode Timer Mode for the auxiliary timer T5 is selected by setting its bitfield T5M in register T5CON to 000B. fGPT fT5 Prescaler BPS2 Count T5I Auxiliary Timer T5 T5IRQ Clear T5R T6R 0 MUX 1 T5RC T5UD 0 =1 MUX 1 Up/Down T5EUD T5UDE MCB05406_X4 Figure 14-25 Block Diagram of Auxiliary Timer T5 in Timer Mode User’s Manual GPT_X41, V2.0 14-42 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Timer T5 in Gated Timer Mode Gated timer mode for the auxiliary timer T5 is selected by setting bitfield T5M in register T5CON to 010B or 011B. Bit T5M.0 (T5CON.3) selects the active level of the gate input. Note: A transition of the gate signal at line T5IN does not cause an interrupt request. fGPT Prescaler BPS2 Gate Ctrl. fT5 Count Auxiliary Timer T5 T5IRQ T5I T5IN Clear T5R T6R 0 MUX 1 T5RC T5UD 0 =1 MUX 1 Up/Down T5EUD T5UDE MCB05407_X4 Figure 14-26 Block Diagram of Auxiliary Timer T5 in Gated Timer Mode Note: There is no output toggle latch for T5. Start/stop of the auxiliary timer can be controlled locally or remotely. Timer T5 in Counter Mode Counter mode for auxiliary timer T5 is selected by setting bitfield T5M in register T5CON to 001B. In counter mode, the auxiliary timer can be clocked either by a transition at its external input line T5IN, or by a transition of timer T6’s toggle latch T6OTL. The event causing an increment or decrement of a timer can be a positive, a negative, or both a positive and a negative transition at either the respective input pin or at the toggle latch. Bitfield T5I in control register T5CON selects the triggering transition (see Table 14-13). User’s Manual GPT_X41, V2.0 14-43 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units T5IN T6 Toggle Latch 0 Edge MUX Count 1 Auxiliary Timer T5 T5IRQ Select T5I.2 T5R T6R T5I 0 Clear MUX 1 T5RC T5UD 0 =1 MUX Up/Down 1 T5EUD T5UDE MCB05408_X4 Figure 14-27 Block Diagram of Auxiliary Timer T5 in Counter Mode Table 14-13 GPT2 Auxiliary Timer (Counter Mode) Input Edge Selection T5I Triggering Edge for Counter Increment/Decrement X00 None. Counter T5 is disabled 001 Positive transition (rising edge) on T5IN 010 Negative transition (falling edge) on T5IN 011 Any transition (rising or falling edge) on T5IN 101 Positive transition (rising edge) of T6 toggle latch T6OTL 110 Negative transition (falling edge) of T6 toggle latch T6OTL 111 Any transition (rising or falling edge) of T6 toggle latch T6OTL Note: Only state transitions of T6OTL which are caused by the overflows/underflows of T6 will trigger the counter function of T5. Modifications of T6OTL via software will NOT trigger the counter function of T5. For counter operation, pin T5IN must be configured as input (the respective direction control bit DPx.y must be 0). The maximum input frequency allowed in counter mode depends on the selected prescaler value. To ensure that a transition of the count input signal applied to T5IN is recognized correctly, its level must be held high or low for a minimum number of module clock cycles before it changes. This information can be found in Section 14.2.6. User’s Manual GPT_X41, V2.0 14-44 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Timer Concatenation Using the toggle bit T6OTL as a clock source for the auxiliary timer in counter mode concatenates the core timer T6 with the auxiliary timer T5. This concatenation forms either a 32-bit or a 33-bit timer/counter, depending on which transition of T6OTL is selected to clock the auxiliary timer. • • 32-bit Timer/Counter: If both a positive and a negative transition of T6OTL are used to clock the auxiliary timer, this timer is clocked on every overflow/underflow of the core timer T6. Thus, the two timers form a 32-bit timer. 33-bit Timer/Counter: If either a positive or a negative transition of T6OTL is selected to clock the auxiliary timer, this timer is clocked on every second overflow/underflow of the core timer T6. This configuration forms a 33-bit timer (16-bit core timer + T6OTL + 16-bit auxiliary timer). As long as bit T6OTL is not modified by software, it represents the state of the internal toggle latch, and can be regarded as part of the 33-bit timer. The count directions of the two concatenated timers are not required to be the same. This offers a wide variety of different configurations. T6, which represents the low-order part of the concatenated timer, can operate in timer mode, gated timer mode or counter mode in this case. T6IRQ fGPT T6IN Operating Mode Control BPS2 T5IN 0 MUX T6I Count Core Timer T6 T6R Clear Edge T6OUT Auxiliary Timer T5 T5IRQ Up/Down Count 1 Toggle Latch Select T5I.2 T5I T5R T6R 0 MUX Clear Up/Down 1 T5RC MCA05409 Figure 14-28 Concatenation of Core Timer T6 and Auxiliary Timer T5 User’s Manual GPT_X41, V2.0 14-45 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.2.5 GPT2 Register CAPREL Operating Modes The Capture/Reload register CAPREL can be used to capture the contents of timer T5, or to reload timer T6. A special mode facilitates the use of register CAPREL for both functions at the same time. This mode allows frequency multiplication. The capture function is triggered by the input pin CAPIN, or by GPT1 timer’s T3 input lines T3IN and T3EUD. The reload function is triggered by an overflow or underflow of timer T6. In addition to the capture function, the capture trigger signal can also be used to clear the contents of timers T5 and T6 individually. The functions of register CAPREL are controlled via several bit(field)s in the timer control registers T5CON and T6CON. GPT2 Capture/Reload Register CAPREL in Capture Mode Capture mode for register CAPREL is selected by setting bit T5SC in control register T5CON (set bitfield CI in register T5CON to a non-zero value to select a trigger signal). In capture mode, the contents of the auxiliary timer T5 are latched into register CAPREL in response to a signal transition at the selected external input pin(s). Bit CT3 selects the external input line CAPIN or the input lines T3IN and/or T3EUD of GPT1 timer T3 as the source for a capture trigger. Either a positive, a negative, or both a positive and a negative transition at line CAPIN can be selected to trigger the capture function, or transitions on input T3IN or input T3EUD or both inputs, T3IN and T3EUD. The active edge is controlled by bitfield CI in register T5CON. Table 14-14 summarizes these options. Table 14-14 CAPREL Register Input Edge Selection CT3 CI Triggering Signal/Edge for Capture Mode X 00 None. Capture Mode is disabled. 0 01 Positive transition (rising edge) on CAPIN. 0 10 Negative transition (falling edge) on CAPIN. 0 11 Any transition (rising or falling edge) on CAPIN. 1 01 Any transition (rising or falling edge) on T3IN. 1 10 Any transition (rising or falling edge) on T3EUD. 1 11 Any transition (rising or falling edge) on T3IN or T3EUD. User’s Manual GPT_X41, V2.0 14-46 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Count Clock Auxiliary Timer T5 T5IRQ Clear Up/Down Edge CAPIN T5CLR Select 0 MUX 1 T3IN T3EUD Signal Select CT3 Capture Correction Capture T5SC T5CC CAPREL Register CI CRIRQ Clear T6 T6CLR MCA05410 Figure 14-29 GPT2 Register CAPREL in Capture Mode When a selected trigger is detected, the contents of the auxiliary timer T5 are latched into register CAPREL and the interrupt request line CRIRQ is activated. The same event can optionally clear timer T5 and/or timer T6. This option is enabled by bit T5CLR in register T5CON and bit T6CLR in register T6CON, respectively. If TxCLR = 0 the contents of timer Tx is not affected by a capture. If TxCLR = 1 timer Tx is cleared after the current timer T5 value has been latched into register CAPREL. Note: Bit T5SC only controls whether or not a capture is performed. If T5SC is cleared the external input pin(s) can still be used to clear timer T5 and/or T6, or as external interrupt input(s). This interrupt is controlled by the CAPREL interrupt control register CRIC. When capture triggers T3IN or T3EUD are enabled (CT3 = 1), register CAPREL captures the contents of T5 upon transitions of the selected input(s). These values can be used to measure T3’s input signals. This is useful, for example, when T3 operates in User’s Manual GPT_X41, V2.0 14-47 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units incremental interface mode, in order to derive dynamic information (speed, acceleration) from the input signals. For capture mode operation, the selected pins CAPIN, T3IN, or T3EUD must be configured as input. To ensure that a transition of a trigger input signal applied to one of these inputs is recognized correctly, its level must be held high or low for a minimum number of module clock cycles, detailed in Section 14.2.6. GPT2 Capture/Reload Register CAPREL in Reload Mode Reload mode for register CAPREL is selected by setting bit T6SR in control register T6CON. In reload mode, the core timer T6 is reloaded with the contents of register CAPREL, triggered by an overflow or underflow of T6. This will not activate the interrupt request line CRIRQ associated with the CAPREL register. However, interrupt request line T6IRQ will be activated, indicating the overflow/underflow of T6. CAPREL Register Reload T6SR T6IRQ Count Clock Core Timer T6 Up/Down Toggle Latch T6OUT T6OUF to T5 MCA05411 Figure 14-30 GPT2 Register CAPREL in Reload Mode User’s Manual GPT_X41, V2.0 14-48 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units GPT2 Capture/Reload Register CAPREL in Capture-And-Reload Mode Since the reload function and the capture function of register CAPREL can be enabled individually by bits T5SC and T6SR, the two functions can be enabled simultaneously by setting both bits. This feature can be used to generate an output frequency that is a multiple of the input frequency. Count Clock Auxiliary Timer T5 T5IRQ Clear Up/Down Edge CAPIN T5CLR Select 0 MUX 1 T3IN T3EUD Capture Correction Capture T5CC Edge CT3 T5SC CAPREL Register Select CI CRIRQ Reload Clear T6SR T6IRQ T6CLR Count Clock Core Timer T6 Toggle Latch Up/Down T6OUT T6OUF to T5 MCA05412 Figure 14-31 GPT2 Register CAPREL in Capture-And-Reload Mode This combined mode can be used to detect consecutive external events which may occur aperiodically, but where a finer resolution, that means, more ‘ticks’ within the time between two external events is required. For this purpose, the time between the external events is measured using timer T5 and the CAPREL register. Timer T5 runs in timer mode counting up with a frequency of e.g. fGPT/32. The external events are applied to pin CAPIN. When an external event occurs, User’s Manual GPT_X41, V2.0 14-49 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units the contents of timer T5 are latched into register CAPREL and timer T5 is cleared (T5CLR = 1). Thus, register CAPREL always contains the correct time between two events, measured in timer T5 increments. Timer T6, which runs in timer mode counting down with a frequency of e.g. fGPT/4, uses the value in register CAPREL to perform a reload on underflow. This means, the value in register CAPREL represents the time between two underflows of timer T6, now measured in timer T6 increments. Since (in this example) timer T6 runs 8 times faster than timer T5, it will underflow 8 times within the time between two external events. Thus, the underflow signal of timer T6 generates 8 ‘ticks’. Upon each underflow, the interrupt request line T6IRQ will be activated and bit T6OTL will be toggled. The state of T6OTL may be output on pin T6OUT. This signal has 8 times more transitions than the signal which is applied to pin CAPIN. Note: The underflow signal of Timer T6 can furthermore be used to clock one or more of the timers of the CAPCOM units, which gives the user the possibility to set compare events based on a finer resolution than that of the external events. This connection is accomplished via signal T6OUF. Capture Correction A certain deviation of the output frequency is generated by the fact that timer T5 will count actual time units (e.g. T5 running at 1 MHz will count up to the value 64H/100D for a 10 kHz input signal), while T6OTL will only toggle upon an underflow of T6 (i.e. the transition from 0000H to FFFFH). In the above mentioned example, T6 would count down from 64H, so the underflow would occur after 101 timing ticks of T6. The actual output frequency then is 79.2 kHz, instead of the expected 80 kHz. This deviation can be compensated for by activating the Capture Correction (T5CC = 1). If capture correction is active, the contents of T5 are decremented by 1 before being captured. The described deviation is eliminated (in the example, T5 would count up to the value 64H/100D, but the CAPREL register will capture the decremented value 63H/99D, T6 would count exactly 100 ticks, and the output frequency is 80 kHz). User’s Manual GPT_X41, V2.0 14-50 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.2.6 GPT2 Clock Signal Control All actions within the timer block GPT2 are triggered by transitions of its basic clock. This basic clock is derived from the system clock by a basic block prescaler, controlled by bitfield BPS2 in register T6CON (see Figure 14-20). The count clock can be generated in two different ways: • • Internal count clock, derived from GPT2’s basic clock via a programmable prescaler, is used for (gated) timer mode. External count clock, derived from the timer’s input pin(s), is used for counter mode. For both ways, the basic clock determines the maximum count frequency and the timer’s resolution: Table 14-15 Basic Clock Selection for Block GPT2 Block Prescaler1) BPS2 = 00B2) BPS2 = 11B BPS2 = 10B Prescaling Factor F(BPS2) for GPT2: F(BPS2) = 2 F(BPS2) =4 F(BPS2) =8 F(BPS2) = 16 Maximum External fGPT/4 Count Frequency fGPT/8 fGPT/16 fGPT/32 4 × tGPT 8 × tGPT 16 × tGPT Input Signal Stable Time BPS2 = 01B 2 × tGPT 1) Please note the non-linear encoding of bitfield BPS2. 2) Default after reset. Internal Count Clock Generation In timer mode and gated timer mode, the count clock for each GPT2 timer is derived from the GPT2 basic clock by a programmable prescaler, controlled by bitfield TxI in the respective timer’s control register TxCON. The count frequency fTx for a timer Tx and its resolution rTx are scaled linearly with lower clock frequencies, as can be seen from the following formula: f GPT f Tx = -------------------------------------------<Txl> F ( BPS2 ) × 2 <Txl> ( BPS2 ) × 2 --------------------------------------------r Tx [ µs ] = F f GPT [ MHz ] (14.2) The effective count frequency depends on the common module clock prescaler factor F(BPS2) as well as on the individual input prescaler factor 2<TxI>. Table 14-16 summarizes the resulting overall divider factors for a GPT2 timer that result from these cascaded prescalers. User’s Manual GPT_X41, V2.0 14-51 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units Table 14-16 GPT2 Overall Prescaler Factors for Internal Count Clock Individual Prescaler for Tx Common Prescaler for Module Clock1) BPS2 = 01B BPS2 = 00B BPS2 = 11B BPS2 = 10B TxI = 000B 2 4 8 16 TxI = 001B 4 8 16 32 TxI = 010B 8 16 32 64 TxI = 011B 16 32 64 128 TxI = 100B 32 64 128 256 TxI = 101B 64 128 256 512 TxI = 110B 128 256 512 1024 TxI = 111B 256 512 1024 2048 1) Please note the non-linear encoding of bitfield BPS2. Table 14-17 lists a timer’s parameters (such as count frequency, resolution, and period) resulting from the selected overall prescaler factor and the applied system frequency. Note that some numbers may be rounded. Table 14-17 GPT2 Timer Parameters System Clock = 10 MHz Overall Divider Factor System Clock = 40 MHz Frequency Resolution Period 5.0 MHz 200 ns 13.11 ms 2 20.0 MHz 50 ns 3.28 ms 2.5 MHz 400 ns 26.21 ms 4 10.0 MHz 100 ns 6.55 ms 1.25 MHz 800 ns 52.43 ms 8 5.0 MHz 200 ns 13.11 ms 625.0 kHz 1.6 µs 104.9 ms 16 2.5 MHz 400 ns 26.21 ms 312.5 kHz 3.2 µs 209.7 ms 32 1.25 MHz 800 ns 52.43 ms 156.25 kHz 6.4 µs 419.4 ms 64 625.0 kHz 1.6 µs 104.9 ms 78.125 kHz 12.8 µs 838.9 ms 128 312.5 kHz 3.2 µs 209.7 ms 39.06 kHz 25.6 µs 1.678 s 256 156.25 kHz 6.4 µs 419.4 ms 19.53 kHz 51.2 µs 3.355 s 512 78.125 kHz 12.8 µs 838.9 ms 9.77 kHz 102.4 µs 6.711 s 1024 39.06 kHz 25.6 µs 1.678 s 4.88 kHz 204.8 µs 13.42 s 2048 19.53 kHz 51.2 µs 3.355 s User’s Manual GPT_X41, V2.0 14-52 Frequency Resolution Period V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units External Count Clock Input The external input signals of the GPT2 block are sampled with the GPT2 basic clock (see Figure 14-20). To ensure that a signal is recognized correctly, its current level (high or low) must be held active for at least one complete sampling period, before changing. A signal transition is recognized if two subsequent samples of the input signal represent different levels. Therefore, a minimum of two basic clock periods are required for the sampling of an external input signal. Thus, the maximum frequency of an input signal must not be higher than half the basic clock. Table 14-18 summarizes the resulting requirements for external GPT2 input signals. Table 14-18 GPT2 External Input Signal Limits System Clock = 10 MHz Input Max. Input Min. Level Frequ. Frequency Hold Time Factor 2.5 MHz 200 ns 1.25 MHz 400 ns 625.0 kHz 800 ns 312.5 kHz 1.6 µs fGPT/4 fGPT/8 fGPT/16 fGPT/32 GPT2 Divider BPS1 System Clock = 40 MHz Input Phase Max. Input Min. Level Duration Frequency Hold Time 01B 2 × tGPT 10.0 MHz 50 ns 00B 4 × tGPT 5.0 MHz 100 ns 11B 8 × tGPT 2.5 MHz 200 ns 10B 16 × tGPT 1.25 MHz 400 ns These limitations are valid for all external input signals to GPT2, including the external count signals in counter mode and the gate input signals in gated timer mode. User’s Manual GPT_X41, V2.0 14-53 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.2.7 GPT2 Timer Registers GPT12E_Tx Timer x Count Register 15 14 13 12 11 SFR (FE4xH/2yH) 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 Txvalue rwh Table 14-19 GPT1 Timer Register Locations Timer Register Physical Address 8-Bit Address T5 FE46H 23H T6 FE48H 24H GPT12E_CAPREL Capture/Reload Register 15 14 13 12 11 SFR (FE4AH/25H) 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 Capture/Reloadvalue rwh User’s Manual GPT_X41, V2.0 14-54 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.2.8 Interrupt Control for GPT2 Timers and CAPREL When a timer overflows from FFFFH to 0000H (when counting up), or when it underflows from 0000H to FFFFH (when counting down), its interrupt request flag (T5IR or T6IR) in register TxIC will be set. Whenever a transition according to the selection in bit field CI is detected at pin CAPIN, interrupt request flag CRIR in register CRIC is set. Setting any request flag will cause an interrupt to the respective timer or CAPREL interrupt vector (T5INT, T6INT or CRINT) or trigger a PEC service, if the respective interrupt enable bit (T5IE or T6IE in register TxIC, CRIE in register CRIC) is set. There is an interrupt control register for each of the two timers and for the CAPREL register. GPT12E_T5IC Timer 5 Intr. Ctrl. Reg. SFR (FF66H/B3H) 15 14 13 12 11 10 9 - - - - - - - - - - - - - - GPT12E_T6IC Timer 6 Intr. Ctrl. Reg. 8 7 6 Reset Value: - - 00H 5 GPX T5IR T5IE rw rwh 4 3 14 13 12 11 10 9 - - - - - - - - - - - - - - GPT12E_CRIC CAPREL Intr. Ctrl. Reg. 8 7 rw rw Reset Value: - - 00H 5 GPX T6IR T6IE rw rwh 4 3 14 13 12 11 10 9 - - - - - - - - - - - - - - 8 7 GPX CRIR CRIE rw rwh rw 1 0 GLVL rw rw rw 6 2 ILVL SFR (FF6AH/B5H) 15 0 GLVL rw 6 1 ILVL SFR (FF68H/B4H) 15 2 Reset Value: - - 00H 5 4 3 2 1 0 ILVL GLVL rw rw Note: Please refer to the general Interrupt Control Register description for an explanation of the control fields. User’s Manual GPT_X41, V2.0 14-55 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The General Purpose Timer Units 14.3 Interfaces of the GPT Module Besides the described intra-module connections, the timer unit blocks GPT1 and GPT2 are connected to their environment in two basic ways (see Figure 14-32): • • Internal connections interface the timers with on-chip resources such as clock generation unit, interrupt controller, or other timers. External connections interface the timers with external resources via port pins. System Control Unit f GPT T2EUD GPTDIS P5.15 T4EUD P5.14 T2IN T3IN T4IN T3IRQ T4IRQ T5IRQ T6IRQ General Purpose Timer Units CRIRQ T3EUD T3OUT T5IN T6IN T5EUD T6EUD CAPCOM Units CAPIN T6OUF T6OUT P3.6 Port Logic for P3 and P5 T2IRQ Interrupt Control Unit P3.7 P3.5 P3.4 P3.3 P5.13 P5.12 P5.11 P5.10 P3.2 P3.1 mc_gpt0105_modinterface_x.vsd Figure 14-32 GPT Module Interfaces Port pins to be used for timer input signals must be switched to input, the respective direction control bits must be cleared (DPx.y = 0). Port pins to be used for timer output signals must be switched to output, the respective direction control bits must be set (DPx.y = 1). The alternate timer output signal must be selected for these pins via the respective alternate select registers (see Chapter 7). Interrupt nodes to be used for timer interrupt requests must be enabled and programmed to a specific interrupt level. User’s Manual GPT_X41, V2.0 14-56 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Real Time Clock 15 Real Time Clock The Real Time Clock (RTC) module of the XC164 basically consists of a chain of prescalers and timers. Its count clock is derived from the auxiliary oscillator or from the prescaled main oscillator. The RTC serves various purposes: • • • 48-bit timer for long term measurements System clock to determine the current time and date (the RTC’s structure supports the direct representation of time and date) Cyclic time based interrupt (can be generated by any timer of the chain) A number of programming options as well as interrupt request signals adjust the operation of the RTC to the application’s requirements. The RTC can continue its operation while the XC164 is in a power-saving mode, such that real time date and time information is provided. C on trol R egisters D ata R egisters C ounter R e gisters Inte rru pt C ontrol R TC _ C O N E R TC _T 14R E L E R T C _T 14 E R T C _IS N C E SYSCON0 E R TC _R E LH E R T C _R T C H E R T C _IC E SYSCON3 E R TC _R E LL E R T C _R T C L E R T C _C O N SYSCON0 SYSCON3 R T C _IS N C R T C _IC R ea l T im e C lock C ontrol R egister G eneral S yste m C ontrol R egister P ow er M a nagem ent C ontrol R eg. Interrupt S ubnode C ontrol R egister R T C Interrupt C ontrol R egister R T C _T 14 R T C _T 14R E L R T C _R T C H /L R T C _R E LH /L T im er T 14 C ount R eg ister T im er T 14 R eload R egister R T C C ount R eg isters, H igh/Low R T C R eload R eg., H igh/Low m ca04463_xc .vs d Figure 15-1 SFRs Associated with the RTC Module The RTC module consists of a chain of 3 divider blocks: • • • a selectable 8:1 divider (on - off) the reloadable 16-bit timer T14 the 32-bit RTC timer block (accessible via RTC_RTCH and RTC_RTCL), made of: – the reloadable 10-bit timer CNT0 – the reloadable 6-bit timer CNT1 – the reloadable 6-bit timer CNT2 – the reloadable 10-bit timer CNT3 All timers count upwards. Each of the five timers can generate an interrupt request. All requests are combined to a common node request. Note: The RTC registers are not affected by a system reset in order to maintain the correct system time even when intermediate resets are executed. User’s Manual RTC_X41, V2.1 15-1 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Real Time Clock 15.1 Defining the RTC Time Base The timer chain of the RTC is clocked with the count clock signal fRTC which is derived from the prescaled main oscillator (see Figure 15-2 and Figure 15-3). Optionally prescaled by a factor of 8, this is the basic RTC clock. Depending on the operating mode, timer T14 may provide the count increments used by the application and thus determine the input frequency of the RTC timer, that is, the RTC time base (see also Table 15-3). The RTC is also supplied with the system clock fSYS of the XC164. This clock signal is used to control the RTC’s logic blocks and its bus interface. To synchronize properly to the count clock, the system clock must run at least four times faster than the count clock, this means fSYS ≥ 4 × fCNT. RUN fRTC 1 8:1 MUX 0 fCNT >1 RTC Count Clock PRE Main fOSCm OSC fSYS 32:1 Async Mode 1 Sync Mode 0 Clock Generation Unit RTC Module Clock MUX RTCCM SYSCON0.14 MCB05413_X4 Figure 15-2 RTC Clock Supply Block Diagram For an example, Table 15-1 lists the interrupt period range and the T14 reload values (for a time base of 1 s and 1 ms): Table 15-1 RTC Time Base Examples Oscillator Frequency T14 Intr. Period Reload Value A Reload Value B Min. Max. T14REL Base T14REL Base 4 MHz 8.0 µs 4.194 s ------H/ C2F7H 1.000 s FF83H/ FFF0H 1.000 ms/ 1.024 ms Note: Select one value from the reload value pairs, depending if the 8:1 prescaler is disabled/enabled. User’s Manual RTC_X41, V2.1 15-2 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Real Time Clock Asynchronous Operation When the system clock frequency becomes lower than 4 × fCNT proper synchronization is not possible and count events may be missed. When the XC164 enters e.g. sleep mode the system clock stops completely and the RTC would stop counting. In these cases the RTC can be switched to Asynchronous Mode (by setting bit RTCCM in register SYSCON0). In this mode the count registers are directly controlled by the count clock independent of the system clock (hence the name). Asynchronous operation ensures correct time-keeping even during sleep mode or powerdown mode. However, as no synchronization between the count registers and the bus interface can be maintained in asynchronous mode, the RTC registers cannot be written. Read accesses may interfere with count events and, therefore, must be verified (e.g. by reading the same value with three consecutive read accesses). Note: The access restrictions in asynchronous mode are only meaningful if the system clock is not switched off, of course. Switching Clocking Modes The clocking mode of the RTC (synchronous or asynchronous) is selected via bit RTCCM in register SYSCON0. After reset, the RTC operates in Synchronous Mode (RTCCM = 0) with the 8:1 prescaler enabled. The selected clocking mode also affects the access to RTC registers. Bit ACCPOS in register RTC_CON indicates if full register access is possible (ACCPOS = 1, default after reset) or not (ACCPOS = 0). This also indicates the current clocking mode. Attention: Software should poll bit ACCPOS to determine the proper transition to the intended clocking mode. After switching to Asynchronous Mode (RTCCM = 1), bit ACCPOS = 0 indicates proper operation in Asynchronous Mode. In this case the system clock can be stopped or reduced. After switching to Synchronous Mode, (RTCCM = 0), bit ACCPOS = 1 indicates proper operation in Synchronous Mode. In this case the RTC registers can again be accessed properly (read and write). Note: The RTC might lose a counting event (edge of fCNT) when switching from synchronous mode to asynchronous mode while the 8:1 prescaler is disabled. For these applications it is, therefore, recommended to set up the RTC with the 8:1 prescaler enabled. User’s Manual RTC_X41, V2.1 15-3 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Real Time Clock Increased RTC Accuracy through Software Correction The accuracy of the XC164’s RTC is determined by the oscillator frequency and by the respective prescaling factor (excluding or including T14 and the 8:1 prescaler). The accuracy limit generated by the prescaler is due to the quantization of a binary counter (where the average is zero), while the accuracy limit generated by the oscillator frequency is due to the difference between the ideal and real frequencies (and therefore accumulates over time). This effect is predictable and can be compensated. The total accuracy of the RTC can be further increased via software for specific applications that demand a high time accuracy. The key to the improved accuracy is knowledge of the exact oscillator frequency. The relation of this frequency to the expected ideal frequency is a measure of the RTC’s deviation. The number of cycles, N, after which this deviation causes an error of ±1 cycle can be easily computed. So, the only action is to correct the count by ±1 after each series of N cycles. The correction may be made cyclically, for instance, within an interrupt service routine, or by evaluating a formula when the RTC registers are read (for this the respective “last” RTC value must be available somewhere). Note: For the majority of applications, however, the standard accuracy provided by the RTC’s structure will be more than sufficient. Adjusting the current RTC value would require reading and then writing the complete 48-bit value. This can only be accomplished by three successive accesses each. To avoid the hassle of reading/writing multi-word values, the RTC incorporates a correction option to simply add or suppress one count pulse. This is done by setting bit T14INC or T14DEC, respectively, in register RTC_CON. This will add an extra count pulse (T14INC) upon the next count event, or suppress the next count event (T14DEC). The respective bit remains set until its associated action has been performed and is automatically cleared by hardware after this event. Note: Setting both bits, T14INC and T14DEC, at the same time will have no effect on the count values. User’s Manual RTC_X41, V2.1 15-4 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Real Time Clock 15.2 RTC Run Control If the RTC shall operate bit RUN in register RTC_CON must be set (default after reset). Bit RUN can be cleared, for example, to exclude certain operation phases from time keeping. The RTC can be completely disabled by setting the corresponding bit RTCDIS in register SYSCON3. Note: A valid count clock is required for proper RTC operation, of course. A reset for the RTC is triggered via software by setting bit RTCRST in register SYSCON0. In this case all RTC registers are set to their initial values and bit RTCRST is cleared automatically. A normal system reset does not affect the RTC registers and its operation (RTC_IC will be reset, however). The initialization software must ensure the proper RTC operating mode. The RTC control register RTC_CON selects the basic operation of the RTC module. RTC_CON Control Register ESFR (F110H/88H) Reset Value: 8003H 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 ACC POS - - - - - - - - - - - T14 T14 PRE RUN INC DEC rh - - - - - - - - - - - rwh rwh rw 0 rw Field Bits Type Description ACCPOS 15 rh RTC Register Access Possible 0 No write access is possible, only asynchronous reads 1 Registers can be read and written T14INC 3 rwh Increment Timer T14 Value Setting this bit to 1 adds one count pulse upon the next count event, thus incrementing T14. This bit is cleared by hardware after incrementation. T14DEC 2 rwh Decrement Timer T14 Value Setting this bit to 1 suppresses the next count event, thus decrementing T14. This bit is cleared by hardware after decrementation. User’s Manual RTC_X41, V2.1 15-5 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Real Time Clock Field Bits Type Description PRE 1 rw RTC Input Source Prescaler Enable 0 Prescaler disabled, T14 clocked with fRTC 1 Prescaler enabled, T14 clocked with fRTC/8 RUN 0 rw RTC Run Bit 0 RTC stopped 1 RTC runs User’s Manual RTC_X41, V2.1 15-6 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Real Time Clock 15.3 RTC Operating Modes The RTC can be configured for several operating modes according to the purpose it is meant to serve. These operating modes are configured by selecting appropriate reload values and interrupt signals. PRE RUN fRTC 1 MUX 0 8 R TC IN T Interru pt S u b N od e CNT IN T 0 CNT IN T 1 CNT IN T2 CNT IN T 3 R EL-R egister fCNT T14REL 1 0 B its 6 B its 6 B its 1 0 B its T14 1 0 B its 6 B its 6 B its 1 0 B its T14-R egister C N T-R egister m cb04805_x c.vsd Figure 15-3 RTC Block Diagram RTC Register Access The actual value of the RTC is indicated by the three registers T14, RTCL, and RTCH. As these registers are concatenated to build the RTC counter chain, internal overflows occur while the RTC is running. When reading or writing the RTC value, such internal overflows must be taken into account to avoid reading/writing corrupted values. Care must be taken, when reading the timer(s), as this requires up to three read accesses to the different registers with an inherent time delay between the accesses. An overflow from T14 to RTCL and/or from RTCL to RTCH might occur between the accesses, which needs to be taken into account appropriately. For example, reading/writing 0000H to RTCH and then accessing RTCL could produce a corrupted value as RTCL may overflow before it can be accessed. In this case, RTCH would be 0001H. The same precautions must be taken for T14 and T14REL. User’s Manual RTC_X41, V2.1 15-7 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Real Time Clock Timer T14 and its reload register are accessed via dedicated locations. The four RTC counters CNT3 … CNT0 are accessed via the two 16-bit RTC timer registers, RTCH and RTCL. The associated four reload values REL3 … REL0 are accessed via the two 16-bit RTC reload registers, RELH and RELL. Table 15-2 Register Locations for Timer T14 Register Name Long/Short Address Reset Value Notes RTC_T14 F0D2H/69H 0000H 16-bit timer, can be used as prescaler for the RTC block RTC_T14REL F0D0H/68H 0000H Timer T14 reload register RTC_RTCH RTC Timer High Register 15 14 13 12 11 ESFR (F0D6H/6BH) 10 14 13 12 8 7 6 5 4 2 CNT2 rwh rwh 11 ESFR (F0D4H/6AH) 10 9 8 7 6 5 4 CNT0 rwh rwh Field Bits Type CNTx (x = 3 … 0) [15:6] rwh [5:0] [15:10] [9:0] 1 0 Reset Value: 0000H CNT1 User’s Manual RTC_X41, V2.1 3 CNT3 RTC_RTCL RTC Timer Low Register 15 9 Reset Value: 0000H 3 2 1 0 Description RTC Timer Count Section CNTx An overflow of this bitfield triggers a count pulse to the next count section CNTx+1 (except for CNT3) followed by a reload of CNTx from bitfield RELx. In addition, an interrupt request is triggered. 15-8 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Real Time Clock RTC_RELH RTC Reload High Register 15 14 13 12 11 ESFR (F0CEH/67H) 10 14 13 12 8 7 6 5 4 3 2 REL3 REL2 rw rw RTC_RELL RTC Reload Low Register 15 9 Reset Value: 0000H 11 ESFR (F0CCH/66H) 10 9 8 7 6 5 4 REL0 rw rw Bits Type RELx (x = 3 … 0) [15:6] rw [5:0] [15:10] [9:0] 0 Reset Value: 0000H REL1 Field 1 3 2 1 0 Description RTC Reload Value RELx This bitfield is copied to bitfield CNTx upon an overflow of count section CNTx. Note: The registers of the RTC receive their reset values only upon a specific RTC reset. This reset is not triggered upon a system reset, but via software. User’s Manual RTC_X41, V2.1 15-9 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Real Time Clock 15.3.1 48-bit Timer Operation The concatenation of timers T14 and COUNT0 … COUNT3 can be regarded as a 48-bit timer which is clocked with the RTC input frequency, optionally divided by the prescaler. The reload registers T14REL, RELL, and RELH must be cleared to produce a true binary 48-bit timer. However, any other reload value may be used. Reload values other than zero must be used carefully, due to the individual sections of the RTC timer with their own individual overflows and reload values. The maximum usable timespan is 248 (≈ 1014) T14 input clocks (assuming no prescaler), which would equal more than 200 years at an oscillator frequency of 32 kHz. 15.3.2 System Clock Operation A real time system clock can be maintained that keeps on running also during power saving modes (optionally) and indicates the current time and date. This is possible because the RTC module is not affected by a system reset1). The resolution for this clock information is determined by the input clock of timer T14. By selecting appropriate reload values each cascaded timer can represent directly a part of the current time and/or date. Due to its width, T14 can adjust the RTC to the intended range of operation (time or date). The maximum usable timespan is achieved when T14REL is loaded with 0000H and so T14 divides by 216. System Clock Example The RTC count clock is fOSCm/32 (8:1 prescaler off). With fOSCm = 4 MHz, the resulting count clock is fCNT = 125 kHz. By selecting appropriate reload values the RTC timers directly indicate the current time (see Figure 15-4 and Table 15-3). 3E8H 04H 04H 018H FF83H REL3 REL2 REL1 REL0 T14REL fCNT = CNT3 CNT2 CNT1 CNT0 T14 Hours Minutes Seconds 1/1000 Seconds Prescaler 125 kHz MCA05414_X4 Figure 15-4 RTC Configuration Example Note: This setup can generate an interrupt request every millisecond, every second, every minute, every hour, or every day. 1) After a power on reset, however, the RTC registers are undefined. User’s Manual RTC_X41, V2.1 15-10 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Real Time Clock Each timer in the chain divides the clock by (2<timer_width> - <reload_value>) : 1, as the timers count up. Table 15-3 shows the reload values which must be chosen for a specific scenario (i.e. operating mode of the RTC). Day of the Week Time of Day (Figure 15-4) Table 15-3 15.3.3 Reload Value Scenarios REL3 REL2 REL1 REL0 T14REL Formula 210 - 24 26 - 60 26 - 60 210 - 1000 216 - 125 Rel. Value 3E8H 04H 04H 018H FF83H Function h m s 1/1000 s Prescaler Intr. Period day hour minute second millisec. Formula 210 - 7 26 - 24 26 - 60 210 - 600 216 - 12500 Rel. Value 3F9H 28H 04H 1A8H CF2CH Function day h m 1/10 s Prescaler Intr. Period week day hour minute 100 millisec Cyclic Interrupt Generation The RTC module can generate an interrupt request whenever one of the timers overflows and is reloaded. This interrupt request may be used, for example, to provide a system time tick independent of the CPU frequency without loading the general purpose timers, or to wake up regularly from sleep mode. The interrupt cycle time can be adjusted by choosing appropriate reload values and by enabling the appropriate interrupt request. In this mode, the other operating modes can be combined. For example, a reload value of T14REL = F9C0H (216 - 1600) generates a T14 interrupt request every 50 ms to wakeup the system regularly. Still the subsequent timers can be configured to represent the time or build a binary counter, however with a different time base. User’s Manual RTC_X41, V2.1 15-11 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Real Time Clock 15.4 RTC Interrupt Generation The overflow signals of each timer of the RTC timer chain can generate an interrupt request. The RTC’s interrupt subnode control register ISNC combines these requests to activate the common RTC interrupt request line RTC_IRQ. Each timer overflow sets its associated request flag in register ISNC. Individual enable bits for each request flag determine whether this request also activates the common interrupt line. The enabled requests are ORed together on this line (see Figure 15-5). The interrupt handler can determine the source of an interrupt request via the specific request flags and must clear them after appropriate processing (not cleared by hardware). The common node request bit is automatically cleared when the interrupt handler is vectored to. Note: If only one source is enabled, no additional software check is required, of course. Both the individual request and the common interrupt node must be enabled. Register RTC_ISNC CNT3 Overflow Set SW Clear CNT2 Overflow Set SW Clear CNT1 Overflow Set SW Clear CNT0 Overflow Set SW Clear T14 Overflow Set SW Clear CNT3 IR CNT2 IR CNT1 IR CNT0 IR T14 IR & CNT3 IE & CNT2 IE & CNT1 IE _ >1 Interrupt Request RTC_IRQ & CNT0 IE & T14 IE MCB05415 Figure 15-5 Interrupt Block Diagram User’s Manual RTC_X41, V2.1 15-12 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Real Time Clock RTC_ISNC Interrupt Subnode Ctrl. Reg. ESFR (F10CH/86H) 15 14 13 12 11 10 - - - - - - CNT CNT CNT CNT CNT CNT CNT CNT T14 T14 3IR 3IE 2IR 2IE 1IR 1IE 0IR 0IE IR IE - - - - - - rwh Type 9 8 rw 7 rwh 6 Reset Value: 0000H rw 5 rwh 4 3 rw rwh 2 1 rw 0 rwh rw Field Bits Description CNTxIR (x = 3 … 0) 9, 7, 5, rwh 3 Section CNTx Interrupt Request Flag 0 No request pending 1 This source has raised an interrupt request CNTxIE (x = 3 … 0) 8, 6, 4, rw 2 Section CNTx Interrupt Enable Control Bit 0 Interrupt request is disabled 1 Interrupt request is enabled T14IR 1 rwh T14 Overflow Interrupt Request Flag 0 No request pending 1 This source has raised an interrupt request T14IE 0 rw T14 Overflow Interrupt Enable Control Bit 0 Interrupt request is disabled 1 Interrupt request is enabled Note: The interrupt request flags in register ISNC must be cleared by software. They are not cleared automatically when the service routine is entered. RTC_IC RTC Interrupt Ctrl. Reg. ESFR (F1A0H/D0H) 15 14 13 12 11 10 9 8 - - - - - - - GPX - - - - - - - rw 7 6 RTC RTC IR IE rwh rw Reset Value: 0000H 5 4 3 2 1 0 ILVL GLVL rw rw Note: Please refer to the general Interrupt Control Register description for an explanation of the control fields. Register RTC_IC is not part of the RTC module and is reset with any system reset. User’s Manual RTC_X41, V2.1 15-13 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter 16 The Analog/Digital Converter The XC164 provides an Analog/Digital Converter with 8-bit or 10-bit resolution and a sample & hold circuit on-chip. An input multiplexer selects between up to 14 analog input channels (alternate functions of Port 5) either via software (fixed channel modes) or automatically (auto scan modes). To fulfill most requirements of embedded control applications the ADC supports the following conversion modes: • • • • • • Fixed Channel Single Conversion produces just one result from the selected channel Fixed Channel Continuous Conversion repeatedly converts the selected channel Auto Scan Single Conversion produces one result from each of a selected group of channels Auto Scan Continuous Conversion repeatedly converts the selected group of channels Wait for ADDAT Read Mode start a conversion automatically when the previous result was read Channel Injection Mode start a conversion when a hardware trigger occurs, can insert the conversion of a specific channel into a group conversion (auto scan) A set of SFRs and port pins provide access to control functions and results of the ADC. The enhanced-mode registers provide more detailed control functions for the ADC. Data Registers Control Registers ADC_DAT ADC_DAT2 E Interrupt Control System Registers ADC_CON ADC_CIC P5 ADC_CON1 ADC_EIC P5DIDIS E ADC_CTR0 ADC_CTR2 ADC_CTR2IN Compatibility Mode: ADC_CON ADC Control Register ADC_CON1 ADC Control Register 1 Enhanced Mode: ADC_CTR0 ADC Control Register 0 ADC_CTR2 ADC Control Register 2 ADC_CTR2IN ADC Control Injection Register SYSCON3 ADC_DAT ADC_DAT2 ADC_CIC ADC_EIC P5 P5DIDIS ADC Result Register ADC Injection Result Register ADC End-of-Conversion Intr. Reg. ADC Conversion-Error Intr. Reg. Port 5 Analog Input Port (AN15...AN10, AN7...AN0) Port 5 Digital Input Disable Reg. mc_adc0101_registers_x4.vsd Figure 16-1 SFRs and Port Pins Associated with the A/D Converter User’s Manual ADC_X41, V2.1 16-1 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter The external analog reference voltages VAREF and VAGND are fixed. The separate supply for the ADC reduces the interference with other digital signals. The reference voltages must be stable during the reset calibration phase and during an entire conversion, to achieve a maximum of accuracy. The sample time as well as the conversion time is programmable, so the ADC can be adjusted to the internal resistances of the analog sources and/or the analog reference voltage supply (you may also want to refer to application note AP2428). CTR0 CTR2 CON1 CTR2IN MUX CON Injection Requests AN0 AN7 AN12 ADC_CIRQ ADC_EIRQ Conversion Control MUX Sample & Hold 8/10-bit Capacitive Network Conversion DAT DAT2 AN15 MCB05416 Figure 16-2 Analog/Digital Converter Block Diagram The ADC is implemented as a capacitive network using successive approximation conversion. A conversion consists of 3 phases. • • • During the sample phase, the capacitive network is connected to the selected analog input and is charged or discharged to the voltage of the analog signal. During the actual conversion phase, the network is disconnected from the analog input and is repeatedly charged or discharged via VAREF during the steps of successive approximation. After the (optional) post-calibration phase (to adjust the network to changing conditions such as temperature) the result is written to the result register and an interrupt request is generated. There are two sets of control, data, and status registers, one set for compatibility mode and one set for enhanced mode. Only one of these register sets may be active at a given time. As most of the bits and bitfields of the registers of the two sets control the same functionality or control the functionality in a very similar way, the following description is organized according to the functionality, not according to the two register sets. User’s Manual ADC_X41, V2.1 16-2 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter 16.1 Mode Selection The analog input channels AN15 … AN10, AN7 … AN0 are alternate functions of Port 5 which is an input-only port. The Port 5 lines may either be used as analog or digital inputs. For pins that shall be used as analog inputs it is recommended to disable the digital input stage via register P5DIDIS. This avoids undesired cross currents and switching noise while the (analog) input signal level is between VIL and VIH. The functions of the A/D converter are controlled by two sets of bit-addressable control registers. In compatibility mode, registers ADC_CON and ADC_CON1 are used, in enhanced mode, registers ADC_CTR0, ADC_CTR2, and ADC_CTR2IN are used. Their bitfields specify the analog channel to be acted upon, the conversion mode, and also reflect the status of the converter. 16.1.1 Compatibility Mode In compatibility mode (MD = 0), registers ADC_CON and ADC_CON1 select the basic functions. The register layout is compatible with previous versions of the ADC module, while providing limited options. ADC_CON ADC Control Register 15 14 13 12 ADCTC ADSTC rw rw SFR (FFA0H/D0H) 11 10 AD AD CRQ CIN rwh rw 8 7 AD AD AD WR BSY ST rw rwh rwh 6 5 4 3 2 1 - ADM ADCH - rw rw 0 Field Bits ADCTC [15:14] rw ADC Conversion Time Control (Defines the ADC basic conversion clock fBC) 00 fBC = fADC/4 01 fBC = fADC/2 10 fBC = fADC/16 11 fBC = fADC/8 ADSTC [13:12] rw ADC Sample Time Control (Defines the ADC sample time in a certain range) 00 tBC × 8 01 tBC × 16 10 tBC × 32 11 tBC × 64 ADCRQ 11 rwh ADC Channel Injection Request Flag ADCIN 10 rw ADC Channel Injection Enable User’s Manual ADC_X41, V2.1 Type 9 Reset Value: 0000H Function 16-3 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter Field Bits Type Function ADWR 9 rw ADC Wait for Read Control ADBSY 8 rh ADC Busy Flag 0 ADC is idle 1 A conversion is active ADST 7 rwh ADC Start Bit 0 Stop a running conversion 1 Start conversion(s) ADM [5:4] rw ADC Mode Selection 00 Fixed Channel Single Conversion 01 Fixed Channel Continuous Conversion 10 Auto Scan Single Conversion 11 Auto Scan Continuous Conversion ADCH [3:0] rw ADC Analog Channel Input Selection Selects the (first) ADC channel which is to be converted. ADC_CON1 ADC Control Register 1 15 ICST rw 14 13 12 SFR (FFA6H/D3H) 11 10 SAM CAL RES PLE rh rh rw 9 8 7 6 Reset Value: 0000H 5 4 3 2 ADCTC ADSTC rw rw 1 0 Field Bits Type Description ICST 15 rw Improved Conversion and Sample Timing Selects the active timing control bitfields 0 Standard conversion and sample time control, 2-bit fields in ADC_CON (default after reset) 1 Improved conversion and sample time control, 6-bit fields in ADC_CON1 SAMPLE 14 rh Sample Phase Status Flag 0 A/D Converter is not in sampling 1 A/D Converter is currently in the sample phase CAL 13 rh Reset Calibration Phase Status Flag 0 A/D Converter is not in calibration phase 1 A/D Converter is in calibration phase User’s Manual ADC_X41, V2.1 16-4 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter Field Bits Type Description RES 12 rw Conversion Resolution Control 0 10-bit resolution (default after reset) 1 8-bit resolution ADCTC [11:6] rw ADC Conversion Time Control Defines the ADC basic conversion clock: fBC = fADC / (<ADCTC> + 1) ADSTC [5:0] rw ADC Sample Time Control Defines the ADC sample time: tS = tBC × 4 × (<ADSTC> + 1) Note: The limit values for fBC (see data sheet) must not be exceeded when selecting ADCTC and fADC. 16.1.2 Enhanced Mode In enhanced mode (MD = 1), registers ADC_CTR0, ADC_CTR2, and ADC_CTR2IN select the basic functions. The register layout differs from the compatibility-mode layout, but this mode provides more options. Conversion timing is selected via registers ADC_CTR2(IN), where ADC_CTR2 controls standard conversions and ADC_CTR2IN controls injected conversions. ADC_CTR0 ADC Control Register 0 15 14 13 12 MD SAM PLE ADCTS rw rh rw SFR (FFBEH/DFH) 11 10 AD AD CRQ CIN rwh rw 9 8 7 AD AD AD WR BSY ST rw rh rwh Reset Value: 1000H 6 5 4 3 2 1 ADM CAL OFF ADCH rw rw rw Field Bits Type Description MD 15 rw Mode Control 0 Compatibility Mode 1 Enhanced Mode 0 Note: Any modification of control bit MD is forbidden while a conversion is currently running. User software must take care. SAMPLE User’s Manual ADC_X41, V2.1 14 rh Sample Phase Status Flag 0 A/D Converter is not in sample phase 1 A/D Converter in sample phase 16-5 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter Field Bits Type ADCTS [13:12] rw Description Channel Injection Trigger Input Select 00 Channel injection trigger input disabled 01 Trigger input CAPCOM2 selected 10 Trigger input CAPCOM6 selected 11 Reserved Note: Reset value of bitfield ADCTS is 01B for compatibility purposes. ADCRQ 11 rwh Channel Injection Request Flag ADCIN 10 rw Channel Injection Enable Control ADWR 9 rw Wait for Read Control ADBSY 8 rh Busy Flag 0 ADC is idle 1 A conversion is active ADST 7 rwh ADC Start/Stop Control 0 Stop a running conversion 1 Start conversion(s) ADM [6:5] rw Mode Selection Control 00 Fixed Channel Single Conversion 01 Fixed Channel Continuous Conversion 10 Auto Scan Single Conversion 11 Auto Scan Continuous Conversion CALOFF 4 rw Calibration Disable Control 0 Calibration cycles are executed 1 Calibration is disabled (off) Note: This control bit is active in both compatibility and enhanced mode. ADCH User’s Manual ADC_X41, V2.1 [3:0] rw Analog Input Channel Selection Selects the (first) ADC channel which is to be converted 16-6 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter ADC_CTR2 ADC Control Register 2 15 14 13 12 ESFR (F09CH/4EH) 11 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 - RES ADCTC ADSTC - rw rw rw ADC_CTR2IN Injection Control Register 2 15 14 13 12 11 10 ESFR (F09EH/4FH) 9 8 7 6 0 Reset Value: 0000H 5 4 3 2 - RES ADCTC ADSTC r rw rw rw Type 1 1 Field Bits RES [13:12] rw Converter Resolution Control 00 10-bit resolution (default after reset) 01 8-bit resolution 1x Reserved ADCTC [11:6] rw ADC Conversion Time Control Defines the ADC basic conversion clock: fBC = fADC / (<ADCTC> + 1) ADSTC [5:0] rw ADC Sample Time Control Defines the ADC sample time: tS = tBC × 4 × (<ADSTC> + 1) 0 Description Note: The limit values for fBC (see data sheet) must not be exceeded when selecting ADCTC and fADC. User’s Manual ADC_X41, V2.1 16-7 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter 16.2 ADC Operation Channel Selection, ADCH Bitfield ADCH controls the input channel multiplexer logic. In the Single Channel Modes, it specifies the analog input channel which is to be converted. In the Auto Scan Modes, it specifies the highest channel number to be converted in the auto scan round. ADCH may be changed while a conversion is in progress. The new value will go into effect after the current conversion is finished in the fixed channel modes, or after the current conversion round is finished in the auto scan modes. ADC Flags, ADBSY, SAMPLE The ADC Busy Status Flag is set when the ADC is started (by setting ADST) and remains set as long as the ADC performs conversions or calibration cycles. ADBSY is cleared when the ADC is idle, meaning there are no conversion or calibration operations in progress. Bit SAMPLE is set during the sample phase. ADC Start/Stop Control, ADST Bit ADST is used to start or to stop the ADC. A single conversion or a conversion sequence is started by setting bit ADST. The busy flag ADBSY will be set and the converter then selects and samples the input channel, which is specified by the channel selection field ADCH. The sampled level will then be held internally during the conversion. When the conversion of this channel is complete, the result together with the number of the converted channel is transferred into the result register and the interrupt request is generated. The conversion result is placed into bitfield ADRES. ADST remains set until cleared either by hardware or by software. Hardware clears the bit dependent on the conversion mode: • • In Fixed Channel Single Conversion mode, ADST is cleared after the conversion of the specified channel is finished. In Auto Scan Single Conversion mode, ADST is cleared after the conversion of channel 0 is finished. Note: In the continuous conversion modes, ADST is never cleared by hardware. Stopping the ADC via software is performed by clearing bit ADST. The reaction of the ADC depends on the conversion mode: • • In Fixed Channel Single Conversion mode, the ADC finishes the conversion and then stops. There is no difference to the operation if ADST was not cleared by software. In Fixed Channel Continuous Conversion mode, the ADC finishes the current conversion and then stops. This is the usual way to terminate this conversion mode. User’s Manual ADC_X41, V2.1 16-8 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter • • In Auto Scan Single Conversion mode, the ADC continues the auto scan round until the conversion of channel 0 is finished, then it stops. There is no difference to the operation if ADST was not cleared by software. In Auto Scan Continuous Conversion mode, the ADC continues the auto scan round until the conversion of channel 0 is finished, then it stops. This is the usual way to terminate this conversion mode. A restart of the ADC can be performed by clearing and then setting bit ADST. This sequence will abort the current conversion and restart the ADC with the new parameters given in the control registers. Conversion Mode Selection, ADM Bitfield ADM selects the conversion mode of the A/D converter, as listed in Table 16-1. Table 16-1 A/D Converter Conversion Mode ADM Description 00 Fixed Channel Single Conversion 01 Fixed Channel Continuous Conversion 10 Auto Scan Single Conversion 11 Auto Scan Continuous Conversion While a conversion is in progress, the mode selection field ADM and the channel selection field ADCH may be changed. ADM will be evaluated after the current conversion. ADCH will be evaluated after the current conversion (fixed channel modes) or after the current conversion sequence (auto scan modes). Conversion Resolution Control, RES The ADC can produce either a 10-bit result (RES = 0) or an 8-bit result (RES = 1). Depending on the application’s needs a higher conversion speed (an 8-bit conversion requires less conversion time) or a higher resolution can be chosen. User’s Manual ADC_X41, V2.1 16-9 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter Conversion Result The result of a conversion is stored in the result register ADC_DAT, or in register ADC_DAT2 for an injected conversion. The position of the result depends on the basic operating mode (compatibility or enhanced) and on the selected resolution (8-bit or 10-bit). Note: Bitfield CHNR of register ADC_DAT is loaded by the ADC to indicate, which channel the result refers to. Bitfield CHNR of register ADC_DAT2 is loaded by the CPU to select the analog channel, which is to be injected. ADC_DAT ADC Result Register 15 14 13 12 SFR (FEA0H/50H) 11 10 8 7 6 5 CHNR ADRES rwh rwh ADC_DAT2 ADC Chan. Inj. Result Reg. 15 9 Reset Value: 0000H 14 13 12 11 4 ESFR (F0A0H/50H) 10 9 8 7 6 2 1 0 Reset Value: 0000H 5 CHNR ADRES rw rwh Type 3 4 3 2 1 0 Field Bits CHNR [15:12] rw[h] Channel Number (identifies the converted analog channel) ADRES [11:0] A/D Conversion Result The digital result of the most recent conversion. In compatibility mode, the result is placed as follows: 8-bit: ADRES[9:2] 10-bit: ADRES[9:0] In enhanced mode, the result is placed as follows: 8-bit: ADRES[11:4] 10-bit: ADRES[11:2] rwh Function Note: Unused bits of ADRES are always set to 0. User’s Manual ADC_X41, V2.1 16-10 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter 16.2.1 Fixed Channel Conversion Modes These modes are selected by (single conversion) or to 01B through bit ADST the busy flag ADCH will be converted. After ADCIR will be set. programming the mode selection bitfield ADM to 00B (continuous conversion). After starting the converter ADBSY will be set and the channel specified in bitfield the conversion is complete, the interrupt request flag In Single Conversion Mode the converter will automatically stop and reset bits ADBSY and ADST. In Continuous Conversion Mode the converter will automatically start a new conversion of the channel specified in ADCH. ADCIR will be set after each completed conversion. When bit ADST is reset by software, while a conversion is in progress, the converter will complete the current conversion and then stop and reset bit ADBSY. User’s Manual ADC_X41, V2.1 16-11 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter 16.2.2 Auto Scan Conversion Modes These modes are selected by programming the mode selection field ADM to 10B (single conversion) or to 11B (continuous conversion). Auto Scan modes automatically convert a sequence of analog channels, beginning with the channel specified in bitfield ADCH and ending with channel 0, without requiring software to change the channel number. After starting the converter through bit ADST, the busy flag ADBSY will be set and the channel specified in bitfield ADCH will be converted. After the conversion is complete, the interrupt request flag ADCIR will be set and the converter will automatically start a new conversion of the next lower channel. ADCIR will be set after each completed conversion. After conversion of channel 0 the current sequence is complete. In Single Conversion Mode the converter will automatically stop and reset bits ADBSY and ADST. In Continuous Conversion Mode the converter will automatically start a new sequence beginning with the conversion of the channel specified in ADCH. When bit ADST is reset by software, while a conversion is in progress, the converter will complete the current sequence (including conversion of channel 0) and then stop and reset bit ADBSY. #3 Conversion of Channel.. Write ADC_DAT ADC_DAT Full Generate Interrupt Request Read of ADC_DAT; Result of Channel: #x #x #2 #3 #1 #0 #2 #1 #2 #3 #3 #0 ADC_DAT Full; Channnel 0 # 1 Result Lost #2 #3 #3 Overrun Error Interrupt Request MC_ADC0001_AUTOSCAN Figure 16-3 Auto Scan Conversion Mode Example Note: Auto Scan sequences that begin with channel numbers above 7 will generate (up to) 2 invalid results from channels 9 and 8 which are not connected to input pins. Starting an Auto Scan sequence with ADCH = EH will generate the following 15 results: 14, 13, 12, 11, 10, x, x, 7, 6, 5, 4, 3, 2, 1, 0. Starting a sequence with ADCH = 9H or 8H generates 2 or 1 invalid results at the beginning of the sequence and therefore makes no sense in an application. User’s Manual ADC_X41, V2.1 16-12 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter 16.2.3 Wait for Read Mode If in default mode of the ADC a previous conversion result has not been read out of the result register by the time a new conversion is complete, the previous result is lost because it is overwritten by the new value, and the A/D overrun error interrupt request flag ADEIR will be set. In order to avoid error interrupts and the loss of conversion results especially when using continuous conversion modes, the ADC can be switched to “Wait for Read Mode” by setting bit ADWR. If the result value has not been read by the time the current conversion is complete, the new result is stored in a temporary buffer and the next conversion is suspended (ADST and ADBSY will remain set in the meantime, but no end-of-conversion interrupt will be generated). After reading the previous value the temporary buffer is copied into ADC_DAT (generating an ADCIR interrupt) and the suspended conversion is started. This mechanism applies to both single and continuous conversion modes. Note: While in standard mode continuous conversions are executed at a fixed rate (determined by the conversion time), in “Wait for Read Mode” there may be delays due to suspended conversions. However, this only affects the conversions, if the CPU (or PEC) cannot keep track with the conversion rate. #3 #2 #1 wait #0 #3 Conversion of Channel.. Write ADC_DAT ADC_DAT Full Temp-Latch Full #x #3 #2 #0 #3 1 Generate Interrupt Request Read of ADC_DAT; Result of Channel: #1 Hold Result in Temp-Latch #x #3 #2 #1 #0 MC_ADC0002_WAITREAD Figure 16-4 Wait for Read Mode Example User’s Manual ADC_X41, V2.1 16-13 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter 16.2.4 Channel Injection Mode Channel Injection Mode allows the conversion of a specific analog channel (also while the ADC is running in a continuous or auto scan mode) without changing the current operating mode. After the conversion of this specific channel the ADC continues with the original operating mode. Channel Injection mode is enabled by setting bit ADCIN and requires the Wait for Read Mode (ADWR = 1). The channel to be converted in this mode is specified in bitfield CHNR of register ADC_DAT2. Note: Bitfield CHNR in ADC_DAT2 is not modified by the A/D converter, but only the ADRES bitfield. Since the channel number for an injected conversion is not buffered, bitfield CHNR of ADC_DAT2 must never be modified during the sample phase of an injected conversion, otherwise the input multiplexer will switch to the new channel. It is recommended to only change the channel number with no injected conversion running. #x # x-1 Conversion of Channel.. Write ADC_DAT; # x+1 ADC_DAT Full Read ADC_DAT Injected Conversion of Channel # y #x # x+1 # x-2 # x-1 # x-2 #x # x-4 # x-3 # x-1 # x-3 # x-2 # ... # x-4 # x-3 # x-4 #y Channel Injection Request Write ADC_DAT2 ADC_DAT2 Full Int. Request ADEINT Read ADC_DAT2 MC_ADC0003_INJECT Figure 16-5 Channel Injection Example User’s Manual ADC_X41, V2.1 16-14 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter A channel injection can be triggered in three ways: • • • setting of the Channel Injection Request bit ADCRQ via software a compare or a capture event of Capture/Compare register CC31 of the CAPCOM2 unit, which also sets bit ADCRQ a period-match of timer T13 of the CAPCOM6 unit, which also sets bit ADCRQ. The second method triggers a channel injection at a specific time, on the occurrence of a predefined count value of the CAPCOM2 timers, stored in register CC31. Note: The channel injection request bit ADCRQ will be set on any selected injection trigger (interrupt request of CAPCOM2 channel CC31 or period match of CAPCOM6 timer T13), regardless whether the channel injection mode is enabled or not. It is recommended to always clear bit ADCRQ before enabling the channel injection mode. After the completion of the current conversion (if any is in progress) the converter will start (inject) the conversion of the specified channel. When the conversion of this channel is complete, the result will be placed into the alternate result register ADC_DAT2, and a Channel Injection Complete Interrupt request will be generated, which uses the interrupt request flag ADEIR (for this reason the Wait for Read Mode is required). Note: The result of an injected conversion is directly written to ADC_DAT2. If the previous result has not been read in the meantime, it is overwritten. Standard conversions are suspended if the temporary buffer is full. User’s Manual ADC_X41, V2.1 16-15 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter Arbitration of Conversions Conversion requests that are activated while the ADC is idle immediately trigger the respective conversion. If a conversion is requested while another conversion is currently in progress the operation of the A/D converter depends on the kind of the involved conversions (standard or injected). Note: A conversion request is activated if the respective control bit (ADST or ADCRQ) is toggled from 0 to 1, i.e. the bit must have been zero before being set. Table 16-2 summarizes the ADC operation in the possible situations. Table 16-2 Conversion in Progress Conversion Arbitration New Requested Conversion Standard Injected Standard Abort running conversion, and start requested new conversion.1) Complete running conversion, start requested conversion after that. Injected Complete running conversion, start requested conversion after that. Complete running conversion, start requested conversion after that. Bit ADCRQ will be 0 for the second conversion, however. 1) If an injected conversion is pending when a standard conversion is re-started, the injected conversion is executed before the newly started standard conversion. User’s Manual ADC_X41, V2.1 16-16 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter 16.3 Automatic Calibration The ADC of the XC164 features automatic self-calibration. This calibration corrects gain errors, which are mainly due to process variation, and offset errors, which are mainly due to temperature changes. Two types of calibration are supported: • • Reset calibration performs a thorough basic calibration of the ADC after a reset. In particular this is required after a power-on reset. Post-calibration performs one small calibration step after each conversion. Reset Calibration After a reset, a thorough power-up calibration is performed automatically to correct gain and offset errors of the A/D converter. To achieve best calibration results, the reference voltages as well as the supply voltages must be stable during the power-up calibration. During the calibration sequence a series of calibration cycles is executed, where the step width for adjustments is reduced gradually. The total number of executed calibration cycles depends on the actual properties of the respective ADC module. The maximum duration of the power-up calibration is 11,696 cycles of the basic clock fBC. Status flag CAL is set as long as this power-up calibration takes place. Note: The reset calibration must be completed (CAL = 0) before entering Sleep mode, Idle mode, or Powerdown mode. Otherwise, the analog comparator remains active and draws its supply current, which is undesired during power-save conditions. Post-Calibration After each conversion a small calibration step can be executed. For 8-bit and 10-bit conversions post-calibration is not mandatory in order not to exceed the total unadjusted error (TUE) specified in the data sheet. Post-calibration can be disabled by setting bit CALOFF in register ADC_CTR0. When disabled, the post-calibration cycles are skipped which reduces the total conversion time. Note: Calibration may be disabled only after the reset calibration is complete. User’s Manual ADC_X41, V2.1 16-17 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter 16.4 Conversion Timing Control When a conversion is started, first the capacitances of the converter are loaded via the respective analog input pin to the current analog input voltage. The time to load the capacitances is referred to as sample time. Next the sampled voltage is converted to a digital value in successive steps, which correspond to the resolution of the ADC. During these phases (except for the sample time) the internal capacitances are repeatedly charged and discharged via pins VAREF and VAGND. The current that has to be drawn from the sources for sampling and changing charges depends on the time that each respective step takes, because the capacitors must reach their final voltage level within the given time, at least with a certain approximation. The maximum current, however, that a source can deliver, depends on its internal resistance. The time that the two different actions during conversion take (sampling, and converting) can be programmed within a certain range in the XC164 relative to the CPU clock. The absolute time that is consumed by the different conversion steps therefore is independent from the general speed of the controller. This allows adjusting the A/D converter of the XC164 to the properties of the system: Fast Conversion can be achieved by programming the respective times to their absolute possible minimum. This is preferable for scanning high frequency signals. The internal resistance of analog source and analog supply must be sufficiently low, however. High Internal Resistance can be achieved by programming the respective times to a higher value, or the possible maximum. This is preferable when using analog sources and supply with a high internal resistance in order to keep the current as low as possible. The conversion rate in this case may be considerably lower, however. Control Bitfields For the timing control of the conversion and the sample phase two mechanisms are provided: • • Standard timing control uses two 2-bit fields in register ADC_CON to select prescaler values for the general conversion timing and the duration of the sample phase. This provides compact control, while limiting the prescaler factors to a few steps. Improved timing control uses two 6-bit fields in register ADC_CON1 (compatibility mode) or register ADC_CTR2/ADC_CTR2IN (enhanced mode). This provides a wide range of prescaler factors, so the ADC can be better adjusted to the internal and external system circumstances. Improved timing control is selected by setting bit ICST in register ADC_CON1 in compatibility mode, or by selecting enhanced mode. User’s Manual ADC_X41, V2.1 16-18 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter Standard Timing Control Standard timing control is performed by using two 2-bit fields in register ADC_CON. Bitfield ADCTC (conversion time control) selects the basic conversion clock (fBC), used for the operation of the A/D converter. The sample time is derived from this conversion clock and controlled by bitfield ADSTC. The sample time is always a multiple of 8 fBC periods. Table 16-3 lists the possible combinations. Table 16-3 Standard Conversion and Sample Timing Control ADC_CON.15|14 (ADCTC) A/D Converter Basic Clock fBC1) ADC_CON.13|12 (ADSTC) Sample Time tS 00 fADC/4 fADC/2 fADC/16 fADC/8 00 tBC × 8 tBC × 16 tBC × 32 tBC × 64 01 10 11 01 10 11 Improved Timing Control To provide a finer resolution for programming of the timing parameters, wider bitfields have been implemented for timing control (the 2-bit bitfields in register ADC_CON are disregarded in all cases). In compatibility mode (with bit ICST = 1), the bitfields in register ADC_CON1 are used for all conversions. In enhanced mode (bit MD = 1), the bitfields in register ADC_CTR2 are used for standard conversions. Injected conversions use the bitfields in register ADC_CTR2IN. Bitfield ADCTC (conversion time control) selects the basic conversion clock (fBC), used for the operation of the A/D converter. The sample time is derived from this conversion clock and controlled by bitfield ADSTC. The sample time is always a multiple of 4 fBC periods. Table 16-4 lists the possible combinations. Table 16-4 Improved Conversion and Sample Timing Control ADCTC A/D Converter Basic Clock fBC1) ADSTC Sample Time tS 00’0000B = 00H fADC/1 fADC/2 fADC/3 fADC/(ADCTC + 1) fADC/64 00’0000B = 00H tBC × 8 tBC × 12 tBC × 16 tBC × 4 × (ADSTC + 2) tBC × 260 00’0001B = 01H 00’0010B = 02H … 11’1111B = 3FH 00’0001B = 01H 00’0010B = 02H … 11’1111B = 3FH 1) The limit values for fBC (see data sheet) must not be exceeded when selecting ADCTC and fADC. User’s Manual ADC_X41, V2.1 16-19 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter Total Conversion Time Examples The time for a complete conversion includes the sample time tS, the conversion itself (successive approximation and calibration), and the time required to transfer the digital value to the result register as shown in the example below (standard conversion timing). The timings refer to module clock cycles, where tADC = 1/fADC. • • • Assumptions: fADC = 40 MHz (i.e. tADC = 25 ns), ADCTC = 01B, ADSTC = 00B Basic clock: fBC = fADC/2 = 20 MHz, i.e. tBC = 50 ns Sample time: tS = tBC × 8 = 400 ns Conversion 10-bit: • • With post-calibr.: tC10P = tS + 52 × tBC + 6 × tADC = (2600 + 400 + 150) ns = 3.15 µs Post-calibr. off: tC10 = tS + 40 × tBC + 6 × tADC = (2000 + 400 + 150) ns = 2.55 µs Conversion 8-bit: • • With post-calibr.: tC8P = tS + 44 × tBC + 6 × tADC = (2200 + 400 + 150) ns = 2.75 µs Post-calibr. off: tC8 = tS + 32 × tBC + 6 × tADC = (1600 + 400 + 150) ns = 2.15 µs Note: For the exact specification please refer to the data sheet of the selected derivative. User’s Manual ADC_X41, V2.1 16-20 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter 16.5 A/D Converter Interrupt Control At the end of each conversion, interrupt request flag ADCIR in interrupt control register ADC_CIC is set. This end-of-conversion interrupt request may cause an interrupt to vector ADCINT, or it may trigger a PEC data transfer which reads the conversion result from register ADC_DAT, e.g. to store it into a table in internal RAM for later evaluation. The interrupt request flag ADEIR in register ADC_EIC will be set either, if a conversion result overwrites a previous value in register ADC_DAT (error interrupt in standard mode), or if the result of an injected conversion has been stored into ADC_DAT2 (endof-injected-conversion interrupt). This interrupt request may be used to cause an interrupt to vector ADEINT, or it may trigger a PEC data transfer. ADC_CIC ADC Conversion Intr. Ctrl. Reg. SFR (FF98H/CCH) 15 14 13 12 11 10 9 - - - - GPX - - ADC_EIC ADC Error Intr. Ctrl. Reg. 15 14 13 12 11 - - - - rw 10 9 8 GPX - 7 6 5 ADC ADC IR IE rwh 4 3 - - rw 7 ADE ADE IR IE rwh rw 1 0 GLVL rw rw rw 6 2 ILVL SFR (FF9AH/CDH) - 8 Reset Value: - - 00H Reset Value: - - 00H 5 4 3 2 1 0 ILVL GLVL rw rw Note: Please refer to the general Interrupt Control Register description for an explanation of the control fields. User’s Manual ADC_X41, V2.1 16-21 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter 16.6 Interfaces of the ADC Module The ADC is connected to its environment in different ways. Internal Connections The capture/compare signal CC31IO of the CAPCOM2 unit and the timer T13 period match signal of the CAPCOM6 unit are connected to the ADC, providing optional trigger sources for injected conversions. The 2 interrupt request lines of the ADC are connected to the interrupt control block. External Connections The analog input signals for the ADC are connected with Port 5 of the XC164 (input only). Two dedicated pins (VAREF and VAGND) provide the analog reference voltage for the conversion mechanism. User’s Manual ADC_X41, V2.1 16-22 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) The Analog/Digital Converter System Control Unit (SCU) fADC P5.0/AN0 ADCDIS P5.1/AN1 P5.2/AN2 Interrupt Control Block P5.3/AN3 ADC_CIRQ P5.4/AN4 ADC_EIRQ P5.5/AN5 P5.6/AN6 ADC Module CAPCOM2 Unit Port P5 Control CC31_CIT P5.7/AN7 P5.8 P5.9 P5.10/AN10 CAPCOM6 Unit P5.11/AN11 T13_PM P5.12/AN12 P5.13/AN13 VAREF P5.14/AN14 VGND P5.15/AN15 GPT External Inputs MCA05417_X4 Figure 16-6 ADC Module IO Interface User’s Manual ADC_X41, V2.1 16-23 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units 17 Capture/Compare Units The XC164 provides two, almost identical, Capture/Compare (CAPCOM) units, which only differ in the way they are connected to the pins. Each CAPCOM unit provides 16 capture/compare channels, which interact with 2 timers. A CAPCOM channel can capture the contents of a timer on specific internal or external events, or it can compare a timer’s contents with given values, and modify output signals in case of a match. Data Registers Control Registers T0, T0REL Port Registers Interrupt Control T01CON T0IC T1, T1REL T1IC T7, T7REL E T8, T8REL E T78CON T7IC T8IC CC0-CC3 CC1_M0 CC0IC-CC3IC CC4-CC7 CC1_M1 CC4IC-CC7IC CC8-CC11 CC1_M2 CC8IC-CC11IC P9, DP9 CC12-CC15 CC1_M3 CC12IC-CC15IC ODP9 CC16-CC19 CC2_M4 CC16IC-CC19IC E CC20-CC23 CC2_M5 CC20IC-CC23IC E CC24-CC27 CC2_M6 CC24IC-CC27IC E CC28-CC31 CC2_M7 CC28IC-CC31IC E CC1/2_OUT E CC1/2_SEE P1L, P1H CC1/2_SEM DP1L, DP1H E CC1/2_DRM ALTSEL0P1L/H E CC1/2_IOC CC0...15 CC0...15IC CCM0...3 T01CON T0, T1 T0/1REL T0IC, T1IC CC1/2_SEE CC1/2_SEM CC1/2_DRM CC1/2_OUT CC1/2_IOC ALTSEL0/1P9 CAPCOM1 Register 0...15 CAPCOM1 Intr. Ctrl. Reg. 0...15 CAPCOM1 Mode Ctrl. Reg. 0...3 CAPCOM1 Timer Control Reg. CAPCOM1 Timer Register CAPCOM1 Timer Reload Register CAPCOM1 Timer x Intr. Ctrl. Reg. CAPCOM Single Event En. Reg. CAPCOM Single Event Mode Reg. CAPCOM Double Reg. Mode Reg. CAPCOM Output Register CAPCOM Input/Outp. Control Reg. SYSCON3 CC16...31 CC16...31IC CCM4...7 T78CON T7, T8 T7/8REL T7IC, T8IC Px DPx ODPx ALTSEL0Px SYSCON3 E CAPCOM2 Register 16...31 CAPCOM2 Intr. Ctrl. Reg. 16...31 CAPCOM2 Mode Ctrl. Reg. 4...7 CAPCOM2 Timer Control Reg. CAPCOM2 Timer Register CAPCOM2 Timer Reload Register CAPCOM2 Timer x Intr. Ctrl. Reg. Port x Data Register Port x Direction Control Register Port x Open Drain Control Register Port x Alternate Outp. Select Reg.0 System Ctrl. Reg. 3 (Per. Mgmt.) mc_capcom120101_registers_x4.vsd Figure 17-1 SFRs Associated with the CAPCOM Units User’s Manual CC12_X41, V2.1 17-1 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units With this mechanism, each CAPCOM unit supports generation and control of timing sequences on up to 16 channels with a minimum of software intervention. From the programmer’s point of view, the term ‘CAPCOM unit’ refers to a set of registers which are associated with this peripheral, including the port pins which may be used for alternate input/output functions, and their direction control bits (see also Figure 17-1). A CAPCOM unit is typically used to handle high speed IO tasks such as pulse and waveform generation, pulse width modulation, or recording of the time when a specific event occurs. It also supports the implementation of up to 16 software-controlled interrupt events. Each CAPCOM Unit consists of two 16-bit timers (T0/T1, T7/T8), each with its own reload register (TxREL), and a bank of sixteen dual-purpose 16-bit capture/compare registers (CCy). The input clock for the CAPCOM timers is programmable to several prescaled values of the module input clock (fCC), or it can be derived from the overflow/underflow of timer T6. T0/T7 may also operate in counter mode (from an external input), clocked by external events. Each capture/compare register may be programmed individually for capture or compare operation, and each register may be allocated to either of the two timers. Each capture/compare register has one signal associated with it, which serves as an input signal for the capture operation or as an output signal for the compare operation. The capture operation causes the current timer contents to be latched into the respective capture/compare register, triggered by an event (transition) on the associated input signal. This event also activates the associated interrupt request line. The compare operation may cause an output signal transition on the associated output signal, when the allocated timer increments to the value stored in a capture/compare register. The compare match event also activates the associated interrupt request line. In Double-register compare mode a pair of registers controls one common output signal. The compare output signals are available via a dedicated output register, and may also control the output latches of the connected port pins. The output path can be selected. For the switching of the output signals two timing schemes (see Section 17.8) can be selected: In Staggered Mode1) the output signals are switched consecutively in 8 steps, which distributes the switching steps over a certain time. In staggered mode, the maximum resolution is 8 tCC. In Non-Staggered Mode the output signals are switched immediately at the same time. In non-staggered mode, the maximum resolution is 1 tCC. Figure 17-2 shows the basic structure of a CAPCOM unit. 1) Staggered mode is compatible with the CAPCOM units of previous 16-bit controllers. User’s Manual CC12_X41, V2.1 17-2 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units Reload Reg. T0REL/T7REL fCC T0IN/T7IN T6OUF T0/T7 Input Control Timer T0/T7 CCxIRQ CCxIRQ CCxIO CCxIO Mode Control (Capture or Compare) Sixteen 16-bit Capture/ Compare Registers CCxIRQ CCxIO fCC T6OUF T0IRQ, T7IRQ T1/T8 Input Control Timer T1/T8 T1IRQ, T8IRQ Reload Reg. T1REL/T8REL CAPCOM1 provides channels x = 0 … 15, CAPCOM2 provides channels x = 16 … 31. (see signals CCxIO and CCxIRQ) MCB05418 Figure 17-2 CAPCOM Unit Block Diagram User’s Manual CC12_X41, V2.1 17-3 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units 17.1 The CAPCOM Timers The primary use of the timers T0/T7 and T1/T8 is to provide two independent time bases for the capture/compare channels of each unit. The maximum resolution is 8 tCC in staggered mode, and 1 tCC in non-staggered mode. The basic structure of the two timers, illustrated in Figure 17-3, is identical, except for the input pin (see mark). Reload Reg. TxREL fCC Prescaler TxI T6OUF Edge TxIN fTx TxM MUX TxI Count TxR Select TxI Timer Tx TxIRQ to Capure/Compare Register Array x = 0, 1, 7, 8 MCB05419 Figure 17-3 Block Diagram of a CAPCOM Timer Note: When an external input signal is connected to the input lines of both T0 and T7, these timers count the input signal synchronously. Thus, the two timers can be regarded as one timer whose contents can be compared with 32 compare registers. The functions of the CAPCOM timers are controlled via the bit-addressable control registers T01CON and T78CON. The high-byte of T01CON controls T1, the low-byte of T01CON controls T0. The high-byte of T78CON controls T8, the low-byte of T78CON controls T7. The control options are identical for all four timers (except for external input). In all modes, the timers are always counting upward. The current timer values are accessible for the CPU in the timer registers Tx, which are non bit-addressable registers. When the CPU writes to a register Tx in the state immediately before the respective timer increment or reload is to be performed, the CPU write operation has priority and the increment or reload is disabled to guarantee correct timer operation. User’s Manual CC12_X41, V2.1 17-4 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units CC1_T01CON Timer 0/1 Control Register 15 14 13 12 11 - T1R - T1M - rw - rw SFR (FF50H/A8H) 10 CC2_T78CON Timer 7/8 Control Register 15 14 13 12 11 - T8R - T8M - rw - rw 9 8 Reset Value: 0000H 7 6 5 4 T1I - T0R - T0M T0I rw - rw - rw rw SFR (FF20H/90H) 10 9 8 3 2 1 0 Reset Value: 0000H 7 6 5 4 3 2 1 T8I - T7R - T7M T7I rw - rw - rw rw Field Bits Type Description TxR 14, 6 rw Timer/Counter Tx Run Control 0 Timer/Counter Tx is disabled 1 Timer/Counter Tx is enabled TxM 11, 3 rw Timer/Counter Tx Mode Selection 0 Timer Mode 1 Counter Mode TxI [10:8], [2:0] rw Timer/Counter Tx Input Selection Timer Mode (TxM = 0): Input frequency fTx = fCC/2(<TxI>+3) or fCC/2(<TxI>), depending on (non-)staggered mode, see Table 17-1 Counter Mode (TxM = 1): 000 Overflow/Underflow of GPT Timer T6 001 Positive (rising) edge on pin TxIN 010 Negative (falling) edge on pin TxIN 011 Any edge (rising and falling) on pin TxIN 1XX Reserved. Do not use this combination! 0 Note: For timers T1 and T8 the only option in counter mode is 000B. T1 and T8 stop in other cases. The timer run flags TxR allow the starting and stopping of the timers. The following description of the timer modes and operation always applies to the enabled state of the timers, i.e. the respective run flag is assumed to be set. User’s Manual CC12_X41, V2.1 17-5 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units Timer Mode In Timer Mode (TxM = 0), the input clock for a CAPCOM timer is derived from fCC, divided by a programmable prescaler. Each timer has its own individual prescaler, controlled through the individual bitfields TxI in the timer control registers T01CON and T78CON. The input frequency fTx for a timer Tx and its resolution rTx are determined by the following formulas: Staggered Mode: f CC [ MHz ] f Tx [ MHz ] = ------------------------( <Txl> + 3 ) 2 ( <Txl> + 3 ) 2 r Tx [ µs ] = ------------------------f CC [ MHz ] (17.1) Non-Staggered Mode: f CC [ MHz ] f Tx [ MHz ] = ------------------------<Txl> 2 <Txl> 2 r Tx [ µs ] = ------------------------f CC [ MHz ] (17.2) When a timer overflows from FFFFH to 0000H, it is reloaded with the value stored in its respective reload register TxREL. The reload value determines the period PTx between two consecutive overflows of Tx as follows: Staggered Mode: 16 ( <Txl> + 3 ) ( 2 – <TxREL> ) × 2 P Tx [ µs ] = ------------------------------------------------------------------------f CC [ MHz ] (17.3) Non-Staggered Mode: 16 <Txl> ( 2 – <TxREL> ) × 2 P Tx [ µs ] = ---------------------------------------------------------------f CC [ MHz ] (17.4) After a timer has been started by setting its run flag (TxR), the first increment will occur within the time interval which is defined by the selected timer resolution. All further increments occur exactly after the time defined by the timer resolution. Examples for timer input frequencies, resolution and periods, which result from the selected prescaler option in TxI when using a 40 MHz clock, are listed in Table 17-1 below. The numbers for the timer periods are based on a reload value of 0000H. Note that some numbers may be rounded. User’s Manual CC12_X41, V2.1 17-6 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units Table 17-1 Timer Tx Input Clock Selection for Timer Mode, fCC = 40 MHz TxI Prescaler Input Frequency Resolution Period Non-Staggered Mode 000B 8 5 MHz 200 ns 13.11 ms 001B 16 2.5 MHz 400 ns 26.21 ms 010B 32 1.25 MHz 800 ns 52.43 ms 011B 64 625 kHz 1.6 µs 104.86 ms 100B 128 312.5 kHz 3.2 µs 209.72 ms 101B 256 156.25 kHz 6.4 µs 419.43 ms 110B 512 78.125 kHz 12.8 µs 838.86 ms 111B 1024 39.0625 kHz 25.6 µs 1677.72 ms Non-Staggered Mode 000B 1 40 MHz 25 ns 1.6384 ms 001B 2 20 MHz 50 ns 3.2768 ms 010B 4 10 MHz 100 ns 6.5536 ms 011B 8 5 MHz 200 ns 13.11 ms 100B 16 2.5 MHz 400 ns 26.21 ms 101B 32 1.25 MHz 800 ns 52.43 ms 110B 64 625 kHz 1.6 µs 104.86 ms 111B 128 312.5 kHz 3.2 µs 209.72 ms User’s Manual CC12_X41, V2.1 17-7 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units Counter Mode In Counter Mode (TxM = 1), the input clock of a CAPCOM timer is either derived from an associated external input pin, T0IN/T7IN, or from the over-/underflows of GPT timer T6. Using an external signal connected to pin TxIN as a counting signal is only possible for timers T0 and T7. The only counter option for timers T1 and T8 is using the over/underflows of the GPT timer T6 (selected by TxI = 000B). Bitfields T0I/T7I are used to select either a positive, a negative, or both a positive and a negative transition of the external signal at pin T0IN/T7IN to trigger an increment of timer T0/T7. Please note that certain criteria must be met for the external signal and the port pin programming for this mode in order to operate properly. These conditions are detailed in Chapter 17.10. Timer Overflow and Reload When a CAPCOM timer contains the value FFFFH at the time a new count trigger occurs, a timer interrupt request is generated, and the timer is loaded with the contents of its associated reload register TxREL. The timer then resumes incrementing with the next count trigger starting from the reloaded value. The reload registers TxREL are not bitaddressable. After reset, they contain the value 0000H. User’s Manual CC12_X41, V2.1 17-8 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units 17.2 CAPCOM Timer Interrupts Upon a timer overflow the corresponding timer interrupt request flag TxIR for the respective timer will be set. This flag can be used to generate an interrupt or trigger a PEC service request, when enabled by the respective interrupt enable bit TxIE. Each timer has its own bitaddressable interrupt control register and its own interrupt vector. The organization of the interrupt control registers TxIC is identical with the other interrupt control registers. CC1_T0IC CAPCOM T0 Intr. Ctrl. Reg. 15 14 13 12 11 SFR (FF9CH/CEH) 10 9 - - - - 14 13 12 - - 11 - - - - 10 14 13 12 9 - - 11 - - - - 10 14 13 12 9 - - 11 - - - - 8 7 6 rw rwh 8 7 rw rwh 10 9 8 7 - - rw rwh rw 0 rw rw Reset Value: - - 00H 5 4 3 2 1 0 ILVL GLVL rw rw Reset Value: - - 00H 5 4 3 2 1 0 ILVL GLVL rw rw rw 6 1 GLVL rw 6 2 ILVL rw GPX T8IR T8IE - 3 ESFR (F17CH/BFH) - rwh GPX T7IR T7IE CC2_T8IC CAPCOM T8 Intr. Ctrl. Reg. 15 rw 4 ESFR (F17AH/BEH) - 5 GPX T1IR T1IE CC2_T7IC CAPCOM T7 Intr. Ctrl. Reg. 15 6 SFR (FF9EH/CFH) - 7 GPX T0IR T0IE CC1_T1IC CAPCOM T1 Intr. Ctrl. Reg. 15 8 Reset Value: - - 00H Reset Value: - - 00H 5 4 3 2 1 0 ILVL GLVL rw rw Note: Please refer to the general Interrupt Control Register description for an explanation of the control fields. User’s Manual CC12_X41, V2.1 17-9 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units 17.3 Capture/Compare Channels The 16-bit capture/compare registers CC0 through CC15 (CC16 through CC31) are used as data registers for capture or compare operations with respect to timers T0/T7 and T1/T8. The capture/compare registers are not bit-addressable. The functions of the 16 capture/compare registers of a unit are controlled by 4 bitaddressable 16-bit mode control registers, named CC1_M0 … CC1_M3 (CC2_M4 … CC2_M7), which are all organized identically (see description below). Each register contains the bits for mode selection and timer allocation for four capture/comp. registers. Capture/Compare Registers for the CAPCOM1 Unit (CC15 … CC0) CC1_M0 CAPCOM Mode Ctrl. Reg. 0 15 14 13 12 11 10 SFR (FF52H/A9H) 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 ACC 3 MOD3 ACC 2 MOD2 ACC 1 MOD1 ACC 0 MOD0 rw rw rw rw rw rw rw rw CC1_M1 CAPCOM Mode Ctrl. Reg. 1 15 14 13 12 11 10 SFR (FF54H/AAH) 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 ACC 7 MOD7 ACC 6 MOD6 ACC 5 MOD5 ACC 4 MOD4 rw rw rw rw rw rw rw rw CC1_M2 CAPCOM Mode Ctrl. Reg. 2 15 14 13 12 11 10 SFR (FF56H/ABH) 9 8 7 6 5 4 3 2 1 MOD11 ACC 10 MOD10 ACC 9 MOD9 ACC 8 MOD8 rw rw rw rw rw rw rw rw 15 14 13 12 11 10 SFR (FF58H/ACH) 9 8 7 6 5 4 3 2 1 MOD15 ACC 14 MOD14 ACC 13 MOD13 ACC 12 MOD12 rw rw rw rw rw rw rw rw 17-10 0 Reset Value: 0000H ACC 15 User’s Manual CC12_X41, V2.1 0 Reset Value: 0000H ACC 11 CC1_M3 CAPCOM Mode Ctrl. Reg. 3 0 0 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units Capture/Compare Registers for the CAPCOM2 Unit (CC31 … CC16) CC2_M4 CAPCOM Mode Ctrl. Reg. 4 15 14 13 12 11 10 SFR (FF22H/91H) 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 ACC 19 MOD19 ACC 18 MOD18 ACC 17 MOD17 ACC 16 MOD16 rw rw rw rw rw rw rw rw CC2_M5 CAPCOM Mode Ctrl. Reg. 5 15 14 13 12 11 10 SFR (FF24H/92H) 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 ACC 23 MOD23 ACC 22 MOD22 ACC 21 MOD21 ACC 20 MOD20 rw rw rw rw rw rw rw rw CC2_M6 CAPCOM Mode Ctrl. Reg. 6 15 14 13 12 11 10 SFR (FF26H/93H) 9 8 7 6 5 4 3 2 1 MOD27 ACC 26 MOD26 ACC 25 MOD25 ACC 24 MOD24 rw rw rw rw rw rw rw rw 15 14 13 12 11 10 SFR (FF28H/94H) 9 8 7 6 0 Reset Value: 0000H ACC 27 CC2_M7 CAPCOM Mode Ctrl. Reg. 7 0 0 Reset Value: 0000H 5 4 3 2 1 ACC 31 MOD31 ACC 30 MOD30 ACC 29 MOD29 ACC 28 MOD28 rw rw rw rw rw rw rw rw 0 Field Bits Type Description ACCy 15, 11, 7, 3 rw Allocation Bit for CAPCOM Register CCy 0 CCy allocated to Timer T0 or T7, respectively 1 CCy allocated to Timer T1 or T8, respectively MODy [14:12], [10:8], [6:4], [2:0] rw Mode Selection for CAPCOM Register CCy See Table 17-2. User’s Manual CC12_X41, V2.1 17-11 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units Each of the registers CCy may be individually programmed for capture mode or for one of 4 different compare modes, and may be allocated individually to one of the two timers of the respective CAPCOM unit. A special double-register compare mode combines two registers to act on one common output signal. When capture or compare operations are disabled for one of the CCy registers, it may be used for general purpose variable storage. Table 17-2 Selection of Capture Modes and Compare Modes Mode MODy Selected Operating Mode Disabled 000 Disable Capture and Compare Modes The respective CAPCOM register may be used for general variable storage. Capture 001 Capture on Positive Transition (Rising Edge) at Pin CCyIO 010 Capture on Negative Transition (Falling Edge) at Pin CCyIO 011 Capture on Positive and Negative Transition (Both Edges) at Pin CCyIO 100 Compare Mode 0: Interrupt Only Several interrupts per timer period. Can enable double-register compare mode for Bank2 registers. 101 Compare Mode 1: Toggle Output Pin on each Match Several compare events per timer period. Can enable double-register compare mode for Bank1 registers. 110 Compare Mode 2: Interrupt Only Only one interrupt per timer period. 111 Compare Mode 3: Set Output Pin on each Match Reset output pin on each timer overflow; only one interrupt per timer period. Compare The detailed discussion of the capture and compare modes is valid for all the capture/compare channels, so registers, bits and pins are only referenced by a placeholder. Note: For channels not connected to a pin, only compare modes 0 and 2 make sense. A capture or compare event on channel 31 may be used to trigger a channel injection on the XC164’s A/D converter if enabled. User’s Manual CC12_X41, V2.1 17-12 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units 17.4 Capture Mode Operation In Capture Mode, the current contents of a CAPCOM timer are latched (captured) into the respective capture/compare register in response to an external event. This is used, for example, to record the time at which an external event has occurred, or to measure the distance between two external events in timer increments. The event to cause a capture of a timer’s contents can be programmed to be either the positive, the negative, or both the positive and the negative transition of the external signal connected to the input pin. This triggering transition is selected by bitfield MODy in the respective mode control register. When the selected external signal transition occurs, the selected timer’s contents is latched into the capture/compare register and the respective interrupt request line CCyIRQ is activated. This can cause an interrupt or PEC service request, when enabled. Note: A capture input can be used as an additional external interrupt input. The capture operation can be disregarded in this case. Either the contents of timer T0/T7 or T1/T8 can be captured, selected by the timer allocation control bit ACCy in the respective mode control register. Timer T0/T7 ACCy Timer T1/T8 Interrupt Requests MUX Input Clock Edge CCyIO CCyIRQ Select Capture Register CCy MODy MCB05420 Figure 17-4 Capture Mode Block Diagram For capture operation, the respective pin must be programmed for input. To ensure that a transition of the input signal is recognized correctly, its level must be held high or low for a minimum number of module clock cycles before it changes. This information can be found in Section 17.10. User’s Manual CC12_X41, V2.1 17-13 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units 17.5 Compare Mode Operation The compare modes allow triggering of events (interrupts and/or output signal transitions) or generation of pulse trains with minimum software overhead. In all compare modes, the 16-bit value stored in a capture/compare register CCy (in the following also referred to as ‘compare value’) is continuously compared with the contents of the allocated timer (T0/T7 or T1/T8). If the current timer contents match the compare value, the interrupt request line associated with register CCy is activated and, depending on the compare mode, an output signal can be generated at the corresponding output pin CCyIO. Four different compare modes are available, which can be selected individually for each of the capture/compare registers by bitfield MODy in the respective mode control register. Modes 0 and 2 do not influence the output signals. In the following, each mode is described in detail. In addition to these ‘single-register’ modes, a ‘double-register’ compare mode enables two registers to operate on the same pin. This feature can further reduce software overhead, as two different compare values can be programmed to control a sequence of transitions for a signal. See Section 17.5.5 for details for this operation. In all Compare Modes, the comparator performs an ‘equal to’ comparison. This means, a match is only detected when the timer contents are equal to the contents of a compare register. In addition, the comparator is only enabled in the clock cycle directly after the timer was incremented by hardware. This is done to prevent repeated matches if the timer does not operate with the highest possible input clock (either in timer or counter mode). In this case, the timer contents would remain at the same value for several or up to thousands of cycles. This operation has the side-effect, that software modifications of the timer contents will have no effect regarding the comparator. If a timer is set by software to the same value stored in one of the compare registers, no match will be detected. If a compare register is set to a value smaller than the current timer contents, no action will take place. For the exact operation of the port output function, please see Section 17.6. When two or more compare registers are programmed to the same compare value1), their corresponding interrupt request flags will be set and the selected output signals will be generated after the allocated timer is incremented to this compare value. Further compare events on the same compare value are disabled2) until the timer is incremented again or written to by software. After a reset, compare events for register CCy will only become enabled, if the allocated timer has been incremented or written to by software and one of the compare modes described in the following has been selected for this register. 1) In staggered mode these interrupts and output signals are generated sequentially (see Section 17.8). 2) Even if more compare cycles are executed before the timer increments (lower timer frequency) a given compare value only results in one single compare event. User’s Manual CC12_X41, V2.1 17-14 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units 17.5.1 Compare Mode 0 This is an interrupt-only mode which can be used for software timing purposes. In this mode, the interrupt request line CCyIRQ is activated each time a match is detected between the contents of the compare register CCy and the allocated timer. A match means, the contents of the timer are equal to (‘=’) the contents of the compare register. Several of these compare events are possible within a single timer period, if the compare value in register CCy is updated during the timer period. The corresponding port signal CCyIO is not affected by compare events in this mode and can be used as general purpose IO. Note: If compare mode 0 is programmed for one of the bank2 registers the doubleregister compare mode may be enabled for this register (see Chapter 17.5.5). 17.5.2 Compare Mode 1 This is a compare mode which influences the associated output signal. Besides this, the basic operation is as in compare mode 0. Each time a match is detected between the contents of the compare register CCy and the allocated timer, the interrupt request line CCyIRQ is activated. In addition, the associated output signal is toggled. Several of these compare events are possible within a single timer period, if the compare value in register CCy is updated during the timer period. Note: If compare mode 1 is programmed for one of the bank1 registers the doubleregister compare mode may be enabled for this register (see Section 17.5.5). For the exact operation of the port output signal, please see Section 17.6. User’s Manual CC12_X41, V2.1 17-15 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units Timer T0/T7 Timer T1/T8 T1IRQ, T8IRQ ACCy MUX T0IRQ, T7IRQ Mode 1 only! Mode & Output Ctrl. MODy Mode Control SEEy SEMy Comparator =? to Port Logic CCyIRQ Compare Register CCy MCB05421 Figure 17-5 Compare Mode 0 and 1 Block Diagram Note: The signal remains unaffected in compare mode 0. Figure 17-6 illustrates a few example cases for compare modes 0 and 1. In all examples, the reload value of the used timer is set to FFF9H. When the timer overflows, it starts counting from this value upwards. In Case 1, register CCy contains the value FFFCH. When the timer reaches this value, a match is detected, and the interrupt request line CCyIRQ is activated. In compare mode 0, this is all that will happen. In compare mode 1, additionally the associated port output is toggled, causing an inversion of the output signal. If the contents of register CCy are not changed, this operation will take place each time the timer reaches the programmed compare value. In Case 2, software reloads the compare register CCy with FFFFH after the first match with FFFCH has occurred. As the timer continues to count up, it finally reaches this new compare value, and a new match is detected, activating the interrupt request line (both modes) and toggling the output signal (compare mode 1). If then the compare value is left unchanged, the next match will occur when the timer reaches FFFFH again. This example illustrates, that further compare matches are possible within the current timer period (this is in contrast to compare modes 2 and 3). User’s Manual CC12_X41, V2.1 17-16 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units Timer Contents FFFF FFFF FFFE FFFE FFFD FFFD FFFC FFFC FFFB FFFB FFFA FFFA FFF9 FFF9 Reload Value = FFF9 CCxIO Case 1 CC0 = FFFF CCxIO Case 2 CC0 = FFFA CC0 = FFFD CC0 = FFFC CCxIO Case 3 CC0 = FFF9 CC0 = FFFA CC0 = FFFC CC0 = FFFF CC0 = FFFB CCxIO Case 4 Symbolizes activation of the interrupt request line CCyIRQ MCT05422 Figure 17-6 Examples for Compare Modes 0 and 1 In Case 3, a new compare value, higher than the current timer contents, causes a new match within the current timer period. The compare register is reloaded with FFFAH after the first match (at FFFCH). However, the timer has already passed this value. Thus, it will take until the timer reaches FFFAH in the following timer period to cause the desired compare match. Reloading register CCy now with a value higher than the current timer contents will cause the next match within this period. In Case 4, the compare values are equal to the timer reload value or to the maximum count value, FFFFH. User’s Manual CC12_X41, V2.1 17-17 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units 17.5.3 Compare Mode 2 Compare mode 2 is an interrupt-only mode similar to compare mode 0. The main difference is that only one compare match, corresponding to one interrupt request, is possible within a given timer period. when a match is detected in compare mode 2 for the first time within a count period of the allocated timer, the interrupt request line CCyIRQ is activated. In addition, all further compare matches within the current timer period are disabled, even if a new compare value, higher than the current timer contents, would be written to the register. This blocking is only released when the allocated timer overflows. A new compare value written to the compare register after the first match will only go into effect within the following timer period. 17.5.4 Compare Mode 3 Compare mode 3 is based on compare mode 2, but additionally influences the associated port pin. Only one compare event is possible within one timer period. When a match is detected in compare mode 3 for the first time within a count period of the allocated timer, the interrupt request line CCyIRQ is activated, and the associated output signal is set to 1. In addition, all further compare matches within the current timer period are disabled, even if a new compare value, higher than the current timer contents, would be written to the register. This blocking is only released when the allocated timer overflows. A new compare value written to the compare register after the first match will only go into effect within the following timer period. The overflow signal is also used to reset the associated output signal to 0. Special attention has to be paid when the compare value is set equal to the timer reload value. In this case, the compare match signal would try to set the output signal, while the timer overflow tries to reset the output signal. This conflict is avoided such that the state of the output signal is left unchanged in this case. Note: When the compare value is changed from a value above the current timer contents to a value below the current timer contents, the new value is not recognized before the next timer period. For the exact operation of the port output signal, please see Section 17.6. User’s Manual CC12_X41, V2.1 17-18 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units Timer T0/T7 T1IRQ, T8IRQ Timer T1/T8 MUX ACCy MUX T0IRQ, T7IRQ ACCy Mode 3 only! Mode & Output Ctrl. MODy Mode Control SEEy SEMy Comparator =? to Port Logic CCyIRQ Compare Register CCy MCB05423 Figure 17-7 Compare Mode 2 and 3 Block Diagram Note: The port latch and signal remain unaffected in compare mode 2. Figure 17-8 illustrates a few timing examples for compare modes 2 and 3. In all examples, the reload value of the used timer is set to FFF9H. When the timer overflows, it starts counting from this value upwards. In Case 1, register CCy contains the value FFFCH. When the timer reaches this value, a match is detected, and the interrupt request line CCyIRQ is activated. In compare mode 2, this is all that will happen. In compare mode 3, additionally the associated port output is set to 1. The timer continues to count, and finally reaches its overflow. At this point, the port output is reset to 0 again. Note that, although not shown in the diagrams, the overflow signal of the timer also activates the associated interrupt request line TxIRQ. If the contents of register CCy are not changed, the port output will be set again during the following timer period, and reset again when the timer overflows. This operation is ideal for the generation of a pulse width modulated (PWM) signal with a minimum of software overhead. The pulse width is varied by changing the compare value accordingly. In Case 2, the compare operation is blocked after the first match within a timer period. After the first match at FFFCH, the interrupt request is generated and the port output is set. In addition, further compare matches are disabled. If now a new compare value is written to register CCy, no interrupt request and no port output influence will take place, although the new compare value is higher than the current timer contents. Only after the overflow of the timer, the compare logic is enabled again, and the next match will be User’s Manual CC12_X41, V2.1 17-19 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units detected at FFFFH. One can see, that this operation is ideal for PWM generation, as software can write a new compare value regardless of whether this value is higher or lower than the current timer contents. It is assured that the new value (usually written to the compare register in the appropriate interrupt service routine) will only go into effect during the following timer period. Timer Contents FFFF FFFF FFFE FFFE FFFD FFFD FFFC FFFC FFFB FFFB FFFA FFFA FFF9 FFF9 Reload Value = FFF9 CCxIO Case 1 CC0 = FFFF CCxIO Case 2 CC0 = FFFA CC0 = FFFC CCxIO Case 3 CC0 = FFFA CC0 = FFFC CCxIO Case 4 MCT05424 Figure 17-8 Timing Example for Compare Modes 2 and 3 Note: In compare mode 2, only interrupt requests are generated, in mode 3, also the output signals are generated. In Case 3, further examples for the operation of the compare match blocking are illustrated. In Case 4, a new compare value is written to a compare register before the first match within the timer period. One can see that, of course, the originally programmed compare match (at FFFAH) will not take place. The first match will be detected at FFFCH. However, it is important to note that the reprogramming of the compare register took place asynchronously - this means, the register was written to without any regard to the current contents of the timer. This is dangerous in the sense that the effect of such an asynchronous reprogramming is not easily predictable. If the timer would have already reached the originally programmed compare value of FFFAH by the time the software User’s Manual CC12_X41, V2.1 17-20 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units wrote to the register, a match would have been detected and the reprogramming would go into effect during the next timer period. The examples in Figure 17-9 show special cases for compare modes 2 and 3. Case 1 illustrates the effect when the compare value is equal to the reload value of the timer. An interrupt is generated in both modes. In mode 3, the output signal is not affected - it remains at the high level. Setting the compare value equal to the reload value easily enables a 100% duty cycle signal for PWM generation. The important advantage here is that the compare interrupt is still generated and can be used to reload the next compare value. Thus, no special treatment is required for this case (see Case 3). Cases 2, 4, and 5 show different options for the generation of a 0% duty cycle signal. Case 2 shows an asynchronous reprogramming of the compare value equal to the reload value. At the end of the current timer period, a compare interrupt will be generated, which enables software to set the next compare value. The disadvantage of this method is that at least two timer periods will pass until a new regular compare value can go into effect. The compare match with the reload value FFF9H will block further compare matches during that timer period. This is additionally illustrated by Case 4. Timer Contents FFFF FFFF FFFE FFFE FFFD FFFD FFFC FFFC FFFB FFFB FFFA FFFA FFF9 FFF9 Reload Value = FFF9 Int. CC0 = FFF9 Int. Int. CCxIO Case 1 Int. CC0 = FFF9 CCxIO Case 2 Int. CC0 = FFF9 Int. Int. CC0 = FFFB CCxIO Case 3 Int. CC0 = FFF9 CCxIO Case 4 Int. CC0 = FFF8 Int. CC0 = FFFC CC0 = FFFC CCxIO Case 5 No Comp. Int. MCT05425 Figure 17-9 Special Cases in Compare Modes 2 and 3 User’s Manual CC12_X41, V2.1 17-21 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units Case 5 shows an option to get around this problem. Here, the compare register is reloaded with FFF8H, a value which is lower than the timer reload value. Thus, the timer will never reach this value, and no compare match will be detected. The output signal will be set to 0 after the first timer overflow. However, after the second overflow, software now reloads the compare register with a regular compare value. As no compare blocking has taken place (since there was no compare match), the newly written compare value will go into effect during the current timer period. 17.5.5 Double-Register Compare Mode The Double-Register Compare Mode makes it possible to further reduce software overhead for a number of applications. In this mode, two compare registers work together to control one output. This mode is selected via the DRM register, or by a special combination of compare modes for the two registers. For double-register compare mode, the 16 capture/compare registers of a CAPCOM unit are regarded as two banks of 8 registers each. The lower eight registers form bank1, while the upper eight registers form bank2. For double-register mode, a bank1 register and a bank2 register form a register pair. Both registers of this register pair operate on the pin associated with the bank1 register. The relationship between the bank1 and bank2 register of a pair and the effected output pins for double-register compare mode is listed in Table 17-3. Table 17-3 Register Pairs for Double-Register Compare Mode CAPCOM1 Unit1) Register Pair CAPCOM2 Unit Register Pair Control Bitfield in Bank 1 Bank 2 CC1DRM Used Output Pin Control Bitfield in CC2DRM Bank 1 Bank 2 Used Output Pin CC0 CC8 – DR0M CC16 CC24 CC16IO DR0M CC1 CC9 – DR1M CC17 CC25 CC17IO DR1M CC2 CC10 – DR2M CC18 CC26 CC18IO DR2M CC3 CC11 – DR3M CC19 CC27 CC19IO DR3M CC4 CC12 – DR4M CC20 CC28 CC20IO DR4M CC5 CC13 – DR5M CC21 CC29 CC21IO DR5M CC6 CC14 – DR6M CC22 CC30 CC22IO DR6M CC7 CC15 – DR7M CC23 CC31 CC23IO DR7M 1) CAPCOM1 is not connected to pins. Therefore, double-register compare mode makes no sense here. The double-register compare mode can be programmed individually for each register pair. Double-register compare mode can be selected via a certain combination of User’s Manual CC12_X41, V2.1 17-22 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units compare modes for the two registers of a pair. The bank1 register must be programmed for mode 1 (with port influence), while the bank2 register must be programmed for mode 0 (interrupt-only). Double-register compare mode can be controlled (this means, enabled or disabled) for each register pair via the associated control bitfield DRxM in register CC1_DRM or CC2_DRM, respectively. CC1_DRM Double-Reg. Cmp. Mode Reg. 15 14 13 12 11 10 SFR (FF5AH/ADH) 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 DR7M DR6M DR5M DR4M DR3M DR2M DR1M DR0M rw rw rw rw rw rw rw rw CC2_DRM Double-Reg. Cmp. Mode Reg. 15 14 13 12 11 10 SFR (FF2AH/95H) 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 DR7M DR6M DR5M DR4M DR3M DR2M DR1M DR0M rw rw rw rw rw rw rw rw Field Bits Type Description DRxM [1:0], [3:2], [5:4], [7:6], [9:8], [11:10], [13:12], [15:14] rw Double Register x Compare Mode Selection 00 DRM is controlled via the combination of compare modes 1 and 0 (compatibility mode) 01 DRM disabled regardless of compare modes 10 DRM enabled regardless of compare modes 11 Reserved Note: “x” indicates the register pair index in a bank. Double-register compare mode can be controlled individually for each of the register pairs. In the block diagram of the double-register compare mode (Figure 17-10), a bank2 register will be referred to as CCz, while the corresponding bank1 register will be referred to as CCy. User’s Manual CC12_X41, V2.1 17-23 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units DRyM Mode Control MODy SEEy DRyM SEEz CCyIRQ Mode & Output Ctrl. SEMy SEMz ACCz Comp. =? Mode Control MODz MUX ACCy Timer T1/T8 MUX Timer T0/T7 Comparator =? Compare Register CCy Compare Register CCz to Port Logic CCzIRQ z=y+8 MCB05426 Figure 17-10 Double-Register Compare Mode Block Diagram When a match is detected for one of the two registers in a register pair (CCy or CCz), the associated interrupt request line (CCyIRQ or CCzIRQ) is activated, and pin CCyIO, corresponding to the bank1 register CCy, is toggled. The generated interrupt always corresponds to the register that caused the match. Note: If a match occurs simultaneously for both register CCy and register CCz of the register pair, pin CCyIO will be toggled only once, but two separate compare interrupt requests will be generated. Each of the two registers of a pair can be individually allocated to one of the two timers in the CAPCOM unit. This offers a wide variety of applications, as the two timers can run in different modes with different resolution and frequency. However, this might require sophisticated software algorithms to handle the different timer periods. Note: The signals CCzIO (which do not serve for double-register compare mode) may be used for general purpose IO. User’s Manual CC12_X41, V2.1 17-24 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units 17.6 Compare Output Signal Generation This section discusses the interaction between the CAPCOM Unit and the Port Logic. The block diagram illustrated in Figure 17-11 details the logic of the block “Mode & Output Control”, shown in Figure 17-5, Figure 17-7, and Figure 17-10. Each output signal is latched in its associated bit of the respective output latch register CCx_OUT. The individual bits are updated each time an associated compare event occurs. The bits of these registers are connected to the respective port pins as an alternate output function of a port line. Compare signals can also directly affect the associated port output latch Px. In this case, the port latch must be selected for the respective pin. The direct port latch option is disabled in non-staggered mode or it can be disabled by setting bit PL in register CCx_IOC. Register CCx_OUT is always updated in parallel to the update of the port output latch. CC1_OUT Compare Output Reg. SFR (FF5CH/AEH) 15 14 13 12 11 10 CC 15 IO CC 14 IO CC 13 IO CC 12 IO CC 11 IO CC CC9 CC8 CC7 CC6 CC5 CC4 CC3 CC2 CC1 CC0 10 IO IO IO IO IO IO IO IO IO IO IO rwh rwh rwh rwh rwh rwh CC2_OUT Compare Output Reg. 9 rwh 8 rwh 7 rwh 6 Reset Value: 0000H rwh 5 rwh 4 rwh SFR (FF2CH/96H) rwh rwh Reset Value: 0000H 12 11 10 CC 15 IO CC 14 IO CC 13 IO CC 12 IO CC 11 IO CC CC9 CC8 CC7 CC6 CC5 CC4 CC3 CC2 CC1 CC0 10 IO IO IO IO IO IO IO IO IO IO IO rwh rwh rwh rwh rwh rwh Bits CCyIO 15 … 0 rwh User’s Manual CC12_X41, V2.1 Type rwh 6 rwh 0 13 rwh 7 1 14 rwh 8 rwh 2 15 Field 9 3 rwh 5 rwh 4 rwh 3 rwh 2 1 rwh rwh 0 rwh Description Compare Output for Channel y Alternative port output for the associated port pin. 17-25 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units STAG _ >1 PL & Compare Match TxOV Output Value Control Port Latch 0 Driver MUX Port Pin Pm.n 1 OUT Latch ALTSEL0Pn Direction MODy CAPCOM Logic Port Logic MCB05427 Figure 17-11 Port Output Block Diagram for Compare Modes Note: A compare output signal is visible at the pin only in compare modes 1 or 3. The output signal of a compare event can either be a 1, a 0, the complement of the current level, or the previous level. The block ‘Output Value Control’ determines the correct new level based on the compare event, the timer overflow signal, and the current states of the Port and OUT latches. For the output toggle function (e.g. in compare mode 1), the state of the output latch is read, inverted, and then written back. The associated output pins either drives the port latch signal or the OUT signal, selected by register ALTSEL (see Figure 17-11). Note: If the port output latch is written to by software at the same time it would be altered by a compare event, the software write will have priority. In this case the hardwaretriggered change will not become effective. User’s Manual CC12_X41, V2.1 17-26 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units 17.7 Single Event Operation If an application requires that one and only one compare event needs to take place (within a certain time frame), single event operation helps to reduce software overhead and to eliminate the need for fast reaction upon events. In order to achieve a single event operation without this feature, software would have to either disable the compare mode or write a new value, which is outside of the count range of the timer, into the compare register, after the programmed compare match has taken place. Thus, usually an interrupt service routine is required to perform this operation. Interrupt response time may be critical if the timer period is very short - the disable operation needs to be completed before the timer would reach the same value again. The single event operation eliminates the need for software to react after the first compare match. The complete operation can be set up before the event, and no action is required after the event. The hardware takes care of generating only one event, and then disabling all further compare matches. This option is programmed via the Single Event Mode register CCx_SEM and the Single Event Enable register CCx_SEE. Each register provides one bit for each CCy register of a unit. CC1_SEM Single Event Mode Ctrl. Reg. 15 14 13 12 11 10 SFR (FE28H/14H) 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 SEM SEM SEM SEM SEM SEM SEM SEM SEM SEM SEM SEM SEM SEM SEM SEM 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 rw rw rw rw rw rw CC2_SEM Single Event Mode Ctrl. Reg. 15 14 13 12 11 10 rw rw rw rw rw rw SFR (FE2CH/16H) 9 8 7 6 rw rw rw rw Reset Value: 0000H 5 4 3 2 1 0 SEM SEM SEM SEM SEM SEM SEM SEM SEM SEM SEM SEM SEM SEM SEM SEM 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 rw rw rw rw rw rw rw rw rw rw rw rw rw rw rw Field Bits Type Description SEMy 15 … 0 rw Single Event Mode Control 0 Single Event Mode disabled for channel y 1 Single Event Mode enabled for channel y User’s Manual CC12_X41, V2.1 17-27 rw V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units CC1_SEE Single Event Enable Reg. 15 14 13 12 11 SFR (FE2EH/17H) 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 SEE SEE SEE SEE SEE SEE SEE SEE SEE SEE SEE SEE SEE SEE SEE SEE 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 rwh rwh rwh rwh rwh rwh CC2_SEE Single Event Enable Reg. 15 14 13 12 11 rwh rwh rwh rwh rwh rwh SFR (FE2AH/15H) 10 9 8 7 6 rwh rwh rwh rwh Reset Value: 0000H 5 4 3 2 1 0 SEE SEE SEE SEE SEE SEE SEE SEE SEE SEE SEE SEE SEE SEE SEE SEE 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 rwh rwh rwh rwh rwh rwh rwh rwh rwh rwh rwh rwh rwh rwh Field Bits Type Description SEEy 15 … 0 rwh Single Event Enable Control 0 Single Event disabled for channel y 1 Single Event enabled for channel y rwh rwh Note: This bit is cleared by hardware after the event. To setup a single event operation for a CCy register, software first programs the desired compare operation and compare value, and then sets the respective bit in register CCx_SEM to enable the single event mode. At last, the respective event enable bit in register CCx_SEE is set. When the programmed compare match occurs, all operations of the selected compare mode take place. In addition, hardware automatically disables all further compare matches and reset the event enable bit in register CCx_SEE to 0. As long as this bit is cleared, any compare operation is disabled. To setup a new event, this bit must first be set again. User’s Manual CC12_X41, V2.1 17-28 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units 17.8 Staggered and Non-Staggered Operation The CAPCOM units can run in one of two basic operation modes: Staggered Mode and Non-Staggered Mode. The selection between these modes is performed via register IOC. CC1_IOC I/O Control Register 15 14 13 12 ESFR (F062H/31H) 11 10 9 3 2 1 0 - - ST AG PL - - - rw rw - CC2_IOC I/O Control Register 15 14 13 12 8 7 6 Reset Value: 0000H 5 4 ESFR (F066H/33H) 11 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 - - ST AG PL - - - rw rw - Field Bits Type Description STAG 2 rw Staggered Mode Control 0 CAPCOM operates in Staggered Mode 1 CAPCOM operates in Non-Staggered Mode PL 1 rw Port Lock Control1) 0 Compare output signals affect the associated port output latch 1 Direct influence of the port output latch by the compare output signals is disabled 1) CAPCOM1 is not connected to pins. Therefore, port control options make no sense here. Note: Whenever Non-Staggered Mode is enabled (STAG = 1) or Port Lock is activated (PL = 1), the port output registers are not changed by the CAPCOM unit. In staggered mode, a CAPCOM operation cycle consists of 8 module clock cycles, and the outputs of the compare events of the different registers are staggered, that is, the outputs for compare matches with the same compare value are not switched at the same time, but with a fixed time delay. This operation helps to reduce noise and peak power consumption caused by simultaneous switching outputs. In non-staggered Mode, a CAPCOM operation cycle is equal to one module clock cycle, and all compare outputs for compare events with the same compare value are switched User’s Manual CC12_X41, V2.1 17-29 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units in the same clock cycle. This mode offers a faster operation and increased resolution of the CAPCOM unit, 8 times higher than in staggered mode. Staggered Mode Figure 17-12 illustrates the staggered mode operation. In this example, all CCy registers are programmed for compare mode 3. Registers CC0, CC1, and CC2 are all programmed for a compare value of FFFEH. When the timer increments to FFFEH, the comparator detects a match for all of the three registers. The output CC0IO of register CC0 is switched to 1 one cycle after the comparator match. However, the outputs CC1IO and CC2IO are not switched at the same time, but one, respectively two cycles later. This staggering of the outputs continues for all registers including register CC7. The number of the register indicates the delay of the output signal in clock cycles - the output of register CC7 is switched 7 cycles later than the one of register CC0. In the example, the compare value for register CC7 is set to FFFDH. Thus, the output is switched in the last clock cycle of the CAPCOM cycle in which the timer reached FFFDH. When the timer overflows, all compare outputs are reset to 0 (compare mode 3). Again, the staggering of the output signals can be seen from Figure 17-12. Looking at registers CC8 through CC15 shows that their outputs are switched in parallel to the respective outputs of registers CC0 through CC15. In fact, the staggering is performed in parallel for the upper and the lower register bank. In this way, it is assured, that both compare signals of a register pair in double-register compare mode operate simultaneously. In staggered mode direct port latch switching (see Section 17.6) is possible. However, it is possible to use the alternate output function option of the associated port pins to output the compare signals. Note: This is a general description and only refers to channels connected to pins. User’s Manual CC12_X41, V2.1 17-30 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units Timer contents = FFFD Timer increments to FFFE Timer increments to FFFF Timer overflow Timer is reloaded with FFFC 1 CAPCOM Cycle = 8 fCC Clock Cycles 1 CAPCOM Cycle = 8 fCC Clock Cycles CC0 = FFFE CC1 = FFFE CC2 = FFFE CC3 = FFFF CC4 = FFFE CC5 = FFFF CC6 = FFFF CC7 = FFFD CC8 = FFFE CC9 = FFFE CC10 = FFFE CC11 = FFFF CC12 = FFFE CC13 = FFFF CC14 = FFFF CC15 = FFFD MCT05428 Figure 17-12 Staggered Mode Operation User’s Manual CC12_X41, V2.1 17-31 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units Non-Staggered Mode To gain maximum speed and resolution with the CAPCOM unit, it can be switched to non-staggered mode. In this mode, one CAPCOM operation cycle is equal to one module clock cycle. Timer increment and the comparison of its new contents with the contents of the compare register takes place within one clock cycle. The appropriate output signals are switched in the following clock cycle (in parallel to the next possible timer increment and comparison). Figure 17-13 illustrates the non-staggered mode. Note that when the timer overflows, it also takes one additional clock cycle to switch the output signals. Note: In non-staggered mode, direct port latch switching is disabled. This is a general description and only refers to channels connected to pins. User’s Manual CC12_X41, V2.1 17-32 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units Timer contents = FFFD Timer increments to FFFE Timer increments to FFFF Timer overflow Timer is reloaded with FFFC 1 CAPCOM Cycle = 1 fCC Clock Cycle 1 CAPCOM Cycle = 1 fCC Clock Cycle CC0 = FFFE CC1 = FFFE CC2 = FFFE CC3 = FFFF CC4 = FFFE CC5 = FFFF CC6 = FFFF CC7 = FFFD CC8 = FFFE CC9 = FFFE CC10 = FFFE CC11 = FFFF CC12 = FFFE CC13 = FFFF CC14 = FFFF CC15 = FFFD MCT05429 Figure 17-13 Non-Staggered Mode Operation User’s Manual CC12_X41, V2.1 17-33 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units 17.9 CAPCOM Interrupts Upon a capture or compare event, the interrupt request flag CCxIR for the respective capture/compare register CCx is automatically set. This flag can be used to generate an interrupt or trigger a PEC service request when enabled by the interrupt enable bit CCxIE. Capture interrupts can be regarded as external interrupt requests with the additional feature of recording the time at which the triggering event occurred. Each of the capture/compare registers has its own bitaddressable interrupt control register and its own interrupt vector allocated. These registers are organized in the same way as all other interrupt control registers. The basic register layout is shown below, Table 17-4 lists the associated addresses. CCx_CCyIC CAPCOM Intr. Ctrl. Reg. 15 14 13 12 11 (E)SFR (Table 17-4) 10 9 - - - - 8 GPX - - - rw 7 6 CCy CCy IR IE rwh rw Reset Value: - - 00H 5 4 3 2 1 0 ILVL GLVL rw rw Note: Please refer to the general Interrupt Control Register description for an explanation of the control fields. User’s Manual CC12_X41, V2.1 17-34 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units Table 17-4 CAPCOM Unit Interrupt Control Register Addresses CAPCOM1 Unit CAPCOM2 Unit Register Name Address Reg. Space Register Name Address Reg. Space CC1_CC0IC FF78H/BCH SFR CC2_CC16IC F160H/B0H ESFR CC1_CC1IC FF7AH/BDH SFR CC2_CC17IC F162H/B1H ESFR CC1_CC2IC FF7CH/BEH SFR CC2_CC18IC F164H/B2H ESFR CC1_CC3IC FF7EH/BFH SFR CC2_CC19IC F166H/B3H ESFR CC1_CC4IC FF80H/C0H SFR CC2_CC20IC F168H/B4H ESFR CC1_CC5IC FF82H/C1H SFR CC2_CC21IC F16AH/B5H ESFR CC1_CC6IC FF84H/C2H SFR CC2_CC22IC F16CH/B6H ESFR CC1_CC7IC FF86H/C3H SFR CC2_CC23IC F16EH/B7H ESFR CC1_CC8IC FF88H/C4H SFR CC2_CC24IC F170H/B8H ESFR CC1_CC9IC FF8AH/C5H SFR CC2_CC25IC F172H/B9H ESFR CC1_CC10IC FF8CH/C6H SFR CC2_CC26IC F174H/BAH ESFR CC1_CC11IC FF8EH/C7H SFR CC2_CC27IC F176H/BBH ESFR CC1_CC12IC FF90H/C8H SFR CC2_CC28IC F178H/BCH ESFR CC1_CC13IC FF92H/C9H SFR CC2_CC29IC F184H/C2H ESFR CC1_CC14IC FF94H/CAH SFR CC2_CC30IC F18CH/C6H ESFR CC1_CC15IC FF96H/CBH SFR CC2_CC31IC F194H/CAH ESFR User’s Manual CC12_X41, V2.1 17-35 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units 17.10 External Input Signal Requirements The external input signals of a CAPCOM unit are sampled by the CAPCOM logic based on the module clock and the basic operation mode (staggered or non-staggered mode). To assure that a signal level is recognized correctly, its high or low level must be held active for at least one complete sampling period. The duration of a sampling period is one module clock cycle in non-staggered mode, and 8 module clock cycles in staggered mode. To recognize a signal transition, the signal needs to be sampled twice. If the level of the first sampling is different to the level detected during the second sampling, a transition is recognized. Therefore, a minimum of two sampling periods are required for the sampling of an external input signal. Thus, the maximum frequency of an input signal must not be higher than half the module clock frequency in non-staggered mode, and a 1/16th of the module clock frequency in staggered mode. Table 17-5 summarizes the requirements and limits for external input signals. Table 17-5 CAPCOM External Input Signal Limits Non-Staggered Mode fCC/2 Minimum Input Signal Level 1/fCC Staggered Mode fCC/16 8/fCC Maximum Input Frequency Duration In order to use an external signal as a count or capture input, the port pin to which it is connected must be configured as input. Note: For example for test purposes a pin used as a count or capture input may be configured as output. Software or an other peripheral may control the respective signal and thus trigger count or capture events. In order to cause a compare output signal to be seen by the external world, the associated port pin must be configured as output. Compare output signals can either directly switch the port latch, or the output of the CCx_OUT latch is used as an alternate output function of a port. User’s Manual CC12_X41, V2.1 17-36 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units 17.11 Interfaces of the CAPCOM Units The CAPCOM units CAPCOM1 (see Figure 17-14) and CAPCOM2 (see Figure 17-15) are connected to their environment in different ways. Internal Connections The overflow/underflow signal T6OUF of GPT2 timer T6 is connected to the CAPCOM units, providing an optional clock source for the CAPCOM timers. The 18 interrupt request lines of each CAPCOM unit are connected to the interrupt control block. Note: The upper 8 input lines from PORT1, connected with the CAPCOM2 unit, can also be used as individual external interrupt inputs. The interrupt request line of channel 31 is connected to the ADC, as a possible trigger source for injected conversions. External Connections Twelve capture/compare signals of the CAPCOM2 unit are connected with input/output ports of the XC164. Depending on the selected direction, these ports may provide capture trigger signals from the external system or issue compare output signals to external circuitry. Note: Capture trigger signals may also be derived from output pins. In this case, software can generate the trigger edges, for example. Timer T0 can be clocked by an external signal. User’s Manual CC12_X41, V2.1 17-37 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units System Control Unit (SCU) fCC CC0IO CC1DIS CC1IO CC2IO GPT12 Unit T6OUF CC3IO CC4IO T0IRQ CC5IO T1IRQ CC6IO CC0IRQ CC7IO CC1IRQ CC2IRQ CC8IO CC3IRQ CC4IRQ CC5IRQ CC6IRQ Interrupt Control CC7IRQ CAPCOM1 Module CC9IO CC9IRQ CC13IO CC12IRQ P1H.2/EX2IN CC11IO CC8IRQ CC11IRQ P1H.1/EX1IN CC10IO CC12IO CC10IRQ P1H.0/EX0IN P1H.3/EX3IN P1H.4/EX4IN P1H.5/EX5IN CC14IO P1H.6/EX6IN CC15IO P1H.7/EX7IN CC13IRQ CC14IRQ T0IN CC15IRQ Alternate Input Select External Interrupt Inputs EXnIN Alternate External Interrupt Input MCA05430_X4 Figure 17-14 CAPCOM1 Unit Interfaces User’s Manual CC12_X41, V2.1 17-38 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Units System Control Unit (SCU) fCC CC16IO CC2DIS CC17IO P9.0/CC16IO P9.1/CC17IO CC18IO GPT12 Unit T6OUF CC19IO Port P9 Control CC20IO T7IRQ P9.5/CC21IO T8IRQ CC22IO CC17IRQ CC23IO CC18IRQ CC20IRQ Interrupt Control P1L.7/CC22IO P1H.0/CC23IO CC24IO CC19IRQ CAPCOM2 Module CC25IO CC21IRQ CC26IO CC22IRQ CC27IO Port P1 Control CC28IO CC25IRQ CC29IO CC26IRQ CC27IRQ CC28IRQ P1H.4/CC24IO P1H.5/CC25IO P1H.6/CC26IO P1H.7/CC27IO CC23IRQ CC24IRQ P9.3/CC19IO P9.4/CC20IO CC21IO CC16IRQ P9.2/CC18IO CC30IO CC31IO CC29IRQ CC30IRQ T7IN CC31IRQ Port P2 Control P1H.3/T7IN ADC Injection Trigger MCA05431_X4 Figure 17-15 CAPCOM2 Unit Interfaces User’s Manual CC12_X41, V2.1 17-39 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18 Capture/Compare Unit 6 (CAPCOM6) The CAPCOM6 unit is made up of a Timer T12 Block with three capture/compare channels and a Timer T13 Block with one compare channel. The T12 channels can independently generate PWM signals or accept capture triggers, or they can jointly generate control signal patterns to drive AC-motors or inverters. Special operating modes support the control of Brushless DC-motors using Hall sensors or Back-EMF detection. Furthermore, block commutation and control mechanisms for multi-phase machines are supported. Data Registers Control Registers System Registers Interrupt Control T12 X CMPSTAT X CCU6_IS X P1L T12PR X CMPMODIF X CCU6_ISS X DP1L E T12DTC X TCTR0 X CCU6_ISR X ALTSEL0P1L E CC60R X TCTR2 X CCU6_INP X CC60SR X TCTR4 X CCU6_IEN X CC61R X MODCTR X CC61SR X TRPCTR X CCU6_T12IC E CC62R X PSLR X CCU6_T13IC E CC62SR X MCMOUTS X CCU6_EIC E T13 X MCMOUT X CCU6_IC E T13PR X MCMCTR X CC63R X T12MSEL X CC63SR X T12/T13 CAPCOM6 Timer T12/T13 Register T12PR/T13PR CAPCOM6 T12/T13 Period Register T12DTC CAPCOM6 T12 Deadtime Control Reg. TCTRx CAPCOM6 Timer Control Register T12MSEL T12 Capture/Compare Mode Select Reg. CC6xR CAPCOM6 Capture/Compare Register CC6xSR CAPCOM6 Capt./Comp. Shadow Reg. CMPSTAT Capture/Compare State Register CMPMODIF Capture/Comp. State Modification Reg. MODCTR Modulation Control Register MCMOUT Multi-Channel Mode Output Register MCMOUTS Multi-Ch. Mode Output Shadow Reg. MCMCTR Multi-Channel Mode Control Register TRPCTR PSLR IS ISS/ISR IEN INP T12IC/T13IC CCU6_IC CCU6_EIC P1L/P1H DP1L/DP1H ALTSEL0P1x SYSCON3 P1H DP1H E ALTSEL0P1H E SYSCON3 E Trap Control Register Passive State Level Register Interrupt Status Register Interrupt Status Set/Reset Register Interrupt Enable Register Interrupt Node Pointer Register CAPCOM6 Timer Interrupt Control Reg. CAPCOM6 Interrupt Control Register CAPCOM6 Error Interrupt Control Reg. PORT1 Data Register PORT1 Direction Control Register PORT1 Alternate Outp. Select Reg. 0 System Control Reg. 3 (Per. Mgmt.) mc_capcom60100_registers.vsd Figure 18-1 SFRs Associated with the CAPCOM6 Unit User’s Manual CAPCOM6_X, V2.0 18-1 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) A rich set of status bits, synchronized updating of parameter values via shadow registers, and flexible generation of interrupt request signals provide means for efficient software-control. Timer 12 Block Features • • • • • • • • • Three capture/compare channels, each channel can be used either as capture or as compare channel Generation of a three-phase PWM supported (six outputs, individual signals for highside and lowside switches) 16-bit resolution, maximum count frequency = peripheral clock Dead-time control for each channel to avoid short-circuits in the power stage Concurrent update of the required T12/T13 registers Center-aligned and edge-aligned PWM can be generated Single-shot mode supported Many interrupt request sources Hysteresis-like control mode Timer 13 Block Features • • • • • One independent compare channel with one output 16-bit resolution, maximum count frequency = peripheral clock Can be synchronized to T12 Interrupt generation at period-match and compare-match Single-shot mode supported Additional Features • • • • • • • • Block commutation for Brushless DC-drives implemented Position detection via Hall-sensor pattern Hall-Effect noise filter Automatic rotational speed measurement for block commutation Integrated error handling Fast emergency stop without CPU load via external signal (CTRAP) Control modes for multi-channel AC-drives Output levels can be selected and adapted to the power stage User’s Manual CAPCOM6_X, V2.0 18-2 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Module Kemel Compare Channel 3 Compare Interrupt Control 1 3+3 2 2 2 Trap Input T13 Output Select Start Trap Control Hall Input 1 Multichannel Control Output Select Channel 2 DeadTime Control Compare 1 Compare Clock Control Channel 1 Compare T12 1 Capture Address Decoder Channel 0 3 1 CTRAP CCPOS2 CCPOS1 CCPOS0 CC62 COUT62 CC61 COUT61 CC60 COUT60 COUT63 T13RH T12HR Input / Output Control Port Control MCB05506 Figure 18-2 CAPCOM6 Block Diagram The Timer T12 can work in capture and/or compare mode for its three channels. The modes can also be combined. The Timer T13 can work in compare mode only. The multichannel control unit generates output patterns which can be modulated by T12 and/or T13. The modulation sources can be selected and combined for the signal modulation. User’s Manual CAPCOM6_X, V2.0 18-3 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.1 Timer T12 Block The timer T12 block is the main unit to generate the 3-phase PWM. A 16-bit counter is connected to 3 channel registers via comparators, which generate a signal when the counter contents match one of the channel register contents. A variety of control functions facilitate the adaptation of the T12 structure to different application needs. Besides the 3-phase PWM generation, the T12 block offers options for individual compare and capture functions, as well as dead-time control and hysteresis-like compare mode. State Bits Capture/Compare Channel 60 Timer T12 Logic Ext. Inputs CC60ST Capture/Compare Channel 61 CC61ST Capture/Compare Channel 62 CC62ST To Dead-Time Control and Output Modulation Input and Control/Status Logic MCA05507 Figure 18-3 Overview Diagram of the Timer T12 Block Figure 18-4 shows a detailed block diagram of Timer T12. It receives its input clock, fT12, from the module clock fCC6 via a programmable prescaler and an optional 1/256 divider. These options are controlled via bitfields T12CLK and T12PRE (see Table 18-1). T12 can count up or down, depending on the selected operation mode. A direction flag, CDIR, indicates the current counting direction. Via a comparator, T12 is connected to a Period Register, T12PR. This register determines the maximum count value for T12. In Edge-Aligned mode, T12 is reset to 0000H after it has reached the period value. In Center-Aligned mode, the count direction of T12 is set from ‘up’ to ‘down’ after it has reached the period value (please note that in this mode, T12 exceeds the period value by one before counting down). In both cases, signal T12_PM (T12 Period Match) is generated. The Period Register receives a new period value from its Shadow Period Register, T12PS, which is loaded via software. The transfer of a new period value from the shadow register into T12PR (see Section 18.8) is controlled via the ‘T12 Shadow Transfer’ control signal, T12_ST. The generation of this signal depends on the operating mode and on control bit STE12. Providing a shadow register for the period value as well as for other values related to the generation of the PWM signal facilitates a concurrent update by software for all relevant parameters. User’s Manual CAPCOM6_X, V2.0 18-4 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Two further signals indicate whether the counter contents are equal to 0000H (T12_ZM) or 0001H (T12_OM). These signals control the counting and switching behavior of T12. The basic operating mode of T12, either Edge-Aligned mode (Figure 18-5) or CenterAligned mode (Figure 18-6), is selected via bit CTM. A Single-Shot control bit, T12SSC, enables an automatic stop of the timer when the current counting period is finished (see Figure 18-7 and Figure 18-8). T12STR T12RR T12STD CTM T12RS T12R fCC6 n T12CLK 256 MUX fT12 T12 Control & Status Counter Register T12 CDIR STE12 T12RES T12SSC T12PRE = 0000H = 0001H Comp. =? T12_ZM T12_OM T12_PM T12_SSEP Read-Only Write-Only Period Register T12PR Period Shadow Register T12PR T12_ST MCA05508 Figure 18-4 Timer T12 Logic and Period Comparators The start or stop of T12 is controlled by the Run bit, T12R. This control bit can be set by software via the associated set/reset bits T12RS or T12RR, or it is reset by hardware according to preselected conditions. Timer T12 can be cleared via control bit T12RES. Setting this write-only bit does only clear the timer contents, but has no further effects, for example, it does not stop the timer. The generation of the T12 shadow transfer control signal, T12_ST, is enabled via bit STE12. This bit can be set or reset by software indirectly through its associated set/reset control bits T12STR and T12STD. Note: The control registers to select the T12 operating mode are described in Section 18.3. User’s Manual CAPCOM6_X, V2.0 18-5 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Register T12 represents the counting value of Timer T12. It can only be written while Timer T12 is stopped. Write actions while T12 is running are not taken into account. Register T12 can always be read by software. CCU6_T12 Timer T12 Count Register 15 14 13 12 11 XSFR (E890H/--) 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 T12CV rwh Field Bits Type Description T12CV [15:0] rwh T12 Count Value Represents the 16-bit count value of Timer T12 Register T12PR contains the period value for Timer T12. The period value is compared to the actual count value of T12 and the resulting actions depend on the defined counting rules. CCU6_T12PR Timer T12 Period Register 15 14 13 12 11 XSFR (E892H/--) 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 T12PV rwh Field Bits Type Description T12PV [15:0] rwh T12 Period Value When T12 equals value T12PV a period-match is triggered. When reaching this value, Timer T12 is set to zero (edge-aligned mode) or changes its count direction to down counting (center-aligned mode). This register has a shadow register (using the same address) and the shadow transfer is controlled by bit STE12. A read action by SW delivers the value which is currently used for the period compare, whereas a write action targets the shadow register. The shadow register structure allows concurrent updating of all T12-related values. User’s Manual CAPCOM6_X, V2.0 18-6 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.1.1 Timer T12 Operation The input clock fT12 of Timer T12 is derived from the module clock fCC6 through a programmable prescaler and an optional 1/256 divider. The resulting prescale factors are listed in Table 18-1. The prescaler of T12 is reset while T12 is not running to ensure reproducible timings and delays. Table 18-1 Timer T12 Input Clock Options T12CLK Resulting Input Clock Prescaler Off (T12PRE = 0) Resulting Input Clock Prescaler On (T12PRE = 1) 000B fCC6 fCC6/2 fCC6/4 fCC6/8 fCC6/16 fCC6/32 fCC6/64 fCC6/128 fCC6/256 fCC6/512 fCC6/1024 fCC6/2048 fCC6/4096 fCC6/8192 fCC6/16384 fCC6/32768 001B 010B 011B 100B 101B 110B 111B The period of the timer is determined by the value in the period Register T12PR and by the timer mode. In Edge-Aligned mode, the timer period is: T12PER = <Period-Value> + 1; in T12 clocks (fT12) (18.1) In Center-Aligned mode, the timer period is: T12PER = (<Period-Value> + 1) × 2; in T12 clocks (fT12) (18.2) While Timer T12 is running, write accesses to the count register T12 are not taken into account. If T12 is stopped and the Dead-Time counters are 0, write actions to register T12 are immediately taken into account. User’s Manual CAPCOM6_X, V2.0 18-7 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) As described above, T12 can operate in Edge-Aligned mode or Center-Aligned mode. In both modes, a certain set of ‘counting rules’ determine the behavior of the T12 counter. The counting rules lead to a behavior in Edge-Aligned mode as illustrated in Figure 18-5. In the Center-Aligned mode (T12 counts up and down), the counting rules lead to the behavior shown in Figure 18-6. T12 in Edge-Aligned Mode: • With the next clock of fT12 the counter is reset to zero when a Period-Match is detected. The counting direction is always upwards (CDIR = 0). fT12 Period Value T12 Count Period Zero Match Match Zero Up Up Value n+1 Value n+2 CDIR CC6x Shadow Transfer MCT05509 Figure 18-5 T12 Operation in Edge-Aligned Mode User’s Manual CAPCOM6_X, V2.0 18-8 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) T12 in Center-Aligned mode: • • • With the next clock of fT12 the count direction is set to counting up (CDIR = 0) when the counter reaches 0001H while counting down. With the next clock of fT12 the count direction is set to counting down (CDIR = 1) when the Period-Match is detected while counting up. With the next clock of fT12 the counter counts up while CDIR = 0 and it counts down while CDIR = 1. Note: Bit CDIR changes with the next timer clock after the one-match or the periodmatch. Therefore, the timer continues counting in the previous direction for one cycle before actually changing its direction (see Figure 18-6). fT12 <Period Value> + 1 Period Value Zero Match T12 Count Period Match Period Match Zero Down Up Up Down Value n Value n+1 Value n+1 Value n+2 CDIR CC6x Shadow Transfer Shadow Transfer MCT05510 Figure 18-6 T12 Operation in Center-Aligned Mode User’s Manual CAPCOM6_X, V2.0 18-9 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) T12 Shadow Transfer Signal, T12_ST A special shadow transfer signal (T12_ST) can be generated to facilitate updating the period and compare values synchronously to the operation of T12. The generation of this signal is requested by software via bit STE12 (set by writing 1 to the write-only bit T12STR, cleared by writing 1 to the write-only bit T12STD). If requested (STE12 = 1), signal T12_ST is generated when: • • • a Period-Match is detected while counting up, or the counter reaches 0001H while counting down, or timer T12 is not running (T12R = 0) When signal T12_ST is active, a shadow register transfer is triggered with the next cycle of the T12 clock. A new period value is loaded from the shadow register into the actual period register T12PR, and new compare values are transferred from their shadow registers into the actual compare registers (see Section 18.1.2). With the shadow register transfer bit STE12 is automatically cleared. T12 Start/Stop and Reset Control Timer T12 is counting while bit T12R is set. Software can control the timer’s count operation via bit T12R (set by writing 1 to the write-only bit T12RS, cleared by writing 1 to the write-only bit T12RR). T12R can also be cleared by hardware in Single Shot mode. Software can clear timer T12 by writing 1 to the write-only bit T12RES. This operation only sets the timer contents to 0000H. No further actions will take place, for example, the timer run bit is not cleared. User’s Manual CAPCOM6_X, V2.0 18-10 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Single-Shot Mode The run bit T12R is also influenced by hardware in Single-Shot mode. This mode is enabled through bit T12SSC. When this bit is set, the timer will stop when the current timer period is finished. In Edge-Aligned mode, this is when the timer is cleared to 0000H after having reached the period value. In Center-Aligned mode, the period is finished when the timer has counted down to 0000H. See Figure 18-7 and Figure 18-8. fT12 Compare-Match Period Value Compare Value Zero T12 Count CC6xST T12SSC MCT05511 Figure 18-7 Single-Shot Operation in Edge-Aligned Mode fT12 Compare-Match Compare-Match T12 Count Period Value Compare Value Zero CC6xST T12SSC MCT05512 Figure 18-8 Single-Shot Operation in Center-Aligned Mode User’s Manual CAPCOM6_X, V2.0 18-11 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.1.2 T12 Compare Modes Associated with Timer T12 are three individual capture/compare channels, which can perform compare or capture operations with regard to the contents of the T12 counter. The capture functions are explained in Section 18.1.4. In Compare Mode (see Figure 18-9), the three channels can operate either independently as individual channels, or generate a three-phase PWM pattern. CDIR Counter Register T12 fT12 & & CM_61_DN CM_61_UP Compare Match CM_61 Comp. =? Comp. =? Comp. =? Compare Match CM_62 Compare Match CM_60 Compare Register CC60R Compare Register CC61R Compare Register CC62R T12_ST Compare Shadow Register CC60SR Compare Shadow Register CC61SR Compare Shadow Register CC62SR MCA05513 Figure 18-9 T12 Channel Comparators Each channel is connected to the T12 counter register via its individual equal-to comparator, which generates a match signal when the contents of the counter matches the contents of the associated compare register. Each channel consists of the comparator and a double register structure - the actual compare register CC6xR, feeding the comparator, and an associated shadow register CC6xSR, which is preloaded by software and transferred into the compare register when signal T12 shadow transfer, T12_ST, gets active. Providing a shadow register for the compare value as well as for other values related to the generation of the PWM signal facilitates a concurrent update by software for all relevant parameters (see also Section 18.8). User’s Manual CAPCOM6_X, V2.0 18-12 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Associated with each channel is a State Bit, CC6xST, which holds the status of the compare (or capture) operation (see Figure 18-10). Rising Edge Falling Edge T12R CM_60 CDIR Set/Reset Control Logic CC60ST Compare State Bit CC60ST CC60ST CC60ST Change MCC60S/R MSEL60 Rising Edge Falling Edge CM_61 Set/Reset Control Logic Rising Edge Falling Edge T12_ZM T12_SSEP Compare State Bit CC62ST CC62ST Change MCC62S/R MSEL62 To Interrupt Control CC61ST CC61ST Change Set/Reset Control Logic DTC0_IN CC61ST Compare State Bit CC61ST MCC61S/R MSEL61 CM_62 To Interrupt Control DTC1_IN To Interrupt Control CC62ST CC62ST DTC2_IN MCB05514 Figure 18-10 Compare State Bits Block Diagram for Compare Mode The inputs to the set/reset logic for the CC6xST bits are the timer direction (CDIR), the timer run bit (T12R), the timer zero-match signal (T12_ZM), the end-of-single-shot mode signal (T12_SSEP), and the actual individual compare-match signals CM_6x as well as the mode control bits, MSEL6x. In addition, each state bit can be set or reset by software via the appropriate set and reset bits, MCC6xS and MCC6xR. Note: In Hall Sensor mode, additional inputs are taken into account (see Section 18.5). User’s Manual CAPCOM6_X, V2.0 18-13 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) A hardware-modification of a State Bit CC6xST is only possible while Timer T12 is running (T12R = 1). If this is the case, the following rules apply for setting and resetting the State Bits in Compare Mode (illustrated in Figure 18-11 and Figure 18-12): A State Bit CC6xST is set to 1 • • with the next T12 clock (fT12) after a compare-match when T12 is counting up (i.e., when the counter is incremented above the compare value); with the next T12 clock (fT12) after a zero-match AND a parallel compare-match when T12 is counting up. A State Bit CC6xST is reset to 0 • • with the next T12 clock (fT12) after a compare-match when T12 is counting down (i.e., when the counter is decremented below the compare value); with the next T12 clock (fT12) after a zero-match AND NO parallel compare-match when T12 is counting up. fT12 Compare-Match Compare-Match Period Value Compare Value Zero T12 Count CC6xST MCT05515 Figure 18-11 Compare Operation, Edge-Aligned Mode fT12 Compare-Match Compare-Match T12 Count Period Value Compare Value Zero CC6xST MCT05516 Figure 18-12 Compare Operation, Center-Aligned Mode User’s Manual CAPCOM6_X, V2.0 18-14 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Figure 18-13 illustrates some more examples for compare waveforms. It is important to note that in these examples, it is assumed that some of the compare values are changed while the timer is running. This change is performed via a software preload of the Shadow Register, CC6xSR. The value is transferred to the actual Compare Register CC6xR with the T12 Shadow Transfer signal, T12_ST, which is assumed to be enabled. fT12 Period Value = 5 T12 Count Zero Down Up Down Up Value n Value n+1 Value n+2 Value n+3 CC6x = 2 CC6x = 2 CC6x = 1 CC6x = 1 CC6x = 1 CC6x = 0 CC6x = 0 CC6x = 0 CC6x = 3 CC6x = 3 CC6x = 3 CC6x = 3 CC6x = 4 CC6x = 4 CC6x = 4 CC6x = 4 CC6x = 5 CC6x = 5 CC6x = 5 CC6x = 5 CC6x = 3 CC6x = 6 CC6x = 6 CC6x = 6 CDIR CC6x a) b) c) d) e) f) MCT05517 Figure 18-13 Compare Waveform Examples Example b) illustrates the transition to a duty cycle of 100%. First, a compare value of 0001H is used, then changed to 0000H. Please note that a low pulse with the length of one T12 clock is still produced in the cycle where the new value 0000H is in effect; this pulse originates from the previous value 0001H. In the following timer cycles, the State Bit CCxST remains at 1, producing a 100% duty cycle signal. In this case, the compare rule ‘zero-match AND compare-match’ is in effect. User’s Manual CAPCOM6_X, V2.0 18-15 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Example f) shows the transition to a duty cycle of 0%. The new compare value is set to <Period-Value> + 1, and the State Bit CC6ST remains cleared. Figure 18-14 illustrates an example for the waveforms of all three channels. With the appropriate dead-time control and output modulation, a very efficient 3-phase PWM signal can be generated. Period Value CC60R CC62R T12 Count Down Up Down Up CC61R Zero Down CDIR Shadow Transfer CC60ST CC61ST CC62ST MCT05518 Figure 18-14 Three-Channel Compare Waveforms User’s Manual CAPCOM6_X, V2.0 18-16 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Compare Mode Output Path Figure 18-15 gives an overview on the signal path from a channel State Bit to its output pin in its simplest form. As illustrated, a user has a variety of controls to determine the desired output signal switching behavior in relation to the current state of the State Bit, CC6xST. Please refer to Chapter 18.7 for details on the output modulation. State Selection CC6xPS CC6xST & DTRx CC6xST State Bit CC6xST Dead-Time Generation Output Modulation T12 MODENx PSLx CC6x_O Level Select COUT6x_O Level Select CC6x To Output Pins DTCx_IN CC6xST & DTRx COUT6xPS COUT6x T12 PSLy MODENy MCA05519 Figure 18-15 Compare Mode Simplified Output Path Diagram User’s Manual CAPCOM6_X, V2.0 18-17 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Compare Mode Registers In compare mode, registers CC6xR (x = 0, 1, 2) are the actual compare registers for T12. The values stored in CC6xR are compared (all three channels in parallel) to the count value of T12. Registers CC6xR can only be read by SW, the modification of the value is done by a shadow register transfer from the corresponding shadow registers CC6xSR. These registers can be read and written by SW. In capture mode, the current value of the T12 counter register is captured into registers CC6xR or CC6xSR when the corresponding capture event is detected (depending on the selected mode). CCU6_CC60R Channel 0 Capt./Comp. Reg. 15 14 13 12 11 10 XSFR (E898H/--) 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 CC60V rh CCU6_CC61R Channel 1 Capt./Comp. Reg. 15 14 13 12 11 10 XSFR (E89AH/--) 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 CC61V rh CCU6_CC62R Channel 2 Capt./Comp. Reg. 15 14 13 12 11 10 XSFR (E89CH/--) 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 CC62V rh Field Bits Type Description CC6xV (x = 0, 1, 2) [15:0] rh Channel x Compare Value In compare mode, the bitfields CC6xV contain the values that are compared to the T12 count value. In capture mode, the captured value of T12 can be read from these registers. User’s Manual CAPCOM6_X, V2.0 18-18 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) CCU6_CC60SR Ch. 0 Capt./Cmp. Shadow Reg. XSFR (E8A0H/--) 15 14 13 12 11 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 CC60S rwh CCU6_CC61SR Ch. 1 Capt./Cmp. Shadow Reg. XSFR (E8A2H/--) 15 14 13 12 11 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 CC61S rwh CCU6_CC62SR Ch. 2 Capt./Cmp. Shadow Reg. XSFR (E8A4H/--) 15 14 13 12 11 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 CC62S rwh Field Bits Type Description CC6xS (x = 0, 1, 2) [15:0] rwh Shadow Register for Channel x Compare Value In compare mode, the contents of bitfields CC6xS are transferred to bitfields CC6xV in registers CC6xR during a shadow transfer. In capture mode, the captured value of T12 can be read from these registers. User’s Manual CAPCOM6_X, V2.0 18-19 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Register T12MSEL contains control bits to select the capture/compare functionality of the three channels of Timer T12. CCU6_T12MSEL T12 Mode Select Register 11 XSFR (E8C6H/--) 10 9 8 7 Reset Value: 0000H 15 14 13 12 6 5 4 3 2 1 - - - - MSEL62 MSEL61 MSEL60 - - - - rw rw rw 0 Field Bits Type Description MSEL62 MSEL61 MSEL60 [11:8] [7:4] [3:0] rw Capture/Compare Mode Selection These bitfields select the operating mode of the three T12 capture/compare channels. Each channel (x = 0, 1, 2) can be programmed individually for one of these modes (except for Hall Sensor Mode). See Table 18-2. Table 18-2 Capture/Compare Modes Overview MSEL6x Selected Operating Mode 0000B Compare outputs disabled, pins CC6x and COUT6x can be used for IO. 0001B Compare output on pin CC6x, pin COUT6x can be used for IO. 0010B Compare output on pin COUT6x, pin CC6x can be used for IO. 0011B Compare output on pins COUT6x and CC6x. 01XXB Double-Register Capture modes, see Chapter 18.1.4 and Table 18-3. 1000B Hall Sensor Mode, see Chapter 18.5. In order to properly enable this mode, all three MSEL6x fields have to be programmed to Hall Sensor mode. 1001B Hysteresis-like mode, see Chapter 18.1.5. 101XB 11XXB Multi-Input Capture modes, see Chapter 18.1.4 and Table 18-4. Note: Channel status information is available through the channel state (modification) registers, described in Section 18.3. User’s Manual CAPCOM6_X, V2.0 18-20 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.1.3 Dead-Time Generation The generation of (complementary) signals for the highside and the lowside switches of one power inverter phase is based on the same compare channel. For example, if the highside switch should be active while the T12 counter value is above the compare value (State Bit = 1), then the lowside switch should be active while the counter value is below the compare value (State Bit = 0). In most cases, the switching behavior of the connected power switches is not symmetrical concerning the switch-on and switch-off times. A general problem arises if the time for switch-on is smaller than the time for switch-off of the power device. In this case, a short-circuit can occur in the inverter bridge leg, which may damage the complete system. In order to solve this problem by HW, this capture/compare unit contains a programmable Dead-Time Generation Block, which is able to delay the passive to active edge of the switching signals (the active to passive edge is not delayed). The Dead-Time Generation Block, illustrated in Figure 18-16, is built in a similar way for all three channels of T12. Any change of a CC6xST bit triggers the corresponding DeadTime Counter, a single-shot 6-bit down counter which is clocked with the same input clock as T12 (fT12). A trigger pulse DTCx_IN, activated by the change of the State Bit CC6xST, leads to a reload of the dead-time counter with the value DTM stored in register T12DTC and starts the counter. Reload Value DTM DTC0_IN DTE0 DTC1_IN & DTE1 6-bit Down Counter DTC2_IN & DTE2 6-bit Down Counter & 6-bit Down Counter DTR2 fT12 DTRES DTR1 DTR0 MCB05520 Figure 18-16 Dead-Time Generation Block Diagram User’s Manual CAPCOM6_X, V2.0 18-21 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) While counting down, the output line DTRx is 0. Thus, the reload value determines the length of the low phase (the passive state) of the output signal, and therefore the delay of the 0-to-1 transition of the State Bit outputs. The active state of the output signal is represented by a 1. The programmable reload value DTM applies to all three channels. When the counter reaches zero, the counter is stopped and output line DTRx is set to 1. While DTRx is 0 both outputs are forced into passive state. While DTRx is 1 the outputs can go to active state. Each of the three dead-time counters has its individual enable control bit, DTEx, for the trigger input, DTCx_IN. A reload of a counter is only possible while the counter is not running. This avoids a possible retriggering of the dead-time if a change in the State Bit CC6xST is detected. Figure 18-17 illustrates the waveforms of the dead-time generation (passive state = 0). The associated registers are detailed below. T12 Count Compare CC6xST CC6xST DTCx_IN Down Counter DTRx CC6xST & DTRx CC6xST & DTRx MCT05521 Figure 18-17 Dead-Time Generation Waveforms User’s Manual CAPCOM6_X, V2.0 18-22 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Register T12DTC controls the dead-time generation for the T12 compare channels. Each channel can be independently enabled/disabled for dead-time generation. If enabled, the transition from passive state to active state is delayed by the value defined by bitfield DTM. CCU6_T12DTC T12 Dead-Time Control Reg. 15 - 14 13 12 DTR DTR DTR 2 1 0 rh rh rh 11 10 XSFR (E894H/--) 9 8 DTE DTE DTE 2 1 0 - rw rw rw Reset Value: 0000H 7 6 5 4 3 2 - - DTM - - rw 1 0 Field Bits Type Description DTR2 DTR1 DTR0 14, 13, 12 rh Dead Time Run Indication Flags Indicate the status of the dead-time generation for each corresponding compare channel (0, 1, 2) 0 The dead-time counter is stopped 1 The dead-time counter is running (delay is active) DTE2 DTE1 DTE0 10, 9, 8 rw Dead-Time Generation Enable Bits Enable/disable the dead-time generation for each corresponding compare channel (0, 1, 2) 0 Dead-time generation is disabled 1 Dead-time generation is enabled DTM [5:0] rw Dead-Time Value DTM specifies the programmable delay between switching from the passive state to the active state of the selected outputs Note: The Dead-Time Counters can be cleared by setting bit DTRES in register TCTR4. User’s Manual CAPCOM6_X, V2.0 18-23 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.1.4 T12 Capture Modes Each of the three channels of the T12 Block can also be used to capture T12 time information in response to an external signal. There are a number of different modes for capture operation. In all modes, both of the registers of a channel are used. This can reduce the interrupt rate to the CPU, as it needs to react only to every second event. The selection of the capture modes is done via the MSEL6x bitfields in register T12MSEL and can be selected individually for each of the channels. Table 18-3 Capture Modes Overview MSEL6x Mode Pin Active Edge CC6nSR Stored in T12 Stored in 0100B 1 CC6x Rising – CC6xR CC6x Falling – CC6xSR 0101B 2 CC6x Rising CC6xR CC6xSR 0110B 3 CC6x Falling CC6xR CC6xSR 0111B 4 CC6x Any CC6xR CC6xSR Figure 18-18 illustrates Capture Mode 1. When a rising edge (0-to-1 transition) is detected at the corresponding input pin CC6x, the current contents of Timer T12 are captured into register CC6xR. When a falling edge (1-to-0 transition) is detected at pin CC6x, the contents of Timer T12 are captured into register CC6xSR. fT12 MSEL6x CC6x Counter Register T12 MSEL6x Rising Edge Falling Select Detect Set State Bit CC6xST Register CC6xR Shadow Register CC6xSR To Interrupt Logic MCB05522 Figure 18-18 Capture Mode 1 Block Diagram User’s Manual CAPCOM6_X, V2.0 18-24 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Capture Modes 2, 3 and 4 are shown in Figure 18-19. They differ only in the active edge causing the capture operation. In each of the three modes, when the selected edge is detected at the corresponding input pin CC6x, the current contents of the shadow register CC6xSR are latched into register CC6xR, and the current Timer T12 contents are captured in register CC6xSR (simultaneous transfer). The active edge is a rising edge at pin CC6x for Capture Mode 2, a falling edge for Mode 3, and both, a rising or a falling edge for Capture Mode 4, as shown in Table 18-3. These capture modes are very useful in cases where there is little time between two consecutive edges of the input signal. Counter Register T12 fT12 MSEL6x CC6x MSEL6x Edge Shadow Register CC6xSR Select Detect Set State Bit CC6xST Register CC6xR Rising Falling To Interrupt Logic MCB05523 Figure 18-19 Capture Modes 2, 3 and 4 Block Diagram User’s Manual CAPCOM6_X, V2.0 18-25 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Five further capture modes are called Multi-Input Modes, as they use two different external inputs, pin CC6x and pin CC6POSx. fT12 MSEL6x CC6x Counter Register T12 MSEL6x Edge Select Detect Set State Bit CC6xST Set Register CC6xR Rising Falling CC6POSx Shadow Register CC6xSR To Interrupt Logic Edge Select Detect MSEL6x MSEL6x MCB05524 Figure 18-20 Multi-Input Capture Modes Block Diagram In each of these modes, the current T12 contents are latched in register CC6xR in response to a selected event at pin CC6x, and in register CC6xSR in response to a selected event at pin CC6POSx. The possible events can be opposite input transitions, or the same transitions, or any transition at the two input pins. The different options are detailed in Table 18-4. In each of the various capture modes, the Channel State Bit, CC6xST, is set to 1 when the selected capture trigger event at pin CC6x or CC6POSx has occurred. The State Bit must be reset by software. In addition, appropriate signal lines to the interrupt logic are activated, which can generate an interrupt request to the CPU. Regardless of the selected active edge, all edges detected at pin CC6x lead to the activation of the appropriate interrupt request line (see also Section 18.9). User’s Manual CAPCOM6_X, V2.0 18-26 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Table 18-4 Multi-Input Capture Modes Overview MSEL6x Mode Pin Active Edge T12 Stored in 1010B 5 CC6x Rising CC6xR CCPOSx Falling CC6xSR CC6x Falling CC6xR CCPOSx Rising CC6xSR CC6x Rising CC6xR CCPOSx Rising CC6xSR CC6x Falling CC6xR CCPOSx Falling CC6xSR CC6x Any CC6xR CCPOSx Any CC6xSR 1011B 1100B 1101B 1110B 1111B 6 7 8 9 – User’s Manual CAPCOM6_X, V2.0 reserved (no capture or compare action) 18-27 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.1.5 Hysteresis-Like Control Mode The hysteresis-like control mode (MSEL6x = 1001B) offers the possibility to switch off the PWM output if the input CCPOSx becomes 0 by resetting bit CC6xST. This can be used as a simple motor control feature by using a comparator indicating, e.g., overcurrent. While CCPOSx = 0, the PWM outputs of the corresponding channel are driving their passive levels. The setting of bit CC6xST is only possible while CCPOSx = 1. CC6POSx T12R CDIR Edge Detect CM_6x T12_ZM T12_SSEP Set/ Reset Control Logic Bit CC6xST + Dead-Time Generation MCC6xS/R MSELx2 State Select Logic CC6xO COUT6xO MCA05525 Figure 18-21 Hysteresis-Like Control Mode Logic In this mode, the State Bit CC6xST is reset when pin CC6POSx shows a negative edge. As long as input CC6POSx is 0, the outputs of the State Bit are in passive state. When CC6POSx is at high level, the outputs can be in active state and are determined by bit CC6xST (see Figure 18-10 for the state bit logic and Figure 18-15 for the output paths). This mode can be used to introduce a timing-related behavior to a hysteresis controller. A standard hysteresis controller detects if a value exceeds a limit and switches its output according to the compare result. Depending on the operating conditions, the switching frequency and the duty cycle are not fixed, but change permanently. If (outer) time-related control loops based on a hysteresis controller (inner loop) should be implemented, the outer loops show a better behavior if they are synchronized to the inner loops. Therefore, the hysteresis-like mode can be used, which combines timerrelated switching with a hysteresis controller behavior. For example, in this mode, an output can be switched on according to a fixed time base, but it is switched off as soon as a falling edge is detected at input CCPOSx. This mode can be used for standard PWM with overcurrent protection. As long as there is no low level signal at pin CC6POSx, the output signals are generated in the normal manner as described in the previous sections. Only if input CC6POSx shows a low level, e.g. due to the detection of overcurrent, the outputs are shut off to avoid harmful stress to the system. User’s Manual CAPCOM6_X, V2.0 18-28 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.2 Timer T13 Block Timer T13 is implemented similarly to Timer T12, but only with one channel in compare mode. A 16-bit up-counter is connected to a channel register via a comparator, which generates a signal when the counter contents match the contents of the channel register. A variety of control functions facilitate the adaptation of the T13 structure to different application needs. In addition, T13 can be triggered synchronously to timer T12 events. State Bit Timer T13 Logic Compare Channel 63 CC63ST Control/Status Logic To Output Modulation MCA05526 Figure 18-22 Overview Diagram of the Timer T13 Block Figure 18-23 shows a detailed block diagram of Timer T13. It receives its input clock, fT13, from the module clock fCC6 via a programmable prescaler and an optional 1/256 divider. T13 can only count up (similar to the Edge-Aligned mode of T12). Via a comparator, T13 is connected to a Period Register, T13PR. This register determines the maximum count value for T13. When T13 reaches the period value, signal T13_PM (T13 Period Match) is generated and T13 is reset to 0000H with the next T13 clock edge. The Period Register receives a new period value from its Shadow Period Register, T13PS, which is loaded via software. The transfer of a new period value from the shadow register into T13PR is controlled via the ‘T13 Shadow Transfer’ control signal, T13_ST. The generation of this signal depends on the associated control bit STE13. Providing a shadow register for the period value as well as for other values related to the generation of the PWM signal facilitates a concurrent update by software for all relevant parameters (see also Section 18.8). Another signal indicates whether the counter contents are equal to 0000H (T13_ZM). A Single-Shot control bit, T13SSC, enables an automatic stop of the timer when the current counting period is finished (see Figure 18-25). User’s Manual CAPCOM6_X, V2.0 18-29 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) T13STR T13TEC T13RR T13STD T13TED T13RS fCC6 n 256 MUX fT13 T13R T13 Control & Status Counter Register T13 STE13 T13RES T13SSC T13CLK T13PRE = 0000H Comp. =? T13_ZM T13_PM T13_ST Read-Only Period Register T13PR Write-Only Period Shadow Register T13PS MCA05527 Figure 18-23 T13 Counter Logic and Period Comparators The start or stop of T13 is controlled by the Run bit, T13R. This control bit can be set by software via the associated set/reset bits T13RS or T13RR, or it is reset by hardware according to preselected conditions. Timer T13 can be cleared to 0000H via control bit T13RES. Setting this write-only bit only clears the timer contents, but has no further effects, e.g., it does not stop the timer. The generation of the T13 shadow transfer control signal, T13_ST, is enabled via bit STE13. This bit can be set or reset by software indirectly through its associated set/reset control bits T13STR and T13STD. Two bitfields, T13TEC and T13TED, control the synchronization of T13 to Timer T12 events. T13TEC selects the trigger event, while T13TED determines for which T12 count direction the trigger should be active. Note: The T13 Period Register and its associated shadow register are located at the same physical address. A write access to this address targets the Shadow Register, while a read access reads from the actual period register. User’s Manual CAPCOM6_X, V2.0 18-30 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Register T13 represents the counting value of Timer T13. It can only be written while Timer T13 is stopped. Write actions while T13 is running are not taken into account. Register T13 can always be read by SW. CCU6_T13 Timer T13 Count Register 15 14 13 12 11 XSFR (E8B0H/--) 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 T13CV rwh Field Bits Type Description T13CV [15:0] rwh Timer T13 Count Value Represents the 16-bit count value of Timer T13 Register T13PR contains the period value for Timer T13. The period value is compared to the actual count value of T13 and T13 is reset when the two values match. This register has a shadow register and the shadow transfer is controlled by bit STE13. A read action by SW delivers the value which is currently used for the period compare, whereas a write action targets the shadow register. The shadow register structure allows a concurrent update of all T13-related values. CCU6_T13PR Timer T13 Period Register 15 14 13 12 11 XSFR (E8B2H/--) 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 T13PV rwh Field Bits Type Description T13PV [15:0] rwh T13 Period Value T13PV defines the count value for T13 which leads to a Period-Match. When reaching this value, Timer T13 is set to zero. User’s Manual CAPCOM6_X, V2.0 18-31 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.2.1 T13 Operation The input clock fT13 of Timer T13 is derived from the module clock fCC6 through a programmable prescaler and an optional 1/256 divider. The resulting prescale factors are listed in Table 18-5. The prescaler of T13 is reset while T13 is not running to ensure reproducible timings and delays. Table 18-5 Timer T13 Input Clock Options T13CLK Resulting Input Clock Prescaler Off (T13PRE = 0) Resulting Input Clock Prescaler On (T13PRE = 1) 000B fCC6/1 fCC6/2 fCC6/4 fCC6/8 fCC6/16 fCC6/32 fCC6/64 fCC6/128 fCC6/256 fCC6/512 fCC6/1024 fCC6/2048 fCC6/4096 fCC6/8192 fCC6/16384 fCC6/32768 001B 010B 011B 100B 101B 110B 111B The period of the timer is determined by the value in the period Register T13PR according to the following formula: T13PER = <Period-Value> + 1; in T13 clocks (fT13) (18.3) While Timer T13 is running, write accesses to the count register T13 are not taken into account. If T13 is stopped, write actions to register T13 are immediately taken into account. As described above, T13 can only count up, comparable to the Edge-Aligned mode of T12. This leads to very simple ‘counting rules’ for the T13 counter: • The counter is reset to zero with the next T13 clock edge if a Period-Match is detected. The counting direction is always upwards. The behavior of T13 is illustrated in Figure 18-24. User’s Manual CAPCOM6_X, V2.0 18-32 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) fT13 Period Value Period Zero Match Match T13 Count Zero CC63 Value n+1 Value n+2 Shadow Transfer MCT05528 Figure 18-24 T13 Operation T13 Shadow Transfer Signal, T13_ST A special shadow transfer signal (T13_ST) can be generated to facilitate updating the period and compare values synchronously to the operation of T13. The generation of this signal is requested by software via bit STE13 (set by writing 1 to the write-only bit T13STR, cleared by writing 1 to the write-only bit T13STD). If requested (STE13 = 1), signal T13_ST is generated when: • • the counter is reset to 0000H after the Period-Match, or timer T13 is not running (T13R = 0) With signal T13_ST, a new period value is loaded from the shadow register into the actual period register T13PR, and a new compare value is transferred from its shadow register into the actual compare register (see Section 18.1.2). T13 Start/Stop and Reset Control Timer T13 is started through software by setting the write-only bit T13RS. This operation sets the timer run bit T13R, and the timer starts counting. To stop the timer, the writeonly bit T13RR needs to be set to 1. The run bit T13R is cleared to 0, and the timer stops counting. The run bit can also be cleared by hardware in Single Shot mode. In addition, T13 can be started by events generated by the T12 Block, which set the run bit T13R. Please see the next sections for details on these modes. Software can clear timer T13 by writing 1 to the write-only bit T13RES. This operation only sets the timer contents to 0000H. No further actions will take place, for example, the timer run bit is not cleared. User’s Manual CAPCOM6_X, V2.0 18-33 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Single-Shot Mode The run bit T13R is also influenced by hardware in Single-Shot mode. This mode is enabled through bit T13SSC. When this bit is set, the timer will stop when the current timer period is finished (see Figure 18-25). This is when the timer is cleared to 0000H after having reached the period value. fT13 Compare-Match Period Value Compare Value T13 Count Zero CC63ST T13SSC MCT05529 Figure 18-25 Single-Shot Operation of Timer T13 User’s Manual CAPCOM6_X, V2.0 18-34 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Synchronization of T13 to T12 Timer T13 can be synchronized to a T12 event. Bitfields T13TEC and T13TED select the event which is used to start Timer T13. The selected event sets bit T13R via HW, and T13 starts counting. Combined with the Single-Shot mode, this feature can be used to generate a programmable delay after a T12 event. Figure 18-26 shows an example for the synchronization of T13 to a T12 event. Here, the selected event is a compare-match (compare value = 2) while counting up. The clocks of T12 and T13 can be different (other prescaler factor); the figure shows an example in which T13 is clocked with half the frequency of T12. fT12 Period Value Compare-Match T12 Count Compare Value Zero T13R T13 Count fT13 MCT05530 Figure 18-26 Synchronization of T13 to T12 Bitfield T13TEC selects the trigger event to start T13 (automatic set of T13R for synchronization to T12 compare signals) according to the combinations shown in Table 18-6. Bitfield T13TED additionally specifies for which count direction of T12 the selected trigger event should be regarded (see Table 18-7). User’s Manual CAPCOM6_X, V2.0 18-35 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Table 18-6 T12 Trigger Event Selection T13TEC Selected Event 000B None. 001B T12 Compare Event on Channel 0. 010B T12 Compare Event on Channel 1. 011B T12 Compare Event on Channel 2. 100B T12 Compare Event on any Channel (0, 1, 2). 101B T12 Period-Match. 110B T12 Zero-Match while counting up. 111B Any Hall State Change. Table 18-7 T12 Trigger Event Additional Specifier T13TED Selected Event Specifier 00B Reserved, no action. 01B Selected event is active while T12 is counting up. 10B Selected event is active while T12 is counting down. 11B Selected event is active independently of the count direction of T12. User’s Manual CAPCOM6_X, V2.0 18-36 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.2.2 T13 Compare Modes Associated with Timer T13 is one compare channel, which can perform compare operations with regard to the contents of the T13 counter. Figure 18-27 gives an overview on the T13 channel in Compare Mode. The channel is connected to the T13 counter register via an Equal-to comparator, which generates a match signal when the contents of the counter matches the contents of the compare register. The channel consists of the comparator and a double register structure - the actual compare register, CC63R, feeding the comparator, and an associated shadow register, CC63SR, which is preloaded by software and transferred into the compare register when signal T13 shadow transfer, T13_ST, gets active. Providing a shadow register for the compare value as well as for other values related to the generation of the PWM signal facilitates a concurrent update by software for all relevant parameters. See also Section 18.8, which provides an overview on this functionality. fT13 Counter Register T13 Comp. =? Compare Match CM_63 Compare Register CC63R T13_ST Compare Shadow Register CC63SR MCA05531 Figure 18-27 T13 Channel Comparator Associated with the channel is a State Bit, CC63ST, which holds the status of the compare operation. This bit is set and reset according to certain conditions, which are explained in more detail in the following sections. Figure 18-28 gives an overview on the logic for the State Bit. User’s Manual CAPCOM6_X, V2.0 18-37 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) T13R CM_63 CC63ST Set/Reset Control Logic T13_ZM State Bit CC63ST T13_SSEP CC63ST MCC63S/R MCB05532 Figure 18-28 T13 State Bit Block Diagram The inputs to the set/reset logic for the CC6xST bits are the timer run bit (T13R), the timer zero-match signal (T13_ZM), the end-of-single-shot mode signal (T13_SSEP), and the actual individual compare-match signal CM_63. In addition, the state bit can be set or reset by software via the set and reset bits, MCC63S and MCC63R. A modification of the State Bit CC63ST by hardware is only possible while Timer T13 is running (T13R = 1). If this is the case, the following rules apply for setting and resetting the State Bit in Compare Mode: State Bit CC63ST is set to 1 • • with the next T13 clock (fT13) after a compare-match (T13 is always counting up) (i.e., when the counter is incremented above the compare value); with the next T13 clock (fT13) after a zero-match AND a parallel compare-match. State Bit CC63ST is reset to 0 • with the next T13 clock (fT13) after a zero-match AND NO parallel compare-match. fT13 Compare-Match Compare-Match Period Value Compare Value T13 Count Zero CC63ST MCT05533 Figure 18-29 T13 Compare Operation Note: The waveforms in Figure 18-29 correspond to the T12-waveforms in Figure 18-11. User’s Manual CAPCOM6_X, V2.0 18-38 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) T13 Compare Mode Output Path Figure 18-30 gives an overview on the signal path from the channel State Bit to its output pin in its simplest form. As illustrated, a user has a variety of controls to determine the desired output signal switching behavior in relation to the current state of the State Bit, CC63ST. Please refer to Section 18.7 for detailed information on the output modulation control. State Selection T13IM CC63ST CC63_O State Bit CC63ST Output Modulation COUT63_O CC63ST COUT63PS Level Select ECT13O PSL63 To Output Pin COUT63 MCA05534 Figure 18-30 CC63 Output Path The output line COUT63_O can generate a T13 PWM at the output pin COUT63. The signal CC63_O can be used to modulate the T12-related output signals with a T13 PWM. In order to decouple COUT63 from the internal modulation, the compare state leading to an active signal can be selected independently by bits T13IM and COUT63PS. User’s Manual CAPCOM6_X, V2.0 18-39 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) T13 Compare Mode Registers Register CC63R is the actual compare registers for T13. The value stored in CC63R is compared to the count value of T13. Register CC63R can only be read by SW, the modification of the value is done by a shadow register transfer from the corresponding shadow register CC63SR. This register can be read and written by SW. CCU6_CC63R Channel 3 Compare Register 15 14 13 12 11 10 XSFR (E8B4H/--) 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 CC63V rh Field Bits Type Description CC63V [15:0] rh Channel 3 Compare Value Bitfield CC6xV contains the value that is compared to the T13 count value CCU6_CC63SR Channel 3 Comp. Shadow Reg. XSFR (E8B6H/--) 15 14 13 12 11 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 CC63S rwh Field Bits Type Description CC63S [15:0] rwh Shadow Register for Channel 3 Compare Value The contents of CC63S are transferred to bitfield CC63V in register CC63R during a shadow transfer User’s Manual CAPCOM6_X, V2.0 18-40 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.3 Timer Block Control Most features of timers T12 and T13 are controlled via the timer control registers TCTR0, TCTR2, and TCTR4. Register TCTR0 controls the basic functionality of both timers, T12 and T13. CCU6_TCTR0 Timer Control Register 0 15 14 - - - - Field 13 12 11 XSFR (E8ACH/--) 10 STE T13 T13R 13 PRE rh rh rw 9 T13CLK rw 8 7 6 CTM CDIR rw rh Reset Value: 0000H 5 4 3 STE T12 T12R 12 PRE rh rh rw 2 1 0 T12CLK rw Bits Type Description 13 rh Timer T13 Shadow Transfer Enable 0 The shadow register transfer is not requested 1 The shadow register transfer is requested T13R2) 12 rh Timer T13 Run Bit T13R starts and stops timer T13. It is set/reset by SW via bits T13RR or T13RS or it is reset by HW according to the function defined by bitfield T13SSC. 0 Timer T13 is stopped 1 Timer T13 is running T13PRE 11 rw Timer T13 Prescaler Enable Bit Enables the additional 1/256-prescaler of T13 0 The additional prescaler is disabled 1 The additional prescaler is enabled T13CLK [10:8] rw Timer T13 Input Clock Select Selects the input clock for Timer T13 which is derived from the CAPCOM6 input clock according to the equation: fT13 = fCC6/2<T13CLK>. See Table 18-5. CTM 7 rw T12 Operating Mode 0 Edge-Aligned Mode 1 Center-Aligned Mode CDIR 6 rh Count Direction of Timer T12 Displays the current counting direction of T12 0 T12 counts up 1 T12 counts down STE13 1) User’s Manual CAPCOM6_X, V2.0 18-41 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Field Bits Type Description STE121) 5 rh Timer T12 Shadow Transfer Enable 0 The shadow register transfer is not requested 1 The shadow register transfer is requested T12R2) 4 rh Timer T12 Run Bit T12R starts and stops Timer T12. It is set/reset by SW via bits T12RR or T12RS, or it is reset by HW according to the function defined by bitfield T12SSC. 0 Timer T12 is stopped 1 Timer T12 is running T12PRE 3 rw Timer T12 Prescaler Enable Bit Enables the additional 1/256-prescaler of T12 0 The additional prescaler is disabled 1 The additional prescaler is enabled T12CLK [2:0] rw Timer T12 Input Clock Select Selects the input clock for Timer T12 which is derived from the CAPCOM6 input clock according to the equation: fT12 = fCC6/2<T12CLK>. See Table 18-1. 1) Bit STE12/STE13 is cleared when the shadow transfer takes place. 2) A concurrent set/reset action on T13R/T12R (from TxSSC, TxRR or TxRS) will have no effect. Bit T13R/T12R will remain unchanged. Note: A write action to the bitfields T12CLK/T13CLK or T12PRE/T13PRE is only taken into account while timer T12/T13 is not running (T12/T13R = 0). User’s Manual CAPCOM6_X, V2.0 18-42 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Register TCTR2 controls the single-shot and the synchronization functionality of both timers T12 and T13. CCU6_TCTR2 Timer Control Register 2 XSFR (E8AEH/--) Reset Value: 0000H 15 14 13 12 11 10 9 8 7 6 5 4 3 - - - - - - - - - T13 TED T13 TEC - - - - - - - - - rw rw 2 1 0 T13 T12 SSC SSC rw rw Field Bits Type Description T13TED [6:5] rw Trigger Event Direction Control Bitfield T13TED additionally specifies for which count direction of T12 the selected trigger event should be regarded (see Table 18-7). T13TEC [4:2] rw Trigger Event Selection Bitfield T13TEC selects the trigger event to start T13 (automatic set of T13R for synchronization to T12 compare signals) according to Table 18-6. T13SSC T12SSC 1 0 rw Timer T13/T12 Single Shot Control This bit enables the Single-Shot Mode of T13/T12 0 Single-Shot Mode is disabled 1 Single-Shot Mode is enabled Register TCTR4 provides software-control (independent set and clear conditions) for the run bits T12R and T13R. Furthermore, the timers can be reset (while running) and bits STE12 and STE13 can be controlled by software. Reading these bits always returns 0s. User’s Manual CAPCOM6_X, V2.0 18-43 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) CCU6_TCTR4 Timer Control Register 4 15 14 T13 T13 STD STR w w 13 12 11 - - - - - - XSFR (E8A6H/--) 10 9 8 7 6 T13 T13 T13 T12 T12 RES RS RR STD STR w w w w w Reset Value: 0000H 5 4 - - - - 3 2 1 0 DT T12 T12 T12 RES RES RS RR w w w w Field Bits Type Description T13STD T12STD 15 7 w Timer T13/T12 Shadow Transfer Disable 0 No action 1 STE13/STE12 is cleared without triggering the shadow transfer T13STR T12STR 14 6 w Timer T13/T12 Shadow Transfer Request 0 No action 1 STE13/STE12 is set, requesting the shadow transfer T13RES T12RES 10 2 w Timer T13/T12 Reset 0 No effect on T13/T12 1 The T13/T12 counter register is reset to zero. The switching of the output signals is according to the switching rules. Setting of T13RES/T12RES has no impact on bit T13R/T12R. T13RS T12RS 9 1 w Timer T13/T12 Run Bit Set Control1) Software can set bit T13R/T12R (start timer T13/T12) by writing to bit T13RS/T12RS. 0 T13R/T12R is not set 1 T13R/T12R is set, T13/T12 starts counting T13RR T12RR 8 0 w Timer T13/T12 Run Bit Reset Control1) Software can clear bit T13R/T12R (stop timer T13/T12) by writing to bit T13RR/T12RR. 0 T13R/T12R is not cleared 1 T13R/T12R is cleared, T13/T12 stops counting DTRES 3 w Dead-Time Counter Reset 0 No effect on the Dead-Time counters 1 All three Dead-Time counters are cleared and stopped 1) Setting the respective set- and reset-control bits together will not influence the associated timer. User’s Manual CAPCOM6_X, V2.0 18-44 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) The channel state register CMPSTAT contains status bits displaying the current capture or compare state and control bits defining the active/passive state of a compare channel. CCU6_CMPSTAT Compare State Register 15 14 13 12 11 XSFR (E8A8H/--) 10 9 8 7 C C C C T13 CC CC CC OUT OUT OUT OUT IM 62PS 61PS 60PS 63PS 62PS 61PS 60PS - rwh - rwh rwh rwh rwh rwh rwh rwh 6 Reset Value: 0000H 5 4 3 2 1 0 CC CC CC CC CC CC CC POS POS POS 63ST 62ST 61ST 60ST 2 1 0 rh rh rh rh rh rh rh Field Bits Type Description T13IM 15 rwh T13 Inverted Modulation Control Bit T13IM inverts signal CC63_O for the modulation of the CC6x and COUT6x (x = 0, 1, 2) signals 0 CC63_O is not inverted 1 CC63_O is inverted for further modulation COUT63PS1) COUT62PS CC62PS COUT61PS CC61PS COUT60PS CC60PS 14 13 12 11 10 9 8 rwh Passive State Select for Compare Output Bit COUT6xPS/CC6xPS selects the state of the compare channel, considered as the passive state. During the passive state, the passive level (defined in register PSLR) is driven by the output pin. 0 The compare output drives passive level while CC6xST is 0 1 The compare output drives passive level while CC6xST is 1 Note: In capture mode, these bits are not used. CC63ST2) CC62ST CC61ST CC60ST 6 2 1 0 rh T13/T12 Compare State Bit Bits CC6xST monitor the state of the capture/ compare channels. Compare mode: 0 The timer count is less than the compare value 1 The timer count is greater than the comp. value Capture mode (channels 0 … 2 only): 0 The selected edge has not yet been detected 1 The selected edge has been detected CCPOSx 5, 4, 3 rh Sampled Hall Pattern Bits 1) These bits have shadow bits and are updated in parallel to the capture/compare registers of T12 or T13, respectively. A read action targets the actually used values, whereas a write action targets the shadow bits. 2) These bits are set and reset according to the T12, T13 switching rules. User’s Manual CAPCOM6_X, V2.0 18-45 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) The Compare Status Modification Register CMPMODIF provides software-control (independent set and clear conditions) for the channel state bits CC6xST. This feature enables the user to individually change the status of the output lines by software, for example when the corresponding compare timer is stopped. CCU6_CMPMODIF Comp. State Modification Reg. XSFR (E8AAH/--) 15 14 13 12 11 - MCC 63R - - - - w - - - 10 9 8 MCC MCC MCC 62R 61R 60R w w w Reset Value: 0000H 7 6 5 4 3 - MCC 63S - - - - w - - - 2 1 0 MCC MCC MCC 62S 61S 60S w w Field Bits Type Description MCC63R MCC62R MCC61R MCC60R 14 10 9 8 w Capture/Compare Channel x Status Reset Bit 0 No action 1 Bit CC6xST is cleared1) MCC63S MCC62S MCC61S MCC60S 6 2 1 0 w Capture/Compare Channel x Status Set Bit 0 No action 1 Bit CC6xST is set1) w 1) Setting the respective set- and reset-control bits together will toggle the associated status bit. User’s Manual CAPCOM6_X, V2.0 18-46 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.4 Multi-Channel Mode The Multi-Channel mode offers the possibility to modulate all six T12-related output signals with one instruction. The bits in bitfield MCMOUT.MCMP are used to specify the outputs which may become active. If Multi-Channel mode is enabled (bit MODCTR.MCMEN = 1), only those outputs may become active, which have a 1 at the corresponding bit position in bitfield MCMP. This bitfield has its own shadow bitfield, MCMPS, which can be written by software. The transfer of the new value in MCMPS to the bitfield MCMP can be triggered by, and synchronized to, T12 or T13 events. This structure permits the software to write the new value, which is then taken into account by the hardware at a well-defined moment and synchronized to a PWM signal. This avoids unintended pulses due to unsynchronized modulation sources (T12, T13, software). Shadow Register MCMOUTS.MCMPS SWSYN SW Update, STRMCM T12_ZM T13_ZM 0 Corr. Hall Evt. CM_CHE T13_PM T12_OM CM_61_UP T12_PM Switching Synchronization Shadow Transfer MCM_ST MUX Register MCMOUTS.MCMP State Bit Outputs Modulation Control SWSEL Output Pins CC6x/COUT6x MCB05535 Figure 18-31 Multi-Channel Mode Block Diagram Figure 18-31 shows the modulation selection for the Multi-Channel mode. The event that triggers the update of bitfield MCMP is chosen by SWSEL. In order to synchronize the update of MCMP to a PWM generated by T12 or T13, bitfield SWSYN allows the selection of the synchronization event, which leads to the transfer from MCMPS to MCMP. Due to this structure, an update takes place with a new PWM period. A reminder flag, bit R, is set when the selected switching event occurs, and is reset when the transfer takes place. This flag can be monitored by software to check for the status of this logic. User’s Manual CAPCOM6_X, V2.0 18-47 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) If it is explicitly desired, the update takes place immediately with the occurrence of the selected event when the direct synchronization mode is selected. The update can also be requested by software by writing to bitfield MCMPS with the shadow transfer request bit STRMCM set. By using the direct mode and bit STRMCM, the update takes place completely under software control. The event selection and synchronization options are summarized in Table 18-8 and Table 18-9. Table 18-8 Multi-Channel Mode Trigger Event Selection SWSEL Selected Event (see register CCU6_MCMCTR)1) 000B None 001B Correct Hall Event (CM_CHE) at pins CCPOS6x 010B T13 Period-Match (T13_PM) 011B T12 One-Match while counting down (T12_OM) 100B T12 Compare Event of Channel 1 while counting up (CM_61_UP; see Section 18.5 and Figure 18-34). Phase delay function 101B T12 Period-Match while counting up (T12_PM) 11xB Reserved, no action 1) Software control is always possible. Table 18-9 Multi-Channel Mode Trigger Event Synchronization SWSYN Synchronization Event (see register CCU6_MCMCTR) 00B Direct Mode: the trigger event directly causes the shadow transfer 01B T13 Zero-Match 10B T12 Zero-Match while counting up 11B Reserved, no action User’s Manual CAPCOM6_X, V2.0 18-48 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Register MODCTR contains control bits enabling the modulation of the corresponding output signal by PWM patterns generated by timers T12 and T13. Furthermore, the Multi-Channel mode can be enabled as additional modulation source for the output signals. CCU6_MODCTR Modulation Control Register 15 14 ECT 13O - rw - 13 12 11 10 XSFR (E8C0H/--) 9 8 Reset Value: 0000H 7 6 5 4 3 2 1 T13MODEN MCM EN - T12MODEN rw rw - rw 0 Field Bits Type Description ECT13O 15 rw Enable Compare Timer T13 Output 0 Signal COUT63 is forced to 0 1 Signal COUT63 can switch as programmed T13MODEN T12MODEN [13:8] [5:0] rw T13/T12 Modulation Enable These bits enable the modulation of the corresponding compare channel(s) by a PWM pattern generated by timer T13 or T12. 0 No modulation by T13/T12 1 Corresponding output is modulated by a T13/T12 PWM pattern T13MODEN[5:0] and T12MODEN[5:0] correspond (left to right) to: COUT62, CC62, COUT61, CC61, COUT60, CC60. MCMEN 7 rw Multi-Channel Mode Enable Enables the modulation of the output signals by a multi-channel pattern according to bitfield MCMOUT 0 The modulation is disabled 1 The modulation is enabled Note: Registers MCMOUT, MCMOUTS, and MCMCTR are also related to MultiChannel Mode operation. User’s Manual CAPCOM6_X, V2.0 18-49 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.5 Hall Sensor Mode For Brushless DC-Motors, usually the Multi-Channel Mode is used, as the modulation patterns need to be output to properly control the motor. These patterns need to be output in relation to the angular position of the motor. For this, usually Hall sensors or Back-EMF sensing are used to determine the angular rotor position. The CAPCOM6 provides three inputs, CC6POS0 … CC6POS2, which can be used as inputs for the Hall sensors or the Back-EMF detection signals. There is a strong correlation between the motor position and the output modulation pattern. When a certain position of the motor has been reached, indicated by the sampled Hall sensor inputs (the Hall pattern), the next, pre-determined Modulation pattern has to be output. Because of different machine types, the modulation pattern for driving the motor can vary. Therefore, it is wishful to have a wide flexibility in defining the correlation between the Hall pattern and the corresponding Modulation pattern. The CAPCOM6 offers this by having a register which contains the actual current Hall pattern (CURH), the next expected Hall pattern (EXPH) and the corresponding output pattern (MCMP). A new Modulation pattern is output when the sampled Hall inputs match the expected ones (EXPH). To detect the next rotation phase (segment for block commutation), the CAPCOM6 monitors the Hall inputs for changes. When the next expected Hall pattern is detected, the next corresponding Modulation pattern is output. To provide for noise immunity (to a certain extend), the CAPCOM6 offers the possibility to introduce a sampling delay for the Hall inputs. In addition, it compares the sampled Hall signals to the current Hall pattern (CURH) to provide for some tolerance in case of short spikes. For the Hall and Modulation patterns, a double-register structure is implemented. While register MCMOUT holds the actually used values, its shadow register MCMOUTS can be loaded by software from a pre-defined table, holding the appropriate Hall and Modulation patterns for the given motor control. A transfer from the shadow register into register MCMOUT can take place when a correct Hall pattern change is detected, that is, when the sampled Hall pattern matches the expected one. Software can then load the next values into register MCMOUTS. It is also possible by software to force a transfer from MCMOUTS into MCMOUT. User’s Manual CAPCOM6_X, V2.0 18-50 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.5.1 Hall Pattern Compare Logic Figure 18-32 gives an overview on the double-register structure and the pattern compare logic. Software writes the next modulation pattern (MCMPS) and the corresponding current (CURHS) and expected (EXPHS) Hall patterns into the shadow register MCMOUTS. Register MCMOUT holds the actually used values. The modulation pattern MCMP is provided to the Output Modulation Control block. The current (CURH) and expected (EXPH) Hall patterns are compared to the sampled Hall sensor inputs (pins CC6POSx) by comparators. Sampling of the inputs and the evaluation of the comparator outputs is controlled by signal HCRDY (Hall Compare Ready), which is detailed in the next section. SW Write SW Write SW Write CURHS EXPHS MCMPS Shadow Transfer CM_CHE Shadow Transfer MCM_ST EXPH Sample CURH CC6POS0..2 Register MCMOUTS Register MCMOUT MCMP To Output Modulation Comp. =? Comp. =? Correct Hall Event CM_CHE Comb. Logic HCRDY HCRDY Wrong Hall Event CM_WHE MCA05536 Figure 18-32 Hall Pattern Compare Logic When the sampled Hall pattern matches the expected one (EXPH), signal CM_CHE (Correct Hall Event) is generated. When the sampled Hall pattern matches the current one (CURH), no signal is generated, as this is a normal case after a spike on the input line. If the sampled pattern matches neither EXPH nor CURH, signal CM_WHE is generated, which indicates a wrong Hall event. At every correct Hall event (CM_CHE), the next Hall patterns are transferred from the shadow register MCMOUTS into MCMOUT, and a new Hall pattern with its corresponding output pattern can be loaded (from a predefined table) by software into MCMOUTS. For the Modulation patterns, signal MCM_ST is used to trigger the transfer. This signal can be generated through signal CM_CHE (see Figure 18-31). Loading this User’s Manual CAPCOM6_X, V2.0 18-51 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) shadow register can also be done by a write action on MCMOUTS with bit STRHP = 1. In case of a phase delay (generated by T12 channel 1), a new pattern is applied when the Multi-Channel mode shadow transfer MCM_ST (indicated by bit STR) occurs. 18.5.2 Sampling of the Hall Pattern The Hall sensor inputs (CC6POSx) are monitored with the module clock (fCC6) via an edge detection block. When a level change is detected on any one of the three inputs, a signal is generated. In order to suppress spikes on the Hall inputs due to high di/dt in rugged inverter environment, a hardware noise filter can be used. This noise filtering is performed using the Dead-Time Counter DTC0. For this function, the mode control bitfields MSELx for the T12 Channels must all be programmed to ‘1000’. The output signal of the edge detection block is used to trigger DTC0. It is reloaded, starts counting, and thus generates a delay. An output signal, DTC0_O, is generated when the counter reaches the value one. This signal is used as the input sampling and compare evaluation signal HCRDY (see Figure 18-32). This feature provides a noise filter by delay. Most disturbances, such as switching spikes and signal bouncing, can be eliminated this way. When an input signal change was detected, the inputs are sampled a certain time later, determined by the reload value of DTC0. They are then compared to the current and expected Hall patterns. If the sampled pattern matches the current pattern (CURH), the detected input signal change was due to a noise spike (which is not visible anymore), and no further action will be triggered. If the sampled pattern matches the expected one (EXPH), the signal change was a correct Hall event, and signal CM_CHE is generated to trigger further actions. However, when the sampled pattern matches none of CURH and EXPH, the detected input change lead to a wrong Hall pattern. Signal CM_WHE is generated to indicate this fault and to allow further appropriate actions. CCPOS60..62 Figure 18-33 illustrates the noise filter logic. Hall Compare Logic Edge Dead-Time DTC0_O Gen. Block DTC0 Detect HCRDY MCB05537 Figure 18-33 Hall Trigger Logic Block Diagram User’s Manual CAPCOM6_X, V2.0 18-52 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.5.3 Brushless DC-Motor Control with Timer T12 Block The CAPCOM6 provides a mode for the Timer T12 Block especially targeted for convenient control of Brushless DC-Motors. This mode is selected by setting all MSELx bitfields of the three T12 Channels to 1000B. In this mode, illustrated in Figure 18-34, channel 0 is placed in capture mode, while channels 1 and 2 are in compare mode. Counter Register T12 fT12 Reset CM_CHE CM_61 CM_CHE Capture Register CC60R Comp. =? Comp. =? Compare Register CC61R Compare Register CC62R CM_62 CM_CHE Compare Shadow Register CC61SR Compare Shadow Register CC62SR MCA05538 Figure 18-34 T12 Block in Hall Sensor Mode The signal to transfer the new compare values from the shadow registers (CC6xSR) into the actual compare registers (CC6xR) is now taken from the Correct Hall Event Compare, CM_CHE. In addition, this signal triggers a capture of the current T12 contents into register CC60R, and then forces a reset of T12 to 0000H. The same signal is also used to perform the shadow transfer of the new T12 period value. Note: In this mode, the shadow transfer signal T12_ST is not generated. Shadow bits, such as the PSLy bits, will not be transferred to their main registers. To program the main registers, SW needs to write to these registers while Timer T12 is stopped. In this case, a SW write actualizes both registers. User’s Manual CAPCOM6_X, V2.0 18-53 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) CC62 Compare for Time-Out Hall Event captures and resets T12 CC62 Comp. T12 Count CC61 Compare for Phase Delay CC61 Comp. 0000H CC6POS0 1 1 1 0 0 0 CC6POS1 0 0 1 1 1 0 CC6POS2 1 0 0 0 1 1 CURH = 101 = 001 = 011 = 010 = 110 = 100 EXPH = 001 = 011 = 010 = 110 = 100 = ??? MCMP CC6x COUT6x MCT05539 Figure 18-35 Brushless DC-Motor Control Example (all MSEL6x = 1000B) After the detection of a valid expected Hall pattern, the T12 count value is captured into channel 0 (representing the actual motor speed), and T12 is reset. When the timer reaches the compare value in channel 1, the next multi-channel state is switched by triggering the shadow transfer of bitfield MCMP (if enabled in bitfield SWEN). This trigger event can be combined with several conditions which are necessary to implement a noise filtering (correct Hall event) and to synchronize the next multi-channel state to the modulation sources (avoiding spikes on the output lines). This compare function of channel 1 can be used as a phase delay from the position sensor input signals to the switching of the output signals, which is necessary if a sensorless back-EMF technique is used instead of Hall sensors. The compare value in channel 2 can be used as a timeout trigger (interrupt), indicating that the motor’s actual speed is far below the desired destination value, which can be caused by an abnormal load change. In this mode, the modulation of the outputs by T12 needs to be disabled (T12MODENx = 0). User’s Manual CAPCOM6_X, V2.0 18-54 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) The capturing of the timer value in register CC60R, the shadow transfer from registers CC61SR to CC61R, from CC62SR to CC62R, and for the T12 period value, is done together with the reset event for T12. 18.5.4 Hall Mode Flags Depending on the Hall pattern compare operation, a number of flags are set in order to indicate the status of the module and to trigger further actions and interrupt requests. Flag CHE (Correct Hall Event) in register IS is set via signal CM_CHE when the sampled Hall pattern matches the expected one (EXPH). This flag can also be set by SW via setting bit SCHE in register ISS. If enabled through bit ENCHE (in register IEN), the set signal for CHE can also generate an interrupt request to the CPU. To clear flag CHE, SW needs to write a 1 to bit RCHE in register ISR. Flag WHE indicates a Wrong Hall Event. Its handling for flag setting and resetting as well as interrupt request generation is the same as described above for flag CHE. The implementation of flag STR is done in the same way as for CHE and WHE. This flag is set by HW via the shadow transfer signal MCM_ST (see also Figure 18-31). User’s Manual CAPCOM6_X, V2.0 18-55 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Set SCHE Reset CHE _ >1 RCHE & CM_CHE ENCHE Set SWHE Reset WHE _ >1 RWHE & CM_WHE Interrupt Req. ENWHE Interrupt Req. SIDLE _ >1 & Set Reset ENIDLE IDLE Clear MCMP RIDLE Set SSTR STR Reset _ >1 MCM_ST RSTR & ENSTR Interrupt Req. MCA05540 Figure 18-36 Hall Mode Flag Logic Please note that for flags CHE, WHE, and STR, the interrupt request generation is triggered by the set signal for the flag. That means, a request can be generated even if the flag is already set. There is no need to reset the flag in order to enable further interrupt requests. The implementation for the IDLE flag is different. It is set by HW through signal CM_WHE if enabled by bit ENIDLE. Software can also set the flag via bit SIDLE. As long as bit IDLE is set, the modulation pattern field MCMP is cleared to force the outputs to the passive state. Flag IDLE must be reset by software through bit RIDLE in order to return to normal operation. To fully restart from IDLE mode, the transfer requests for the bitfields in register MCMOUTS to register MCMOUT have to be initiated by software via bits STRMCM and STRHP in register MCMOUTS. In this way, the release from IDLE mode is under software control, but can be performed synchronously to the PWM signal. User’s Manual CAPCOM6_X, V2.0 18-56 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Hall Mode Registers Register MCMOUTS contains the shadow bitfields for the modulation and Hall patterns as well as control bits for a software-initiated shadow transfer. The contents of bitfields MCMPS, EXPHS, and CURHS are transferred into the corresponding fields of register MCMOUT when the associated shadow transfer signals are activated. CCU6_MCMOUTS Multi-Ch. Mode Outp. Shad. R. 15 14 13 12 STR HP - CURHS w - rw 11 10 XSFR (E8CAH/--) 9 8 Reset Value: 0000H 7 6 5 4 3 2 1 EXPHS STR MCM - MCMPS rw w - rw 0 Field Bits Type Description STRHP 15 w Shadow Transfer Request for the Hall Patterns Setting this bit during a write action leads to an immediate update of bitfields CURH and EXPH by the value written to CURHS and EXPHS. This functionality permits an update triggered by SW. When read, this bit always delivers 0. 0 CURH and EXPH are updated according to the defined HW action. The write access to CURHS and EXPH does not modify bitfields CURH and EXPH. 1 CURH and EXPH are updated by the value written to bitfields CURHS and EXPHS. CURHS [13:11] rw Current Hall Pattern Shadow Field CURHS is the shadow field for bitfield CURH. The bitfield is transferred to CURH when a correct Hall event is detected. EXPHS [10:8] Expected Hall Pattern Shadow Field EXPHS is the shadow field for bitfield EXPH. The bitfield is transferred to EXPH when a correct Hall event is detected. User’s Manual CAPCOM6_X, V2.0 rw 18-57 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Field Bits Type Description STRMCM 7 w Shadow Transfer Request for MCMPS Setting this bit during a write action leads to an immediate update of bitfield MCMP by the value written to MCMPS. This functionality permits an update triggered by SW. When read, this bit always delivers 0. 0 MCMP is updated according to the defined HW action. The write access to MCMPS does not modify MCMP. 1 MCMP is updated by the value written to MCMPS. MCMPS [5:0] rw Multi-Channel PWM Pattern Shadow Field MCMPS is the shadow field for bitfield MCMP. The Multi-Channel shadow transfer is triggered according to the transfer conditions defined by register MCMCTR. Register MCMOUT holds the Modulation and Hall patterns that are currently used. CCU6_MCMOUT Multi-Ch. Mode Output Reg. 15 14 13 12 - - CURH - - rh 11 Field Bits CURH1) [13:11] rh User’s Manual CAPCOM6_X, V2.0 10 Type XSFR (E8CCH/--) 9 8 Reset Value: 0000H 7 6 5 4 3 2 EXPH - R MCMP rh - rh rh 1 0 Description Current Hall Pattern CURH is written by a shadow transfer from bitfield CURHS. Bitfield CURH is compared to the sampled Hall pattern after every detected edge at the Hall sensor inputs CC6POSx. If the pattern match, the detected edge has been an invalid transition (e.g. due to a spike), and no further action is performed. If the sampled pattern do not either match CURH or EXPH, a Wrong Hall Event signal is set, which can trigger further actions. 18-58 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Field Bits Type Description EXPH1) [10:8] rh Expected Hall Pattern EXPH is written by a shadow transfer from bitfield EXPHS. Bitfield EXPH is compared to the sampled Hall pattern after every detected edge at the Hall sensor inputs CC6POSx. If the pattern match, a Correct Hall Event signal is generated, which triggers further actions. R 6 rh Reminder Flag Indicates that the shadow transfer from bitfield MCMPS to MCMP has been requested by the selected trigger source. This bit is cleared while MCMEN = 0 and when the shadow transfer takes place. 0 No shadow transfer is requested 1 A shadow transfer from MCMPS to MCMP has been requested but not yet executed MCMP2) [5:0] rh Multi-Channel Modulation Pattern MCMP contains the output modulation pattern for the Multi-Channel mode, which can set the corresponding output to the passive state. It is written by a shadow transfer from bitfield MCMPS. 0 The output is set to the passive state. 1 The output can deliver the PWM generated by T12 or T13 (according to register MODCTR). MCMP[5:0] corresponds to (left to right): COUT62, CC62, COUT61, CC61, COUT60, CC60. 1) The bits in the bitfields EXPH and CURH correspond to the hall patterns at the input pins CCPOSx (x = 0, 1, 2) in the order (EXPH.2, EXPH.1, EXPH.0), (CURH.2, CURH.1, CURH.0), (CCPOS2, CCPOS.1, CCPOS0). 2) While bit IS.IDLE = 1, bitfield MCMP is cleared. User’s Manual CAPCOM6_X, V2.0 18-59 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Register MCMCTR contains control bits for the Multi-Channel mode, controlling the output modulation pattern. CCU6_MCMCTR Multi-Ch. Mode Control Reg. XSFR (E8CEH/--) Reset Value: 0000H 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 - - - - - - - - - - SWSYN - SWSEL - - - - - - - - - - rw - rw 0 Field Bits Type Description SWSYN [5:4] rw Switching Synchronization SWSYN triggers the shadow transfer from MCMPS to MCMP, if it has been requested before (flag R set) by an event selected by SWSEL. This permits the synchronization of the outputs to the source which is used for modulation (T12 or T13). See Table 18-9. SWSEL [2:0] rw Switching Selection SWSEL selects the trigger source (next multichannel event) for the shadow transfer from MCMPS to MCMP. The transfer takes place synchronously with the selected event. See Table 18-8. Note: The generation of the shadow transfer request by HW is only enabled if bit MCMEN = 1. User’s Manual CAPCOM6_X, V2.0 18-60 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.6 Trap Handling The trap functionality permits the PWM outputs to react on the state of the input pin CTRAP. This functionality can be used to switch off the power devices if the trap input becomes active (e.g. to perform an emergency stop). The Trap Flag TRPF monitors the trap input and initiates the entry into the Trap State. It can also be set by SW. The Trap State Bit TRPS determines the effect on the outputs and controls the exit of the Trap State. When a trap condition is detected, both, the Trap Flag TRPF and the Trap State Bit TRPS, are set to 1. The Trap State is entered immediately. The output of the Trap State Bit TRPS leads to the Output Modulation Block and can there deactivate the outputs (set them to the passive state). Individual enable control bits for each of the six T12-related outputs and the T13-related output facilitate a flexible adaptation to the application needs (see Section 18.7). There are a number of different ways to exit the Trap State. This offers SW the option to select the operation which is best for the given application. Exiting the Trap State can be done either immediately when the trap condition is removed, or under software control, or synchronously to the PWM generated by either Timer T12 or Timer T13. Figure 18-37 gives an overview on the trap function. Both, the Trap Flag TRPF and the Trap State Bit TRPS, located in register IS, are set to 1 when input CTRAP is activated. The Trap Flag TRPF can also be set by SW via bit STRPF. In turn, the Trap State Bit TRPS will also be set through its Set/Reset Control block. As long as pin CTRAP = 0, TRPF and TRPS remain set and can not be cleared (assuming TRPPEN = 1). STRPF RTRPF Reg. IS Set Set/Reset Control CTRAP Reset Trap Flag TRPF TRPPEN TRPM2 Reg. IS Set T12_ZM T13_ZM Set/Reset Control TRPM1 TRPM0 Reset Trap State TRPS To Output Modulation MCB05541 Figure 18-37 Trap Logic Block Diagram User’s Manual CAPCOM6_X, V2.0 18-61 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) The reset of TRPF is controlled by the mode control bit TRPM2 (located in the Trap Control Register TRPCTR). When TRPM2 = 0, TRPF is automatically cleared by HW when CTRAP returns to the inactive level (CTRAP = 1). When TRPM2 = 1, TRPF must be reset by SW after CTRAP has become inactive. The reset of TRPS is controlled by the mode control bits TRPM1 and TRPM0 (located in the Trap Control Register TRPCTR). A reset of TRPS terminates the Trap State and returns to normal operation. There are three options selected by TRPM1 and TRPM0. One is that the Trap State is left immediately when the Trap Flag TRPF is cleared, without any synchronization to timers T12 or T13. The other two options facilitate the synchronization of the termination of the Trap State to the count periods of either Timer T12 or Timer T13. Figure 18-38 gives an overview on the associated operation. T12 Count T13 Count TRPF CTRAP active TRPS Sync. to T12 TRPS Sync. to T13 TRPS No sync. MCT05542 Figure 18-38 Trap State Synchronization (with TRM2 = 0) User’s Manual CAPCOM6_X, V2.0 18-62 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Trap Handling Registers Register TRPCTR controls the trap functionality. It contains independent enable bits for each output signal and control bits to select the behavior in case of a trap condition. CCU6_TRPCTR Trap Control Register 15 14 13 12 TRP TRP EN PEN 13 rw rw XSFR (E8C2H/--) 11 10 9 8 Reset Value: 0000H 7 6 5 4 3 TRPEN - - - - - rw - - - - - 2 1 0 TRP TRP TRP M2 M1 M0 rw rw rw Field Bits Type Description TRPPEN 15 rw Trap Pin Enable Control 0 The trap input pin CTRAP is disabled. Software can generate a trap by setting bit TRPF. 1 The trap input pin CTRAP is enabled. A trap can be generated by SW by setting bit TRPF or by CTRAP = 0. TRPEN13 14 rw Trap Enable Control for T13 Output Enables the trap functionality for the T13 output signal CC63. 0 The trap functionality is disabled. The output state is independent from bit TRPS. 1 The trap functionality is enabled. The output is set to the passive state while TRPS = 1. TRPEN [13:8] rw Trap Enable Control for T12 Outputs Enables the trap functionality for the individual output signals CC6x and COUT6x. 0 The trap functionality is disabled. The output state is independent from bit TRPS. 1 The trap functionality is enabled. The output is set to the passive state while TRPS = 1. TRPEN[5:0] corresponds to (left to right): COUT62, CC62, COUT61, CC61, COUT60, CC60. User’s Manual CAPCOM6_X, V2.0 18-63 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Field Bits Type Description TRPM2 2 rw Trap Mode Control Bit 2 This bit controls whether the Trap State Exit is initiated by hardware or by software. 0 Trap State Exit initiated by HW. Bit TRPF is automatically cleared by HW if the input pin CTRAP becomes inactive (CTRAP = 1). 1 Trap State Exit initiated by SW. Bit TRPF must be reset by SW after the input CTRAP becomes inactive (CTRAP = 1). TRPM1, TRPM0 [1:0] rw Trap Mode Control Bits 1, 0 These two bits control the termination of the Trap State. When the Trap Flag TRPF is reset to 0, the Trap State Bit TRPS is reset and the Trap State is left according to the following options: 00 T12 Synchronization: Reset of TRPS and Trap State Exit on a T12 Zero-Match (T12_ZM). 01 T13 Synchronization: Reset of TRPS and Trap State Exit on a T13 Zero-Match (T13_ZM). 10 Reserved, no action. 11 No Synchronization: Reset of TRPS and Trap State Exit immediately after reset of the Trap Flag TRPF. User’s Manual CAPCOM6_X, V2.0 18-64 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.7 Output Modulation Control The last block of the data path is the Output Modulation Control Logic. Here, all the modulation sources are combined and control the actual level of the output pins. In the following, the six T12-related outputs (CC6x, COUT6x) are discussed separately from the T13-related output CC63. Figure 18-39 gives an overview on the six control blocks and control signals regarding the T12-related outputs. Four individual modulation signals and their associated enable controls lead to each one of the blocks. The modulation signals CC6x_O and COUT6x_O come from the State Selection logic (see Figure 18-15) at the outputs of the three State Bits CC6xST. Signals MCMPy are the six outputs of the Multi-Channel Mode register MCMOUT (see Figure 18-31). Signal CC63_O is the T13-generated signal from the State Selection logic at the output of the State Bit CC63_ST (see Figure 18-30), and leads in parallel to all 6 blocks. The trap signal TRPS also is connected to all six blocks, and is the output of the Trap State bit (see Figure 18-37). While signals CC6x_O/COUT6x_O, CC63_O, and TRPS have individual enable controls for each of the six blocks, there is only one general enable signal, MCMEN, for the MCMPy signals. The output of each of the modulation control blocks is connected to a level select block, which offers the option to determine the actual output level of a pin, depending on the state of the output line. Figure 18-40 provides a closer look at one of the modulation and level select blocks. The logic, which combines the various signals, is designed such that only signals which are enabled by their respective enable signal can influence the output line, MCL_OUT. If one of the modulation signals CC6x_O/COUT6x_O, CC63_O, or MCMPx is enabled and is at passive state, output MCL_OUT is also in passive state, regardless of the state of the other enabled signals. Only if all enabled signals are in active state output MCL_OUT shows an active state. If the Trap State is active (TRPS = 1), then all outputs for which the trap signal is enabled (TRPENy = 1) are set to the passive state. The output MCL_OUT of the modulation control block is then used to select the actual level of the output, specified through the Passive State Select bit PSLy. When MCL_OUT is in the passive state, the level specified directly by PSLy is output. When MCL_OUT is in the active state, the inverted level of PSLy is output. The PSLy bits have shadow registers to allow for updates without undesired pulses on the output lines. The bits are updated with the T12 shadow transfer signal (T12_ST). A read action returns the actually used values, whereas a write action targets the shadow bits. Providing a shadow register for the PSL value as well as for other values related to the generation of the PWM signal facilitates a concurrent update by software for all relevant parameters (see also Section 18.8). User’s Manual CAPCOM6_X, V2.0 18-65 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) CC60_O MCMP.0 CC63_O Modulation Control CC60 MCMEN T13MODEN.0 TRPS TRPEN.0 MCL_OUT0 COUT60_O MCMP.1 T13MODEN.1 MCL_OUT1 CC61_O T13MODEN.2 MCL_OUT2 COUT61_O T13MODEN.3 MCL_OUT3 CC62_O PSL1 Level Select COUT60 PSL2 Level Select CC61 PSL3 Level Select COUT61 T12MODEN.4 Modulation Control CC62 T13MODEN.4 TRPEN.4 MCL_OUT4 COUT62_O MCMP.5 CC60 T12MODEN.3 Modulation Control COUT61 TRPEN.3 MCMP.4 Level Select T12MODEN.2 Modulation Control CC61 TRPEN.2 MCMP.3 PSL0 T12MODEN.1 Modulation Control COUT60 TRPEN.1 MCMP.2 To Output Pins T12MODEN.0 PSL4 Level Select CC62 T12MODEN.5 Modulation Control COUT62 T13MODEN.5 TRPEN.5 MCL_OUT5 PSL5 Level Select COUT62 MCA05543 Figure 18-39 Output Modulation Overview User’s Manual CAPCOM6_X, V2.0 18-66 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) WriteOnly PSLy Shadow CC6x_O COUT6x_O T12MODENy T12_ST MCMPy Modulation Control Logic CC6x/ COUT6x MCMEN CC63_O T13MODENy ReadOnly PSLy 1 MUX 0 TRPS MCL_OUTy TRPENy To Output Pins CC6x COUT6x 0: Passive State 1: Active State x = 0, 1, 2 y = 0..5 To Other Blocks MCA05544 Figure 18-40 Output Modulation, Timer T12 Block WriteOnly PSL63 Shadow T13_ST ReadOnly PSL63 COUT63_O Modulation Control Logic COUT63 ECT13O TRPS TRPEN13 1 0 MCL_OUT63 To Other Blocks MUX To Output Pin COUT63 0: Passive State 1: Active State MCA05545 Figure 18-41 Output Modulation, Timer T13 Block User’s Manual CAPCOM6_X, V2.0 18-67 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Register PSLR defines the passive state level driven by the output pins of the module. The passive state level is the value that is driven by the port pin during the passive state of the output. During the active state, the corresponding output pin drives the active state level, which is the inverted passive state level. The passive state level permits to adapt the driven output levels to the driver polarity (inverted, not inverted) of the connected power stage. CCU6_PSLR Passive State Level Register XSFR (E8C4H/--) Reset Value: 0000H 15 14 13 12 11 10 9 8 7 6 5 4 3 2 - - - - - - - - PSL 63 - PSL - - - - - - - - rwh - rwh 1 0 Field Bits Type Description PSL63 7 rwh T13 Output COUT63 Passive State Level Control This bitfield defines the passive level of the output pin COUT63. 0 The passive level is 0 1 The passive level is 1 PSL [5:0] rwh T12 Outputs Passive State Level Control Defines the passive level driven by the module outputs during the passive state. 0 The passive level is 0 1 The passive level is 1 PSL[5:0] corresponds to (left to right): COUT62, CC62, COUT61, CC61, COUT60, CC60. User’s Manual CAPCOM6_X, V2.0 18-68 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.8 Shadow Register Transfer Control Figure 18-42 and Figure 18-43 give an overview on the shadow register structure and the shadow transfer signals, as well as on the read/write accessibility of the various registers. Providing a shadow register for values describing one PWM period facilitates a concurrent update by software for all relevant parameters. The next PWM period can run with a new set of parameters. Read (T12) PSLy CC6xPS Read T12_ST Write (T12) PSLy Shadow CC6xPS Shadow Write Read Period Register T12PR COUT6xPS Read Write Period Shadow Register T12PR COUT6xPS Shadow Write Read Compare Register CC6xR _ >1 Read Write Compare Shadow Register CC6xSR Other Modes (Hall, Capture, etc.) MCA05546 Figure 18-42 T12 Shadow Register and Transfer Signal Overview User’s Manual CAPCOM6_X, V2.0 18-69 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Read PSL63 T13IM Read T13IM Shadow Write T13_ST Write PSL63 Shadow Read Period Register T13PR Write Period Shadow Register T13PR Read Compare Register CC63R Read Write Compare Shadow Register CC63SR MCA05547 Figure 18-43 T13 Shadow Register and Transfer Signal Overview User’s Manual CAPCOM6_X, V2.0 18-70 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.9 Interrupt Generation The interrupt structure is shown in Figure 18-44. The HW interrupt event or the SW setting of the corresponding interrupt set bit (in register ISS) can trigger the interrupt generation. The interrupt pulse is generated independently from the interrupt flag in register IS. The interrupt flag can be reset by SW by writing to the corresponding bit in register ISR. If enabled by the related interrupt enable bit in register IEN, an interrupt pulse can be generated on one of the four interrupt output lines, I0 … I3, of the module. If more than one interrupt source is connected to the same interrupt node pointer (in register INP), the requests are combined to one common line. Interrupt Enable Register IEN 16 CC60 Cap./Com. Rising CC60 Cap./Com. Falling Interrupt Status Register IS 16 I0 CC6_INT CC61 Cap./Com. Rising CC61 Cap./Com. Falling I1 CC6_EINT CC62 Cap./Com. Rising CC62 Cap./Com. Falling I2 CC6_T12INT I3 CC6_T13INT T12 One-Match T12 Period-Match Interrupt Control Logic T13 Compare-Match T13 Period-Match Correct Hall Event MCM Shadow Transfer 14 Trap Condition Wrong Hall Event 16 Interrupt Set Register ISS Node Pointer Register INP 16 Interrupt Reset Register ISR MCA05548 Figure 18-44 Interrupt Structure Overview User’s Manual CAPCOM6_X, V2.0 18-71 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Int. Flag SW Request Reset INPx Set SW Request Set HW Interrupt Event a _ >1 _ >1 6 _ >1 Interrupt Enable _ >1 & I2 _ >1 6 Int. Flag I1 _ >1 6 Set SW Request Reset I0 & Interrupt Enable HW Interrupt Event b SW Request Set _ >1 6 I3 From Other Interrupt Sources MCA05549 Figure 18-45 Interrupt Structure Detail Interrupt Registers Register IS contains the individual interrupt request and status bits. This register can only be read, write actions have no impact on the contents of this register. Software can set or reset the bits individually by writing to register ISS (to set the bits) or to register ISR (to reset the bits). CCU6_IS Interrupt Status Register 15 - 14 13 12 IDLE WHE CHE rh rh rh 11 XSFR (E8D0H/--) 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 TRP TRP T13 T13 T12 T12 ICC ICC ICC ICC ICC ICC S F PM CM PM OM 62F 62R 61F 61R 60F 60R rh rh rh rh rh rh rh rh rh rh rh rh Field Bits Type Description IDLE 14 rh IDLE State Flag If enabled (ENIDLE = 1), this bit is set together with bit WHE (Wrong Hall Event). It has to be reset by SW. 0 No action 1 Bitfield MCMP is cleared, the selected outputs are set to passive state User’s Manual CAPCOM6_X, V2.0 18-72 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Field Bits Type Description WHE 13 rh Wrong Hall Event Flag 0 No wrong hall pattern yet 1 A transition to a wrong hall pattern (not the expected one) has occurred CHE 12 rh Correct Hall Event Flag 0 No correct (= expected) hall pattern yet 1 A transition to an expected hall pattern has occurred TRPS1) 11 rh Trap State Bit 0 The Trap State is not active 1 The Trap State is active. Bit TRPS is set while bit TRPF = 1. It is reset according to the mode selected in register TRPCTR. TRPF 10 rh Trap Flag The trap flag TRPF is set either by HW, if TRPPEN = 1 and CTRAP = 0, or by SW. If TRPM2 = 0, bit TRPF is reset by HW if the input CTRAP becomes inactive (TRPPEN = 1). If TRPM2 = 1, bit TRPF has to be reset by SW in order to leave the trap state. 0 The trap condition has not occurred 1 The trap condition has occurred (CTRAP = 0 or by SW) T13PM 9 rh Timer T13 Period-Match Flag 0 No T13 Period-Match yet 1 A T13 Period-Match has occurred T13CM 8 rh Timer T13 Compare-Match Flag 0 No T13 Compare-Match yet 1 A T13 Compare-Match has occurred T12PM 7 rh Timer T12 Period-Match Flag 0 No T12 Period-Match yet 1 A T12 Period-Match has occurred while counting up T12OM 6 rh Timer T12 One-Match Flag 0 No T12 One-Match yet 1 A T12 One-Match has been detected while counting down User’s Manual CAPCOM6_X, V2.0 18-73 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Field Bits Type Description ICC62F ICC61F ICC60F 5 3 1 rh Capture, Compare-Match Falling Edge Flag In compare mode, a Compare-Match has been detected while T12 was counting down. In capture mode, a falling edge has been detected at the input CC6x (x = 0, 1, 2). 0 The event has not yet occurred 1 The event described above has occurred ICC62R ICC61R ICC60R 4 2 0 rh Capture, Compare-Match Rising Edge Flag In compare mode, a compare-match has been detected while T12 was counting up. In capture mode, a rising edge has been detected at the input CC6x (x = 0, 1, 2). 0 The event has not yet occurred 1 The event described above has occurred 1) During the trap state, the selected outputs are set to the passive state. Note: Not all bits in register IS can generate an interrupt. Other status bits have been added, which have a similar structure for their set and reset actions. Note: In compare mode (and hall mode), the timer-related interrupts are only generated while the timer is running (TxR = 1). In capture mode, the capture interrupts are also generated while the Timer T12 is stopped. User’s Manual CAPCOM6_X, V2.0 18-74 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Registers ISS and ISR contain write-only bits corresponding to the interrupt and status flags in register IS (except for bit 11). By writing 1s to these bits, software can set (ISS) or clear (ISR) the associated flag(s). Reading these bits always returns 0s. Setting a bit in register ISS will set the corresponding flag in register IS and may trigger an interrupt request (if enabled and if available for that function). Setting a bit in register ISR will clear the corresponding flag in register IS. CCU6_ISS Interrupt Status Set Register 15 - 14 13 12 S S S IDLE WHE CHE - w w w 11 10 XSFR (E8D2H/--) 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 S S S S S S S S S S S TRP T13 T13 T12 T12 CC CC CC CC CC CC F PM CM PM OM 62F 62R 61F 61R 60F 60R - w w w w w w w w w w w Field Bits Type Description1) SIDLE 14 w Set IDLE Flag SWHE 13 w Set Wrong Hall Event Flag SCHE 12 w Set Correct Hall Event Flag STRPF 10 w Set Trap Flag ST13PM 9 w Set Timer T13 Period-Match Flag ST13CM 8 w Set Timer T13 Compare-Match Flag ST12PM 7 w Set Timer T12 Period-Match Flag ST12OM 6 w Set Timer T12 One-Match Flag SCC62F SCC61F SCC60F 5 3 1 w Set Capture, Compare-Match Falling Edge Flag SCC62R SCC61R SCC60R 4 2 0 w Set Capture, Compare-Match Rising Edge Flag 1) Writing 1 to one of these bits will set the associated flag. Writing 0 has no effect. User’s Manual CAPCOM6_X, V2.0 18-75 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) CCU6_ISR Interrupt Status Reset Reg. 15 - 14 13 12 R R R IDLE WHE CHE - w w w 11 XSFR (E8D4H/--) 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 R R R R R R R R R R R TRP T13 T13 T12 T12 CC CC CC CC CC CC F PM CM PM OM 62F 62R 61F 61R 60F 60R - w w w w w w w w w w w Field Bits Type Description1) RIDLE 14 w Reset IDLE Flag RWHE 13 w Reset Wrong Hall Event Flag RCHE 12 w Reset Correct Hall Event Flag RTRPF 10 w Reset Trap Flag RT13PM 9 w Reset Timer T13 Period-Match Flag RT13CM 8 w Reset Timer T13 Compare-Match Flag RT12PM 7 w Reset Timer T12 Period-Match Flag RT12OM 6 w Reset Timer T12 One-Match Flag RCC62F RCC61F RCC60F 5 3 1 w Reset Capture, Compare-Match Falling Edge Flag RCC62R RCC61R RCC60R 4 2 0 w Reset Capture, Compare-Match Rising Edge Flag 1) Writing 1 to one of these bits will clear the associated flag. Writing 0 has no effect. Note: The set/clear bits in registers ISS and ISR can be written (set) via bit-operations (e.g. BSET), logical operations (e.g. OR), or single MOV-operations (e.g. executed via PEC). User’s Manual CAPCOM6_X, V2.0 18-76 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) Register IEN contains the interrupt enable bits and a control bit to enable the automatic idle function in the case of a wrong hall pattern. Setting a bit in this register will enable the interrupt request (or defined function for a bit). Clearing a bit disables the interrupt request (or defined other function). CCU6_IEN Interrupt Enable Register 15 - 14 13 12 EN EN EN IDLE WHE CHE rw rw rw 11 XSFR (E8D8H/--) 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 EN EN EN EN EN EN EN EN EN EN EN TRP T13 T13 T12 T12 CC CC CC CC CC CC F PM CM PM OM 62F 62R 61F 61R 60F 60R - rw rw rw rw rw rw rw rw rw rw Field Bits Type Description ENIDLE 14 rw Enable Idle Flag Set Function ENWHE 13 rw Enable Wrong Hall Event Interrupt ENCHE 12 rw Enable Correct Hall Event Interrupt ENTRPF 10 rw Enable Trap Flag Interrupt ENT13PM 9 rw Enable T13 Period-Match Interrupt ENT13CM 8 rw Enable T13 Compare-Match Interrupt ENT12PM 7 rw Enable T12 Period-Match Interrupt ENT12OM 6 rw Enable T12 One-Match Interrupt ENCC62F ENCC61F ENCC60F 5 3 1 rw Enable Capture, Compare-Match Interrupt upon Falling Edge ENCC62R ENCC61R ENCC60R 4 2 0 rw Enable Capture, Compare-Match Interrupt upon Rising Edge User’s Manual CAPCOM6_X, V2.0 0 18-77 rw V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) The interrupt sources of the CAPCOM6 module can be mapped to four interrupt nodes by programming the interrupt node pointer register CC6_INP. The encoding valid for all bitfields is shown in Table 18-10. CCU6_INP Interrupt Node Pointer Reg. 13 12 11 10 XSFR (E8D6H/--) 15 14 - - INP T13 INP T12 INP ERR INP CHE INP CC62 INP CC61 INP CC60 - - rw rw rw rw rw rw rw Type 9 8 7 6 Reset Value: 3940H 5 4 3 2 1 0 Field Bits Description INPT13 [13:12] rw Interrupt Node Pointer for Timer13 Interrupt This bitfield selects the interrupt request line for source T13CM and/or source T13PM. INPT12 [11:10] rw Interrupt Node Pointer for Timer12 Interrupts This bitfield selects the interrupt request line for source T12OM and/or source T12PM. INPERR [9:8] rw Interrupt Node Pointer for Error Interrupts This bitfield selects the interrupt request line for source TRPF and/or source WHE. INPCHE [7:6] rw Interrupt Node Pointer for the CHE Interrupt This bitfield selects the interrupt request line for source CHE and/or source STR. INPCC62 INPCC61 INPCC60 [5:4] [3:2] [1:0] rw Interrupt Node Pointer for Channel x Interrupts This bitfield selects the interrupt request line for source CC6xR and/or source CC6xF. Table 18-10 Encoding of Interrupt Node Pointer Bitfields Bitfield INPxx Interrupt Output Line to be Activated 00B I0 01B I1 10B I2 11B I3 The default assignment of the interrupt sources to the nodes and their corresponding control registers are listed in Table 18-11. User’s Manual CAPCOM6_X, V2.0 18-78 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) All interrupt control registers have the same structure. The basic register layout is shown below, Table 18-11 lists the associated addresses. CCU6_xIC CAPCOM6 Intr. Ctrl. Reg. 15 14 13 12 11 ESFR (Table 18-11) 10 9 - - - - 8 GPX - - - rw 7 6 Reset Value: - - 00H 5 4 CCy CCy IR IE rwh rw 3 2 1 0 ILVL GLVL rw rw Note: Please refer to the general Interrupt Control Register description for an explanation of the control fields. Table 18-11 CAPCOM6 Default Interrupt Node Register Assignment Source of Interrupt Interrupt Request Nr. Interrupt Control Register Register Address Channel 0 Interrupts I0 CCU6_IC F140H Channel 1 Interrupts I0 Channel 2 Interrupts I0 Correct Hall Pattern Interrupt I1 CCU6_EIC F188H Emergency Interrupts I1 Timer T12 Interrupts I2 CCU6_T12IC F190H Timer T13 Interrupts I3 CCU6_T13IC F198H User’s Manual CAPCOM6_X, V2.0 18-79 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.10 Suspend Mode In suspend mode, the functional clock fCC6 of the module kernel is stopped. The registers can still be accessed by the CPU (read only). This mode is useful for debugging purposes, e.g. where the current device status should be ‘frozen’ in order to get a snapshot of the internal values. In suspend mode, the timers T12 and T13 are not running. The suspend mode is non-intrusive concerning the register bits. This means, register bits are not changed by hardware when entering or leaving the suspend mode. Software actions are also not required. In suspend mode, all registers can be accessed by read instructions for debugging purposes. The suspend mode can be entered when the suspend mode is requested, the suspend mode is enabled and the module has reached a safe, deterministic state (like the timer stop conditions in single shot mode). This behavior avoids critical situations if a power inverter is connected to the module’s outputs. The suspend state has no direct influence on the output signals. User’s Manual CAPCOM6_X, V2.0 18-80 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Capture/Compare Unit 6 (CAPCOM6) 18.11 Interfaces of the CAPCOM6 Unit The CAPCOM6 units is connected to its environment in different ways. Internal Connections The 4 interrupt request lines of the CAPCOM6 unit are connected to the interrupt control block. The period match signal of timer T13 (T13_PM) is connected to the ADC, as a possible trigger source for injected conversions. External Connections The signals of the CAPCOM6 unit are connected with input/output ports of the XC164. These ports may provide capture trigger signals from the external system, issue compare output signals to external circuitry, or accept control input signals. System Control Unit (SCU) fCC6 CC60 CC6DIS COUT60 CAPCOM6 Module CCU6IRQ Interrupt Control CCU6EIRQ CCU6T12IRQ CCU6T13IRQ CC61 CCOUT61 CC62 I0 CCOUT62 I1 CCOUT63 I2 I3 CTRAP CC6POS0 ADC CC6POS1 CCU6T13PM CC6POS2 P1L.0 P1L.1 P1L.2 P1L.3 P1L.4 P1L.5 P1L.6 P1L.7 P1H.0 P1H.1 P1H.2 MCA05550 Figure 18-46 CAPCOM6 Unit Interfaces User’s Manual CAPCOM6_X, V2.0 18-81 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19 Asynchronous/Synchronous Serial Interface (ASC) The XC164 contains two Asynchronous/Synchronous Serial Interfaces, ASC0 and ASC1. The following sections present the general features and operations of such an ASC module. The final section describes the actual implementation of the two ASC modules including their interconnections with other on-chip modules. The ASC supports full-duplex asynchronous communication and half-duplex synchronous communication. The ASC provides the following features and functions. Features and Functions • • • • • • • • • Full-duplex asynchronous operating modes – 8- or 9-bit data frames, LSB first – Parity bit generation/checking – One or two stop bits – Baudrate from 2.5 Mbit/s to 50 bit/s (@ 40 MHz module clock fASC) Multiprocessor Mode for automatic address/data byte detection Loopback capability Support for IrDA data transmission up to 115.2 kbit/s maximum Half-duplex 8-bit synchronous operating mode – Baudrate from 5 Mbit/s to 202 bit/s (@ 40 MHz module clock fASC) Double buffered transmitter/receiver Interrupt generation – On a transmitter buffer empty condition – On a transmit last bit of a frame condition – On a receiver buffer full condition – On an error condition (frame, parity, overrun error) Autobaud detection unit for asynchronous operating modes – Detection of standard baudrates 1200, 2400, 4800, 9600, 19200, 38400, 57600, 115200, and 230400 bit/s – Detection of non-standard baudrates – Detection of Asynchronous Modes – 7 bit, even parity; 7 bit, odd parity; 8 bit, even parity; 8 bit, odd parity; 8 bit, no parity – Automatic initialization of control bits and baudrate generator after detection – Detection of a serial two-byte ASCII character frame FIFO – 8-stage receive FIFO (RXFIFO), 8-stage transmit FIFO (TXFIFO) – Independent control of RXFIFO and TXFIFO – 9-bit FIFO data width – Programmable Receive/Transmit Interrupt Trigger Level – Receive and transmit FIFO filling level indication – Overrun and Underflow error generation Figure 19-1 shows all functional relevant interfaces associated with the ASC Kernel. User’s Manual ASC_X, V2.0 19-1 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Bus Interface Product Interface Module fASC Clock Control ASCxDIS Address Decoder TxD TIR TBIR Interrupt Control ASC Module (Kernel) RxD Port Control RIR EIR ABSTIR ABDETIR MCA05432 Figure 19-1 ASC Interface Diagram User’s Manual ASC_X, V2.0 19-2 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.1 Operational Overview Figure 19-2 shows a block diagram of the ASC with its operating modes (Asynchronous and Synchronous Mode). Asynchronous Mode fASC Prescaler / Fractional Divider fDIV Autobaud Detection Baudrate Timer Serial Port Control RxD MUX IrDA Decoding Receive / Transmit Buffers and Shift Registers MUX IrDA Decoding TxD Synchronous Mode fASC 2 or 3 Baudrate Timer Serial Port Control TxD Shift Clock Receive / Transmit Buffers and Shift Registers RxD RxD MCB05433 Figure 19-2 Block Diagram of the ASC The ASC supports full-duplex asynchronous communication with up to 2.5 Mbit/s and half-duplex synchronous communication with up to 5 Mbit/s (@ 40 MHz module clock). In Synchronous Mode, data are transmitted or received synchronous to a shift clock that is generated by the microcontroller. In Asynchronous Mode, either 8- or 9-bit data transfer, parity generation, and the number of stop bits can be selected. Parity, framing, and overrun error detection is provided to increase the reliability of data transfers. Transmission and reception of data is double-buffered. For multiprocessor communication, a mechanism is provided to distinguish address bytes from data bytes. User’s Manual ASC_X, V2.0 19-3 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Testing is supported by a loop-back option. A 13-bit baudrate timer with a versatile input clock divider circuitry provides the serial clock signal. In a Special Asynchronous Mode, the ASC supports IrDA data transmission up to 115.2 kbit/s with fixed or programmable IrDA pulse width. Autobaud Detection allows to detect asynchronous data frames with its baudrate and mode with automatic initialization of the baudrate generator and the mode control bits. A transmission is started by writing to the transmit buffer register TBUF. The selected operating mode determines the number of data bits that will actually be transmitted, so that, bits written to positions 9 through 15 of register TBUF are always insignificant. Data transmission is double-buffered, so a new character may be written to the transmit buffer register before the transmission of the previous character is complete. This allows the transmission of characters back-to-back without gaps. Data reception is enabled by the Receiver Enable Bit REN. After reception of a character has been completed, the received data can be read from the (read-only) receive buffer register RBUF; the received parity bit can also be read if provided by the selected operating mode. Bits in the upper half of RBUF that are not valid in the selected operating mode will be read as zeros. Data reception is double-buffered, so that reception of a second character may already begin before the previously received character has been read out of the receive buffer register. In all modes, receive overrun error detection can be selected through bit OEN. When enabled, the overrun error status flag OE and the error interrupt request line EIR will be activated when the receive buffer register has not been read by the time reception of a ninth character is complete. The previously received character in the receive buffer is overwritten. The Loopback Mode (selected by bit LB) allows the data currently being transmitted to be received simultaneously in the receive buffer. This may be used to test serial communication routines at an early stage without having to provide an external network. Note: In Loopback Mode, the alternate input/output functions of the associated port pins are not necessary. Note: Serial data transmission or reception is only possible when the Baudrate Generator Run bit R is set. Otherwise, the serial interface is idle. Note: Do not program the Mode Control bitfield M to one of the reserved combinations to avoid unpredictable behavior of the serial interface. The operating mode of the serial channel ASC is controlled by its control register ASCx_CON. This register contains control bits for mode and error check selection, and status flags for error identification. User’s Manual ASC_X, V2.0 19-4 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.2 Asynchronous Operation Asynchronous Mode supports full-duplex communication in which both transmitter and receiver use the same data frame format and the same baudrate. Data is transmitted on line TxD and received on line RxD. IrDA data transmission/reception is supported up to 115.2 kbit/s. Figure 19-3 shows the block diagram of the ASC when operating in Asynchronous Mode. CON.FDE CON.BRS 13-bit Reload Register Fractional Divider fASC MUX fDIV 2 Autobaud Start Int. ABSTIR Autobaud Detection ABDETIR Autobaud Detect Int. CON.FE CON.PE CON.OE RIR Shift Clock TIR Serial Port Control FIFO Shift Clock Control TBIR EIR Receive Int. Request Transmit Int. Request Transmit Buffer Int. Request Error Int. Request Receive Shift Register Transmit Shift Register IrDA Decoding Receive Buffer Reg. RBUF Transmit Buffer Reg. TBUF MUX Sampling IrDA Coding Internal Bus MUX RxD MUX CON.ODD CON.STP CON.M CON.REN CON.FEN CON.PEN CON.OEN CON.LB fBR fBRT 3 CON.R MUX 16 13-bit Baudrate Timer 1 1 TxD MCA05434 Figure 19-3 User’s Manual ASC_X, V2.0 Asynchronous Mode of Serial Channel ASC 19-5 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.2.1 Asynchronous Data Frames 8-Bit Data Frames 8-bit data frames consist of either eight data bits D7 … D0 (M = 001B), or seven data bits D6 … D0 plus an automatically generated parity bit (M = 011B). Parity may be odd or even, depending on bit ODD. An even parity bit will be set if the modulo-2-sum of the 7 data bits is 1. An odd parity bit will be cleared in this case. Parity checking is enabled via bit PEN (always OFF in 8-bit data mode). The parity error flag PE will be set, along with the error interrupt request flag, if a wrong parity bit is received. The parity bit itself will be stored in bit RBUF.7. 10-/11-bit UART Frame 8 Data Bits 1 M = 001B Start D0 Bit LSB 0 D1 D2 D3 D4 D5 D6 1 (1st) (2nd) D7 Stop Stop MSB Bit Bit 10-/11-bit UART Frame 7 Data Bits 1 M = 011B Start D0 Bit LSB 0 D1 D2 D3 D4 D5 1 (1st) (2nd) D6 Parity Stop Stop MSB Bit Bit Bit MCT05435 Figure 19-4 Asynchronous 8-Bit Frames User’s Manual ASC_X, V2.0 19-6 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 9-Bit Data Frames 9-bit data frames consist of either nine data bits D8 … D0 (M = 100B), eight data bits D7 … D0 plus an automatically generated parity bit (M = 111B), or eight data bits D7 … D0 plus wake-up bit (M = 101B). Parity may be odd or even, depending on bit ODD. An even parity bit will be set if the modulo-2-sum of the 8 data bits is 1. An odd parity bit will be cleared in this case. Parity checking is enabled via bit PEN (always OFF in 9-bit data and wake-up mode). The parity error flag PE will be set, along with the error interrupt request flag, if a wrong parity bit is received. The parity bit itself will be stored in bit RBUF.8. 11-/12-bit UART Frame 9 Data Bits 1 Start D0 Bit LSB 0 D1 D2 D3 D4 D5 D6 D7 1 (1st) (2nd) Bit 9 Stop Stop Bit Bit CON.M = 100B : Bit 9 = Data Bit D8 CON.M = 101B : Bit 9 = Wake-up Bit CON.M = 111B : Bit 9 = Parity Bit MCT05436 Figure 19-5 Asynchronous 9-Bit Frames In wake-up mode, received frames are transferred to the receive buffer register only if the 9th bit (the wake-up bit) is 1. If this bit is 0, no receive interrupt request will be activated and no data will be transferred. This feature may be used to control communication in a multi-processor system: When the master processor wants to transmit a block of data to one of several slaves, it first sends out an address byte to identify the target slave. An address byte differs from a data byte in that the additional 9th bit is a 1 for an address byte, but is a 0 for a data byte; so, no slave will be interrupted by a data ‘byte’. An address ‘byte’ will interrupt all slaves (operating in 8-bit data + wake-up bit mode), so each slave can examine the eight LSBs of the received character (the address). The addressed slave will switch to 9-bit data mode (such as by clearing bit M[0]), to enable it to also receive the data bytes that will be coming (having the wake-up bit cleared). The slaves not being addressed remain in 8-bit data + wake-up bit mode, ignoring the following data bytes. User’s Manual ASC_X, V2.0 19-7 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) IrDA Frames The modulation schemes of IrDA are based on standard asynchronous data transmission frames. The asynchronous data format in IrDA Mode (M = 010B) is defined as follows: 1 start bit/8 data bits/1 stop bit The coding/decoding of/to the asynchronous data frames is shown in Figure 19-6. In general, during IrDA transmissions, UART frames are encoded into IR frames and vice versa. A low level on the IR frame indicates an “LED off” state. A high level on the IR frame indicates an “LED on” state. For a 0-bit in the UART frame, a high pulse is generated. For a 1-bit in the UART frame, no pulse is generated. The high pulse starts in the middle of a bit cell and has a fixed width of 3/16 of the bit time. The ASC also allows the length of the IrDA high pulse to be programmed. Further, the polarity of the received IrDA pulse can be inverted in IrDA Mode. Figure 19-6 shows the non-inverted IrDA pulse scheme. UART Frame 8 Data Bits Start Bit Stop Bit 0 1 0 1 0 0 1 1 0 1 IR Frame 8 Data Bits Start Bit 0 Stop Bit 1 0 Bit Time 1 0 0 1 1/2-bit Time 1 0 1 Pulse Width = 3/16-bit Time (or variable length) MCT05437 Figure 19-6 IrDA Frame Encoding/Decoding The ASC IrDA pulse mode/width register PMW contains the 8-bit IrDA pulse width value and the IrDA pulse width mode select bit. This register is required in the IrDA operating mode only. User’s Manual ASC_X, V2.0 19-8 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.2.2 Asynchronous Transmission Asynchronous transmission begins at the next overflow of the divide-by-16 baudrate timer (transition of the baudrate clock fBR), if bit R is set and data has been loaded into TBUF. The transmitted data frame consists of three basic elements: • • • Start bit Data field (eight or nine bits, LSB first, including a parity bit, if selected) Delimiter (one or two stop bits) Data transmission is double-buffered. When the transmitter is idle, the transmit data loaded in the transmit buffer register is immediately moved to the transmit shift register, thus freeing the transmit buffer for the next data to be sent. This is indicated by the transmit buffer interrupt request line TBIR being activated. TBUF may now be loaded with the next data, while transmission of the previous data continues. The transmit interrupt request line TIR will be activated before the last bit of a frame is transmitted, that is, before the first or the second stop bit is shifted out of the transmit shift register. Note: The transmitter output pin TxD must be configured for alternate data output. 19.2.3 Transmit FIFO Operation The transmit FIFO (TXFIFO) provides the following functionality: • • • • • Enable/disable control Programmable filling level for transmit interrupt generation Filling level indication FIFO clear (flush) operation FIFO overflow error generation The 8-stage transmit FIFO is controlled by the TXFCON control register. When bit TXFEN is set, the transmit FIFO is enabled. The interrupt trigger level defined by TXFITL defines the filling level of the TXFIFO at which a transmit buffer interrupt TBIR or a transmit interrupt TIR is generated. These interrupts are always generated when the filling level of the transmit FIFO is equal to or less than the value stored in TXFITL. Bitfield TXFFL in the FIFO status register ASCx_FSTAT indicates the number of entries that are actually written (valid) in the TXFIFO. Therefore, the software can verify, in the interrupt service routine, for instance, how many bytes can still be written into the transmit FIFO via register TBUF without getting an overrun error. The transmit FIFO cannot be accessed directly. All data write operations into the TXFIFO are executed by writing into the TBUF register. User’s Manual ASC_X, V2.0 19-9 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) TXFCON.TXFITL = 0011 B Byte 6 Byte 6 Byte 6 Byte 7 Byte 7 Byte 6 Byte 6 Byte 5 Byte 5 Byte 5 Byte 5 Byte 4 Byte 4 Byte 6 Byte 5 Byte 5 Byte 4 Byte 4 Byte 4 3 Byte Byte 3 Byte 3 Byte Byte 3 22 Byte Byte 2 Byte 2 Byte 2 FSTAT. 0000 TXFFL TxD TXFIFO Empty Byte 3 0101 Byte 1 TBIR Byte 7 0100 0011 Byte 2 TBIR Writing Byte 1 Writing Byte 2 Writing Byte 3 Writing Byte 4 Writing Byte 5 Writing Byte 6 0010 Byte 3 0010 Byte 4 TIR TBIR 0001 Byte 5 TIR TBIR TIR TBIR 0000 Byte 6 Byte 7 TIR TBIR TIR Writing Byte 7 MCT05438 Figure 19-7 Transmit FIFO Operation Example The example in Figure 19-7 shows a typical 8-stage transmit FIFO operation. In this example seven bytes are transmitted via the TxD output line. The transmit FIFO interrupt trigger level TXFITL is set to 0011B. The first byte written into the empty TXFIFO via TBUF is directly transferred into the transmit shift register and is not written into the FIFO. A transmit buffer interrupt will be generated in this case. After byte 1, bytes 2 to 6 are written into the transmit FIFO. After the transfer of byte 3 from the TXFIFO into the transmit shift register of the ASC, 3 bytes remain in the TXFIFO. Therefore, the value of TXFITL is reached and a transmit buffer interrupt will be generated at the beginning and a transmit interrupt at the end of the byte 3 serial transmission. During the serial transmission of byte 4, another byte (byte 7) is written into the TXFIFO (TBUF write operation). Finally, after the start of the serial transmission of byte 7, the TXFIFO is again empty. User’s Manual ASC_X, V2.0 19-10 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) If the TXFIFO is full and additional bytes are written into TBUF, the error interrupt will be generated with bit OE set. In this case, the data byte that was last written into the transmit FIFO is overwritten and the transmit FIFO filling level TXFFL is set to maximum. The TXFIFO can be flushed or cleared by setting bit TXFFLU in register ASCx_TXFCON. After this TXFIFO flush operation, the TXFIFO is empty and the transmit FIFO filling level TXFFL is set to 0000B. A running serial transmission is not aborted by a receive FIFO flush operation Note: The TXFIFO is flushed automatically with a reset operation of the ASC module and if the TXFIFO becomes disabled (resetting bit TXFEN) after it was previously enabled. User’s Manual ASC_X, V2.0 19-11 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.2.4 Asynchronous Reception Asynchronous reception is initiated by a falling edge (1-to-0 transition) on line RxD, provided that bits R and REN are set. The receive data input line RxD is sampled at 16 times the rate of the selected baudrate. A majority decision of the 7th, 8th, and 9th sample determines the effective bit value. This avoids erroneous results that may be caused by noise. If the detected value is not a 0 when the start bit is sampled, the receive circuit is reset and waits for the next 1-to-0 transition at line RxD. If the start bit proves valid, the receive circuit continues sampling and shifts the incoming data frame into the receive shift register. When the last stop bit has been received, the content of the receive shift register are transferred to the receive data buffer register RBUF. Simultaneously, the receive interrupt request line RIR is activated after the 9th sample in the last stop bit time slot (as programmed), regardless of whether valid stop bits have been received or not. The receive circuit then waits for the next start bit (1-to-0 transition) at the receive data input line. Note: The receiver input pin RxD must be configured for input. Asynchronous reception is stopped by clearing bit REN. A currently received frame is completed including the generation of the receive interrupt request and an error interrupt request, if appropriate. Start bits that follow this frame will not be recognized. Note: In wake-up mode, received frames are transferred to the receive buffer register only if the 9th bit (the wake-up bit) is 1. If this bit is 0, no receive interrupt request will be activated and no data will be transferred. 19.2.5 Receive FIFO Operation The receive FIFO (RXFIFO) provides the following functionality: • • • • • Enable/disable control Programmable filling level for receive interrupt generation Filling level indication FIFO clear (flush) operation FIFO overflow error generation The 8-stage receive FIFO is controlled by the RXFCON control register. When bit RXFEN is set, the receive FIFO is enabled. The interrupt trigger level defined by RXFITL defines the filling level of RXFIFO at which a receive interrupt RIR is generated. RIR is always generated when the filling level of the receive FIFO is equal to or greater than the value stored in RXFITL. Bitfield RXFFL in the FIFO status register ASCx_FSTAT indicates the number of bytes that have been actually written into the FIFO and can be read out of the FIFO by a user program. User’s Manual ASC_X, V2.0 19-12 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) The receive FIFO cannot be accessed directly. All data read operations from the RXFIFO are executed by reading the RBUF register. RXFCON.RXFITL = 0011 B Byte 6 Byte 4 Content of FSTAT.RXFFL 0000 RxD Byte 1 Byte 1 0001 Byte 2 Byte 3 Byte 3 Byte 2 Byte 2 Byte 2 Byte 1 Byte 1 Byte 1 0010 0011 Byte 3 RIR 0100 Byte 4 RIR Byte 4 0001 Byte 5 Byte 5 Byte 5 Byte 4 Byte 4 RXFIFO Empty 0100 0000 0010 Byte 6 RIR Read RBUF (Byte 1) Read RBUF (Byte 2) Read RBUF (Byte 3) Read RBUF (Byte 4) Read RBUF (Byte 5) Read RBUF (Byte 6) MCT05439 Figure 19-8 Receive FIFO Operation Example The example in Figure 19-8 shows a typical 8-stage receive FIFO operation. In this example, six bytes are received via the RxD input line. The receive FIFO interrupt trigger level RXFITL is set to 0011B. Therefore, the first receive interrupt RIR is generated after the reception of byte 3 (RXFIFO is filled with three bytes). After the reception of byte 4, three bytes are read out of the receive FIFO. After this read operation, the RXFIFO still contains one byte. RIR becomes again active after two more bytes (byte 5 and 6) have been received (RXFIFO filled again with 3 bytes). Finally, the FIFO is cleared after three read operation. If the RXFIFO is full and additional bytes are received, the receive interrupt RIR and the error interrupt EIR will be generated with bit OE set. In this case, the data byte last written into the receive FIFO is overwritten. With the overrun condition, the receive FIFO filling level RXFFL is set to maximum. If a RBUF read operation is executed with the RXFIFO User’s Manual ASC_X, V2.0 19-13 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) enabled but empty, an error interrupt EIR will be generated as well with bit OE set. In this case, the receive FIFO filling level RXFFL is set to 0000B. If the RXFIFO is available but disabled (RXFEN = 0) and the receive operation is enabled (REN = 1), the asynchronous receive operation is functionally equivalent to the asynchronous receive operation of the ASC module. The RXFIFO can be flushed or cleared by setting bit RXFFLU in register RXFCON. After this RXFIFO flush operation, the RXFIFO is empty and the receive FIFO filling level RXFFL is set to 0000B. The RXFIFO is flushed automatically with a reset operation of the ASC module and if the RXFIFO becomes disabled (resetting bit RXFEN) after it was previously enabled. Resetting bit REN without resetting RXFEN does not affect (reset) the RXFIFO state. This means that the receive operation of the ASC is stopped, in this case, without changing the content of the RXFIFO. After setting REN again, the RXFIFO with its content is again available. Note: After a successful autobaud detection sequence (if implemented), the RXFIFO should be flushed before data is received. User’s Manual ASC_X, V2.0 19-14 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.2.6 FIFO Transparent Mode In Transparent Mode, a specific interrupt generation mechanism is used for receive and transmit buffer interrupts. In general, in Transparent Mode, receive interrupts are always generated if data bytes are available in the RXFIFO. Transmit buffer interrupts are always generated if the TXFIFO is not full. The relevant conditions for interrupt generation in Transparent Mode are: • • FIFO filling levels Read/write operations on the RBUF/TBUF data register Interrupt generation for the receive FIFO depends on the RXFIFO filling level and the execution of read operations of register RBUF (see Figure 19-9). Transparent Mode for the RXFIFO is enabled when bits RXTMEN and RXFEN in register ASCx_RXFCON are set. Content of RXFCON. RXFFL 0000 RxD Byte 1 0001 Byte 2 0010 Byte 3 0011 0100 0011 0010 0001 0001 Byte 4 RIR (2) RIR (3) RIR (4) RIR (1) Read RBUF Read Read Byte 1 Byte 2 Read Read Byte 3 Byte 4 MCT05440 Figure 19-9 Transparent Mode Receive FIFO Operation If the RXFIFO is empty, a receive interrupt RIR is always generated when the first byte is written into an empty RXFIFO (RXFFL changes from 0000B to 0001B). If the RXFIFO is filled with at least one byte, the occurrence of further receive interrupts depends on the read operations of register RBUF. The receive interrupt RIR will always be activated after a RBUF read operation if the RXFIFO still contains data (RXFFL is not equal to 0000B). If the RXFIFO is empty after a RBUF read operation, no further receive interrupt will be generated. If the RXFIFO is full (RXFFL = maximum) and additional bytes are received, an error interrupt EIR will be generated with bit OE set. In this case, the data byte last written into the receive FIFO is overwritten. If a RBUF read operation is executed with the RXFIFO enabled but empty (underflow condition), an error interrupt EIR will be generated as well, with bit OE set. If the RXFIFO is flushed in Transparent Mode, the software must take care that a previous pending receive interrupt is ignored. User’s Manual ASC_X, V2.0 19-15 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Note: The Receive FIFO Interrupt Trigger Level bitfield RXFITL is a don’t care in Transparent Mode. Interrupt generation for the transmit FIFO depends on the TXFIFO filling level and the execution of write operations to the register TBUF. Transparent Mode for the TXFIFO is enabled when bits TXTMEN and TXFEN are set. A transmit buffer interrupt TBIR is always generated when the TXFIFO is not full (TXFFL not equal to maximum) after a byte has been written into register ASCx_TBUF. TBIR is also activated after a TXFIFO flush operation or when the TXFIFO becomes enabled (TXTMEN and TXFEN set) when it was previously disabled. In these cases, the TXFIFO is empty and ready to be filled with data. If the TXFIFO is full (TXFFL = maximum) and an additional byte is written into TBUF, no further transmit buffer interrupt will be generated after the TBUF write operation. In this case the data byte last written into the transmit FIFO is overwritten and an overrun error interrupt (EIR) will be generated with bit OE set. Note: The Transmit FIFO Interrupt Trigger Level bitfield TXFITL is a don’t care in Transparent Mode. 19.2.7 IrDA Mode The duration of the IrDA pulse is normally 3/16 of a bit period. The IrDA standard also allows the pulse duration to be independent of the baudrate or bit period. In this case, the width of the transmitted pulse always corresponds to the 3/16 pulse width at 115.2 kbit/s, which is 1.627 µs. Either fixed or bit-period-dependent IrDA pulse width generation can be selected. The IrDA pulse width mode is selected by bit IRPW. In case of fixed IrDA pulse width generation, the lower eight bits in register PMW are used to adapt the IrDA pulse width to a fixed value such as 1.627 µs. The fixed IrDA pulse width is generated by a programmable timer as shown in Figure 19-10. PWM tIPW Start Timer fASC 8-bit Timer IrDA Pulse MCA05441 Figure 19-10 Fixed IrDA Pulse Generation The IrDA pulse width can be calculated according the formulas given in Table 19-1. Note: The name PMW in the formulas of Table 19-1 represents the contents of the pulse mode/width register PMW (PW_VALUE), taken as an unsigned 8-bit integer. User’s Manual ASC_X, V2.0 19-16 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Table 19-1 Formulas for IrDA Pulse Width Calculation PMW PMW_IPMW 1 … 255 0 Formulas PMW >> 1 )t IPW min = (-------------------------------f ASC 3 t IPW = --------------------------------------16 × Baudrate 1 t IPW = PMW --------------f ASC The contents of PW_VALUE further define the minimum IrDA pulse width (tIPW min) that is still recognized as a valid IrDA pulse during a receive operation. This function is independent of the selected IrDA pulse width mode (fixed or variable) which is defined by bit IRPW. The minimum IrDA pulse width is calculated by a shift right operation of PMW bit 7-0 by one bit divided by the module clock fASC. Note: If IRPW is cleared (fixed IrDA pulse width), PW_VALUE must be a value which assures that tIPW > tIPW min. Table 19-2 gives examples for typical frequencies of fASC. Table 19-2 IrDA Pulse Width Adaption to 1.627 µs fASC PMW tIPW Error tIPW min 20 MHz 33 1.650 µs +1.4% 0.8 µs 40 MHz 65 1.625 µs -0.1% 0.8 µs 19.2.8 RxD/TxD Data Path Selection in Asynchronous Modes The data paths for the serial input and output data in Asynchronous Mode are affected by several control bits in the registers CON and ABCON as shown in Figure 19-11. The Synchronous Mode operation is not affected by these data path selection capabilities. The input signal from RxD passes an inverter which is controlled by bit RXINV. The output signal of this inverter is used for the Autobaud Detection and may bypass the logic in the Echo Mode (controlled by bit ABEM). Further, two multiplexers are in the RxD input signal path for providing the Loopback Mode capability (controlled by bit LB) and the IrDA receive pulse inversion capability (controlled by bit RxDI). Depending on the Asynchronous Mode (controlled by bitfield M), output signal or the RxD input signal in Echo Mode (controlled by bit ABEM) is switched to the TxD output via an inverter (controlled by bit TXINV). User’s Manual ASC_X, V2.0 19-17 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Autobaud Detection ABCON RXINV RxD TXINV ABEM MUX MUX MUX IrDA Coding IrDA Decode ASC Asynch. Mode Logic MUX MUX MUX TxD CON LB RxDI M MCA05442 Figure 19-11 RxD/TxD Data Path in Asynchronous Modes Note: In Echo Mode the transmit output signal is blocked by the Echo Mode output multiplexer. Figure 19-11 shows that it is not possible to use an IrDA coded receiver input signal for Autobaud Detection. User’s Manual ASC_X, V2.0 19-18 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.3 Synchronous Operation Synchronous Mode supports half-duplex communication, basically for simple I/O expansion via shift registers. Data is transmitted and received via line RxD while line TxD outputs the shift clock. Synchronous Mode is selected with bitfield M = 000B. Eight data bits are transmitted or received synchronous to a shift clock generated by the internal baudrate generator. The shift clock is active only as long as data bits are transmitted or received. 13-bit Reload Register fASC MUX 2 fDIV 13-bit Baudrate Timer fBRT 3 R 4 fBR BRS M = 000B OE RIR Shift Clock REN OEN LB TxD RxD TIR Serial Port Control FIFO Shift Clock Control 0 1 MUX TBIR EIR Receive Int. Request Transmit Int. Request Transmit Buffer Int. Request Error Int. Request Receive Shift Register Transmit Shift Register Receive FIFO Reg. RBUF Transmit FIFO Reg. TBUF Internal Bus MCA05443 Figure 19-12 Synchronous Mode of Serial Channel ASC User’s Manual ASC_X, V2.0 19-19 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.3.1 Synchronous Transmission Synchronous transmission begins within four state times after data has been loaded into TBUF, provided that bit R is set and bit REN is cleared (half-duplex, no reception). Exception: in Loopback Mode (bit LB set), REN must be set for reception of the transmitted byte. Data transmission is double-buffered. When the transmitter is idle, the transmit data loaded into TBUF is immediately moved to the transmit shift register, thus freeing TBUF for more data. This is indicated by the transmit buffer interrupt request line TBIR being activated. TBUF may now be loaded with the next data, while transmission of the previous continuous. The data bits are transmitted synchronous with the shift clock. After the bit time for the eighth data bit, both the TxD and RxD lines will go high, the transmit interrupt request line TIR is activated, and serial data transmission stops. Note: Pin TxD must be configured for alternate data output in order to provide the shift clock. Pin RxD must also be configured for output during transmission. 19.3.2 Synchronous Reception Synchronous reception is initiated by setting bit REN. If bit R is set, the data applied at RxD is clocked into the receive shift register synchronous to the clock that is output at TxD. After the eighth bit has been shifted in, the contents of the receive shift register are transferred to the receive data buffer RBUF, the receive interrupt request line RIR is activated, the receiver enable bit REN is reset, and serial data reception stops. Note: Pin TxD must be configured for alternate data output in order to provide the shift clock. Pin RxD must be configured as alternate data input. Synchronous reception is stopped by clearing bit REN. A currently received byte is completed, including the generation of the receive interrupt request and an error interrupt request, if appropriate. Writing to the transmit buffer register while a reception is in progress has no effect on reception and will not start a transmission. If a previously received byte has not been read out of a full receive buffer at the time the reception of the next byte is complete, both the error interrupt request line EIR and the overrun error status flag OE will be activated/set, provided the overrun check has been enabled by bit OEN. 19.3.3 Synchronous Timing Figure 19-13 shows timing diagrams of the ASC Synchronous Mode data reception and data transmission. In idle state, the shift clock level is high. With the beginning of a synchronous transmission of a data byte, the data is shifted out at RxD with the falling edge of the shift clock. If a data byte is received through RxD, data is latched with the rising edge of the shift clock. Between two consecutive receive or transmit data bytes, one shift clock cycle (fBR) delay is inserted. User’s Manual ASC_X, V2.0 19-20 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Receive/Transmit Timing Shift Shift Shift Latch Shift Clock (TxD) Transmit Data (RxD) Data Bit n Data Bit n+1 Data Bit n+2 Receive Data (RxD) Valid Data n Valid Data n+1 Valid Data n+2 D4 D6 Continuous Transmit Timing Shift Clock (TxD) Transmit Data (RxD) D0 D1 D2 D3 D5 D7 D0 D1 1. Byte Receive Data (RxD) D0 D1 D2 D3 D4 D2 D3 2. Byte D5 D6 1. Byte D7 D0 D1 D2 D3 2. Byte MCT05444 Figure 19-13 ASC Synchronous Mode Waveforms User’s Manual ASC_X, V2.0 19-21 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.4 Baudrate Generation The serial channel ASC has its own dedicated 13-bit baudrate generator with reload capability, allowing baudrate generation independent of other timers. The baudrate generator is clocked with a clock (fDIV) derived via a prescaler from the ASC input clock fASC. The baudrate timer counts downwards and can be started or stopped through the baudrate generator run bit R. Each underflow of the timer provides one clock pulse to the serial channel. The timer is reloaded with the value stored in its 13-bit reload register each time it underflow. The resulting clock fBRT is again divided by a factor for the baudrate clock (16 in Asynchronous Modes and 4 in Synchronous Mode). The prescaler is selected by the bits BRS and FDE. In addition to the two fixed dividers, a fractional divider prescaler unit is available in the Asynchronous Modes that allows selection of prescaler divider ratios of n/512 with n = 0 … 511. Therefore, the baudrate of ASC is determined by the module clock, the content of FDV, the reload value of BG, and the operating mode (asynchronous or synchronous). Register ASCx_BG is the dual-function Baudrate Generator/Reload register. Reading ASCx_BG returns the contents of the timer BR_VALUE (bits 15 … 13 return zero), while writing to BG always updates the reload register (bits 15 … 13 are insignificant). An autoreload of the timer with the contents of the reload register is performed each time ASCx_BG is written to. However, if bit R is cleared at the time a write operation to ASCx_BG is performed, the timer will not be reloaded until the first instruction cycle after bit R was set. For a clean baudrate initialization, ASCx_BG should be written only if R = 0. If ASCx_BG is written while R = 1, unpredictable behavior of the ASC may occur during running transmit or receive operations. The ASC baudrate timer reload register ASCx_BG contains the 13-bit reload value for the baudrate timer in Asynchronous and Synchronous modes. 19.4.1 Baudrate in Asynchronous Mode For Asynchronous Mode, the baudrate generator provides a clock fBRT with sixteen times the rate of the established baudrate. Every received bit is sampled at the 7th, 8th, and 9th cycle of this clock. The clock divider circuitry, which generates the input clock for the 13-bit baudrate timer, is extended by a fractional divider circuitry that allows adjustment for more accurate baudrate and the extension of the baudrate range. The baudrate of the baudrate generator depends on the following bits and register values: • • • • Input clock fASC Selection of the baudrate timer input clock fDIV by bits FDE and BRS If bit FDE is set (fractional divider): value of register ASCx_FDV Value of the 13-bit reload register ASCx_BG User’s Manual ASC_X, V2.0 19-22 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) The output clock of the baudrate timer with the reload register is the sample clock in the Asynchronous Modes of the ASC. For baudrate calculations, this baudrate clock fBR is derived from the sample clock fDIV by a division by 16. The ASC fractional divider register ASCx_FDV contains the 9-bit divider value for the fractional divider (Asynchronous Mode only). It is also used for reference clock generation of the autobaud detection unit. FDE Fractional Divider fASC 16 MUX fDIV 2 R 13-bit Reload Register 13-bit Baudrate Timer fBRT fBR Baudrate Clock Sample Clock 3 BRS FDE BRS Selected Divider 0 0 2 0 1 3 1 X Fractional Divider MCA05445 Figure 19-14 ASC Baudrate Generator Circuitry in Asynchronous Modes Using the Fixed Input Clock Divider The baudrate for asynchronous operation of serial channel ASC when using the fixed input clock divider ratios (FDE = 0) and the required reload value for a given baudrate can be determined by the following formulas: BG represents the contents of the reload bitfield BR_VALUE, taken as unsigned 13-bit integer. The maximum baudrate that can be achieved for the Asynchronous Modes when using the two fixed clock divider and a module clock of 40 MHz is 1.25 Mbit/s. Table 19-4 lists various commonly used baudrates together with the required reload values and the deviation errors compared to the intended baudrate. Note: FDE must be 0 to achieve the baudrates in Table 19-3. The deviation errors given in the table are rounded. Using a baudrate crystal will provide correct baudrates without deviation errors. User’s Manual ASC_X, V2.0 19-23 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Table 19-3 Asynchronous Baudrate Formulas Using the Fixed Input Clock Dividers FDE BRS BG Formula 0 0 0 … 8191 f ASC Baudrate = ----------------------------------32 × ( BG + 1 ) f ASC BG = --------------------------------------–1 32 × Baudrate 1 f ASC Baudrate = ----------------------------------48 × ( BG + 1 ) f ASC BG = --------------------------------------–1 48 × Baudrate Table 19-4 Typical Asynchronous Baudrates Using the Fixed Input Clock Dividers BRS = 0, fASC = 40 MHz Baudrate BRS = 1, fASC = 40 MHz Deviation Error Reload Value Deviation Error Reload Value 1.25 Mbit/s --- 0000H NA NA 19.2 kbit/s +0.1% / -1.3% 0040H / 0041H +0.9% / -1.3% 002AH / 002BH 9600 bit/s +0.1% / -0.6% 0081H / 0082H +0.9% / -0.2% 0055H / 0056H 4800 bit/s +0.1% / -0.2% 0103H / 0104H +0.3% / -0.2% 00ACH / 00ADH 2400 bit/s +0.1% / -0.0% 0207H / 0208H +0.0% / -0.2% 015AH / 015BH 1200 bit/s +0.0% / -0.0% 0410H / 0411H +0.0% / -0.0% 02B5H / 02B6H Using the Fractional Divider When the fractional divider is selected, the input clock fDIV for the baudrate timer is derived from the module clock fASC by a programmable divider. If bit FDE is set, the fractional divider is activated. It divides fASC by a fraction of n/512 for any value of n from 0 to 511. If n = 0, the divider ratio is 1, which means that fDIV = fASC. In general, the fractional divider allows the baudrate to be programmed with much more accuracy than with the two fixed prescaler divider stages. Note: BG represents the contents of the reload bitfield BR_VALUE, taken as an unsigned 13-bit integer. Note: FDV represents the contents of the fractional divider register FD_VALUE taken as an unsigned 9-bit integer. User’s Manual ASC_X, V2.0 19-24 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Table 19-5 Async. Baudrate Formulas Using the Fractional Input Clock Divider FDE BRS BG FDV Formula 1 – 1 … 8191 1 … 511 f ASC FDV Baudrate = ------------ × ----------------------------------512 16 × ( BG + 1 ) 0 Table 19-6 f ASC Baudrate = ----------------------------------16 × ( BG + 1 ) Typical Asynchronous Baudrates Using the Fractional Input Clock Divider fASC Desired Baudrate BG FDV Resulting Baudrate Deviation 40 MHz 115.2 kbit/s 04H 076H 115.234 kbit/s 0.02% 57.6 kbit/s 04H 03BH 57.617 kbit/s 0.02% 38.4 kbit/s 0EH 076H 38.411 kbit/s 0.02% 19.2 kbit/s 0EH 03BH 19.206 kbit/s 0.02% User’s Manual ASC_X, V2.0 19-25 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.4.2 Baudrate in Synchronous Mode For synchronous operation, the baudrate generator provides a clock with four times the rate of the established baudrate (see Figure 19-15). 13-bit Reload Register 2 MUX fASC fDIV 13-bit Baudrate Timer 3 Shift / Sample Clock 4 fBRT R BRS BRS Selected Divider 0 2 1 3 MCA05446 Figure 19-15 ASC Baudrate Generator Circuitry in Synchronous Mode The baudrate for synchronous operation of serial channel ASC can be determined by the formulas as shown in Table 19-7. Table 19-7 Synchronous Baudrate Formulas BRS BG 0 0 … 8191 1 Formula f ASC Baudrate = -------------------------------8 × ( BG + 1 ) f ASC Baudrate = ----------------------------------12 × ( BG + 1 ) f ASC BG = -----------------------------------–1 8 × Baudrate f ASC BG = --------------------------------------–1 12 × Baudrate Note: BG represents the contents of the reload bitfield BR_VALUE, taken as an unsigned 13-bit integers. The maximum baudrate that can be achieved in Synchronous Mode when using a module clock of 40 MHz is 5 Mbit/s. User’s Manual ASC_X, V2.0 19-26 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.5 Autobaud Detection 19.5.1 General Operation Autobaud Detection provides a capability to recognize the mode and the baudrate of an asynchronous input signal at RxD. Generally, the baudrates to be recognized must be known by the application. With this knowledge always a set of nine baudrates can be detected. The Autobaud Detection is not designed to calculate a baudrate of an unknown asynchronous frame. Figure 19-16 shows how the Autobaud Detection is integrated into its Asynchronous Mode configuration. The RxD data line is an input to the autobaud detection unit. The clock fDIV, generated by the fractional divider, is used by the autobaud detection unit as time base. After successful recognition of baudrate and Asynchronous Mode of the RxD data input signal, bits in register ASCx_CON and the value of register ASCx_BG in the baudrate timer are set to the appropriate values, and the ASC can start immediately with the reception of serial input data. Asynchronous Mode fASC Prescaler / Fractional Divider fDIV Autobaud Detection Baudrate Timer Serial Port Control RxD MUX IrDA Decoding Receive / Transmit Buffers and Shift Registers MUX TxD IrDA Decoding MCA05447 Figure 19-16 Asynchronous Mode Block Diagram Note: Autobaud detection is not available in Synchronous Mode. The following sequence must be executed to start the autobaud detection unit: • • • • • • Definition of the baudrates to be detected: standard or non-standard baudrates Programming of the prescaler/fractional divider to select a specific value of fDIV Starting the prescaler/fractional divider (setting bit R) Preparing the interrupt system Enabling the autobaud detection (setting bit EN and the interrupt enable bits in ABCON for interrupt generation, if required) Polling interrupt request flag or waiting for the autobaud detection interrupt User’s Manual ASC_X, V2.0 19-27 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.5.2 Serial Frames for Autobaud Detection The Autobaud Detection is based on the serial reception of a specific two-byte serial frame. This serial frame is build up by the two ASCII bytes “at” or “AT” (“aT” or “At” are not allowed). Both byte combinations can be detected in five types of asynchronous frames. Figure 19-17 and Figure 19-18 show the serial frames which are detected at least. Note: Some other two-byte combinations will be defined too. 7 Bit, Even Parity ‘a’ = 61H 1 0 0 0 0 ‘t’ = 74H 1 1 Start 1 1 0 Parity Stop 0 1 0 1 1 1 Start 0 1 Parity Stop 7 Bit, Odd Parity ‘a’ = 61H 1 0 0 0 0 ‘t’ = 74H 1 1 Start 0 1 0 Parity Stop 0 1 0 1 1 1 Start 1 1 Parity Stop 8 Bit, No Parity ‘a’ = 61H 1 0 0 0 0 ‘t’ = 74H 1 1 0 Start 1 0 Stop 0 1 0 1 1 1 0 Start 1 Stop 8 Bit, Even Parity ‘a’ = 61H 1 0 0 0 0 ‘t’ = 74H 1 1 0 Start 1 1 0 Parity Stop 0 1 0 1 1 1 0 Start 0 1 Parity Stop 8 Bit, Odd Parity ‘a’ = 61H 1 Start 0 0 0 0 ‘t’ = 74H 1 1 0 0 0 1 Parity Stop 0 1 Start 0 1 1 1 0 1 1 Parity Stop MCT05448 Figure 19-17 Two-Byte Serial Frames with ASCII ‘at’ User’s Manual ASC_X, V2.0 19-28 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 7 Bit, Even Parity ‘A’ = 41H 1 0 0 0 0 ‘T’ = 54H 0 1 Start 0 1 0 Parity Stop 0 1 0 1 0 1 Start 1 1 Parity Stop 7 Bit, Odd Parity ‘A’ = 41H 1 0 0 0 0 ‘T’ = 54H 0 1 Start 1 1 0 Parity Stop 0 1 0 1 0 1 Start 0 1 Parity Stop 8 Bit, No Parity ‘A’ = 41H 1 0 0 0 0 ‘T’ = 54H 0 1 0 Start 1 0 Stop 0 1 0 1 0 1 0 Start 1 Stop 8 Bit, Even Parity ‘A’ = 41H 1 0 0 0 0 ‘T’ = 54H 0 1 0 Start 0 1 0 Parity Stop 0 1 0 1 0 1 0 Start 1 1 Parity Stop 8 Bit, Odd Parity ‘A’ = 41H 1 Start 0 0 0 0 ‘T’ = 54H 0 1 0 1 0 1 Parity Stop 0 1 Start 0 1 0 1 0 0 1 Parity Stop MCT05449 Figure 19-18 Two-Byte Serial Frames with ASCII ‘AT’ 19.5.3 Baudrate Selection and Calculation Autobaud Detection requires some calculations concerning the programming of the baudrate generator and the baudrates to be detected. Two steps must be considered: • • Defining the baudrate(s) to be detected Programming of the baudrate timer prescaler - setup of the clock rate of fDIV User’s Manual ASC_X, V2.0 19-29 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) In general, the baudrate generator in Asynchronous Mode is build up by two parts (see also Figure 19-14): • • The clock prescaler part which derives fDIV from fASC The baudrate timer part which generates the sample clock fBRT and the baudrate clock fBR Prior to an Autobaud Detection the prescaler part has to be set up by the CPU while the baudrate timer (register ASCx_BG) is initialized with a 13-bit value (BR_VALUE) automatically after a successful autobaud detection. For the following calculations, the fractional divider is used (FDE = 1). Note: It is also possible to use the fixed divide-by-2 or divide-by-3 prescaler. But the fractional divider allows the much more precise adaption of fDIV to the required value. Standard Baudrates For standard baudrate detection the baudrates as shown in Table 19-8 can be e.g. detected. Therefore, the output frequency fDIV of the baudrate generator must be set to a frequency derived from the module clock fASC in a way that it is equal to 11.0592 MHz. The value to be written into register FDV is the nearest integer value which is calculated according the following formula: 512 × 11.0592 MHz FDV = ---------------------------------------------------- (19.1) f ASC Table 19-8 defines the nine standard baudrates (Br0 - Br8) which can be detected for fDIV = 11.0592 MHz. Table 19-8 Autobaud Detection Using Standard Baudrates (fDIV = 11.0592 MHz) Baudrate Numbering Detectable Standard Baudrate Divide Factor df BG is Loaded after Detection with Value Br0 230.400 kbit/s 48 2 = 002H Br1 115.200 kbit/s 96 5 = 005H Br2 57.600 kbit/s 192 11 = 00BH Br3 38.400 kbit/s 288 17 = 011H Br4 19.200 kbit/s 576 35 = 023H Br5 9600 bit/s 1152 71 = 047H Br6 4800 bit/s 2304 143 = 08FH Br7 2400 bit/s 4608 287 = 11FH Br8 1200 bit/s 9216 575 = 23FH User’s Manual ASC_X, V2.0 19-30 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) According to Table 19-8 a baudrate of 9600 bit/s is achieved when register ASCx_BG is loaded with a value of 047H, assuming that fDIV has been set to 11.0592 MHz. Table 19-8 also lists a divide factor df which is defined with the following formula: f DIV Baudrate = -------df (19.2) This divide factor df defines a fixed relationship between the prescaler output frequency fDIV and the baudrate to be detected during the Autobaud Detection operation. This means, changing fDIV results in a totally different baudrate table in means of baudrate values. For the baudrates to be detected, the following relations are always valid: Br0 = fDIV/48D, Br1 = fDIV/96D, … up to Br8 = fDIV/9216D A requirement for detecting standard baudrates up to 230.400 kbit/s is the fDIV minimum value of 11.0592 MHz. With the value FD_VALUE the fractional divider fDIV is adapted to the module clock frequency fASC. Table 19-9 defines the deviation of the standard baudrates when using autobaud detection depending on the module clock fASC. Table 19-9 fASC Standard Baudrates - Deviations and Errors for Autobaud Detection Error in fDIV FDV 10 MHz not possible 12 MHz 472 +0.03% 13 MHz 436 +0.1% 16 MHz 354 +0.03% 18 MHz 315 +0.14% 18.432 MHz 307 -0.07% 20 MHz 283 -0.04% 24 MHz 236 +0.03% 25 MHz 226 -0.22% 30 MHz 189 +0.14% 33 MHz 172 +0.24% 40 MHz 142 +0.31% Note: If the deviation of the baudrate after autobaud detection is to high, the baudrate generator (fractional divider FDV and reload register ASCx_BG) can be reprogrammed if required to get a more precise baudrate with less error. User’s Manual ASC_X, V2.0 19-31 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Non-Standard Baudrates Due to the relationship between Br0 to Br8 in Table 19-8 concerning the divide factor df other baudrates than the standard baudrates can be also selected. E.g. if a baudrate of 50 kbit/s has to be detected, Br2 is e.g. defined as baudrate for the 50 kbit/s selection. This further results in: fDIV = 50 kbit/s × df@Br2 = 50 kbit/s × 192 = 9.6 MHz Therefore, depending on the module clock frequency fASC, the value of the fractional divider (register FDV) must be set in this example according to the formula: 512 × f DIV FDV = ------------------------ f ASC with fDIV = 9.6 MHz (19.3) Using this selection (fDIV = 9.6 MHz), the detectable baudrates start at 200 kbit/s (Br0) down to 1042 bit/s (Br8). Table 19-10 shows the baudrate table for this example. Table 19-10 Autobaud Detection Using Non-Standard Baudrates (fDIV = 9.6 MHz) Baudrate Numbering Detectable NonStandard Baudrates Divide Factor df BG is Loaded after Detection with Value Br0 200.000 kbit/s 48 2 = 002H Br1 100.000 kbit/s 96 5 = 005H Br2 50 kbit/s 192 11 = 00BH Br3 33.333 kbit/s 288 17 = 011H Br4 16.667 kbit/s 576 35 = 023H Br5 8333 bit/s 1152 71 = 047H Br6 4167 bit/s 2304 143 = 08FH Br7 2083 bit/s 4608 287 = 11FH Br8 1047 bit/s 9216 575 = 23FH User’s Manual ASC_X, V2.0 19-32 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.5.4 Overwriting Registers on Successful Autobaud Detection With a successful Autobaud Detection some bits in registers ASCx_CON and ASCx_BG are automatically set to a value which corresponds to the mode and baudrate of the detected serial frame conditions (see Table 19-11). In control register ASCx_CON the mode control bits M and the parity select bit ODD are overwritten. Register ASCx_BG is loaded with the 13-bit reload value for the baudrate timer. Table 19-11 Autobaud Detection Overwrite Values for the CON Register Detected Parameters M ODD BR_VALUE Operating Mode 7 bit, even parity 7 bit, odd parity 8 bit, even parity 8 bit, odd parity 8 bit, no parity 011 011 111 111 001 0 1 0 1 0 – Baudrate Br0 Br1 Br2 Br3 Br4 Br5 Br6 Br7 Br8 – – 2 = 002H 5 = 005H 11 = 00BH 17 = 011H 35 = 023H 71 = 047H 143 = 08FH 287 = 11FH 575 = 23FH Note: The autobaud detection interrupts are described in Section 19.7. User’s Manual ASC_X, V2.0 19-33 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.6 Hardware Error Detection Capabilities To improve the safety of serial data exchange, the serial channel ASC provides an error interrupt request flag to indicate the presence of an error, and three (selectable) error status flags in register ASCx_CON to indicate which error has been detected during reception. Upon completion of a reception, the error interrupt request line EIR will be activated simultaneously with the receive interrupt request line RIR, if one or more of the following conditions are met: • • • If the framing error detection enable bit FEN is set and any of the expected stop bits is not high, the framing error flag FE is set, indicating that the error interrupt request is due to a framing error (Asynchronous Mode only). If the parity error detection enable bit PEN is set in the modes where a parity bit is received, and the parity check on the received data bits proves false, the parity error flag PE is set, indicating that the error interrupt request is due to a parity error (Asynchronous Mode only). If the overrun error detection enable bit OEN is set and the last character received was not read out of the receive buffer by software or by a DMA transfer at the time the reception of a new frame is complete, the overrun error flag OE is set indicating that the error interrupt request is due to an overrun error (Asynchronous and Synchronous Mode). User’s Manual ASC_X, V2.0 19-34 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.7 Interrupts Six interrupt sources are provided for serial channel ASC. Line TIR indicates a transmit interrupt, TBIR indicates a transmit buffer interrupt, RIR indicates a receive interrupt and EIR indicates an error interrupt of the serial channel. The autobaud detection unit provides two additional interrupts, the ABSTIR start of autobaud operation interrupt and the ABDETIR autobaud detected interrupt. The interrupt output lines TBIR, TIR, RIR, EIR, ABSTIR, and ABDETIR are activated (active state) for two periods of the module clock fASC. The cause of an error interrupt request (framing, parity, overrun error) can be identified by the error status flags FE, PE, and OE. For the two autobaud detection interrupts register ABSTAT provides status information. Note: In contrary to the error interrupt request line EIR, the error status flags FE/PE/OE are not reset automatically but must be cleared by software. For normal operation (i.e. besides the error interrupt) the ASC provides three interrupt requests to control data exchange via this serial channel: • • • TBIR is activated when data is moved from TBUF to the transmit shift register. TIR is activated before the last bit of an asynchronous frame is transmitted, or after the last bit of a synchronous frame has been transmitted. RIR is activated when the received frame is moved to RBUF. Note: While the receive task is handled by a single interrupt handler, the transmitter is serviced by two interrupt handlers. This provides advantages for the servicing software. For single transfers it is sufficient to use the transmitter interrupt (TIR), which indicates that the previously loaded data has been transmitted, except for the last bit of an asynchronous frame. For multiple back-to-back transfers it is necessary to load the following piece of data at last until the time the last bit of the previous frame has been transmitted. In Asynchronous Mode this leaves just one bit-time for the handler to respond to the transmitter interrupt request, in Synchronous Mode it is impossible at all. Using the transmit buffer interrupt (TBIR) to reload transmit data gives the time to transmit a complete frame for the service routine, as TBUF may be reloaded while the previous data is still being transmitted. The start of autobaud operation interrupt ABSTIR is generated whenever the autobaud detection unit is enabled (ABEN and ABDETEN and ABSTEN are set), and a start bit has been detected at RxD. In this case ABSTIR is generated during Autobaud Detection whenever a start bit is detected. The autobaud detected interrupt ABDETIR is always generated after recognition of the second character of the two-byte frame, this means after a successful Autobaud Detection. If FCDETEN is set the autobaud detected interrupt ABDETIR is also generated after the recognition of the first character of the two-byte frame. User’s Manual ASC_X, V2.0 19-35 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Asynchronous Mode TIR TIR Stop Stop RIR Start TBIR Start TBIR Stop Idle Start TBIR TIR RIR Idle RIR Synchronous Mode TIR TBIR TIR TBIR TIR TBIR Idle Idle RIR RIR RIR Asynchronous Modes Autobaud Detection 2. Character Stop ABDETIR Start 1. Character ABDETIR 1) Stop Idle Start ABSTIR 1) Only if FCDETEN = 1 MCT05450 Figure 19-19 ASC Interrupt Generation As shown in Figure 19-19, TBIR is an early trigger for the reload routine, while TIR indicates the completed transmission. Therefore, software using handshake should rely on TIR at the end of a data block to ensure that all data has actually been transmitted. The six interrupts of the ASC0 and of the ASC1 module are controlled by the following service request control registers: • • • • • ASC0_ABIC, ASC1_ABIC: control the autobaud interrupts ASC0_TIC, ASC1_TIC: control the transmit interrupts ASC0_RIC, ASC1_RIC: control the receive interrupts ASC0_EIC, ASC1_EIC: control the error interrupts ASC0_TBIC, ASC1_TBIC: control the transmit buffer empty interrupt Note: Please refer to the general Interrupt Control Register description for an explanation of the control fields. User’s Manual ASC_X, V2.0 19-36 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) The two autobaud interrupt request lines (start of autobaud detection and end of autobaud detection) in each ASC module are ‘ORed’ together; the ‘ORed’ output signal is connected to the interrupt control register. This is shown in Figure 19-20. ASCx Kernel start_autobaud_detect_irq end_autobaud_detect_irq _ >1 (x = 0 … 1) ASCx_ABIC MCA05451 Figure 19-20 Wiring of Autobaud Interrupts Table 19-12 summarizes all interrupt sources: Table 19-12 ASC Interrupt Sources Interrupt Signal Description TBUF Action TBIR A write action to the transmit shift register from the transmit buffer register ASCx_TBUF. If a FIFO is configured for the ASC and bit TXTMEN is cleared, TXFIFL defines when the interrupt is generated depending on the FIFO fill state. Transmit Interrupt TIR The interrupt is generated after the last (eight) data bit of a transmission frame is send via line TxD by the transmit shift register. Note: Only for Synchronous Mode Transmit Interrupt TIR The interrupt is generated just before the last bit of a transmission frame is send via line TxD by the transmit shift register. If a FIFO is configured for the ASC and bit XTMEN is cleared, TXFIFL defines when the interrupt is generated depending on the FIFO fill state. Note: Only for Asynchronous Modes Receive Interrupt RIR The interrupt is generated when the received frame is copied from the receive shift register to the receive buffer register. Note: Only for Synchronous Mode User’s Manual ASC_X, V2.0 19-37 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Table 19-12 ASC Interrupt Sources (cont’d) Interrupt Signal Description Receive Interrupt RIR The interrupt is generated when the received frame is copied from the receive shift register to the receive buffer register. If a FIFO is configured for the ASC and bit RXTMEN is cleared, RXFIFL defines when the interrupt is generated depending on the FIFO fill state. Note: Only for Asynchronous Modes Receive Error RIR and The interrupt is generated when the received frame is copied Interrupt EIR from the receive shift register to the receive buffer register and the receive buffer contains already valid data. Note: Only for Synchronous Mode Receive Overflow RIR and If an additional frame is received when the FIFO is completely EIR full an overflow error occurs. Both interrupts are generated and the previously received frame is overwritten in the FIFO and therefore lost. Read to empty FIFO EIR A read operation from the CPU to an empty receive FIFO generates this interrupt. Transparent Read Operation RIR In Transparent Mode a receive interrupt is always generated on a read operation from the CPU to the receive FIFO if the FIFO is not empty after this operation. Flush Action TBIR A transmit buffer interrupt is generated when the transmit FIFO is flushed. FIFO Enable TBIR A transmit buffer interrupt is generated when the transmit FIFO is enabled by setting bits TXTMEN and TXFEN when it was previously disabled in Transparent Mode. Transmit Overflow EIR If an additional frame is written to the transmit FIFO when it is completely full an overflow error occurred. The interrupt is generated and the previously written frame is overwritten and therefor lost in the FIFO. Frame Error RIR and An expected stop bit is not high. EIR Note: Asynchronous Mode only Parity Error RIR and When a parity bit is received that does not fit to the parity of EIR the received data. Note: Asynchronous Mode only User’s Manual ASC_X, V2.0 19-38 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.8 Registers Table 19-13 shows all registers which are required for programming the ASC modules. It summarizes the ASC kernel registers and the interrupt control registers and lists their addresses. Table 19-13 ASC Module Register Summary Name Description ASC0 Addresses 16-Bit Reg. Area 8-Bit ASC1 Addresses 16-Bit 8-Bit ASCx_CON Control Register FFB0H D8H SFR FFB8H DCH ASCx_TBUF Transmit Buffer Register FEB0H 58H SFR FEB8H 5CH ASCx_RBUF Receive Buffer Register FEB2H 59H SFR FEBAH 5DH ASCx_ABCON Autobaud Control Register F1B8H DCH ESFR F1BCH DEH ASCx_ABSTAT Autobaud Status Register F0B8H 5CH ESFR F0BCH 5EH ASCx_BG Baudrate Timer Reload Register FEB4H 5AH SFR FEBCH 5EH ASCx_FDV Fractional Divider Register FEB6H 5BH SFR FEBEH 5FH ASCx_PMW IrDA Pulse Mode and Width Register FEAAH 55H SFR FEACH 56H ASCx_RXFCON Receive FIFO Control Register F0C6H 63H ESFR F0A6H 53H ASCx_TXFCON Transmit FIFO Control Register F0C4H 62H ESFR F0A4H 52H ASCx_FSTAT FIFO Status Register F0BAH 5DH ESFR F0BEH 5FH ASCx_ABIC Autobaud Interrupt Control F15CH AEH Register ESFR F1BAH DDH ASCx_TIC Transmit Interrupt Control Register FF6CH B6H SFR/ F182H ESFR C1H ASCx_RIC Receive Interrupt Control Register FF6EH B7H SFR/ F18AH ESFR C5H ASCx_EIC Error Interrupt Control Register FF70H B8H SFR/ F192H ESFR C9H ASCx_TBIC Transmit Buffer Interrupt Control Register F19CH CEH ESFR F150H A8H User’s Manual ASC_X, V2.0 19-39 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Control Register The operating mode of the serial channel ASC is controlled by its control register CON. This register contains control bits for mode and error check selection, and status flags for error identification. ASCx_CON Control Register 13 SFR (Table 19-13) 15 14 R LB BRS ODD FDE OE FE PE OEN FEN rw rw rwh rwh rw 12 rw 11 rw 10 rwh 9 8 7 rw 6 rw Reset Value: 0000H 5 4 3 2 1 PEN/ REN STP RxDI rw rwh 0 M rw rw Field Bits Type Description R 15 rw Baudrate Generator Run Control Bit 0 Baudrate generator disabled (ASC inactive) 1 Baudrate generator enabled Note: BR_VALUE should only be written if R = 0. LB 14 rw Loopback Mode Enabled 0 Loopback Mode disabled. Standard transmit/receive Mode 1 Loopback Mode enabled BRS 13 rw Baudrate Selection 0 Baud rate timer prescaler divide-by-2 selected 1 Baud rate timer prescaler divide-by-3 selected Note: BRS is don’t care if FDE = 1 (fractional divider selected). ODD User’s Manual ASC_X, V2.0 12 rw Parity Selection 0 Even parity selected (parity bit of 1 is included in data stream on odd number of 1 and parity bit of 0 is included in data stream on even number of 1) 1 Odd parity selected (parity bit of 1 is included in data stream on even number of 1 and parity bit of 0 is included in data stream on odd number of 1) 19-40 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Field Bits Type Description FDE 11 rw Fractional Divider Enable 0 Fractional divider disabled 1 Fractional divider enabled and used as prescaler for baudrate generator (bit BRS is don’t care) OE 10 rwh Overrun Error Flag Set by hardware on an overrun/underflow error (OEN = 1). Must be cleared by software. FE 9 rwh Framing Error Flag Set by hardware on a framing error (FEN = 1). Must be cleared by software. PE 8 rwh Parity Error Flag Set by hardware on a parity error (PEN = 1). Must be cleared by software. OEN 7 rw Overrun Check Enable 0 Ignore overrun errors 1 Check overrun errors FEN 6 rw Framing Check Enable (Asynchronous Mode only) 0 Ignore framing errors 1 Check framing errors PEN / RxDI 5 rw Parity Check Enable/RxDI Invert in IrDA Mode All Asynchronous Modes without IrDA Mode (PEN): 0 Ignore parity 1 Check parity Only in IrDA Mode (RxDI): 0 RxD input is not inverted 1 RxD input is inverted REN 4 rwh Receiver Enable Bit 0 Receiver disabled 1 Receiver enabled Note: REN is cleared by hardware after reception of a byte in synchronous mode. STP User’s Manual ASC_X, V2.0 3 rw Number of Stop Bits Selection 0 One stop bit 1 Two stop bits 19-41 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Field Bits Type Description M [2:0] rw Mode Control 000 8-bit-data for synchronous operation 001 8-bit-data for asynchronous operation 010 8-bit-data IrDA Mode for asynchronous operation 011 7-bit-data and parity for asynchronous operation 100 9-bit-data for asynchronous operation 101 8-bit-data and wake up bit for asynchronous operation 110 Reserved. Do not use this combination 111 8-bit-data and parity for asynchronous operation Baudrate Register The ASC baudrate timer reload register BG contains the 13-bit reload value for the baudrate timer in Asynchronous and Synchronous Mode. ASCx_BG Baudrate Timer/Reload Reg. 15 14 13 12 11 10 SFR (Table 19-13) 9 8 7 6 Reset Value: 0000H 5 - BR_VALUE - rw 4 3 2 1 0 Field Bits Type Description BR_VALUE [12:0] rw Baudrate Timer/Reload Value Reading returns the 13-bit content of the baudrate timer; writing loads the baudrate timer/reload value. Note: BG should only be written if R = 0. User’s Manual ASC_X, V2.0 19-42 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Fractional Divider Register The ASC fractional divider register FDV contains the 9-bit divider value for the fractional divider (Asynchronous Mode only). It is also used for reference clock generation of the autobaud detection unit. ASCx_FDV Fractional Divider Register 15 14 13 12 11 10 SFR (Table 19-13) 9 8 7 6 Reset Value: 0000H 5 4 3 - FD_VALUE - rw 2 1 0 Field Bits Type Description FD_VALUE [8:0] rw Fractional Divider Register Value FD_VALUE contains the 9-bit value of the fractional divider which defines the fractional divider ratio n/512 (n = 0 … 511). With n = 0, the fractional divider is switched off (input = output frequency, fDIV = fASC, see Figure 19-14). User’s Manual ASC_X, V2.0 19-43 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) IrDA Pulse Mode/Width Register The ASC IrDA pulse mode and width register PMW contains the 8-bit IrDA pulse width value and the IrDA pulse width mode select bit. This register is only required in the IrDA operating mode. ASCx_PMW IrDA Pulse Mode/Width Reg. 15 14 13 12 11 10 SFR (Table 19-13) 9 8 7 6 Reset Value: 0000H 5 4 3 - IRP W PW_VALUE - rw rw 2 1 0 Field Bits Type Description IRPW 8 rw IrDA Pulse Width Selection 0 IrDA pulse width is 3/16 bit time 1 IrDA pulse width is defined by PW_VALUE PW_VALUE [7:0] rw IrDA Pulse Width Value PW_VALUE is the 8-bit value n, which defines the variable pulse width of an IrDA pulse. Depending on the ASC input frequency fASC, this value can be used to adjust the IrDA pulse width to value which is not equal 3/16 bit time (e.g. 1.6 ms). User’s Manual ASC_X, V2.0 19-44 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Transmitter Buffer Register The ASC transmitter buffer register TBUF contains the transmit data value in Asynchronous and Synchronous Mode. ASCx_TBUF Transmit Buffer Register 15 14 13 12 11 SFR (Table 19-13) 10 9 8 7 6 Reset Value: 0000H 5 4 3 - TD_VALUE - rw 2 1 0 Field Bits Type Description TD_VALUE [8:0] rw Transmit Data Register Value TBUF contains the data to be transmitted in asynchronous and synchronous operating mode of the ASC. Data transmission is double buffered. Therefore, a new value can be written to TBUF before the transmission of the previous value is complete. User’s Manual ASC_X, V2.0 19-45 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Receiver Buffer Register The ASC Receiver buffer register RBUF contains the transmit data value in Asynchronous and Synchronous Modes. ASCx_RBUF Receive Buffer Register 15 14 13 12 11 SFR (Table 19-13) 10 9 8 7 6 Reset Value: 0000H 5 4 3 - RD_VALUE - rw 2 1 0 Field Bits Type Description RD_VALUE [8:0] rw Receive Data Register Value RBUF contains the received data bits and, depending on the selected mode, the parity bit in asynchronous and synchronous operating mode of the ASC. In asynchronous operating mode with M = 011 (7-bit data + parity) the received parity bit is written into RD7. In asynchronous operating mode with M = 111 (8-bit data + parity) the received parity bit is written into RD8. User’s Manual ASC_X, V2.0 19-46 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Autobaud Control Register The autobaud control register ABCON of the ASC module is used to control the autobaud detection operation. It contains its general enable bit, the interrupt enable control bits, and data path control bits. ASCx_ABCON Autobaud Control Register 15 14 13 12 ESFR (Table 19-13) 11 10 9 8 7 6 - RX INV TX INV ABEM - - rw rw rw - Reset Value: 0000H 5 4 3 2 1 0 FC AB ABS AUR AB DET DET T EN EN EN EN EN rw rw rw rw rwh Field Bits Type Description RXINV 11 rw Receive Inverter Enable 0 Receive inverter disabled 1 Receive inverter enabled TXINV 10 rw Transmit Inverter Enable 0 Transmit inverter disabled 1 Transmit inverter enabled ABEM [9:8] rw Autobaud Echo Mode Enable In Echo Mode the serial data at RxD is switched to TxD output. 00 Echo Mode disabled 01 Echo Mode is enabled during Autobaud Detection 10 Echo Mode is always enabled 11 Reserved; do not use this combination FCDETEN 4 rw First Character of Two-Byte Frame Detected Enable 0 Autobaud Detection interrupt ABDETIR becomes active after the two-byte frame recognition 1 Autobaud Detection interrupt ABDETIR becomes active after detection of the first and second byte of the two-byte frame ABDETEN 3 rw Autobaud Detection Interrupt Enable 0 Autobaud Detection interrupt disabled 1 Autobaud Detection interrupt enabled User’s Manual ASC_X, V2.0 19-47 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Field Bits Type Description ABSTEN 2 rw Start of Autobaud Detection Interrupt Enable 0 Start of Autobaud Detection interrupt disabled 1 Start of Autobaud Detection interrupt enabled AUREN 1 rw Automatic Autobaud Control of CON.REN 0 CON.REN is not affected during autobaud detection 1 CON.REN is cleared (receiver disabled) when ABEN and AUREN are set together. CON.REN is set (receiver enabled) after a successful Autobaud Detection (with the stop bit detection of the second character) ABEN 0 rwh Autobaud Detection Enable 0 Autobaud detection is disabled 1 Autobaud detection is enabled Note: ABEN is reset by hardware after a successful Autobaud Detection; (with the stop bit detection of the second character). Resetting ABEN by software if it was set aborts the Autobaud Detection. User’s Manual ASC_X, V2.0 19-48 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Autobaud Status Register The autobaud status register ABSTAT of the ASC module indicates the status of the autobaud detection operation. ASCx_ABSTAT Autobaud Status Register 15 14 13 12 11 ESFR (Table 19-13) 10 9 8 7 6 Reset Value: 0000H 5 4 3 2 1 0 - DET SCC SCS FCC FCS WA DET DET DET DET IT - rwh rwh rwh rwh rwh Field Bits Type Description DETWAIT 4 rwh Autobaud Detection is Waiting 0 Either character ‘a’, ‘A’, ‘t’, or ‘T’ has been detected 1 The autobaud detection unit waits for the first ‘a’ or ‘A’ Bit is cleared when either FCSDET or FCCDET is set (‘a’ or ‘A’ detected). Bit can be also cleared by software. DETWAIT is set by hardware when ABEN is set. SCCDET 3 rwh Second Character with Capital Letter Detected 0 No capital ‘T’ character detected 1 Capital ‘T’ character detected Bit is cleared by hardware when ABEN is set and if FCSDET or FCCDET or SCSDET is set. Bit can be also cleared by software. SCSDET 2 rwh Second Character with Small Letter Detected 0 No small ‘t’ character detected 1 Small ‘t’ character detected Bit is cleared by hardware when ABEN is set and if FCSDET or FCCDET or SCCDET is set. Bit can be also cleared by software. User’s Manual ASC_X, V2.0 19-49 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Field Bits Type Description FCCDET 1 rwh First Character with Capital Letter Detected 0 No capital ‘A’ character detected 1 Capital ‘A’ character detected Bit is cleared by hardware when ABEN is set and if FCSDET or SCSDET or SCCDET is set. Bit can be also cleared by software. FCSDET 0 rwh First Character with Small Letter Detected 0 No small ‘a’ character detected 1 Small ‘a’ character detected Bit is cleared by hardware when ABEN is set and if FCCDET or SCSDET or SCCDET is set. Bit can be also cleared by software. Note: SCSDET or SCCDET are set when the second character has been recognized. ABEN is reset and ABDETIR set after SCSDET or SCCDET have been set. User’s Manual ASC_X, V2.0 19-50 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Receive FIFO Control Register ASCx_RXFCON Receive FIFO Control Reg. 15 14 13 12 11 ESFR (Table 19-13) 10 9 8 7 6 Reset Value: 0100H 5 4 3 2 1 0 - RXFITL - RX RXF RXF TM FLU EN EN - rw - rw rw rw Field Bits Type Description RXFITL [11:8] rw Receive FIFO Interrupt Trigger Level Defines a receive FIFO interrupt trigger level. A receive interrupt request (RIR) is generated after the reception of a byte when the filling level of the receive FIFO is equal to or greater than RXFITL. 0000 Reserved. Do not use this combination 0001 Interrupt trigger level is set to one 0010 Interrupt trigger level is set to two … … 0111 Interrupt trigger level is set to seven 1000 Interrupt trigger level is set to eight Note: In Transparent Mode this bitfield is don’t care. Note: Combinations defining an interrupt trigger level greater than the FIFO size should not be used. RXTMEN 2 rw Receive FIFO Transparent Mode Enable 0 Receive FIFO Transparent Mode is disabled 1 Receive FIFO Transparent Mode is enabled Note: This bit is don’t care if the receive FIFO is disabled (RXFEN = 0). User’s Manual ASC_X, V2.0 19-51 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Field Bits Type Description RXFFLU 1 rw Receive FIFO Flush 0 No operation 1 Receive FIFO is flushed Note: Setting RXFFLU clears bitfield RXFFL in register FSTAT. RXFFLU is always read as 0. RXFEN 0 rw Receive FIFO Enable 0 Receive FIFO is disabled 1 Receive FIFO is enabled Note: Resetting RXFEN automatically flushes the receive FIFO. Note: After a successful autobaud detection sequence, the RXFIFO should be flushed before data is received. User’s Manual ASC_X, V2.0 19-52 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Transmit FIFO Control Register ASCx_TXFCON Transmit FIFO Control Reg. 15 14 13 12 11 ESFR (Table 19-13) 10 9 8 7 6 Reset Value: 0100H 5 4 3 2 1 - TXFITL - TX TM EN - rw - rw 0 TXF TXF FLU EN rw rw Field Bits Type Description TXFITL [11:8] rw Transmit FIFO Interrupt Trigger Level Defines a transmit FIFO interrupt trigger level. A transmit interrupt request (TIR) is generated after the transfer of a byte when the filling level of the transmit FIFO is equal to or lower than TXFITL. 0000 Reserved. Do not use this combination 0001 Interrupt trigger level is set to one 0010 Interrupt trigger level is set to two … … 0111 Interrupt trigger level is set to seven 1000 Interrupt trigger level is set to eight Note: In Transparent Mode this bitfield is don’t care. Note: Combinations defining an interrupt trigger level greater than the FIFO size should not be used. TXTMEN 2 rw Transmit FIFO Transparent Mode Enable 0 Transmit FIFO Transparent Mode is disabled 1 Transmit FIFO Transparent Mode is enabled Note: This bit is don’t care if the receive FIFO is disabled (TXFEN = 0). User’s Manual ASC_X, V2.0 19-53 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Field Bits Type Description TXFFLU 1 rw Transmit FIFO Flush 0 No operation 1 Transmit FIFO is flushed Note: Setting TXFFLU clears bitfield TXFFL in register ASCx_FSTAT. TXFFLU is always read as 0. TXFEN 0 rw Transmit FIFO Enable 0 Transmit FIFO is disabled 1 Transmit FIFO is enabled Note: Resetting TXFEN automatically flushes the transmit FIFO. User’s Manual ASC_X, V2.0 19-54 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) FIFO Status Register ASCx_FSTAT FIFO Status Register 15 14 13 12 ESFR (Table 19-13) 11 10 9 8 7 Reset Value: 0000H 6 5 4 3 2 1 - TXFFL - RXFFL - rh - rh Field Bits Type Description TXFFL [11:8] rh Transmit FIFO Filling Level 0000 Transmit FIFO is filled with zero bytes 0001 Transmit FIFO is filled with one byte … … 0111 Transmit FIFO is filled with seven bytes 1000 Transmit FIFO is filled with eight bytes 0 Note: TXFFL is cleared after a receive FIFO flush operation. RXFFL [3:0] rh Receive FIFO Filling Level 0000 Receive FIFO is filled with zero bytes 0001 Receive FIFO is filled with one byte … … 0111 Receive FIFO is filled with seven bytes 1000 Receive FIFO is filled with eight bytes Note: RXFFL is cleared after a receive FIFO flush operation. User’s Manual ASC_X, V2.0 19-55 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) 19.9 Interfaces of the ASC Modules In the XC164 the ASC modules are connected to IO ports and other internal modules according to Figure 19-21 and Figure 19-22. The input/output lines of ASC0 and ASC1 are connected to pins of Ports P3. The 6 interrupt request lines of each module are connected to the Interrupt Control Block. Clock control and emulation control of the SSC Module is handled by the System Control Unit, SCU. System Control Unit (SCU) fASC ASC0DIS S0RxD P3.11/RxDA0 S0TIRQ S0RIRQ Interrupt Control Block ASC0 Module S0EIRQ S0TxD Port P3 Control P3.10/TxDA0 S0TBIRQ S0ABIRQ1 S0ABIRQ2 MCA05452 Figure 19-21 ASC0 Module Interfaces System Control Unit (SCU) fASC ASC1DIS S1RxD P3.1/RxDA1 S1TIRQ S1RIRQ Interrupt Control Block ASC1 Module S1EIRQ S1TxD Port P3 Control P3.0/TxDA1 S1TBIRQ S1ABIRQ1 S1ABIRQ2 MCA05453 Figure 19-22 ASC1 Module Interfaces User’s Manual ASC_X, V2.0 19-56 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Asynchronous/Synchronous Serial Interface (ASC) Note: In synchronous operating mode, the direction of the RxD pin is not automatically set by the ASC modules; it must be switched by software via the corresponding bit in register DP3, depending on the selected mode (receive or transmit data). Note: To select RxDA1 as alternate output function for P3.1, it is sufficient to set bit 1 of register ALTSEL0P3, the corresponding bit in register ALTSEL1P3 is “don’t care”. User’s Manual ASC_X, V2.0 19-57 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) 20 High-Speed Synchronous Serial Interface (SSC) The XC164 contains two High-Speed Synchronous Serial Interfaces, SSC0 and SSC1. The following sections present the general features and operations of such an SSC module. The final section describes the actual implementation of the two SSC modules including their interconnections with other on-chip modules. 20.1 Introduction The High-Speed Synchronous Serial Interface (SSC) supports both full-duplex and halfduplex serial synchronous communication up to 20 Mbit/s (@ 40 MHz module clock). The serial clock signal can be generated by the SSC itself (Master Mode) or can be received from an external master (Slave Mode). Data width, shift direction, clock polarity, and phase are programmable. This supports communication with SPI-compatible devices. Transmission and reception of data is double-buffered. A 16-bit baudrate generator provides the SSC with a separate serial clock signal. Features and Functions • • • • Master and Slave Mode operation – Full-duplex or half-duplex operation Flexible data format – Programmable number of data bits: 2 to 16 bits – Programmable shift direction: LSB or MSB shift first – Programmable clock polarity: idle low or high state for the shift clock – Programmable clock/data phase: data shift with leading or trailing edge of the shift clock Baudrate generation from 20 Mbit/s to 306.6 bit/s (@ 40 MHz module clock) Interrupt generation – On a Transmitter-Empty condition – On a Receiver-Full condition – On an Error condition (receive, phase, baudrate, transmit error) 20.2 Operational Overview The high-speed synchronous serial interface can be configured in a very flexible way, so it can be used with other synchronous serial interfaces, can serve for master/slave or multimaster interconnections or can operate compatible with the popular SPI interface. Thus, the SSC can be used to communicate with shift registers (IO expansion), peripherals (e.g. EEPROMs, etc.) or other controllers (networking). The SSC supports half-duplex and full-duplex communication. Data is transmitted on lines MTX/STX or received on lines MRX/SRX, connected with pins MTSR (Master Transmit/Slave Receive) and MRST (Master Receive/Slave Transmit). The clock signal is output via line User’s Manual SSC_X, V2.0 20-1 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) MSCLK (Master Serial Shift Clock) or input via line SSCLK (Slave Serial Shift Clock). Both lines are connected to pin SCLK. These pins are alternate functions of port pins. A block diagram of the SSC Module is shown in Figure 20-2. From the programmer’s point of view, the term ‘SSC unit’ refers to a set of registers (see Figure 20-1) which are associated with this peripheral, including the port pins which may be used for alternate input/output functions, and including their direction control bits. Interrupt Registers TB CON TIC P3 RB BR RIC DP3 EIC System Registers ALTSEL0P3 P1H DP1H ALTSEL0P1H SSC0 Control Registers SSC1 Data Registers SYSCON3 OPSEN TB / RB CON BR TIC / RIC / EIC Py DPy ALTSEL0Py SYSCON3 Transmit / Receive Buffer Register SSC Control Register Baudrate Timer / Reload Register Transmit / Receive / Error Interrupt Control Register Port Py Data Register (y = 1H, 3) Port Py Direction Control Register (y = 1H, 3) Port Py Alternate Output Select Register 0 (y = 1H, 3) SCU System Control Register 3 MCA05454 Figure 20-1 SFRs Associated with the SSC Unit User’s Manual SSC_X, V2.0 20-2 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) Baudrate Generator fSSC MSCLK Clock Control TIRQ RIRQ SSC Control Block Status EIRQ Transmit Interrupt Receive Interrupt Request Error Interrupt Request MTX Control Input/ Output Line Control 16-bit Shift Register 16-bit Shift Register to Pin SCLK SSCLK MRX STX SRX to Pin MTSR to Pin MRST 16-bit Shift Register MCB05455 Figure 20-2 Synchronous Serial Channel (SSC) Block Diagram 20.2.1 Operating Mode Selection The operating mode of the SSC module is controlled by its control register SSCx_CON. This register has a double function: • • During programming (SSC disabled by SSCx_CON.EN = 0), it provides access to a set of control bits During operation (SSC enabled by SSCx_CON.EN = 1), it provides access to a set of status flags In the following, the layout of register CON is shown for both functions. User’s Manual SSC_X, V2.0 20-3 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) SSC Control Register (SSCx_CON.EN = 0: Programming Mode) SSCx_CON SSC Control Register 15 14 13 EN =0 MS - rw rw - 12 SFR (Table 20-2) 11 10 9 8 A BEN PEN REN TEN REN rw rw rw rw rw Reset Value: 0000H 7 6 5 4 3 2 1 LB PO PH HB BM rw rw rw rw rw 0 Field Bits Type Description EN 15 rw Enable Bit = 0 Transmission and reception disabled. Access to control bits. MS 14 rw Master Select 0 Slave Mode. Operate on shift clock received via SCLK. 1 Master Mode. Generate shift clock and output it via SCLK. AREN 12 rw Automatic Reset Enable 0 No additional action upon a baudrate error 1 The SSC is automatically reset upon a baudrate error BEN 11 rw Baudrate Error Enable 0 Ignore baudrate errors 1 Check baudrate errors PEN 10 rw Phase Error Enable 0 Ignore phase errors 1 Check phase errors REN 9 rw Receive Error Enable 0 Ignore receive errors 1 Check receive errors TEN 8 rw Transmit Error Enable 0 Ignore transmit errors 1 Check transmit errors LB 7 rw Loop Back Control 0 Normal output 1 Receive input is connected with transmit output (half-duplex mode) User’s Manual SSC_X, V2.0 20-4 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) Field Bits Type Description PO 6 rw Clock Polarity Control 0 Idle clock line is low, leading clock edge is lowto-high transition. 1 Idle clock line is high, leading clock edge is high-to-low transition. PH 5 rw Clock Phase Control 0 Shift transmit data on the leading clock edge, latch on trailing edge. 1 Latch receive data on leading clock edge, shift on trailing edge. HB 4 rw Heading Control 0 Transmit/Receive LSB First 1 Transmit/Receive MSB First BM [3:0] rw Data Width Selection 0000 Reserved. Do not use this combination. 0001 Transfer Data Width is 2 bits … Transfer Data Width is (<BM> + 1) 1111 Transfer Data Width is 16 bits SSC Control Register (SSCx_CON.EN = 1: Operating Mode) SSCx_CON SSC Control Register 15 14 13 EN =1 MS - rw rw - 12 SFR (Table 20-2) Reset Value: 0000H 11 10 9 8 7 6 5 4 BSY BE PE RE TE - - - - BC rwh rwh rwh - - - - rw rh rwh 3 2 1 0 Field Bits Type Description EN 15 rw Enable Bit = 1 Transmission and reception enabled. Access to status flags and M/S control. MS 14 rw Master/Slave Selection 0 Slave Mode. Operate on shift clock received via SCLK. 1 Master Mode. Generate shift clock and output it via SCLK. User’s Manual SSC_X, V2.0 20-5 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) Field Bits Type Description BSY 12 rh Busy Flag Set while a transfer is in progress. Do not write to!!! BE 11 rwh Baudrate Error Flag 0 No error 1 More than factor 2 or 0.5 between slave’s actual and expected baudrate PE 10 rwh Phase Error Flag 0 No error 1 The received data has changed around sampling clock edge RE 9 rwh Receive Error Flag 0 No error 1 A reception was completed before the receive buffer was read TE 8 rwh Transmit Error Flag 0 No error 1 A transfer has started with the slave’s transmit buffer not being updated BC [3:0] rh Bit Count Field Shift counter is updated with every shifted bit. Do not write to!!! Note: The target of an access to SSCx_CON (control bits or flags) is determined by the state of bit EN prior to the access; that is, writing C057H to SSCx_CON in programming mode (EN = 0) will initialize the SSC (EN was 0) and then turn it on (EN = 1). When writing to SSCx_CON, ensure that reserved locations receive zeros. Transmitter Buffer Register The SSC Transmit Buffer Register SSCx_TB (see Table 20-2) contains the transmit data value. Unselected bits of SSCx_TB are ignored during transmission. The transmit value must be right-aligned regardless of MSB or LSB first operation. Receiver Buffer Register The SSC Receive Buffer Register SSCx_RB (see Table 20-2) contains the receive data value. Unselected bits of SSCx_RB will be not valid and should be ignored. The received value is always right-aligned regardless of MSB or LSB first operation. User’s Manual SSC_X, V2.0 20-6 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) The shift register of the SSC is connected to both, the transmit lines and the receive lines via the pin control logic (see block diagram in Figure 20-2). Transmission and reception of serial data are synchronized and take place at the same time, i.e. the same number of transmitted bits is also received. To prepare for a transfer, the transmit data is written into the Transmit Buffer (SSCx_TB) by software. It is moved to the shift register as soon as this is empty. An SSC master (CON.MS = 1) immediately begins transmitting, while an SSC slave (CON.MS = 0) will wait for an active shift clock. When the transfer starts, the busy flag CON.BSY is set and the Transmit Interrupt Request line TIRQ will be activated to indicate that register SSCx_TB may be reloaded again. When the programmed number of bits (2 … 16) has been transferred, the contents of the shift register are moved to the Receive Buffer SSCx_RB and the Receive Interrupt Request line RIRQ is activated. If no further transfer is to take place (SSCx_TB is empty), CON.BSY will be cleared at the same time. Software should not modify CON.BSY, as this flag is hardware controlled. Note: Only one SSC can be master at a given time in a serial system. The transfer of serial data bits can be programmed in many respects: • • • • • • The data width can be specified from 2 bits to 16 bits A transfer may start with either the LSB or the MSB The shift clock may be idle low or idle high The data bits may be shifted with the leading edge or the trailing edge of the shift clock signal The baudrate may be set from 306.6 bit/s up to 20 Mbit/s (@ 40 MHz module clock) The shift clock can be generated (MSCLK) or can be received (SSCLK) These features allow the adaptation of the SSC to a wide range of applications in which serial data transfer is required. The Data Width Selection supports the transfer of frames of any data length, from 2-bit “characters” up to 16-bit “characters”. Starting with the LSB (CON.HB = 0) enables communication with SSC devices in Synchronous Mode or with 8051-like serial interfaces, for example. Starting with the MSB (CON.HB = 1) enables operation compatible with the SPI interface. Regardless of the data width selected and whether the MSB or the LSB is transmitted first, the transfer data is always right-aligned in registers SSCx_TB and SSCx_RB, with the LSB of the transfer data in bit 0 of these registers. The data bits are rearranged for transfer by the internal shift register logic. The unselected bits of SSCx_TB are ignored; the unselected bits of SSCx_RB will not be valid and should be ignored by the receiver service routine. The Clock Control allows the adaptation of transmit and receive behavior of the SSC to a variety of serial interfaces. A specific shift clock edge (rising or falling) is used to shift out transmit data, while the other shift clock edge is used to latch in receive data. Bit PH selects the leading edge or the trailing edge for each function. Bit PO selects the level of User’s Manual SSC_X, V2.0 20-7 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) the shift clock line in the idle state. Thus, for an idle-high clock, the leading edge is a falling edge, a 1-to-0 transition (see Figure 20-3). Shift Clock SCLK CON. CON. PO PH 0 0 0 1 1 0 1 1 Pins MTSR/MRST Transmit Data First Bit Last Bit Latch Data Shift Data MCT05456 Figure 20-3 Serial Clock Phase and Polarity Options 20.2.2 Full-Duplex Operation In a Full-Duplex serial configuration, illustrated in Figure 20-4, the various devices are connected via three lines. The definition of these lines is always determined by the master: The line connected to the master’s data output line MTSR is the transmit line; the receive line is connected to its data input line MRST; the shift clock line is SCLK. Only the device selected for master operation generates and outputs the shift clock on line SCLK. All slaves receive this clock; thus, their SCLK pin must be switched to input mode. The output of the master’s shift register is connected to the external transmit line, which in turn is connected to the slaves’ shift register inputs. The outputs of the slaves’ shift register are connected to the external receive line in order to enable the master to receive the data shifted out of the slaves. The external connections are hard-wired, the function and direction of these pins is determined by the master or slave operation of the individual device. Note: The shift direction shown in Figure 20-4 applies for MSB-first operation as well as for LSB-first operation. When initializing the devices in this configuration, one device must be selected for master operation while all other devices must be programmed for slave operation. Initialization includes the operating mode of the device’s SSC and also the function of the respective port lines. User’s Manual SSC_X, V2.0 20-8 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) Master Device #1 Device #2 Shift Register Clock Slave Shift Register MTSR Transmit MTSR MRST Receive MRST SCLK Clock SCLK Symbols Clock Device #3 Slave Shift Register Input MTSR Push/Pull Output MRST Open-Drain Output SCLK Clock Tri-Stated = Input MCA05457 Figure 20-4 SSC Full-Duplex Configuration The data output pins MRST of all slave devices are connected together onto the one receive line in the configuration shown in Figure 20-4. During a transfer, each slave shifts out data from its shift register. There are two ways to avoid collisions on the receive line due to different slave data: • • Only one slave drives the line, i.e. enables the driver of its MRST pin. All the other slaves must have their MRST pins programmed as input so only one slave can put its data onto the master’s receive line. Only receiving data from the master is possible. The master selects the slave device from which it expects data either by separate select lines, or by sending a special command to this slave. The selected slave then switches its MRST line to output until it gets a de-selection signal or command. In the configuration depicted in Figure 20-4, Device #2 is the slave which has its output driver enabled as push/pull output. Device #3 is an inactive slave, it needs to disable its output driver by programming the pin to input mode. The slaves use their MRST outputs in open-drain mode. This forms a wired-AND connection. The receive line needs an external pull-up in this case. Corruption of the User’s Manual SSC_X, V2.0 20-9 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) data on the receive line sent by the selected slave is avoided when all slaves not selected for transmission to the master only send ones (1). Because this high level is not actively driven onto the line, but only held through the pull-up device, the selected slave can pull this line actively to a low level when transmitting a zero bit. The master selects the slave device from which it expects data either by separate select lines or by sending a special command to this slave. After performing the necessary initialization of the SSC, the serial interfaces can be enabled. For a master device, the clock line MSCLK will now go to its programmed polarity. The output data line MTX will go to either 0 or 1 until the first transfer will start. After a transfer, the data line MTX will always remain at the logic level of the last transmitted data bit. When the serial interfaces are enabled, the master device can initiate the first data transfer by writing the transmit data into register SSCx_TB. This value is copied into the shift register (assumed to be empty at this time), and the selected first bit of the transmit data will be placed onto the transmit line MTSR on the next clock from the baudrate generator (transmission starts only if bit EN = 1). Depending on the selected clock phase, a clock pulse will also be generated on the SCLK line. At the same time, with the opposite clock edge, the master latches and shifts in the data detected at its input line MRST. This “exchanges” the transmit data with the receive data. Because the clock line is connected to all slaves, their shift registers will be shifted synchronously with the master’s shift register, shifting out the data contained in the registers, and shifting in the data detected at the input line. After the preprogrammed number of clock pulses (via the data width selection), the data transmitted by the master is contained in all the slaves’ shift registers, while the master’s shift register holds the data of the selected slave. In the master and all slaves, the contents of the shift register are copied into the receive buffer SSCx_RB and the receive interrupt line RIRQ is activated. A slave device will immediately output the selected first bit (MSB or LSB of the transfer data) at line MRST when the contents of the transmit buffer are copied into the slave’s shift register. Bit BSY is not set until the first clock edge at SCLK appears. The slave device will not wait for the next clock from the baudrate generator, as the master does. The reason for this is that, depending on the selected clock phase, the first clock edge generated by the master may already be used to clock in the first data bit. Thus, the slave's first data bit must already be valid at this time. Note: On the SSC, a transmission and a reception takes place at the same time, regardless of whether valid data has been transmitted or received. Note: The initialization of the CLK pin on the master requires some attention in order to avoid undesired clock transitions, which may disturb the other devices. Before the clock pin is switched to output via the related direction control register, the clock output level shall be selected in the control register SSCx_CON and the alternate output be prepared via the related ALTSEL register, or the output latch must be loaded with the clock idle level. User’s Manual SSC_X, V2.0 20-10 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) 20.2.3 Half-Duplex Operation In a Half-Duplex configuration, only one data line is necessary for both, receiving and transmitting of data. The data exchange line is connected to both, the MTSR and MRST pins of each device, the shift clock line is connected to the SCLK pin. The master device controls the data transfer by generating the shift clock, while the slave devices receive it. Due to the fact that all transmit and receive pins are connected to the one data exchange line, serial data may be moved between arbitrary stations. Similar to Full-Duplex mode, there are two ways to avoid collisions on the data exchange line: • • only the transmitting device may enable its transmit pin driver the non-transmitting devices use open-drain outputs and send only ones (1s). Because the data inputs and outputs are connected together, a transmitting device will clock in its own data at the input pin (MRST for a master device, MTSR for a slave). By this method, any corruptions on the common data exchange line are detected if the received data is not equal to the transmitted data. Master Device #1 Transmit Device #2 Shift Register Clock Slave Shift Register MTSR MTSR MRST MRST SCLK Clock Symbols SCLK Clock Device #3 Slave Shift Register Input MTSR Push/Pull Output MRST Open-Drain Output SCLK Clock Tri-Stated = Input MCA05458 Figure 20-5 SSC Half-Duplex Configuration User’s Manual SSC_X, V2.0 20-11 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) 20.2.4 Continuous Transfers When the transmit interrupt request flag is set, it indicates that the transmit buffer SSCx_TB is empty and ready to be loaded with the next transmit data. If SSCx_TB has been reloaded by the time the current transmission is finished, the data is immediately transferred to the shift register and the next transmission will start without any additional delay. On the data line, there is no gap between the two successive frames. For example, two 8-bit transfers would look the same as one 16-bit transfer. This feature can be used to interface with devices that can operate with or require more than 16 data bits per transfer. It is just a matter of software, how long a total data frame length can be. This option can also be used to interface to byte-wide and word-wide devices on the same serial bus, for instance. Note: Of course, this can happen only in multiples of the selected basic data width, because it would require disabling/enabling of the SSC to reprogram the basic data width on-the-fly. 20.2.5 Baudrate Generation The serial channel SSC has its own dedicated 16-bit Baudrate Generator with 16-bit reload capability, facilitating baudrate generation independent of the timers. Figure 20-6 shows the baudrate generator of the SSC in more detail. 16-bit Reload Register fSSC 2 16-bit Counter fSCLK fSCLKmax in Master Mode ≤ fSSC / 2 fSCLKmax in Slave Mode ≤ fSSC / 4 MCA05459 Figure 20-6 SSC Baudrate Generator The Baudrate Generator is clocked with the module clock fSSC. The counter counts downwards. Access to the Baudrate Generator is performed via one register, SSCx_BR, described below. User’s Manual SSC_X, V2.0 20-12 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) Baudrate Timer/Reload Register The SSC Baudrate Timer/Reload Register SSCx_BR has a double function. While the SSC is disabled, it serves as the reload register for the baudrate timer. Writing to it loads the timer reload register with the written reload value. Reading returns the current reload value. While the SSC is enabled, this register reflects the current baudrate timer contents. Writing to this register is not allowed while the SSC is enabled. Baudrate Calculation The timer is loaded with the reload value and starts counting immediately when the SSC is enabled. The formulas below calculate either the resulting baudrate for a given reload value, or the required reload value for a given baudrate: f SSC Baudrate = -------------------------------------2 × ( <BR> + 1 ) f SSC BG = -----------------------------------–1 2 × Baudrate (20.1) <BR> represents the contents of the reload register, taken as unsigned 16-bit integer; while baudrate is equal to fSCLK as shown in Figure 20-6. The maximum baudrate that can be achieved when using a module clock of 40 MHz is 20 Mbit/s in Master Mode (with <BR> = 0000H) or 10 Mbit/s in Slave Mode (with <BR> = 0001H). Table 20-1 lists some possible baudrates together with the required reload values and the resulting bit times, assuming a module clock of 40 MHz. Table 20-1 Typical Baudrates of the SSC (fSSC = 40 MHz) Reload Value Baudrate (= fSCLK) Deviation 0000H 20 Mbit/s (only in Master Mode) 0.0% 0001H 10 Mbit/s 0.0% 0009H 2 Mbit/s 0.0% 0013H 1 Mbit/s 0.0% 001AH 750 kbit/s -1.25% 0027H 500 kbit/s 0.0% 0063H 200 kbit/s 0.0% 00C7H 100 kbit/s 0.0% FFFFH 306.6 bit/s 0.0% User’s Manual SSC_X, V2.0 20-13 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) 20.2.6 Error Detection Mechanisms The SSC is able to detect four different error conditions. Receive Error and Phase Error are detected in all modes; Transmit Error and Baudrate Error only apply to Slave Mode. When an error is detected, the respective error flag in register SSCx_CON is set and an error interrupt request will be generated by activating the EIRQ line (see Figure 20-7). The error interrupt handler may then check the error flags to determine the cause of the error interrupt. The error flags are not reset automatically but rather must be cleared by software after servicing. This allows servicing of some error conditions via interrupt, while the others may be polled by software. Note: The error interrupt handler must clear the associated (enabled) error flag(s) to prevent repeated interrupt requests. Bits in Register CON TEN Transmit Error TE REN Receive Error Error Error _ >1 Error Interrupt Request EIRQ & PE BEN Baudrate & RE PEN Phase & & BE MCA05460 Figure 20-7 SSC Error Interrupt Control A Receive Error (Master or Slave Mode) is detected when a new data frame is completely received but the previous data was not read out of the receive buffer register SSCx_RB. This condition sets the error flag RE and, when enabled via bit REN, the error interrupt request line EIRQ. The old data in the receive buffer SSCx_RB will be overwritten with the new value and is irretrievably lost. A Phase Error (Master or Slave Mode) is detected when the incoming data at pin MRST (Master Mode) or MTSR (Slave Mode), sampled with the same frequency as the module User’s Manual SSC_X, V2.0 20-14 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) clock, changes between one cycle before and two cycles after the latching edge of the shift clock signal SCLK. This condition sets the error flag PE and, when enabled via bit PEN, the error interrupt request line EIRQ. A Baudrate Error (Slave Mode) is detected when the incoming clock signal deviates from the programmed baudrate by more than 100%, i.e. it either is more than double or less than half the expected baudrate. This condition sets the error flag BE and, when enabled via bit BEN, the error interrupt request line EIRQ. Using this error detection capability requires that the slave’s baudrate generator is programmed to the same baudrate as the master device. This feature detects false, additional or missing, pulses on the clock line (within a certain frame). Note: If this error condition occurs and bit AREN = 1, an automatic reset of the SSC will be performed in case of this error. This is done to re-initialize the SSC if too few or too many clock pulses have been detected. A Transmit Error (Slave Mode) is detected when a transfer was initiated by the master (SCLK gets active), but the transmit buffer SSCx_TB of the slave was not updated since the last transfer. This condition sets the error flag TE and, when enabled via bit TEN, the error interrupt request line EIRQ. If a transfer starts while the transmit buffer is not updated, the slave will shift out the ‘old’ contents of the shift register, which usually is the data received during the last transfer. This may lead to corruption of the data on the transmit/receive line in half-duplex mode (open-drain configuration) if this slave is not selected for transmission. This mode requires that slaves not selected for transmission only shift out ones; that is, their transmit buffers must be loaded with FFFFH prior to any transfer. Note: A slave with push/pull output drivers not selected for transmission will usually have its output drivers switched off. However, in order to avoid possible conflicts or misinterpretations, it is recommended to always load the slave's transmit buffer prior to any transfer. The cause of an error interrupt request (receive, phase, baudrate, transmit error) can be identified by the error status flags in control register SSCx_CON. Note: The error status flags TE, RE, PE, and BE, are not reset automatically upon entry into the error interrupt service routine, but must be cleared by software. User’s Manual SSC_X, V2.0 20-15 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) 20.2.7 SSC Register Summary Table 20-2 Name SSC Module Register Summary Description SSC0 Addresses 16-Bit Reg. Area 8-Bit SSC1 Addresses 16-Bit 8-Bit SSCx_CON Control Register FFB2H D9H SFR FF5EH AFH SSCx_BR Baudrate Timer Reload Register F0B4H 5AH ESFR F05EH 2FH SSCx_TB Transmit Buffer Register F0B0H 58H ESFR F05AH 2DH SSCx_RB Receive Buffer Register F0B2H 59H ESFR F05CH 2EH SSCx_TIC Transmit Interrupt Control FF72H Register B9H SFR/ ESFR F1AAH D5H SSCx_RIC Receive Interrupt Control Register FF74H BAH SFR/ ESFR F1ACH D6H SSCx_EIC Error Interrupt Control Register FF76H BBH SFR/ ESFR F1AEH D7H User’s Manual SSC_X, V2.0 20-16 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) 20.2.8 Port Configuration Requirements Table 20-3 shows the required register setting to configure the IO lines of the SSC modules for master or slave mode operation. Table 20-3 SSC0/SSC1 IO Selection and Setup Module Mode SSC0 Alternate Select Register Direction and Port Output Register IO Master P3.8 / MRST0 ALTSEL0P3.P8 = 1 DP3.P8 = 0 Input P3.9 / MTSR0 ALTSEL0P3.P9 = 1 DP3.P9 = 1 and P3.P9 = 1 Output P3.13 / SCLK0 ALTSEL0P3.P13 = 1 Output DP3.P13 = 1 and P3.P13 = 1 P3.8 / MRST0 ALTSEL0P3.P8 = 1 DP3.P8 = 1 and P3.P8 = 1 Output P3.9 / MTSR0 ALTSEL0P3.P9 = 1 DP3.P9 = 0 Input P3.13 / SCLK0 ALTSEL0P3.P13 = 1 DP3.P13 = 0 Input Master P1H.1 / MRST1 ALTSEL0P1H.P1 = 1 DP1H.P1 = 0 Input P1H.2 / MTSR1 ALTSEL0P1H.P2 = 1 DP1H.P2 = 1 Output P1H.3 / SCLK1 ALTSEL0P1H.P3 = 1 DP1H.P3 = 1 Output P1H.1 / MRST1 ALTSEL0P1H.P1 = 1 DP1H.P1 = 1 Output P1H.2 / MTSR1 ALTSEL0P1H.P2 = 1 DP1H.P2 = 0 Input P1H.3 / SCLK1 ALTSEL0P1H.P3 = 1 DP1H.P3 = 0 Input Slave SSC1 Slave Port Lines Note: The direction control bits in registers DP3 or DP1H must be set or cleared by software depending on the mode of operation selected (master or slave mode). They are not controlled automatically by the SSC modules. User’s Manual SSC_X, V2.0 20-17 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) High-Speed Synchronous Serial Interface (SSC) 20.3 Interfaces of the SSC Modules In the XC164 the SSC modules are connected to IO ports and other internal modules according to Figure 20-8 and Figure 20-9. The input/output lines of SSC0 are connected to pins of Ports P3, while the input/output lines of SSC1 are connected to pins of Ports P1H. The three interrupt request lines of each module are connected to the Interrupt Control Block. Clock control and emulation control of the SSC Module is handled by the System Control Unit, SCU. System Control Unit (SCU) fSSC MTX SSC0DIS P3.8/MRST0 MRX STX SSC0_TIRQ Interrupt Control Block SSC0 Module SRX Port P3 Control P3.9/MTSR0 MSCLK SSC0_RIRQ SSCLK SSC0_EIRQ P3.13/SCLK0 MCA05461 Figure 20-8 SSC0 Module Interfaces System Control Unit (SCU) fSSC MTX SSC1DIS P1H.1/MRST1 MRX STX SSC1_TIRQ Interrupt Control Block SSC1 Module SSC1_RIRQ SSC1_EIRQ SRX Port P1H Control P1H.2/MTSR1 MSCLK SSCLK P1H.3/SCLK1 MCA05462 Figure 20-9 SSC1 Module Interfaces User’s Manual SSC_X, V2.0 20-18 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21 TwinCAN Module 21.1 Kernel Description 21.1.1 Overview The TwinCAN module contains two Full-CAN nodes operating independently or exchanging data and remote frames via a gateway function. Transmission and reception of CAN frames is handled in accordance to CAN specification V2.0 part B (active). Each of the two Full-CAN nodes can receive and transmit standard frames with 11-bit identifiers as well as extended frames with 29-bit identifiers. Both CAN nodes share the TwinCAN module’s resources in order to optimize the CAN bus traffic handling and to minimize the CPU load. The flexible combination of Full-CAN functionality and FIFO architecture reduces the efforts to fulfill the real-time requirements of complex embedded control applications. Improved CAN bus monitoring functionality as well as the increased number of message objects permit precise and comfortable CAN bus traffic handling. Depending on the application, each of the 32 message objects can be individually assigned to one of the two CAN nodes. Gateway functionality allows automatic data exchange between two separate CAN bus systems, which reduces CPU load and improves the real time behavior of the entire system. The bit timings for both CAN nodes are derived from the peripheral clock (fCAN) and are programmable up to a data rate of 1 MBaud. A pair of receive and transmit pins connect each CAN node to a bus transceiver. Features • • • • • • • CAN functionality according to CAN specification V2.0 B active. Dedicated control registers are provided for each CAN node. A data transfer rate up to 1 MBaud is supported. Flexible and powerful message transfer control and error handling capabilities are implemented. Full-CAN functionality: 32 message objects can be individually – assigned to one of the two CAN nodes, – configured as transmit or receive object, – participate in a 2, 4, 8, 16 or 32 message buffer with FIFO algorithm, – setup to handle frames with 11-bit or 29-bit identifiers, – provided with programmable acceptance mask register for filtering, – monitored via a frame counter, – configured to Remote Monitoring Mode. Up to eight individually programmable interrupt nodes can be used. CAN Analyzer Mode for bus monitoring is implemented. User’s Manual TwinCAN_X41, V2.1 21-1 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module TwinCAN Module Kernel Clock Control fCAN CAN Node A CAN Node B TxDCA RxDCA Address Decoder Port Control CAN Message Object Buffer Interrupt Control TxDCB RxDCB TwinCAN Control MCB05471 Figure 21-1 General Block Diagram of the TwinCAN Module The CAN kernel (Figure 21-2) is split into • • A global control shell, subdivided into the initialization logic, the global control and status logic and the interrupt request compressor. – The initialization logic sets up all submodules after power-on or reset. After finishing the initialization of the node control logic and its associated message objects, the respective CAN node is synchronized with the connected CAN bus. – The global control and status logic informs the CPU about pending object transmit and receive interrupts and about the recent transfer history. – The interrupt request compressor condenses the interrupt requests from 72 sources, belonging to CAN node A and B, to 8 interrupt nodes. A message buffer unit, containing the message buffers, the FIFO buffer management, the gateway control logic and a message-based interrupt request generation unit. – The message buffer unit stores up to 32 message objects of 8 bytes maximum data length. Each object has an identifier and its own set of control and status bits. After initialization, the message buffer unit can handle reception and transmission of data without CPU supervision. – The FIFO buffer management stores the incoming and outgoing messages in a circular buffer and determines the next message to be processed by the CAN controller. – The gateway control logic transfers a message from CAN node A to CAN node B or vice versa. – The interrupt request generation unit indicates message-specifically the reception or transmission of an object. User’s Manual TwinCAN_X41, V2.1 21-2 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module • Two separate CAN nodes, subdivided into a bit stream processor, a bit timing control unit, an error handling logic, an interrupt request generation unit and a node control logic: – The bit stream processor performs data, remote, error and overload frames according to the ISO-DIS 11898 standard. The serial data flow between the CAN bus line, the input/output shift register and the CRC register is controlled as well as the parallel data flow between the I/O shift register and the message buffer unit. – The bit timing control unit defines the sampling point in respect to propagation time delays and phase shift errors and performs the resynchronization. – The error handling control logic manages the receive and the transmit error counter. According the contents in both timers, the CAN controller is set into an error-active, error-passive or bus-off state. – The interrupt request generation unit signals globally the successful end of a message transmit or receive operation, all kinds of transfer problems like bit stuffing errors, format, acknowledge, CRC or bit state errors, every change of the CAN bus warning level or of the bus-off state. – The node control logic enables and disables the node specific interrupt sources, enters the CAN analyzer mode and administrates a global frame counter. To CAN Bus A To CAN Bus B Bit Stream Processor Bit Stream Processor Node A Bit Timing Control Control Logic Error Handling Interrupt Request Generation Bit Timing Control Node B Control Logic Error Handling Interrupt Request Generation Message Object Buffers Interrupt Request Generation FIFO Control Gateway Control TwinCAN Conrtol Interrupt Request Compressor Global Status and Control Logic Initialization Logic MCB05472 Figure 21-2 Detailed Block Diagram of the TwinCAN Kernel User’s Manual TwinCAN_X41, V2.1 21-3 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.2 TwinCAN Control Shell 21.1.2.1 Initialization Processing After an external hardware reset or while it is bus-off, the respective CAN controller node is logically disconnected from the associated CAN bus and does not participate in any message transfer. This is indicated by the ACR/BCR control register bit INIT = ‘1’, which is automatically set in case of a reset or while the CAN node is bus-off. Furthermore, the CAN node will be disconnected by setting bit INIT to ‘1’ via software. While INIT is active, all message transfers between the affected CAN node controller and its associated CAN bus are stopped and the bus output pin (TXDC) is held on ‘1’ level (recessive state). After an external hardware reset, all control and message object registers are reset to their associated reset values. During the bus-off-state or after a write access to register ACR/BCR with INIT = ‘1’, all respective control and message object registers hold their current values (except the error counters). Resetting bit INIT to ‘0’ without being in the bus-off-state starts the synchronization sequence (= connection to the CAN bus), which has to monitor at least one bus-idle event (11 consecutive ‘recessive’ bits) on the associated CAN bus before the node is allowed to take part in CAN traffic again. During the bus-off recovery sequence: • • • The receive and the transmit error counter within the error handling logic are reset. 128 bus-idle events (11 consecutive ‘recessive’ bits) have to be detected, before the synchronization sequence can be initiated. The monitoring of the bus idle events is immediately started by hardware after entering the bus-off state. The number of already detected bus-idle events is counted and indicated by the receive error counter. The reconnect procedure tests bit INIT by hardware after 128 bus-idle events. If INIT is still set, the affected CAN node controller waits until INIT is cleared and at least one bus-idle event is detected on the CAN bus, before the node takes part in CAN traffic again. If INIT has been already cleared, the message transfer between the affected CAN node controller and its associated CAN bus is immediately enabled. User’s Manual TwinCAN_X41, V2.1 21-4 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.2.2 Interrupt Request Compressor The CAN module is equipped with 32 × 2 message object specific interrupt request sources and 2 × 4 node control interrupt request sources. A request compressor condenses these 72 sources to 8 CAN interrupt nodes reporting the interrupt requests of the CAN module. Each request source is provided with an interrupt node pointer, selecting the interrupt node to start the associated service routine in order to increase flexibility in interrupt processing. Each of the 8 CAN interrupt nodes can trigger an independent interrupt routine with its own interrupt vector and its own priority. Request Compressor CAN Interrupt Node 0 _ >1 Interrupt Request Source k To Interrupt Controller Interrupt Node Pointer of Request Source k CAN Interrupt Node 7 _ >1 Interrupt Request Source n To Interrupt Controller Interrupt Node Pointer of Request Source n MCA05473 Figure 21-3 Interrupt Node Pointer and Interrupt Request Compressor Note: All interrupts are event-oriented. The event sets the corresponding indication flag and can generate an interrupt to the system. An interrupt event occurring while its corresponding indication flag is still set, can generate a new interrupt. User’s Manual TwinCAN_X41, V2.1 21-5 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.2.3 Global Control and Status Logic The receive interrupt pending register RXIPND contains 32 individual flags indicating a pending receive interrupt for the associated message objects. Flag RXIPNDn is set by hardware if the corresponding message object has correctly received a data or remote frame and the correlated interrupt request generation has been enabled by RXIEn = ‘10’. RXIPNDn can be cleared by software by resetting bit INTPNDn in the corresponding message object control register MSGCTRn. The transmit interrupt pending register TXIPND has a similar functionality as the RXIPND register and provides identical information about pending transmit interrupts. User’s Manual TwinCAN_X41, V2.1 21-6 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.3 CAN Node Control Logic 21.1.3.1 Overview Each node is equipped with an individual node control logic configuring the global behavior and providing status information. The configuration mode is activated when the ACR/BCR register bit CCE is set to ‘1’. This mode allows modifying the CAN bit timing parameters and the error counter registers. The CAN analyzer mode is activated when bit CALM in control register ACR/BCR is set to ‘1’. In this operation mode, data and remote frames are monitored without an active participation in any CAN transfer (CAN transmit pin is held on recessive level). Incoming remote frames are stored in a corresponding transmit message object, while arriving data frames are saved in a matching receive message object. In CAN analyzer mode, the entire configuration information of the received frame is stored in the corresponding message object and can be evaluated by the CPU concerning their identifier, XTD bit information and data length code. If the remote monitoring mode is active by RMM = ‘1’, this information is also available for received remote frames. Incoming frames are not acknowledged and no error frames are generated. Neither remote frames are answered by the corresponding data frame nor data frames can be transmitted by setting TXRQ, if CAN analyzer mode is enabled. Receive interrupts are generated (if enabled) for all correctly received frames and the respective remote pending RMTPNDn is set in case of received remote frames. The node specific interrupt configuration is also defined by the node control logic via the ACR/BCR register bits SIE, EIE and LECIE: • • • If control bit SIE is set to ‘1’, a status change interrupt occurs when the ASR/BSR register has been updated (by each successfully completed message transfer). If control bit EIE is set to ‘1’, an error interrupt is generated when a bus-off condition has been recognized or the error warning level has been exceeded or underrun. If control bit LECIE is set to ‘1’, a last error code interrupt is generated when an error code is set in bitfield LEC in the status registers ASR or BSR. The status register (ASR/BSR) provides an overview about the current state of the respective TwinCAN node: • • • • Flag TXOK is set when a message has been transmitted successfully and acknowledged by at least one other CAN node, flag RXOK indicates an error-free reception of a CAN bus message, bitfield LEC indicates the last error occurred on the CAN bus. Stuff, form, and CRC errors as well as bus arbitration errors (Bit0, Bit1) are reported, bit EWRN is set when at least one of the error counters in the error handling logic has reached the error warning limit (default value 96), User’s Manual TwinCAN_X41, V2.1 21-7 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module • bit BOFF is set when the transmit error counter exceeded the error limit of 255 and the respective CAN node controller has been logically disconnected from the associated CAN bus. The CAN frame counter can be used to check the transfer sequence of message objects or to obtain information about the time instant, a frame has been transmitted or received from the associated CAN bus. CAN frame counting is performed by a 16-bit counter, which is controlled by register AFCR/BFCR. Bitfield CFCMD defines the operation mode and the trigger event incrementing the frame counter: • • • • After correctly transmitted frames, after correctly received frames, after a foreign frame on the CAN bus (not transmitted/received by the CAN node itself), at beginning of a new bit time. The captured frame counter value is copied to the CFCVAL field of the associated MSGCTRn register at the end of the monitored frame transfer. Flag CFCOV is set on a frame counter overflow condition (FFFFH to 0000H) and an interrupt request is generated if bit CFCIE is set to ‘1’. User’s Manual TwinCAN_X41, V2.1 21-8 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.3.2 Timing Control Unit According to ISO-DIS 11898 standard, a CAN bit time is subdivided into different segments (Figure 21-4). Each segment consists of multiples of a time quantum tq. The magnitude of tq is adjusted by the bitfield BRP and by bit DIV8X, both controlling the baud rate prescaler (see bit timing register ABTR/BBTR). The baud rate prescaler is driven by the CAN module clock fCAN. 1 Bit Time TSync TSeg1 TProp TSeg2 Tb1 Tb1 Sync. Segment 1 Time Quantum (tq) Sample Point Transmit Point MCT05474 Figure 21-4 CAN Bus Bit Timing Standard The synchronization segment (TSync) allows a phase synchronization between transmitter and receiver time base. The synchronization segment length is always 1 tq. The propagation time segment (TProp) takes into account the physical propagation delay in the transmitter output driver, on the CAN bus line and in the transceiver circuit. For a working collision detect mechanism, TProp has to be two times the sum of all propagation delay quantities rounded up to a multiple of tq. The phase buffer segments 1 and 2 (Tb1, Tb2) before and after the signal sample point are used to compensate a mismatch between transmitter and receiver clock phase detected in the synchronization segment. The maximum number of time quanta allowed for resynchronization is defined by bitfield SJW in bit timing register ABTR/BBTR. The propagation time segment and the phase buffer segment 1 are combined to parameter TSeg1, which is defined by the value TSEG1 in the respective bit timing register ABTR/BBTR. A minimum of 3 time quanta is requested by the ISO standard. Parameter TSeg2, which is defined by the value of TSEG2 in the bit timing register ABTR/BBTR, covers the phase buffer segment 2. A minimum of 2 time quanta is requested by the ISO standard. According ISO standard, a CAN bit time, calculated as the sum of TSync, TSeg1 and TSeg2, must not fall below 8 time quanta. Note: The access to bit timing register ABTR/BBTR is only enabled if bit CCE in control register ACR/BCR is set to ‘1’. User’s Manual TwinCAN_X41, V2.1 21-9 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Calculation of the Bit Time tq = (BRP + 1) / fCAN, if DIV8X = ‘0’ = (BRP + 1) / 8 × fCAN, if DIV8X = ‘1’ TSync = 1 tq TSeg1 = (TSEG1 + 1) × tq (min. 3 tq) TSeg2 = (TSEG2 + 1) × tq (min. 2 tq) bit time = TSync + TSeg1 + TSeg2 (min. 8 tq) To compensate phase shifts between clocks of different CAN controllers, the CAN controller has to synchronize on any edge from the recessive to the dominant bus level. If the hard synchronization is enabled (at the start of frame), the bit time is restarted at the synchronization segment. Otherwise, the resynchronization jump width TSJW defines the maximum number of time quanta a bit time may be shortened or lengthened by one resynchronization. The value of SJW is programmed in the ABTR/BBTR registers. TSJW = (SJW + 1) × tq TSeg1 ≥ TSJW + Tprop TSeg2 ≥ TSJW The maximum relative tolerance for fCAN depends on the phase buffer segments and the resynchronization jump width. dfCAN ≤ min (Tb1, Tb2) / 2 × (13 × bit time - Tb2) AND dfCAN ≤ TSJW / 20 × bit time Calculation of the Baudrate Baudrate = fCAN / ((BRP + 1) × (1 + TSeg1 + TSeg2)) User’s Manual TwinCAN_X41, V2.1 21-10 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.3.3 Bitstream Processor Based on the objects in the message buffer, the bitstream processor generates the remote and data frames to be transmitted via the CAN bus. It controls the CRC generator and adds the checksum information to the new remote or data frame. After including the start of frame bit SOF and the end of frame field EOF, the bitstream processor starts the CAN bus arbitration procedure and continues with the frame transmission when the bus was found in idle state. While the data transmission is running, the bitstream processor monitors continuously the I/O line. If (outside the CAN bus arbitration phase or the acknowledge slot) a mismatch is detected between the voltage level on the I/O line and the logic state of the bit currently sent out by the transmit shift register, a last error interrupt request is generated and the error code is indicated by bitfield LEC in status register ASR/BSR. An incoming frame is verified by checking the associated CRC field. When an error has been detected, the last error interrupt request is generated and the associated error code is presented in status register ASR/BSR. Furthermore, an error frame is generated and transmitted on the CAN bus. After decomposing a faultless frame into identifier and data portion, the received information is transferred to the message buffer executing remote and data frame handling, interrupt generation and status processing. 21.1.3.4 Error Handling Logic The error handling logic is responsible for the fault confinement of the CAN device. Its two counters, the receive error counter and the transmit error counter (control registers AECNT, BECNT), are incremented and decremented by commands from the bit stream processor. If the bit stream processor itself detects an error while a transmit operation is running, the transmit error counter is incremented by 8. An increment of 1 is used, when the error condition was reported by an external CAN node via an error frame generation. For error analysis, the transfer direction of the disturbed message and the node, recognizing the transfer error, are indicated in the control registers AECNT, BECNT. According to the values of the error counters, the CAN controller is set into the states error-active, error-passive or bus-off. The CAN controller is in error-active state, if both error counters are below the errorpassive limit of 128. It is in error-passive state, if at least one of the error counters equals or exceeds 128. The bus-off state is activated if the transmit error counter equals or exceeds the bus-off limit of 256. This state is reported by flag BOFF in the ASR/BSR status register. The device remains in this state, until the bus-off recovery sequence is finished. Additionally, there is the bit EWRN in the ASR/BSR status register, which is set if at least one of the error counters equals or exceeds the error warning limit defined by bitfield EWRNLVL in the control registers AECNT, BECNT. Bit EWRN is reset if both error counters fall below the error warning limit again. User’s Manual TwinCAN_X41, V2.1 21-11 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.3.5 Node Interrupt Processing Each CAN node is equipped with 4 interrupt sources supporting the • • • global transmit/receive logic, CAN frame counter, error reporting system. SIE TXOK Global CAN Transmit and Receive Logic LECIE TRINP _ >1 RXOK LECINP LEC EWRN EINP _ >1 BOFF EIE CAN Frame Counter CFCINP CFCOV CFCIE MCA05475 Figure 21-5 Node Specific Interrupt Control If enabled by bit SIE = ‘1’ in the ACR/BCR register, the global transmit/receive logic generates an interrupt request, if the node status register (ASR/BSR) is updated after finishing a faultless transmission or reception of a message object. The associated interrupt node pointer is defined by bitfield TRINP in control register AGINP/BGINP. An error is reported by a last error code interrupt request, if activated by LECIE = ‘1’ in the ACR/BCR register. The corresponding interrupt node pointer is defined by bitfield LECINP in control register AGINP/BGINP. The CAN frame counter creates an interrupt request upon an overflow, when the AFCR/BFCR control register bit CFCIE is set to ‘1’. Bitfield CFCINP, located also in the AGINP/BGINP control register, selects the corresponding interrupt node pointer. The error logic monitors the number of CAN bus errors and sets or resets the error warning bit EWRN according to the value in the error counters. If bit EIE in control User’s Manual TwinCAN_X41, V2.1 21-12 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module register ACR/BCR is set to ‘1’, an interrupt request is generated on any modification of bits EWRN and BOFF. The associated interrupt node pointer is defined by bitfield EINP in control register AGINP/BGINP. 21.1.3.6 Message Interrupt Processing Each message object is equipped with 2 interrupt request sources indicating the successful end of a message transmission or reception. Correct Transfer of Message Object n TXINP TXIE TXIPND Transmit _ >1 INTPND Receive RXINP RXIE RXIPND MCA05476 Figure 21-6 Message Specific Interrupt Control The message based transfer interrupt sources are enabled, if bit TXIE or RXIE in the associated message control register MSGCTRn are set to ‘10’. The associated interrupt node pointers are defined by bitfields RXINP and TXINP in message configuration register MSGCFGn. 21.1.3.7 Interrupt Indication The AIR/BIR register provides an INTID bitfield indicating the source of the pending interrupt request with the highest internal priority (lowest message object number). The type of the monitored interrupt requests, taken into account by bitfield INTID, can be selected by registers AIMR0/AIMR4 and BIMR0/BIMR4 containing a mask bit for each interrupt source. If no interrupt request is pending, all bits of AIR/BIR are cleared. The interrupt requests INTPNDn have to be cleared by software. User’s Manual TwinCAN_X41, V2.1 21-13 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Interrupt Request Source IMR4 Mask Register IMC34 TXOK Global CAN Transmit and Receive Logic IMC33 INTID Value IMC32 _ >1 _ >1 RXOK LEC INTD = 1 EWRN _ >1 BOFF MCA05477 Figure 21-7 INTID Mask for Global Interrupt Request Sources Registers AIMR0/4 and BIMR0/4 contain a mask bit for each interrupt source (AIMR0/BIMR0 for message specific interrupt sources and AIMR4/BIMR4 for the node specific interrupt sources). If a mask bit is reset, the corresponding interrupt source is not taken into account for the generation of the INTID value. AIMR0 Mask Register IMCn Message Control Register for Object n AIR Interrupt Pending Register INTID = n + 2 INTPNDn INTID = n + 2 IMCn BIR Interrupt Pending Register BIMR0 Mask Register MCA05478 Figure 21-8 INTID Mask for Message Interrupt Request Sources User’s Manual TwinCAN_X41, V2.1 21-14 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.4 Message Handling Unit A message object is the basic information unit exchanged between the CPU and the CAN controller. 32 message objects are provided by the internal CAN memory. Each of these objects has an identifier, its own set of control and status bits and a separate data area. Each message object covers 32 bytes of internal memory subdivided into control registers and data storage as illustrated in Figure 21-9. Data Module Offset + 300H + n*20H Message Object n +00H Arbitration (Identifier) +08H Acceptance Mask +0CH Message Control +10H Message Configuration +14H FIFO/Gateway Control +18H MCA05479 Figure 21-9 Structure of a Message Object In normal operation mode, each message object is associated with one CAN node. Only in shared gateway mode, a message object can be accessed by both CAN nodes (according to the corresponding bitfield NODE). In order to be taken into account by the respective CAN node control logic, the message object must be declared valid in its associated message control register (bit MSGVAL). When a message object is initialized by the CPU, bitfield MSGVAL in message control register MSGCTRn should be reset, inhibiting a read or write access of the CAN node controller to the associated register and data buffer storage. Afterwards, the message identifier and operation mode (transmit, receive) must be defined. If a successful transmission and/or reception of a message object should be followed by the execution of an interrupt service routine, the respective bitfields TXIE and RXIE have to be set and the interrupt pending indicator (bitfield INTPND) should be reset. If the automatic response of an incoming remote frame with matching identifier is not requested, the respective transmission message object should be configured with CPUUPD = ‘10’. As soon as bitfield MSGVAL is set to ‘10’, the respective message object is operable and taken into account by the associated CAN node controller. User’s Manual TwinCAN_X41, V2.1 21-15 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.4.1 Arbitration and Acceptance Mask Register The arbitration register MSGARn is used to filter the incoming messages and to provide the outgoing messages with an identifier. The acceptance mask register MSGAMRn may be used to disable some identifier bits of an incoming message for the acceptance test. The identifier of a received message is compared (bitwise XOR) to the identifiers of all message objects stored in the internal CAN controller memory. The compare operation starts at object 0 and takes into account all objects with • • • • • a valid message flag (MSGVAL = ‘10’), a suitable NODE declaration (register MSGCFGn), a cleared DIR control bit (receive message object) for data frame reception, DIR = ‘1’ (transmit message object) for remote frame reception, a matching identifier length declaration (XTD = ‘1’ marks extended 29-bit identifiers, XTD = ‘0’ indicates standard 11 bit identifiers). The result of the compare operation is bit-by-bit ANDED with the contents of the acceptance mask register (Figure 21-10). If concordance is detected, the received message is stored into the CAN controller’s message object. The compare operation is finished after analyzing message object 31. Note: Depending on the allocated identifiers and the corresponding mask register contents, multiple message objects may fulfill the selection criteria described above. In this case, the received frame is stored in the fitting message object with the lowest message number. Identifier of Received Frame Bitwise XOR =1 Identifier of Message Object n ‘0’ = Bit Match ‘1’ = No Match & Acceptance Mask of Message Object n Bitwise AND Result = 0: ID of the received frame fits to message object n Result > 0: ID of the received frame does not fit to message object n MCA05480 Figure 21-10 Acceptance Filtering for Received Message Identifiers User’s Manual TwinCAN_X41, V2.1 21-16 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.4.2 Handling of Remote and Data Frames Message objects can be set up for transmit or receive operation according to the selected value for control bit DIR. The impact of the message object type on the associated CAN node controller concerning the generation or reception of remote and data frames is illustrated in Table 21-1. Table 21-1 Handling of Remote and Data Frames A transmission request (TXRQ = ‘10’) for this message object generates … If a data frame with If a remote frame matching identifier with matching identifier is is received … received … Receive Object (receives data frames, transmits remote frames, control bit DIR = ‘0’) … a remote frame. … the data frame is … the remote frame is NOT taken into The requested data stored in this account. message object. frame is stored in this message object on reception. Transmit Object (transmits data frames, receives remote frames, control bit DIR = ‘1’) … the data frame is … a data frame NOT stored. based upon the information stored in this message object. User’s Manual TwinCAN_X41, V2.1 21-17 … the remote frame is stored in this message object and RMTPND and TXRQ are set to ‘10’. A data frame, based upon the information stored in this message object, is automatically generated if CPUUPD is set to ‘01’. V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.4.3 Handling of Transmit Message Objects A message object with direction flag DIR = ‘1’ (message configuration register MSGCFGn) is handled as transmit object. All message objects with bitfield MSGVAL = ‘10’ are operable and taken into account by the CAN node controller operation described below. During the initialization phase, the transmit request bitfield (TXRQ), the new information bitfield (NEWDAT) should be reset to ‘01’ and the update in progress by CPU bitfield (CPUUPD) in register MSGCTRn should be reset to ‘10’. The message bytes to be transmitted are written into the data partition of the message object (MSGDRn0, MSGDRn4). The number of message bytes to be transmitted has to be written to bitfield DLC in register MSGCFGn. The selected identifier has to be written to register MSGARn. Then, bitfield NEWDAT in register MSGCTRn should be set to ‘10’ and bitfield CPUUPD should be reset to ‘01’ by the CPU. When the remote monitoring mode is enabled (RMM = ‘1’ in MSGCFGn), the identifier and the data length code of a received remote frame will be copied to the corresponding transmit message object, if a matching identifier was found during the compare and mask operation with all CAN message objects. The copy procedure may change the identifier in the transmit message object, if some MSGAMRn mask register bits have been set to ‘0’. As long as bitfield MSGVAL in register MSGCTRn is set to ‘10’, the reception of a remote frame with matching identifier automatically sets bitfield TXRQ to ‘10’. Simultaneously, bitfield RMTPND in register MSGCTRn is set to ‘10’ in order to indicate the reception of an accepted remote frame. Alternatively, TXRQ may be set by the CPU via a write access to register MSGCTRn. If the transmit request bitfield TXRQ is found at ‘10’ (while MSGVAL = ‘10’ and CPUUPD = ‘01’) by the appropriate CAN controller node, a data frame based upon the information stored in the respective transmit message object is generated and automatically transferred when the associated CAN bus is idle. If bitfield CPUUPD in register MSGCTRn is set to ‘10’, the automatic transmission of a message object is prohibited and flag TXRQ is not evaluated by the respective CAN node controller. The CPU can release the pending transmission by clearing CPUUPD. This allows the user to listen on the bus and to answer remote frames under software control. When the data partition of a transmit message object has to be updated by the CPU, bitfield CPUUPD in message control register MSGCTRn should be set to ‘10’, inhibiting a read or write access of the associated CAN node controller. If a remote frame with an accepted identifier arrives during the update of a message object’s data storage, bitfields TXRQ and RMTPND are automatically set to ‘10’ and the transmission of the corresponding data frame is pending until CPUUPD is reset again. User’s Manual TwinCAN_X41, V2.1 21-18 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module If several valid message objects with pending transmission request are noticed by the associated CAN node controller, the contents of the message object with the lowest message number is transmitted first. Bitfield NEWDAT is internally reset by the respective CAN node controller when the contents of the selected message object’s data registers is copied to the bitstream processor. Bitfields RMTPND and TXRQ are automatically reset when the message object has been successfully transmitted. The captured value of the frame counter is copied to bitfield CFCVAL in register MSGCTRn and a transmit interrupt request is generated (INTPNDn and TXIPNDn are set) if enabled by TXIE = ‘10’. Then the Frame Counter is incremented by one if enabled in control register AFCR/BFCR. When a data frame with matching identifier is received, it is ignored by the respective transmit object and not indicated by any interrupt request. User’s Manual TwinCAN_X41, V2.1 21-19 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module yes no Bus Free ? no Matching Remote Frame Received ? TXRQ = ‘10’ CPUUPD = ‘01’ yes no yes NEWDAT := ‘01’ Copy Message to Bitstream Processor TXRQ := ‘10’ RMTPND := ‘10’ Send Message no RXIE := ‘10’ no Transmission Successful ? yes INTPND := ‘10’ yes NEWDAT = ‘10’ no TXRQ := ‘01’ RMTPND := ‘01’ yes no TXIE = ‘10’ yes INTPND := ‘10’ ‘01’ : Reset ‘10’ : Set MCA05481 Figure 21-11 Handling of Message Objects with Direction = ‘1’ = Transmit by the CAN Controller Node Hardware User’s Manual TwinCAN_X41, V2.1 21-20 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.4.4 Handling of Receive Message Objects A message object with direction flag DIR = ‘0’ (message configuration register MSGCFGn) is handled as receive object. In the initialization phase, the transmit request bitfield (TXRQ), the message lost bitfield (MSGLST) and the NEWDAT bitfield in register MSGCTR should be reset. All message objects with bitfield MSGVAL = ‘10’ are operable and taken into account by the CAN node controller operation described below. When a data frame has been received, the new information is stored in the data partition of the message object (MSGDRn0, MSGDRn4) and the bitfield DLC in register MSGCFG is updated with the number of received bytes. Unused message bytes will be overwritten by non-specified values. If the NEWDAT bitfield in register MSGCTR is still set, the CAN controller assumes an overwrite of the previously stored message and signals a data loss by setting bitfield MSGLST. In any case, bitfield NEWDAT is automatically set to ‘10’ reporting an update of the data register by the CAN controller. The captured value of the frame counter is copied to bitfield CFCVAL in register MSGCTRn and a receive interrupt request is generated (INTPNDn and RXIPNDn are set) if enabled by RXIE = ‘10’. Then the frame counter is incremented by one if enabled in control register AFCR/BFCR. When a receive object is marked to be transmitted (TXRQ = ‘10’), bit MSGLST changes automatically to CPUUPD. If CPUUPD is reset to ‘01’, the CAN controller generates a remote frame which is emitted to the other communication partners via CAN bus. In case of CPUUPD = ‘10’, the remote frame transfer is prohibited until the CPU releases the pending transmission by resetting CPUUPD to ‘01’. RMTPND and TXRQ are automatically reset, when the remote frame has been successfully transmitted. Finally, a transmit interrupt request is generated if enabled by TXIE = ‘10’. When a remote frame with matching identifier is received, it is not answered and not indicated by an interrupt request. User’s Manual TwinCAN_X41, V2.1 21-21 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module yes no no Bus Idle ? Matching Data Frame Received ? TXRQ = ‘10’ CPUUPD = ‘01’ yes no yes NEWDAT := ‘01’ yes Load Identifier and Control Bits into Bitstream Processor Send Remote Frame no NEWDAT = ‘10’ no MSGLST := ‘10’ Transmission Successful ? yes TXRQ := ‘01’ RMTPND := ‘01’ Store Message NEWDAT := ‘10’ TXRQ := ‘01’ RMTPND := ‘01’ TXIE = ‘10’ RXIE := ‘10’ no yes no yes INTPND := ‘10’ INTPND := ‘10’ ‘01’ : Reset ‘10’ : Set MCA05482 Figure 21-12 Handling of Message Objects with Direction = ‘0’ = Receive by the CAN Controller Node Hardware User’s Manual TwinCAN_X41, V2.1 21-22 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.4.5 Single Data Transfer Mode The single data transfer mode is a useful feature in order to broadcast data over the CAN bus without unintended doubling of information. The single data transfer mode is selected via bit SDT in the FIFO/Gateway control register MSGFGCRn. Each received data frame with matching identifier is automatically stored in the corresponding receive message object if MSGVAL is set to ‘10’. When data frames addressing the same message object are received within a short time interval, information might get lost (indicated by MSGLST = ‘10’), if the CPU has not processed the former message object contents in time. Each arriving remote frame with matching identifier is answered by a data frame based on the contents of the corresponding message object. This behavior may lead to multiple generation and transmission of identical data frames according to the number of accepted remote requests. If SDT is set to ‘1’, the CAN node controller automatically resets bit MSGVAL in a message object after receiving a data frame with corresponding identifier. All following data frames, addressing the disabled message object, are ignored until MSGVAL is set again by the CPU. If SDT is set to ‘1’, the CAN node controller automatically resets bit MSGVAL in the addressed message object, when the transmission of the corresponding data frame has been finished successfully. In consequence, all following remote requests concerning the disabled message object are ignored until MSGVAL is set again by the CPU. This feature allows for transmitting data in a consecutive manner without unintended doubling of any information. If SDT is cleared, control bitfield MSGVAL is not reset by the CAN node controller. User’s Manual TwinCAN_X41, V2.1 21-23 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.5 CAN Message Object Buffer (FIFO) In case of a high CPU load, it may be difficult to process an incoming data frame before the corresponding message object is overwritten with the next input data stream provided by the CAN node controller. Depending on the application, it could be also necessary to ensure a minimum data frame generation rate to fulfill external real time requirements. Therefore, a message buffer facility has been implemented in order to avoid a loss of incoming messages and to minimize the setup time for outgoing messages. Some message objects can be configured as a base object using succeeding slave message objects as individual buffer storage (building a circular buffer used as message FIFO). FIFO Object n + 7 FIFO Object n + 6 FIFO Object n + 5 To / From CAN Bus FIFO Object n + 4 Protocol Layer FIFO Object n + 3 FIFO Object n + 2 FIFO Object n + 1 Message Transferred FIFO Object n (base) Select Object Control Status FIFO Control Unit MCA05483 Figure 21-13 FIFO Buffer Control Structure The number of base and slave message objects, combined to a buffer, has to be a power of two (2, 4, 8 etc.) and the buffer base address has to be an integer multiple of the buffer length (e.g. a buffer containing 8 messages can use object 0, 8, 16 or 24 as base object as illustrated in Table 21-2). A base object is defined by setting bitfield MMC to ‘010’ in control register MSGFGCRn and the requested buffer size is determined by selecting an appropriate value for FSIZE. A slave object is defined by setting bitfield MMC to ‘011’. Bitfield FSIZE has to be equal in all FIFO elements in the same FIFO. User’s Manual TwinCAN_X41, V2.1 21-24 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Table 21-2 Message Objects Providing FIFO Base Functionality Msg. Object n > FIFO Size 0 2 4 6 8 10 12 14 16 18 … 30 2 stage FIFO X X X X X X X X X X X 4 stage FIFO X – X – X – X – X – – 8 stage FIFO X – – – X – – – X – – 16 stage FIFO X – – – – – – – X – – 32 stage FIFO X – – – – – – – – – – The identifiers and corresponding acceptance masks have to be identical in all FIFO elements belonging to the same buffer in case of a receive FIFO (DIR = ‘0’). In case of a transmit FIFO (DIR = ‘1’) the identifier of the currently addressed message object is taken into account for transmission. Each member of a buffer configuration keeps its individual MSGVAL, NEWDAT, CPUUPD or MSGLST, TXRQ and RMTPND flag and its separate interrupt control configuration. Inside a FIFO buffer, all elements must be • • • • • • assigned to the same CAN node (control bit NODE in register MSGCFGn), programmed for the same transfer direction (control bit DIR), set up to the same identifier length (control bit XTD), programmed to the same FIFO length (bitfield FSIZEn) and set up with the same value for the FIFO direction (bit FD in register MSGFGCRn). The slave’s CANPTR has to point to the FIFO base object. The base object’s CANPTR has to be initialized with the message number of the base object, the CANPTR pointers of the slave objects have to be set up with the message number of the base object. The CANPTR of the base object addresses the next FIFO element to be accessed for information transfer and its value can be calculated according the following rule: CANPTRn(new) := CANPTRn(old) & ∼FSIZEn | (CANPTRn(old) + 1) & FSIZEn Control bit FD defines which transfer action (reception or transmission) leads to an update of the CANPTR bitfield. Bit FD works independently from the direction bit DIR of the FIFO elements. The reception of a data frame (DIR = ‘0’) or the reception of a remote frame (DIR = ‘1’) are receive actions leading to an update of CANPTR if FD = ‘0’. The transmission of a data frame (DIR = ‘1’) or the transmission of a remote frame (DIR = ‘0’) are transmit actions initiating an increment of CANPTR if FD = ‘1’. Note: The overall message object storage size is not affected by the configuration of buffer structures. The available storage size may be used for 32 message objects without buffering or for one message object with a buffer depth of 32 elements. Additionally, any combination of buffered and unbuffered message objects User’s Manual TwinCAN_X41, V2.1 21-25 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module according to the FIFO rules is allowed as long as the limit of 32 message objects is not exceeded. 21.1.5.1 Buffer Access by the CAN Controller The data transfer between the message buffer and the CAN bus is managed by the associated CAN controller. Each buffer is controlled by a FIFO algorithm (First In, First Out = First Overwritten) storing messages, delivered by the CAN controller, in a circular order. CAN Pointer = base + 1 CAN Pointer = base + 2 (slave) (slave) Element 1 CAN Pointer = base + 0 Element 2 Element 0 Element 3 (base) (slave) (slave) (slave) Element 7 CAN Pointer = base + 7 CAN Pointer = base + 3 Element 4 Element 6 CAN Pointer = base + 4 Element 5 (slave) (slave) CAN Pointer = base + 6 CAN Pointer = base + 5 MCA05484 Figure 21-14 Structure of a FIFO Buffer with one Base Object and Seven Slave Objects If the FIFO buffer was initialized with receive objects, the first accepted message is stored in the base message object (number n), the second message is written to buffer element (n+1) and so on. The number of the element, used to store the next input message, is indicated by bitfield CANPTR in control register MSGFGCRn of the base object. If the reserved buffer space has been used up, the base message object (followed by the consecutive slave objects) is addressed again to store the next incoming message. When a message object was not read out on time by the CPU, the previous User’s Manual TwinCAN_X41, V2.1 21-26 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module message data is overwritten, which is indicated by flag MSGLST in the corresponding MSGCTR register. If the FIFO buffer was initialized with transmit message objects, the CAN controller starts the transfer with the contents of buffer element 0 (FIFO base object) and increments bitfield CANPTR in control register MSGFGCRn, pointing to the next element to be transmitted. If the message object, which is currently addressed by the base object’s CANPTR, is not valid (MSGVAL = ‘01’), the FIFO is not enabled for data transfer. In this case, the MSGVAL bitfields of the other FIFO elements (including the base element if not currently addressed) are not taken into account. In the case that the MSGVAL bitfields are set to ‘10’ for the FIFO base object and ‘01’ for the currently addressed FIFO slave object, the data will not be delivered to the slave object, whereas the bitfield CANPTR in the FIFO base object is incremented according to FIFO rules. If the FIFO is set up for the transmission of data frames and a matching remote frame is detected for one of the elements of the FIFO, the transmit request and remote pending bits will be set automatically in the corresponding message object. The transmission of the requested data frame is handled according to the FIFO rules and the value of the CANPTR bitfield in the FIFO base object. 21.1.5.2 Buffer Access by the CPU The message transfer between a buffer and the CPU has to be managed by software. All message objects, combined to a buffer, can be accessed directly by the CPU. Bitfield CANPTR in control register MSGFGCRn is not automatically modified by a CPU access to the message object registers. User’s Manual TwinCAN_X41, V2.1 21-27 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.6 Gateway Message Handling The CAN module supports an automatic information transfer between two independent CAN bus systems without CPU interaction. CAN Bus A CAN Bus B CAN Node A CAN Node B Gateway CAN Message Object Memory Bus Interface CPU MCA05485 Figure 21-15 TwinCAN Gateway Functionality The gateway functionality is handled via the CAN message object memory shared by both CAN nodes. Each object stored in the message memory is associated to node A or to node B via bit NODE in the message configuration register MSGCFGn. The information exchange between both CAN nodes can be handled by coupling two message objects (normal gateway mode) or by sharing one common message object (shared gateway mode). In the following paragraphs, the gateway side receiving data frames is named “source” (indicated by <s>) and the side transmitting the data frames, which passed the gateway, is called “destination” (indicated by <d>). In concordance to this notation, remote frames passing the gateway are received on the destination side and transmitted on the source side. The gateway function of a message object and the requested information transfer mode are defined by bitfield MMC in the FIFO/Gateway control register MSGFGCRn. User’s Manual TwinCAN_X41, V2.1 21-28 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module To FIFO Object n Message 1 To FIFO Object n + 1 Message 2 To FIFO Object n + 2 Message 3 To FIFO Object n + 3 Source Bus Speed A Message 4 Node A TwinCAN Node B Destination Bus Speed B Message 1 Message 2 To FIFO Object n Message 3 To FIFO Object n + 1 Message 4 To FIFO Object n + 2 To FIFO Object n + 3 MCA05486 Figure 21-16 Message Burst in Case of FIFO/Gateway 21.1.6.1 Normal Gateway Mode The normal gateway mode consumes two message objects to transfer a message from the source to the destination node. In this mode, different identifiers can be used for the same message data. Details of the message transfer through the normal gateway are controlled by the respective MSGFGCR<s> and MSGFGCR<d> registers. All 8 data bytes from the source object (even if not all bytes are valid) are copied to the destination object. The object receiving the information from the source node has to be configured as receive message object (DIR = 0) and must be associated to the source CAN bus via bit NODE. Register MSGFGCR<s> should be initialized according the following enumeration: • • • Bitfield MMC<s> has to be set to ‘100’ indicating a normal mode gateway for incoming (data) frames. Bitfield CANPTR<s> must be initialized with the number of the message object used as destination for the data copy process. If no FIFO functionality is required on the destination side, bitfield FSIZE<s> has to be filled with ‘00000’. When FIFO capabilities are needed, bitfield FSIZE<s> must contain the FIFO buffer length, which has to be identical with the content of the FIFO base object’s FSIZE bitfield on the destination side. User’s Manual TwinCAN_X41, V2.1 21-29 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module • • • When bit IDC<s> is set, the identifier of the source message object is copied to the destination message object. Otherwise, the identifier of the destination message object is not modified. If DLCC<s> is set, the data length code of the source message is copied to the destination object. Bit GDFS<s> decides, whether the transmit request flag on the destination side is set (TXRQ<d> = ‘10’ if GDFS<s> = ‘1’) after finishing the data copy process. An automatic transmission of the copied data frame on the destination side takes place, if control bit CPUUPD<d> is reset to ‘01’. The destination message object, addressed by CANPTR<s>, has to be configured for transmit operation (DIR = 1). Depending on the required functionality, the destination message object can be set up in three different operating modes: • • • • With MMC<d> = ‘000’, the destination message object is declared as standard message object. In this case, data frames, received on the source side, can be automatically emitted on the destination side if enabled by the respective control bits CPUUPD<d> and GDFS<s>. Remote frames, received on the destination side, are not transferred to the source side, but can be directly answered by the destination message object if CPUUPD<d> is reset to ‘01’. With MMC<d> = ‘100’, the destination message object is declared as normal mode gateway for incoming (remote) frames. Data frames, received on the source side, can be automatically emitted on the destination side if enabled (CPUUPD<d>, GDFS<s>) and remote frames, received on the destination side, are transmitted on the source side if enabled by SRREN<d> = ‘1’. With MMC<d> = ‘01x’, the destination message object is set up as an element of a FIFO buffering the data frames transferred from the source side through the gateway. Remote frames, received on the destination side, are not transferred to the source side, but can be directly answered by the currently addressed FIFO element if CPUUPD<d> is reset (bits SRREN<d> have to be cleared). Remote frame handling is completely done on the destination side according to FIFO rules. User’s Manual TwinCAN_X41, V2.1 21-30 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module MMC<d> = ‘000’: The operation with a standard message object on the destination side is illustrated in Figure 21-17. Source CAN Bus Destination CAN Bus Gateway Gateway Source Gateway Destination Pointer to Destination Message Object Node = <s> Node = <d> MMC = ‘100’ MMC = ‘000’ CANPTR = <d> CANPTR = <d> FSIZE = ‘00000’ FSIZE = ‘00000’ DIR = ‘0’ TXRQ = ‘01’ RMTPND = ‘01’ NEWDAT = ‘10’ INTPND Data Frame DATA Copy if IDC<s> = ‘1’ ID DLC DIR = ‘1’ Copy DATA ID Copy if DLCC<s> = ‘1’ Reset Set if GDFS<s> = ‘1’ Reset Unchanged Set Set Set if RXIE<s> = ‘1’ Pointer to Destination Message Object Set if RXIE<d> = ‘1’ Copy Data Frame DLC TXRQ RMTPND NEWDAT = ‘10’ INTPND Data Frame (GDFS<s> = ‘1’) MCA05487 Figure 21-17 Data Frame Reception in Normal Gateway Mode with a Standard Destination Message Object (MMC<d> = ‘000’) A matching data frame, arrived at the source node, is automatically copied to the destination node’s message object addressed by CANPTR<s>. Bitfield CANPTR<d> is loaded with the destination message object number. Regardless of control bit SRREN<d>, remote frames, received on the destination node, are not transferred to the source side, but can be directly answered by the destination message object. For this purpose, control bitfields TXRQ<d> and RMTPND<d> are set to ‘10’, which immediately initiates a data frame transmission on the destination CAN bus if CPUUPD<d> is reset to ‘01’. User’s Manual TwinCAN_X41, V2.1 21-31 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module MMC<d> = ‘100’: The operation with a normal mode gateway message object for incoming (remote) frames on the destination side is illustrated in Figure 21-18. Source CAN Bus Destination CAN Bus Gateway Gateway Source Pointer to Source Message Object Gateway Destination Pointer to Destination Message Object Node = <s> Node = <d> MMC = ‘100’ MMC = ‘100’ CANPTR = <d> CANPTR = <s> FSIZE = ‘00000’ FSIZE = ‘00000’ DIR = ‘0’ DIR = ‘1’ DATA ID DLC TXRQ RMTPND NEWDAT INTPND Remote Frame DATA Copy if IDC<d> = ‘1’ Copy if DLCC<d> = ‘1’ Set if SRREN<d> = ‘1’ Set if SRREN<d> = ‘0’ Set if SRREN<d> = ‘1’ Set if SRREN<d> = ‘0’ Unchanged Unchanged Set if RXIE<s> = ‘1’ Set if RXIE<d> = ‘1’ Remote Request ID DLC TXRQ Updated if RMM<d> = ‘1’ Updated if RMM<d> = ‘1’ RMTPND NEWDAT INTPND Remote Frame (SRREN<d> = ‘1’) Data Frame (SRREN<d> = ‘0’) MCA05488 Figure 21-18 Remote Frame Transfer in Normal Gateway Mode, MMC<d> = ‘100’ The gateway object on the destination side, setup as transmit object, can receive remote frames. If bit SRREN<d> in the associated gateway control register MSGFGCRn is cleared, a remote frame with matching identifier is directly answered by the CAN destination node controller. For this purpose, control bits TXRQ<d> and RMTPND<d> are set to ‘10’, which immediately initiates a data frame transmission on the destination CAN bus if CPUUPD<d> is reset. When bit SRREN<d> is set to ‘1’, a remote frame received on the destination side is transferred via the gateway and transmitted again by the CAN source node controller. A transmit request for the gateway message object on the source side, initiated by the CPU via setting TXRQ<s>, generates always a remote frame on the source CAN bus system. User’s Manual TwinCAN_X41, V2.1 21-32 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.6.2 Normal Gateway with FIFO Buffering MMC<d> = ‘01x’: When the gateway destination object is programmed as FIFO buffer, bitfield CANPTR<s> is used as pointer to the FIFO element to be addressed as destination for the next copy process. CANPTR<s> has to be initialized with the message object number of the FIFO base element on the destination side. CANPTR<s> is automatically updated according to the FIFO rules, when a data frame was copied to the indicated FIFO element on the destination side. Bit GDFS<s> determines if the TXRQ<d> bit in the selected FIFO element is set after reception of a data frame copied from the source side. The base message object is indicated by <ba>, the slave message objects by <sl>. The number of base and slave message objects, combined to a buffer on the destination side, has to be a power of two (2, 4, 8 etc.) and the buffer base address has to be an integer multiple of the buffer length. Bitfield CANPTR<ba> of the FIFO base element and bitfield CANPTR<s> have to be initialized with the same start value (message object number of the FIFO base element). CANPTR<sl> of all FIFO slave elements must be initialized with the message object number of the FIFO base element. Bitfield FSIZE<d> of all FIFO elements must contain the FIFO buffer length and has to be identical with the content of FSIZE<s>. Figure 21-19 illustrates the operation of a normal gateway with a FIFO buffer on the destination side. User’s Manual TwinCAN_X41, V2.1 21-33 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Source CAN Bus Destination CAN Bus Gateway Gateway Source Gateway Destination Node = <d> MMC<sl> = ‘011’ CANPTR<sl> Node = <s> Node = <d> MMC = ‘100’ MMC<ba> = ‘010’ CANPTR = <d> FSIZE = ‘00001’ Pointer to next addressed Destination Message Object DIR = ‘0’ DATA ID DLC TXRQ = ‘10’ RMTPND = ‘01’ NEWDAT = ‘01’ INTPND Remote Frame Pointer to Base Object CANPTR<ba> FSIZE = ‘00001’ DIR = ‘1’ Copy by SW if Required Copy by SW if Required Set by SW Reset by SW Reset by SW Reset by SW Reset by SW Unchanged Unchanged Set if RXIE<d> = ‘1’ Copy Remote Request by SW DATA ID DLC TXRQ = ‘01’ RMTPND = ‘01’ NEWDAT INTPND FIFO Remote Frame (CPUUPD<d> = ‘10’) Data Frame (CPUUPD<d> = ‘01’) MCA05489 Figure 21-19 Data Frame Transfer in Normal Gateway Mode with a 2 Stage FIFO on the Destination Side (MMC<d> = ‘01x’) Remote frames, received on the destination side by a FIFO element, cannot be automatically passed to the source side. Therefore, the SRREN<d> control bits, associated to the FIFO elements on the destination side, have to be cleared in order to answer incoming remote frames with matching identifiers directly with a data frame. Buffered transfers of remote requests from the destination to the source side can be handled by a software routine operating on the FIFO buffered gateway configuration for data frame transfers. The elements of the FIFO buffer on the destination side should be configured as transmit message objects with CPUUPD<d> = ‘10’. An arriving remote User’s Manual TwinCAN_X41, V2.1 21-34 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module frame with matching identifier should initiate an interrupt service request for the addressed FIFO message object. The associated interrupt service routine may copy the message identifier and the data length code from the received remote frame to a receive message object linked with the source side CAN node. In any case, TXRQ of the selected receive message object must be set to ‘10’ initiating the transmission of a remote frame on the source side. Source CAN Bus Destination CAN Bus Gateway Gateway Source Gateway Destination Node = <d> MMC<sl> = ‘011’ CANPTR<sl> Node = <s> Node = <d> MMC = ‘100’ MMC<ba> = ‘010’ CANPTR = <d> DIR = ‘0’ RMTPND = ‘01’ NEWDAT = ‘10’ INTPND Data Frame DIR = ‘1’ DATA Copy if IDC<s> = ‘1’ ID TXRQ = ‘01’ FSIZE = ‘00001’ Copy DATA DLC CANPTR<ba> Pointer to next addressed Destination Message Object FSIZE = ‘00001’ ID Copy if DLCC<s> = ‘1’ Reset Set if GDFS<s> = ‘0’ Reset Unchanged Set Set Set if RXIE<s> = ‘1’ Pointer to Base Object Set if RXIE<d> = ‘1’ Copy Data Frame DLC TXRQ RMTPND NEWDAT = ‘10’ INTPND FIFO Data Frame (GDFS<s> = ‘1’) MCA05490 Figure 21-20 Remote Frame Transfer in Normal Gateway Mode with a 2-stage FIFO on the Destination Side User’s Manual TwinCAN_X41, V2.1 21-35 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.6.3 Shared Gateway Mode In shared gateway mode, only one message object is required to implement a gateway functionality. The shared gateway object can be considered as normal message object, which is toggled between the source and destination CAN node as illustrated in Figure 21-21. Source CAN Bus Destination CAN Bus Source Node Destination Node Shared Gateway Control Logic Node = <s, d> MMC = ‘101’ CANPTR = ‘n’ Pointer to Message Object FSIZE = ‘00000’ DIR = ‘0’, ‘1’ DATA ID DLC TXRQ RMTPND NEWDAT INTPND MCA05491 Figure 21-21 Principle of the Shared Gateway Mode Each message object can be used as shared gateway by setting MMC in the corresponding MSGFGCRn register to ‘101’. When the message configuration bit NODE is cleared, CAN node A is used as source, transferring data frames to destination node B. If NODE is set to ‘1’, CAN node B operates as data source. A bidirectional gateway is achieved by using a second message object, configured to shared gateway mode with a complementary NODE declaration. Bitfield CANPTR has to be initialized with the shared gateway’s message object number, whereas FSIZE, IDC and DLCC have to be cleared. Bit GDFS in control register MSGFGCRn determines, whether bit TXRQ will be automatically set in case of an arriving data frame with matching identifier (GDFS = ‘1’). User’s Manual TwinCAN_X41, V2.1 21-36 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Bit SRREN determines, whether a remote frame, received on the destination side, is transferred through the gateway to the source node or is directly answered by a data frame generated on the destination side. The functionality of the shared gateway mode is optimized to support different scenarios: • • • a data source, connected with CAN node A, transmits continuously data frames, which have to be automatically emitted on the destination CAN bus by CAN node B. The corresponding transfer state transitions are 1 - 2 - … a data source, connected with CAN node A, transmits continuously data frames, which have to be emitted by CAN node B upon a matching remote frame received from the destination CAN bus. The corresponding transfer state transitions are 7 - 4 - 2 - … a data source, connected with CAN node A, transmits a data frame upon a matching remote frame, which has been triggered by a matching remote frame received by CAN node B. The respective data frame has to be emitted again on the destination CAN bus by CAN node B. The corresponding transfer state transitions are 5 - 6 - 1 - 3 - … Depending on the application, the shared gateway message object can be initialized as receive object on the source side or transmit object on the destination side via an appropriate configuration of NODE, DIR, GDFS and SRREN. The various transfer states are illustrated in Figure 21-22. Data Frame Transmission, SRREN = ‘1’ 3 Transmit Object Destination Side TXRQ Set 1 Data Frame Reception, GDFS = ‘1’ 4 Remote Frame Reception, SRREN = ‘0’ 2 7 Data Frame Transmission, SRREN = ‘0’ Receive Object Source Side TXRQ Reset Data Frame Reception, GDFS = ‘0’ 6 Remote Frame Transmission Transmit Object Destination Side TXRQ Reset 5 Remote Frame Reception, SRREN = ‘1’ Receive Object Source Side TXRQ Set MCA05492 Figure 21-22 Transfer States in Shared Gateway Mode User’s Manual TwinCAN_X41, V2.1 21-37 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module When a shared gateway message object, set up as receive object on the source side (lower left state bubble in Figure 21-22), receives a data frame while GDFS is set to ‘1’, it commutes to a transmission object on the destination side by toggling control bits NODE and DIR and sends the corresponding data frame without any CPU interaction (upper left state bubble). Depending on control bit SRREN, the shared gateway message object returns to its initial function as receive object assigned to the source side (SRREN = ‘0’: state transition 2 to the lower left state bubble in Figure 21-22) or remains assigned to the destination side waiting for a remote frame with matching identifier (SRREN = ‘1’: state transition 3 to the upper right state bubble). When the shared gateway message object is assigned as transmit object to the destination side (upper right state bubble), it responds to remote frames received on the destination side. If bit SRREN is cleared, the remote request is directly answered by a data frame based on the contents of the gateway message object (state transition 4 to the upper left state bubble). If bit SRREN is set and a remote frame is received on the destination side, the shared gateway message object commutes to a receive object on the source side by toggling control bits NODE and DIR and prepares the emission of the received remote frame by setting TXRQ and RMTPND to ‘10’ (state transition 5 to the lower right state bubble). Then the shared gateway message object emits the corresponding remote frame without any CPU interaction (state transition 6 to the lower left state bubble). The gateway message object remains assigned to the source side until a data frame with matching identifier arrives (lower left state bubble). Then the shared gateway message object returns to the destination side and, depending on control bit GDFS, transmits immediately the corresponding data frame (GDFS = ‘1’, upper left state bubble) or waits upon an action of the CPU setting TXRQ to ‘10’ (GDFS = ‘0’: state transition 7 to the upper right state bubble). Alternatively, a remote frame with matching identifier, arriving on the destination side, may set TXRQ to ‘10’ and initiate the data frame transmission. If a data frame arrives on the source side while the shared gateway object with matching identifier is switched to the destination side, the data frame on the source side gets lost. Due to the temporary assignment to the destination node, the shared gateway message object does not notice the data frame on the source node and is not able to report the data loss via control bitfield MSGLST = ‘10’. The probability for a data loss is enlarged, if the automatic data frame transmission on the destination side is disabled by GDFS = ‘0’. A corresponding behavior has to be taken into account for incoming remote frames on the destination bus. Note: As long as bitfield MSGLST is activated, an incoming data frame cannot be automatically transmitted on the destination side. Due to the internal toggling of control bit DIR, the shared gateway object converts from receive to transmit operation and bitfield MSGLST is interpreted as CPUUPD = ‘10’ preventing the automatic transmission of a data frame. User’s Manual TwinCAN_X41, V2.1 21-38 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Impact of the transfer state transitions on the bitfields in the message object in shared gateway mode: Table 21-3 Shared Gateway State Transitions (Part 1 of 2) Bitfields Transition 1: Data Frame Received, GDFS = ‘1’ Transition 2: Data Frame Transmitted, SRREN = ‘0’ Transition 3: Data Frame Transmitted, SRREN = ‘1’ Transition 4: Remote Frame Received, SRREN = ‘0’ Node toggled to <d> toggled to <s> unchanged unchanged DIR set reset unchanged unchanged DATA received unchanged unchanged unchanged Identifier received unchanged unchanged received if RMM = ‘1’ DLC received unchanged unchanged received if RMM = ‘1’ TXRQ set reset reset set RMTPND reset reset reset set NEWDAT set reset reset reset INTPND set if RXIE = ‘10’ set if TXIE = ‘10’ set if TXIE = ‘10’ set if RXIE = ‘10’ Table 21-4 Shared Gateway State Transitions (Part 2 of 2) Bitfields Transition 5: Remote Frame Received, SRREN = ‘1’ Transition 6: Remote Frame Transmitted Transition 7: Data Frame Received, GDFS = ‘0’ Node toggled to <s> unchanged toggled to <d> DIR reset unchanged set DATA unchanged unchanged received Identifier received if RMM = ‘1’ unchanged received DLC received if RMM = ‘1’ unchanged received TXRQ set reset reset RMTPND reset reset reset NEWDAT unchanged unchanged set INTPND set if RXIE = ‘10’ set if TXIE = ‘10’ set if RXIE = ‘10’ User’s Manual TwinCAN_X41, V2.1 21-39 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.7 Programming the TwinCAN Module A software initialization should be performed by setting bit INIT in the CAN node specific control register ACR/BCR to ‘1’. While bit INIT is set, all message transfers between the CAN controller and the CAN bus are disabled. The initialization routine should process the following tasks: • • configuration of the corresponding node, initialization of each associated message object. 21.1.7.1 Configuration of CAN Node A/B Each CAN node can be individually configured by programming the associated register. Depending on the content of the ACR/BCR control registers, the normal operation mode or the CAN analyzer mode is activated. Furthermore, various interrupt categories (status change, error, last error) can be enabled or disabled. The bit timing is defined by programming the ABTR/BBTR register. The prescaler value, the synchronization jump width and the time segments, arranged before and after the sample point, depend on the characteristic of the CAN bus segment linked to the corresponding CAN node. The global interrupt node pointer register (AGINP/BGINP) controls multiplexer connecting an interrupt request source (error, last error, global transmit/receive and frame counter overflow interrupt request) with one of the eight common interrupt nodes. The contents of the INTID mask register (AIMR0/4 and BIMR0/4) decides which interrupt sources may be reported by the AIR/BIR interrupt pending register. 21.1.7.2 Initialization of Message Objects The message memory space, containing 32 message objects, is shared by both CAN nodes. Each message object has to be configured concerning its target node and operation properties. An initialization of the message object properties is always started with disabling the message object via MSGVAL = ‘01’. The CAN node, associated with a message, is defined by bit NODE in register MSGCFGn. The message object can be also defined as gateway, transferring information from CAN node A to B or vice versa. In this case, the FIFO/Gateway control register MSGFGCRn must be programmed to specify the gateway mode (bitfield MMC), the target interrupt node and further details of the information handover. The identifier, correlated with a message, is set up in register MSGARn. Bit XTD in register MSGCFGn indicates, whether an extended 29-bit or a standard 11-bit identifier is used and has to be set accordingly. Incoming messages can be filtered by the mask defined in register MSGAMRn. The message interrupt handling can be individually configured for transmit and receive direction. The direction specific interrupt is enabled by bits TXIE and RXIE in register MSGCNTn and the target interrupt node is selected by bitfields TXINP and RXINP in User’s Manual TwinCAN_X41, V2.1 21-40 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module register MSGCFGn. Message objects can be provided with a FIFO buffer. The buffer size is determined by bitfield FSIZE in the FIFO/Gateway control register MSGFGCRn. For transmit message objects, the object property assignment can be already finished by setting MSGVAL to ‘10’, before the corresponding data partition has been initialized. If bitfield CPUUPD is set to ‘10’, an incoming remote frame with matching identifier is kept in mind via setting TXRQ internally, but is not immediately answered by a corresponding data frame. The message data, stored in register MSGDRn0/MSGDRn4, can be updated as long as CPUUPD is hold on ‘10’. As soon as CPUUPD is reset to ‘01’, the respective data frame is transmitted by the associated CAN node controller. 21.1.7.3 Controlling a Message Transfer Figure 21-23 illustrates the handling of a transmit message object. The initialization of the message object properties is always started with disabling the message object via MSGVAL = ‘01’. After resetting some control flags (INTPND, RMTPND, TXRQ and NEWDAT), the transfer direction and the identifier are defined. The message object initialization is finished by setting MSGVAL to ‘10’. An update of a transmit message data partition should be prepared by setting CPUUPD to ‘10’ followed by a write access to the MSGDRn0/MSGDRn4 register. The data partition update must be indicated by the CPU via setting NEWDAT to ‘10’. Afterwards, bit CPUUPD must be reset to ‘01’, if an automatic message handling is requested. In this case, the data transmission is started, when flag TXRQ in register MSGCTRn has been set to ‘10’ by software or by the respective CAN node hardware due to a received remote frame with matching identifier. If CPUUPD remains set, the CPU must initiate the data transmission by setting TXRQ to ‘10’ and disabling CPUUPD. If a remote frame with an accepted identifier arrives during the update of a message object’s data storage, bit TXRQ and RMTPND are automatically set to ‘10’ and the transmission of the corresponding data frame is automatically started by the CAN controller when CPUUPD is reset again. Figure 21-24 demonstrates the handling of a receive message object. The initialization of the message object properties is embedded between disabling and enabling the message object via MSGVAL as described above. After setting MSGVAL to ‘10’, the transmission of a remote frame can be initiated by the CPU via TXRQ = ‘10’. The reception of a data frame is indicated by the associated CAN node controller via NEWDAT = ‘10’. The processing of the received data frame, stored in register MSGDRn0/MSGDRn4, should be started by the CPU with resetting NEWDAT to ‘01’. After scanning flag MSGLST, indicating a loss of the previous message, the received information should be copied to an application data buffer in order to release the message object for a new data frame. Finally, NEWDAT should be checked again to ensure, that the processing was based on a consistent set of data and not on a part of an old message and part of the new message. User’s Manual TwinCAN_X41, V2.1 21-41 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Power Up (all bits written with reset values) Message Initialization MSGVAL = ‘01’ INTPND := ‘01’ RMTPND := ‘01’ TXRQ := ‘01’ NEWDAT := ‘01’ DIR := ‘1’ (transmit object) Identifier := (application specific) XTD := (application specific) TXIE := (application specific) RXIE := (application specific) CPUUPD := ‘10’ MSGVAL := ‘10’ CPUUPD := ‘10’ NEWDAT := ‘10’ Update : Start Update Write / Calculate Message Contents Update : End CPUUPD := ‘01’ yes Want to Send ? TXRQ := ‘10’ no no ‘01’ : Reset ‘10’ : Set Update Message ? yes MCA05493 Figure 21-23 CPU Handling of Message Objects with Direction = Transmit User’s Manual TwinCAN_X41, V2.1 21-42 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Power Up (all bits written with reset values) Initialization MSGVAL = ‘01’ INTPND := ‘01’ RMTPND := ‘01’ TXRQ := ‘01’ NEWDAT := ‘01’ DIR := 0 (receive object) MSGLST := ‘01’ TXIE := (application specific) RXIE := (application specific) Identifier := (application specific) XTD := (application specific) MSGVAL := ‘10’ NEWDAT := ‘01’ Data Frame Processing Process Message Contents NEWDAT = ‘10’ ? yes Restart Process no no Remote Frame Transmission ? yes Remote Frame Generation TXRQ := ‘10’ ‘01’ : Reset ‘10’ : Set MCA05494 Figure 21-24 CPU Handling of Message Objects with Direction = Receive User’s Manual TwinCAN_X41, V2.1 21-43 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.8 Loop-Back Mode The TwinCAN module’s loop-back mode provides the means to internally test the TwinCAN module and CAN driver software. CAN driver software can be developed and tested without being connected to a CAN bus system. In loop-back mode, the transmit pins deliver recessive signals to the transceiver. The transmit signals are combined together and are connected to the internal receive signals, as shown in Figure 21-25. The receive input pins are not taken into account in loop-back mode. MUX RxDCA MUX 0 1 1 0 1 TxDCA TwinCAN Kernel MUX RxDCB MUX 0 1 1 0 1 TxDCB & LBM MCA05495 Figure 21-25 Loop-back Mode Loop-back mode is controlled by bits LBM in the bit timing registers of Node A and Node B according to Table 21-5. Table 21-5 Loop-Back Mode ABTR.LBM BBTR.LBM Description 0 0 Loop-back mode is disabled. 0 1 Loop-back mode is disabled. 1 0 Loop-back mode is disabled. 1 1 Loop-back mode is enabled. User’s Manual TwinCAN_X41, V2.1 21-44 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.9 Single Transmission Try Functionality Single transmission try functionality is controlled individually for each message object by bit STT in register MSGFGCRn. If the single transmission try functionality is enabled, the transmit request flag TXRQ is reset immediately after the transmission of a frame related to this message object has started. Thus, a transmit frame is only transferred once on the CAN bus, even if it has been corrupted by error frames. Note: A message object must be tagged valid by bitfield MSGVAL in order to enable the transmission of the respective frame. User’s Manual TwinCAN_X41, V2.1 21-45 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.1.10 Module Clock Requirements The functionality of the TwinCAN module is programmable in several respects. In order to operate at a specific baudrate with a given functionality a certain minimum module clock frequency is required. Table 21-6 lists some examples for certain configurations. These examples cover the worst case conditions where the CPU executes accesses to the TwinCAN module consecutively and with maximum speed. The module clock frequency can be reduced (see last column of Table 21-6) if no frames without data (data frames with DLC = 0 or remote frames) are transferred over the CAN bus. This is possible, because internal operations can be executed while the data part is transferred. Table 21-6 Minimum Module Clock Frequencies for 1 Mbit/s 1 Node Active, DLC ≥ 0 2 Nodes Active, DLC ≥ 0 2 Nodes Active, DLC ≥ 1 FIFO/gateway enabled 21 MHz 36 MHz 32 MHz No FIFO/gateway 20 MHz 29 MHz 26 MHz Note: The given numbers are required for the maximum CAN bus speed of 1 Mbit/s. For lower bit-rates the minimum module clock frequency can be reduced linearly, i.e. half the frequency is required for a bit-rate of 500 kbit/s. However, if two nodes are operated with different bit-rates, the module clock frequency must be chosen according to the fastest node. User’s Manual TwinCAN_X41, V2.1 21-46 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.2 TwinCAN Register Description 21.2.1 Register Map Figure 21-26 shows all registers associated with the TwinCAN module kernel. CAN Node A Registers CAN Node B Registers CAN Message Object Registers 1) Global CAN Control / Status Registers ACR BCR MSGDRn0 RXIPND ASR BSR MSGDRn4 TXIPND AIR BIR MSGARn ABTR BBTR MSGAMRn AGINP BGINP MSGCTRn AFCR BFCR MSGCFGn AIMR0 BIMR0 MSGFGCRn AIMR4 BIMR4 AECNT BECNT ACR ASR AIR ABTR AGINP AFCR AIMR0 AIMR4 AECNT Node A Control Register Node A Status Register Node A Interrupt Pending Register Node A Bit Timing Register Node A Global Int. Node Pointer Reg. Node A Frame Counter Register Node A INTID Mask Register 0 Node A INTID Mask Register 4 Node A Error Counter Register BCR BSR BIR BBTR BGINP BFCR BIMR0 BIMR4 BECNT Node B Control Register Node B Status Register Node B Interrupt Pending Register Node B Bit Timing Register Node B Global Int. Node Pointer Reg. Node B Frame Counter Register Node B INTID Mask Register 0 Node B INTID Mask Register 4 Node B Error Counter Register MSGDRn0 MSGARn MSGCTRn MSGFGCRn Msg. Object n Data Register 0 Msg. Object n Arbitration Register Msg. Object n Control Register Msg. Object n FIFO/Gatew. Cont. Reg. MSGDRn4 Msg. Object n Data Register 4 MSGAMRn Msg. Object n Acceptance Mask Reg. MSGCFGn Msg. Object n Configuration Register RXIPND Receive Interrupt Pending Register TXIPND Transmit Interrupt Pending Register 1) The number ‘n’ indicates the message object number, n = 0 … 31. MCA05496 Figure 21-26 TwinCAN Kernel Registers User’s Manual TwinCAN_X41, V2.1 21-47 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Module Offset +000H Reserved +200H CAN Node A Registers Node A +240H CAN Node B Registers Control Reg. +00H Status Reg. +04H Interrupt Pending Reg. +08H Bit Timing Reg. +0CH Global INP Reg. +10H Frame Counter Reg. +14H INTID Mask 0 Reg. +18H INTID Mask 4 Reg. +1CH Error Counter Reg. +20H Control Reg. +00H Status Reg. +04H Interrupt Pending Reg. +08H Bit Timing Reg. +0CH Global INP Reg. +10H Frame Counter Reg. +14H INTID Mask 0 Reg. +18H INTID Mask 4 Reg. +1CH Error Counter Reg. +20H Receive Int. Pending +04H Transmit Int. Pending +08H Data Register 0 +00H Data Register 4 +04H Arbitration Register +08H Acceptance Mask Reg. +0CH Message Control Reg. +10H Message Config. Reg. +14H FIFO/Gateway Control +18H +280H Global Control Registers +2C0H Node B Reserved +300H Message Object 0 +320H Message Object 1 +340H Message Object 2 ... Message Object n ... +6E0H Message Object 31 MCA05497 Figure 21-27 TwinCAN Kernel Address Map User’s Manual TwinCAN_X41, V2.1 21-48 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.2.2 CAN Node A/B Registers The Node Control Register controls the initialization, defines the node specific interrupt handling and selects an operation mode. ACR Node A Control Register BCR Node B Control Register 15 14 13 12 11 Reset Value: 0001H Reset Value: 0001H 10 9 8 7 6 CAL CCE M 0 r rw rw 5 0 r 4 3 LEC EIE IE rw rw 2 1 0 SIE 0 INIT rw r rwh Field Bits Type Description INIT 0 rwh Initialization 0 Resetting bit INIT starts the synchronization to the CAN bus. After a synchronization procedure1), the node takes part in CAN communication. 1 After setting bit INIT, the CAN node stops all CAN bus activities and all registers can be initialized without any impact on the actual CAN bus traffic. Bit INIT is automatically set when the bus-off state is entered. SIE 2 rw Status Change Interrupt Enable A status change interrupt occurs when a message transfer (indicated by the flags TXOK or RXOK in the status registers ASR or BSR) is successfully completed. 0 Status change interrupt is disabled. 1 Status change interrupt is enabled. EIE 3 rw Error Interrupt Enable An error interrupt is generated on a change of bit BOFF or bit EWRN in the status registers ASR or BSR. 0 Error interrupt is disabled. 1 Error interrupt is enabled. User’s Manual TwinCAN_X41, V2.1 21-49 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description LECIE 4 rw Last Error Code Interrupt Enable A last error code interrupt is generated when an error code is set in bitfield LEC in the status registers ASR or BSR. 0 Last error code interrupt is disabled. 1 Last error code interrupt is enabled. CCE 6 rw Configuration Change Enable 0 Access to bit timing register and modification of the error counters are disabled. 1 Access to bit timing register and modification of the error counters are enabled. CALM 7 rw CAN Analyzer Mode Bit CALM defines if the message objects of the corresponding node operate in analyzer mode. 0 The CAN message objects participate in CAN protocol. 1 CAN Analyzer Mode is selected. 0 1, 5, [15:8] r Reserved; returns ‘0’ if read; should be written with ‘0’. 1) After resetting bit INIT by software without being in the bus-off state (e.g. after power-on), a sequence of 11 consecutive recessive bits (11 × ‘1’) on the bus has to be monitored before the module takes part in the CAN traffic. During a bus-off recovery procedure, 128 sequences of 11 consecutive recessive bits (11 × ‘1’) have to be detected. The monitoring of the recessive bit sequences is immediately started by hardware after entering the bus-off state. The number of already detected 11 × ‘1’ sequences is indicated by the receive error counter. At the end of the bus-off recovery sequence, bit INIT is tested by hardware. If INIT is still set, the affected CAN node controller waits until INIT is cleared and 11 consecutive recessive bits (11 × ‘1’) are detected on the CAN bus, before the node takes part in CAN traffic again. If INIT has been already cleared, the message transfer between the affected CAN node controller and its associated CAN bus is immediately enabled. User’s Manual TwinCAN_X41, V2.1 21-50 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module The Node Status Register reports error states and successfully ended data transmissions. This register has to be read in order to release the status change interrupt request. ASR Node A Status Register BSR Node B Status Register 15 14 13 12 11 Reset Value: 0000H Reset Value: 0000H 10 9 8 7 6 B E OFF WRN 0 r rh rh 5 4 3 2 1 0 RX OK TX OK LEC r rwh rwh rwh 0 Field Bits Type Description LEC [2:0] rwh Last Error Code Bitfield LEC indicates if the latest CAN message transfer has been correct (No Error) or it indicates the type of error, which has been detected. The error conditions are detailed in Table 21-7. 000 No Error 001 Stuff Error 010 Form Error 011 Ack Error 100 Bit1 Error 101 Bit0 Error 110 CRC Error 111 reserved TXOK 3 rwh Message Transmitted Successfully 0 No successful transmission since last flag reset. 1 A message has been transmitted successfully (error free and acknowledged by at least one other node). TXOK must be reset by software. RXOK 4 rwh Message Received Successfully 0 No successful reception since last flag reset. 1 A message has been received successfully. RXOK must be reset by software. User’s Manual TwinCAN_X41, V2.1 21-51 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description EWRN 6 rh Error Warning Status 0 No warning limit exceeded. 1 One of the error counters in the Error Management Logic reached the error warning limit of 96. BOFF 7 rh Bus-Off Status 0 CAN controller is not in the bus-off state. 1 CAN controller is in the bus-off state. 0 5, [15:8] r Reserved; returns ‘0’ if read; should be written with ‘0’. Table 21-7 Meaning of the LEC Bitfield LEC Error Description No Error The latest transfer on the CAN bus has been completed successfully. Stuff Error More than 5 equal bits in a sequence have occurred in a part of a received message where this is not allowed. Form Error A fixed format part of a received frame has the wrong format. Ack Error The transmitted message was not acknowledged by another node. Bit1 Error During a message transmission, the CAN node tried to send a recessive level (‘1’), but the monitored bus value was dominant (outside the arbitration field and the acknowledge slot). Bit0 Error Two different conditions are signaled by this code: 1. During transmission of a message (or acknowledge bit, active error flag, overload flag), the CAN node tried to send a dominant level (‘0’), but the monitored bus value has been recessive. 2. During bus-off recovery, this code is set each time a sequence of 11 recessive bits has been monitored. The CPU may use this code as an indication, that the bus is not continuously disturbed. CRC Error The CRC checksum of the received message was incorrect. User’s Manual TwinCAN_X41, V2.1 21-52 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module The Interrupt Pending Register contains the identification number of the pending interrupt request with the highest priority. AIR Node A Interrupt Pending Register BIR Node B Interrupt Pending Register 15 14 13 12 11 10 9 Reset Value: 0000 0000H Reset Value: 0000 0000H 8 7 6 5 4 3 0 INTID r rwh 2 1 0 Field Bits Type Description INTID [7:0] rwh Interrupt Identifier 00H No interrupt is pending. 01H LEC, EI, TXOK or RXOK interrupt is pending. 02H RX or TX interrupt of message object 0 is pending. 03H RX or TX interrupt of message object 1 is pending. … … 21H RX or TX interrupt of message object 31 is pending. Bitfield INTID can be written by software to start an update after software actions and to check for changes. 0 [15:8] r Reserved; returns ‘0’ if read. User’s Manual TwinCAN_X41, V2.1 21-53 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Register AECNT/BECNT contains the values of the receive error counter and the transmit error counter. Some additional status/control bits allow for easier error analysis. AECNTH Node A Error Counter Register High AECNTL Node A Error Counter Register Low BECNTH Node B Error Counter Register High BECNTL Node B Error Counter Register Low 15 15 14 14 13 13 12 Reset Value: 0060H Reset Value: 0000H 8 0 LE INC LE TD EWRNLVL r rh rh rw 9 8 11 10 Reset Value: 0000H 9 12 11 Reset Value: 0060H 10 7 7 6 6 5 5 4 3 4 3 TEC REC rwh rwh 2 1 0 2 1 0 Field Bits Type Description REC [7:0] Low rwh Receive Error Counter Bitfield REC contains the value of the receive error counter for the corresponding node. TEC [15:8] Low rwh Transmit Error Counter Bitfield TEC contains the value of the transmit error counter for the corresponding node. EWRNLVL [7:0] Low rw Error Warning Level Bitfield EWRNLVL defines the threshold value (warning level, default 60H = 96D) to be reached in order to set the corresponding error warning bit EWRN. User’s Manual TwinCAN_X41, V2.1 21-54 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description LETD 8 High rh Last Error Transfer Direction 0 The last error occurred while the corresponding CAN node was receiving a message (REC has been incremented). 1 The last error occurred while the corresponding CAN node was transmitting a message (TEC has been incremented). An error during message reception is indicated without regarding the result of the acceptance filtering. LEINC 9 High rh Last Error Increment 0 The error counter was incremented by 1 due to the error reported by LETD. 1 The error counter was incremented by 8 due to the error reported by LETD. 0 [15:10] r High Reserved; returns ‘0’ if read; should be written with ‘0’. Note: Modifying the contents of register AECNT/BECNT requires bit CCE = ‘1’ in register ACR/BCR. User’s Manual TwinCAN_X41, V2.1 21-55 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module The Bit Timing Register contains all parameters to adjust the data transfer baud rate and the bit timing. ABTRH Node A Bit Timing Register High ABTRL Node A Bit Timing Register Low BBTRH Node B Bit Timing Register High BBTRL Node B Bit Timing Register Low 15 15 14 14 13 12 13 12 11 11 10 9 10 9 Reset Value: 0000H Reset Value: 0000H Reset Value: 0000H Reset Value: 0000H 8 7 6 5 4 3 2 1 0 0 LBM r rw 8 7 6 5 4 3 2 DIV 8X TSEG2 TSEG1 SJW BRP rw rw rw rw rw 1 0 Field Bits Type Description BRP [5:0] Low rw Baudrate Prescaler One bit time quantum corresponds to the period length of the external oscillator clock multiplied by (BRP+1), depending also on bit DIV8X. SJW [7:6] Low rw (Re)Synchronization Jump Width (SJW+1) time quanta are allowed for resynchronization. TSEG1 [11:8] Low rw Time Segment Before Sample Point (TSEG1+1) time quanta before the sample point take into account the signal propagation delay and compensate a mismatch between transmitter and receiver clock phase. Valid values for TSEG1 are 2 … 15. User’s Manual TwinCAN_X41, V2.1 21-56 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description TSEG2 [14:12] Low rw Time Segment After Sample Point (TSEG2+1) time quanta after the sample point take into account a user defined delay and compensate a mismatch between transmitter and receiver clock phase. Valid values for TSEG2 are 1 … 7. DIV8X 15 Low rw Division of Module Clock fCAN by 8 0 The baudrate prescaler is directly driven by fCAN. 1 The baudrate prescaler is driven by fCAN/8. LBM 0 High rw Loop-Back Mode 0 Loop-back mode is disabled. 1 Loop-back mode is enabled, if bits LBM are set in the BTR registers of Node A and Node B. 0 [15:1] High r Reserved; read as ‘0’; should be written with ‘0’. Note: Modifying the contents of register ABTR/BBTR requires bit CCE = ‘1’ in register ACR/BCR. User’s Manual TwinCAN_X41, V2.1 21-57 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module The Frame Counter Register controls the frame counter functionality and provides status information. AFCRH Node A Frame Counter Register High AFCRL Node A Frame Counter Register Low BFCRH Node B Frame Counter Register High BFCRL Node B Frame Counter Register Low 15 15 14 14 13 13 12 11 10 9 Reset Value: 0000H Reset Value: 0000H Reset Value: 0000H Reset Value: 0000H 8 7 6 5 4 3 2 1 0 CFC CFC OV IE 0 CFCMD r rwh rw r rw 7 6 12 11 10 9 8 5 4 3 2 1 0 0 CFC rwh Field Bits Type Description CFC [15:0] Low rwh User’s Manual TwinCAN_X41, V2.1 CAN Frame Counter This bitfield contains the count value of the frame counter. At the end of a correct message transfer, the value of CFC (captured value during SOF bit) is copied to bitfield CFCVAL of the corresponding message object control register MSGCTRn. 21-58 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description CFCMD [3:0] High rw Frame Count Mode This bitfield defines the operation mode of the frame counter. This counter can work on frame base (frame count) or on time base (time stamp). 0XXXB Frame Count:1) 0XX0B The CFC is not incremented after a foreign frame was transferred on the CAN bus. 0XX1B The CFC is incremented each time a foreign frame was transferred correctly on the CAN bus. 0X0XB The CFC is not incremented after a frame was received by the respective CAN node. The CFC is incremented each time a frame 0X1XB was received correctly by the node. 00XXB The CFC is not incremented after a frame was transmitted by the node. 01XXB The CFC is incremented each time a frame was transmitted correctly by the node. 1XXXB Time Stamp: 1000B The CFC is incremented with the beginning of a new bit time. The value is sampled during the SOF bit. 1001B The CFC is incremented with the beginning of a new bit time. The value is sampled during the last bit of EOF. others reserved CFCIE 6 High rw CAN Frame Count Interrupt Enable Setting CFCIE enables the CAN Frame Counter Overflow (CFCO) interrupt request. 0 The CFCO interrupt is disabled. 1 The CFCO interrupt is enabled. CFCOV 7 High rwh CAN Frame Count Overflow Flag Flag CFCOV is set on a CFC overflow condition (FFFFH to 0000H). An interrupt request is generated if the corresponding interrupt is enabled (CFCIE = ‘1’). 0 An overflow has not yet been detected. 1 An overflow has been detected since the bit has been reset. CFCOV must be reset by software. User’s Manual TwinCAN_X41, V2.1 21-59 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description 0 [5:4], [15:8] High r Reserved; read as ‘0’; should be written with ‘0’. 1) If the frame counter functionality has been selected (CFCMD.3 = ‘0’), bit CFCMD.0 enables or disables the counting of foreign frames. A foreign frame is a correct frame on the bus, which has not been transmitted /received by the node itself. Bit CFCMD.1 enables or disables the counting of frames, which have been received correctly by the corresponding CAN node. Bit CFCMD.2 enables or disables the counting of frames, which have been transmitted correctly by the corresponding CAN node. User’s Manual TwinCAN_X41, V2.1 21-60 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module The Global Interrupt Node Pointer Register connects each global interrupt request source with one of the 8 available CAN interrupt nodes. AGINP Node A Global Interrupt Node Pointer Register BGINP Node B Global Interrupt Node Pointer Register 15 14 13 12 11 10 9 8 7 Reset Value: 0000H Reset Value: 0000H 6 5 4 3 2 1 0 CFCINP 0 TRINP 0 LECINP 0 EINP r rw r rw r rw r rw 0 Field Bits Type Description EINP [2:0] rw Error Interrupt Node Pointer Number of interrupt node reporting the “Error Interrupt Request”, if enabled by EIE = ‘1’. 000B CAN interrupt node 0 is selected. … … 111B CAN interrupt node 7 is selected. LECINP [6:4] rw Last Error Code Interrupt Node Pointer Number of interrupt node reporting the last error interrupt request, if enabled by LECIE = ‘1’. 000B CAN interrupt node 0 is selected. … … 111B CAN interrupt node 7 is selected. TRINP [10:8] rw Transmit/Receive OK Interrupt Node Pointer Number of interrupt node reporting the transmit and receive interrupt request, if enabled by SIE = ‘1’. 000B CAN interrupt node 0 is selected. … … 111B CAN interrupt node 7 is selected. CFCINP [14:12] rw Frame Counter Interrupt Node Pointer Number of interrupt node reporting the frame counter overflow interrupt request, if enabled by CFCIE = ‘1’. 000B CAN interrupt node 0 is selected. … … 111B CAN interrupt node 7 is selected. 0 3, 7, 11, 15 r Reserved; read as ‘0’; should be written with ‘0’. User’s Manual TwinCAN_X41, V2.1 21-61 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module The Interrupt Identification Mask Registers allow for disabling the identification notification of a pending interrupt request in the AIR/BIR register. The Interrupt Mask Registers AIMR0/BIMR0 are used to enable the message specific interrupt sources (correct transmission/ reception) for the generation of the corresponding INTID value. AIMRH0 Node A INTID Mask Register 0 High AIMRL0 Node A INTID Mask Register 0 Low BIMRH0 Node B INTID Mask Register 0 High BIMRL0 Node B INTID Mask Register 0 Low 15 14 13 12 11 10 9 Reset Value: 0000H Reset Value: 0000H Reset Value: 0000H Reset Value: 0000H 8 7 6 5 4 3 2 1 0 5 4 3 2 1 0 IMCn (n = 31-16) rw 15 14 13 12 11 10 9 8 7 6 IMCn (n = 15-0) rw Field Bits Type Description IMCn (n = 15-0) n Low rw IMCn (n = 31-16) n-16 High User’s Manual TwinCAN_X41, V2.1 Message Object n INTID Mask Control 0 Message object n is ignored for the generation of the INTID value. 1 The interrupt pending status of message object n is taken into account for the generation of the INTID value. 21-62 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module The Interrupt Mask Registers AIMR4/BIMR4 are used to enable the node specific interrupt sources (last error, correct reception, error warning/bussoff) for the generation of the corresponding INTID value. AIMR4 Node A INTID Mask Register 4 BIMR4 Node B INTID Mask Register 4 15 14 13 12 11 10 Reset Value: 0000H Reset Value: 0000H 9 8 7 6 5 4 3 2 1 0 IMC IMC IMC 34 33 32 0 r rw rw rw Field Bits Type Description IMC32 0 rw Last Error Interrupt INTID Mask Control 0 The last error interrupt source is ignored for the generation of the INTID value. 1 The last error interrupt source is taken into account for the generation of the INTID value. IMC33 1 rw TX/RX Interrupt INTID Mask Control 0 The TX/RX interrupt source is ignored for the generation of the INTID value. 1 The TX/RX interrupt pending status is taken into account for the generation of the INTID value. IMC34 2 rw Error Interrupt INTID Mask Control 0 The error interrupt source is ignored for the generation of the INTID value. 1 The error interrupt pending status is taken into account for the generation of the INTID value. 0 [15:3] r Reserved; read as ‘0’; should be written with ‘0’. User’s Manual TwinCAN_X41, V2.1 21-63 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.2.3 CAN Message Object Registers Each message object is provided with a set of control and data register. The corresponding register names are supplemented with a variable n running from 0 to 31 (e.g. MSGDRn0 means that data register MSGDR300 is assigned with message object number 30). The Message Data Register 0 contains the data bytes 0 to 3 of message object n. MSGDRHn0 (n = 31-0) Message Object n Data Register 0 High MSGDRLn0 (n = 31-0) Message Object n Data Register 0 Low 15 15 14 14 13 13 12 11 10 9 8 Reset Value: 0000H Reset Value: 0000H 7 6 5 4 3 DATA3 DATA2 rwh rwh 12 11 10 9 8 7 6 5 4 3 DATA1 DATA0 rwh rwh 2 1 0 2 1 0 Field Bits Type Description DATA0 [7:0] Low rwh Data Byte 0 Associated to Message Object n DATA1 [15:8] Low rwh Data Byte 1 Associated to Message Object n DATA2 [7:0] High rwh Data Byte 2 Associated to Message Object n DATA3 [15:8] High rwh Data Byte 3 Associated to Message Object n User’s Manual TwinCAN_X41, V2.1 21-64 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module The Message Data Register 4 contains the data bytes 4 to 7 of message object n. MSGDRHn4 (n = 31-0) Message Object n Data Register 4 High MSGDRLn4 (n = 31-0) Message Object n Data Register 4 Low 15 15 14 14 13 13 12 11 10 9 8 Reset Value: 0000H Reset Value: 0000H 7 6 5 4 3 DATA7 DATA6 rwh rwh 12 11 10 9 8 7 6 5 4 3 DATA5 DATA4 rwh rwh 2 1 0 2 1 0 Field Bits Type Description DATA4 [7:0] Low rwh Data Byte 4 Associated to Message Object n DATA5 [15:8] Low rwh Data Byte 5 Associated to Message Object n DATA6 [7:0] High rwh Data Byte 6 Associated to Message Object n DATA7 [15:8] High rwh Data Byte 7 Associated to Message Object n User’s Manual TwinCAN_X41, V2.1 21-65 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Register MSGARn contains the identifier of message object n. MSGARHn (n = 31-0) Message Object n Arbitration Register High MSGARLn (n = 31-0) Message Object n Arbitration Register Low 15 15 14 13 12 11 10 9 8 7 Reset Value: 0000H Reset Value: 0000H 6 0 ID[28:16] r rwh 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 5 4 3 2 1 0 ID[15:0] rwh Field Bits Type Description ID[15:0] [15:0] Low [12:0] High rwh ID[28:16] 0 [15:13] r High User’s Manual TwinCAN_X41, V2.1 Message Identifier Identifier of a standard message (ID[28:18]) or an extended message (ID[28:0]). For standard identifiers bits ID[17:0] are “don’t care”. Reserved; returns ‘0’ if read; should be written with ‘0’. 21-66 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Register MSGAMRn contains the mask bits for the acceptance filtering of message object n. MSGAMRHn (n = 31-0) Message Object n Arbitration Mask Register High MSGAMRLn (n = 31-0) Message Object n Arbitration Mask Register Low 15 15 14 13 12 11 10 9 8 7 6 1 AM[28:16] r rw 14 13 12 11 10 9 8 7 6 Reset Value: FFFFH Reset Value: FFFFH 5 4 3 2 1 0 5 4 3 2 1 0 AM[15:0] rw Field Bits Type Description AM[15:0] [15:0] Low [12:0] High rw AM[28:16] 1 [15:13] r High User’s Manual TwinCAN_X41, V2.1 Message Acceptance Mask Mask to filter incoming messages with standard identifiers (AM[28:18]) or extended identifiers (AM[28:0]). For standard identifiers bits AM[17:0] are “don’t care”. 0 Identifier bit is ignored for acceptance test. 1 Identifier bit is taken into account for the acceptance filtering. Reserved; returns ‘1’ if read; should be written with ‘1’. 21-67 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Register MSGCTRn affects the data transfer between a CAN node controller and the corresponding message object n and provides a bitfield to store the captured value of the frame counter. MSGCTRHn (n = 31-0) Message Object n Message Control Register High MSGCTRLn (n = 31-0) Message Object n Message Control Register Low 15 14 13 12 11 10 9 8 7 Reset Value: 0000H Reset Value: 5555H 6 5 4 3 2 1 0 6 5 4 3 2 1 0 CFCVAL rwh 15 14 13 12 11 10 9 8 7 RMTPND TXRQ MSGLST CPUUPD NEWDAT MSGVAL TXIE RXIE INTPND rwh rwh rwh rwh rwh rw rw rwh Field Bits Type Description INTPND [1:0] Low rwh Message Object Interrupt Pending INTPND is generated by an “OR” operation between the RXIPNDn and TXIPNDn flags (if enabled by TXIE or RXIE). INTPND must be reset by software. Resetting INTPND also resets the corresponding RXIPND and TXIPND flags. 01 No message object interrupt request is pending. 10 The message object has generated an interrupt request. RXIE [3:2] Low rw Message Object Receive Interrupt Enable 01 Message object receive interrupt is disabled. 10 Message object receive interrupt is enabled. If RXIE is set, bits INTPND and RXIPND are set after successful reception of a frame. TXIE [5:4] Low rw Message Object Transmit Interrupt Enable 01 Message object transmit interrupt is disabled. 10 Message object transmit interrupt is enabled. If TXIE is set, bits INTPND and TXIPND are set after successful transmission of a frame. User’s Manual TwinCAN_X41, V2.1 21-68 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description MSGVAL1) [7:6] Low rwh Message Object Valid The CAN controller only operates on valid message objects. Message objects can be tagged invalid while they are changed or if they are not used at all. 01 Message object is invalid. 10 Message object is valid. NEWDAT2) [9:8] Low rwh New Message Object Data Available 01 No update of message object data occurred. 10 New message object data has been updated. MSGLST [11:10] rwh Low Message Lost (for reception only) 01 No message object data is lost. 10 The CAN controller has stored a new message into the message object while NEWDAT was still set. The previously stored message is lost. MSGLST must be reset by software. CPUUPD3) [11:10] rwh Low CPU Update (for transmission only) Indicates that the corresponding message object can not be transmitted now. The software sets this bit in order to inhibit the transmission of a message that is currently updated by the CPU or to control the automatic response to remote requests. 01 The message object data can be transmitted automatically by the CAN controller. 10 The automatic transmission of the message data is inhibited. TXRQ4) [13:12] rwh Low Message Object Transmit Request Flag 01 No message object data transmission is requested by the CPU or a remote frame. 10 The transmission of the message object data, requested by the CPU or by a remote frame, is pending. Automatic setting of TXRQ by the CAN node controller can be disabled for Gateway Message Objects via control bit GDFS = ‘0’. TXRQ is automatically reset, when the message object has been successfully transmitted. If there are several valid message objects with pending transmit requests, the message object with the lowest message number will be transmitted first. User’s Manual TwinCAN_X41, V2.1 21-69 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description RMTPND [15:14] rwh Low Remote Pending Flag (used for transmit-objects) 01 No remote node request for a message object data transmission. 10 Transmission of the message object data has been requested by a remote node but the data has not yet been transmitted. When RMTPND is set, the CAN node controller also sets TXRQ. RMTPND is automatically reset, when the message object data has been successfully transmitted. CFCVAL [15:0] High Message Object Frame Counter Value CFCVAL contains a copy of the frame counter content valid for the last correct data transmission or reception executed for the corresponding message object. rwh 1) MSGVAL has to be set from ‘01’ to ‘10’ in order to take into account an update of bits XTD, DIR, NODE and CANPTR. 2) Bit NEWDAT indicates that new data has been written into the data registers of this corresponding message object. For transmit objects, NEWDAT should be set by software and is reset by the respective CAN node controller when the transmission is started. For receive objects, NEWDAT is set by the respective CAN node controller after receiving a data frame with matching identifier. It has to be reset by software. When the CAN controller writes new data into the message object, unused message bytes will be overwritten with non-specified values. Usually, the CPU will clear this bitfield before working on the data and will verify that the bitfield is still cleared once the CPU has finished working to ensure a consistent set of data. For transmit objects, the CPU should set this bitfield along with clearing bitfield CPUUPD. This will ensure that, if the message is actually being transmitted during the time the message is updated by the CPU, the CAN controller will not reset bitfield TXRQ. In this way, TXRQ is only reset once the actual data has been transferred correctly. 3) While bitfield MSGVAL is set (‘10’) an incoming matching remote frame is taken into account by automatically setting bitfields TXRQ and RMTPND to ‘10’ (independent from bitfield CPUUPD/MSGLST). The transmission of a frame is only possible if CPUUPD is reset (‘01’). 4) If a receive object (DIR = ‘0’) is requested for transmission, a remote frame will be sent in order to request a data frame from another node. If a transmit object (DIR = ‘1’) is requested for transmission, a data frame will be sent. Bitfield TXRQ will be reset by the CAN controller along with bitfield RMTPND after the correct transmission of the data frame if bitfield NEWDAT has not been set or after correct transmission of a remote frame. Note: For transmitting frames (remote CPUUPD/MSGLST has to be reset. User’s Manual TwinCAN_X41, V2.1 21-70 frames or data frames), bitfield V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module The control and status element of the message control registers is implemented with two complementary bits (except the frame counter value). This special mechanism allows the selective setting or resetting of a specific element (leaving others unchanged) without requiring read-modify-write cycles. Table 21-8 illustrates how to use these 2-bitfields. Table 21-8 Setting/Resetting the Control and Status Element of the Message Control Registers Value of the 2-bitfield Function on Write Meaning on Read 00B reserved reserved 01B Reset element Element is reset 10B Set element Element is set 11B Leave element unchanged reserved Register MSGCFGn defines the configuration of message object n and the associated interrupt node pointers. Changes of bits XTD, NODE or DIR by software are only taken into account after setting bitfield MSGVAL to ‘10’. This avoids unintentional modification while the message object is still active by explicitly defining a timing instant for the update. Bits XTD, NODE or DIR can be written while MSGVAL is ‘01’ or ‘10’, the update always takes place by setting MSGVAL to ‘10’. MSGCFGHn (n = 31-0) Message Object n Message Configuration Register High MSGCFGLn (n = 31-0) Message Object n Message Configuration Register Low 15 15 14 14 13 13 12 11 12 User’s Manual TwinCAN_X41, V2.1 10 9 8 7 6 5 Reset Value: 0000H Reset Value: 0000H 4 3 2 1 0 TXINP 0 RXINP r rw r rw 11 10 9 8 7 6 5 4 3 2 1 0 0 0 DLC DIR XTD NO RMM DE r rwh rwh rwh 21-71 rw rw V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description RMM 0 Low rw Transmit Message Object Remote Monitoring Mode 0 Remote Monitoring mode is disabled. 1 Remote Monitoring mode is enabled for this transmit message object. The identifier and DLC code of a remote frame with matching identifier are copied to this transmit message object in order to monitor incoming remote frames. Bit RMM is only available for transmit objects and has no impact for receive objects. NODE 1 Low rwh Message Object CAN Node Select 0 The message object is assigned to CAN node A. 1 The message object is assigned to CAN node B. XTD 2 Low rw Message Object Extended Identifier 0 This message object uses a standard 11-bit identifier. 1 This message object uses an extended 29-bit identifier. DIR 3 Low rwh Message Object Direction Control 0 The message object is defined as receive object. If TXRQ = ‘10’, a remote frame with the identifier of this message object is transmitted. On reception of a data frame with matching identifier, the message data is stored in the corresponding MSGDRn0/MSGDRn4 registers. 1 The message object is declared as transmit object. If TXRQ = ‘10’, the respective data frame is transmitted. On reception of a remote frame with matching identifier, RMTPND and TXRQ are set to ‘10’. DLC1) [7:4] Low rwh Message Object Data Length Code 0000B - 1XXXB DLC contains the number of data bytes associated to the message object. Bitfield DLC may be modified by hardware in Remote Monitoring Mode and in Gateway Mode. User’s Manual TwinCAN_X41, V2.1 21-72 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description RXINP [2:0] High rw Receive Interrupt Node Pointer Bitfield RXINP determines which interrupt node is triggered by a message object receive event, if bitfield RXIE in register MSGCTRn is set. 000B CAN interrupt node 0 is selected. … … 111B CAN interrupt node 7 is selected. TXINP [6:4] High rw Transmit Interrupt Node Pointer Bitfield TXINP determines which interrupt node is triggered by a message object transmit event, if bitfield TXIE in register MSGCTRn is set. 000B CAN interrupt node 0 is selected. … … 111B CAN interrupt node 7 is selected. 0 [15:8] Low 3, [15:7] High r Reserved; returns ‘0’ if read; should be written with ‘0’. 1) The maximum number of data bytes is 8. A value > 8 written by the CPU, is internally corrected to 8 but the content of bitfield DLC is not updated. If a received data frame contains a data length code value > 8, only 8 bytes are taken into account. A read access to bitfield DLC returns the original value of the DLC field of the received data frame. The FIFO/gateway control register MSGFGCRn contains bits to enable and to control the FIFO functionality, the gateway functionality and the desired transfer actions. User’s Manual TwinCAN_X41, V2.1 21-73 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module MSGFGCRHn (n = 31-0) Message Object n FIFO/Gateway Control Register High MSGFGCRLn (n = 31-0) Message Object n FIFO/Gateway Control Register Low 15 15 14 14 STT SDT rw rw 13 12 11 10 9 8 7 6 5 Reset Value: 0000H Reset Value: 0000H 4 3 2 0 MMC 0 CANPTR r rw r rwh 13 12 11 10 FD 0 DL CC IDC rw r rw rw 9 8 7 SRR GD EN FS rw rw 6 5 4 3 2 0 FSIZE r rw 1 0 1 0 Field Bits Type Description FSIZE [4:0] Low rw FIFO Size Control Bitfield FSIZE determines the number of message objects combined to a FIFO buffer. Even numbered message objects may provide FIFO base or slave functionality, while odd numbered message objects are restricted to slave functionality. In gateway mode, FSIZE determines the length of the FIFO on the destination side. 00000B message object n is part of a 1-stage FIFO 00001B message object n is part of a 2-stage FIFO 00011B message object n is part of a 4-stage FIFO 00111B message object n is part of a 8-stage FIFO 01111B message object n is part of a 16-stage FIFO 11111B message object n is part of a 32-stage FIFO else reserved FSIZE = ‘00000’ leads to the behavior of a standard message object (the pointer CANPTR used for this action will not be changed). This value has to be written if a gateway transfer to a single message object (no FIFO) as destination is desired. FSIZE is not evaluated for message objects configured in standard mode, shared gateway mode or FIFO slave functionality. In this case, FSIZE should be programmed to ‘00000’. User’s Manual TwinCAN_X41, V2.1 21-74 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description GDFS 8 Low rw Gateway Data Frame Send Specifies if a CAN data frame will be automatically generated on the destination side after new data has been transferred via gateway from the source to the destination side. 0 No additional action, TXRQ will not be set on the destination side. 1 The corresponding data frame will be sent automatically (TXRQ of the message object, pointed to by CANPTRn, will be set by hardware). Bit GDFS is only taken into account, if a data frame has been received (DIR<s> = ‘0’). SRREN 9 Low rw Source Remote Request Enable Specifies if the transmit request bit is set in message object n itself (to generate a data frame) or in the message object pointed to by CANPTRn (in order to generate a remote frame on the source bus). 0 A remote on the source bus will not be generated, a data frame with the contents of the destination object will be generated on the destination bus, instead (TXRQn will be set). 1 A data frame with the contents of the destination object will not be sent. Instead, a corresponding remote frame will be generated by the message object pointed to by bitfield CANPTRn (TXRQ[CANPTRn] will be set). SRREN is restricted to transmit message objects in normal or shared gateway mode (DIR = ‘1’). This bit is only taken into account if a remote frame has been received. Bit SRREN must not be set if message object n is part of a FIFO buffer. In order to generate a remote frame on the source side, CANPTR has to point to the source message object. User’s Manual TwinCAN_X41, V2.1 21-75 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description IDC 10 Low rw Identifier Copy IDC controls the identifier handling during a frame transfer through a gateway. 0 The identifier of the receiving object is not copied to the transmitting message object. 1 The identifier of the receiving object is automatically copied to the transmitting message object. Bitfield IDC is restricted to message objects configured in normal gateway mode. DLCC 11 Low rw Data Length Code Copy DLCC controls the handling of the data length code during a data frame transfer through a gateway. 0 The data length code, provided by the source object, is not copied to the transmitting object. 1 The data length code, valid for the receiving object, is copied automatically to the transmitting object. Bitfield DLCC is restricted to message objects configured in normal gateway mode. User’s Manual TwinCAN_X41, V2.1 21-76 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description FD 13 Low rw FIFO Direction FD is only taken into account for a FIFO base object (the FD bits of all FIFO elements should have an identical value). It defines which transfer action (reception or transmission) leads to an update of the FIFO base object’s CANPTR. 0 FIFO Reception: The CANPTR (of the FIFO base object) is updated after a correct reception of a data frame (DIR = ‘0’) or a remote frame (DIR = ‘1’) by the currently addressed message object. The CANPTR is left unchanged after any transmission. 1 FIFO Transmission: The CANPTR (of the FIFO base object) is updated after a correct transmission of a data frame (DIR = ‘1’) or a remote frame (DIR = ‘0’) from the currently addressed message object. The CANPTR is left unchanged after any reception. Bitfield FD is not correlated with bit DIR. SDT 14 Low rw Single Data Transfer Mode This bit is taken into account in any transfer mode (FIFO mode or as standard object, receive and transmit objects). 0 Control bit MSGVAL is not reset when this object has taken part in a successful data transfer (receive or transmit). 1 Control bit MSGVAL is automatically reset after a successful data transfer (receive or transmit) has taken place. Bit SDT is not taken into account for remote frames. Bit SDT has to be reset in all message objects belonging to a FIFO buffer. STT 15 Low rw Single Transmission Try 0 Single transmission try is disabled. 1 Single transmission try is enabled. The corresponding TXRQ bit is reset immediately after the transmission has started1). User’s Manual TwinCAN_X41, V2.1 21-77 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description CANPTR [4:0] High rwh CAN Pointer for FIFO/Gateway Functions Message object is configured in standard mode (MMC = ‘000’): No impact, CANPTR should be initialized with the respective message object number. Message object is configured as FIFO base object (MMC = ‘010’): CANPTR contains the number of the message object addressed by the associated CAN controller for the next transmit or receive operation. For initialization, CANPTR should be written with the message number of the respective FIFO base object. Message object is configured as FIFO slave object (MMC = ‘011’): CANPTR has to be initialized with the respective message object number of the FIFO base object. Message object is configured for normal gateway mode (MMC = ‘100’): CANPTR contains the number of the message object used as gateway destination object. Message object is configured as gateway destination object without FIFO functionality (MMC = ‘000’): If SRREN is set to ‘1’, CANPTR has to be initialized with the number of the message object used as gateway source. The backward pointer is required to transfer remote frames from the destination to the source side. If SRREN is cleared, CANPTR is not evaluated and must be initialized with the respective message object number. Message object is configured for shared gateway mode (MMC = ‘101’): No impact, CANPTR has to be initialized with the respective message object number. For FIFO functionality (or gateway functionality with a FIFO as destination), CANPTRn should not be written by software while FIFO mode is activated and data transfer is in progress. This bitfield can be used to reset the FIFO by software. User’s Manual TwinCAN_X41, V2.1 21-78 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Field Bits Type Description MMC [10:8] High rw Message Object Mode Control Bitfield MMC controls the functionality of message object n. 000B Standard message object functionality 010B FIFO functionality enabled (base object) 011B FIFO functionality enabled (slave object) 100B Normal gateway functionality for incoming frames 101B Shared gateway functionality for incoming frames others reserved 0 [7:5], r 12 Low [7:5], [15:11] High Reserved; returns ‘0’ if read; should be written with ‘0’. 1) As a result, a message will not be re-transmitted if it has lost arbitration or has been corrupted by an error frame. Note: Changes of bitfield CANPTR for transmission objects are only taken into account after setting bitfield MSGVAL to ‘10’. This avoids unintentional modification while the message object is still active by explicitly defining a timing instant for the update. Bitfield CANPTR for transmission objects can be written while MSGVAL is ‘01’ or ‘10’, the update always takes place by setting MSGVAL to ‘10’. Changes of bitfield CANPTR for receive objects are immediately taken into account. User’s Manual TwinCAN_X41, V2.1 21-79 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.2.4 Global CAN Control/Status Registers The Receive Interrupt Pending Register indicates the pending receive interrupts for message object n. RXIPNDH Receive Interrupt Pending Register High RXIPNDL Receive Interrupt Pending Register Low 15 14 13 12 11 10 9 8 Reset Value: 0000H Reset Value: 0000H 7 6 5 4 3 2 1 0 5 4 3 2 1 0 RXIPNDn (n = 31-16) rh 15 14 13 12 11 10 9 8 7 6 RXIPNDn (n = 15-0) rh Field Bits Type Description RXIPNDn (n = 15-0) n Low rh RXIPND (n = 31-16) n-16 High User’s Manual TwinCAN_X41, V2.1 Message Object n Receive Interrupt Pending Bit RXIPNDn is set by hardware if message object n received a frame and bit RXIEn has been set. 0 No receive is pending for message object n. 1 Receive is pending for message object n. RXIPNDn can be cleared by software via resetting the corresponding bit INTPNDn. 21-80 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module The Transmit Interrupt Pending Register indicates whether a transmit interrupt is pending for message object n. TXIPNDH Transmit Interrupt Pending Register High TXIPNDL Transmit Interrupt Pending Register Low 15 14 13 12 11 10 9 8 Reset Value: 0000H Reset Value: 0000H 7 6 5 4 3 2 1 0 5 4 3 2 1 0 TXIPNDn (n = 31-16) rh 15 14 13 12 11 10 9 8 7 6 TXIPNDn (n = 15-0) rh Field Bits Type Description TXIPNDn (n = 15-0) n Low rh TXIPND (n = 31-16) n-16 High User’s Manual TwinCAN_X41, V2.1 Message Object n Transmit Interrupt Pending Bit TXIPNDn is set by hardware if message object n transmitted a frame and bit TXIEn has been set. 0 No transmit is pending for message object n. 1 Transmit is pending for message object n. TXIPNDn can be cleared by software via resetting the corresponding bit INTPNDn. 21-81 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.3 XC164 Module Implementation Details This section describes: • • the TwinCAN module related interfaces such as port connections and interrupt control all TwinCAN module related registers with its addresses and reset values 21.3.1 Interfaces of the TwinCAN Module In XC164 the TwinCAN module is connected to IO ports according to Figure 21-28. P4.4_rx fCAN MUX RxDCA Address Decoder Port 4 Control P4.4 P4.6_tx P4.5 P4.7_tx P4.6 P4.7_rx ALTSEL P4.7 P7.4_rx Port 7 Control P7.4 TxDCA CAN0INT TwinCAN Module CAN1INT (Kernel) CAN2INT Interrupt Control P4.5_rx CAN3INT P7.5_tx P7.6_rx TxDCB P7.6 P7.7_tx ALTSEL CAN4INT CAN5INT CAN6INT P7.5 MUX RxDCB P9.0_rx CAN7INT Port 9 Control P9.1_tx 3 3 P9.0 P9.1 P9.2_rx P9.2 P9.3_tx PISEL P7.7 ALTSEL P9.3 MCA05498 Figure 21-28 TwinCAN Module IO Interface The input receive pins can be selected by bitfield RISA (for node A) and bitfield RISB (for node B) in the PISEL register. The output transmit pins are defined by the corresponding ALTSEL registers of Port 4 or Port 9. The TwinCAN has eight interrupt request lines. User’s Manual TwinCAN_X41, V2.1 21-82 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.3.2 TwinCAN Module Related External Registers Figure 21-29 shows the module related external registers which are required for programming the TwinCAN module. Port Registers Interrupt Registers System Registers ALTSEL0P4 CAN_0IC CAN_PISEL DP4 CAN_1IC CAN_2IC CAN_3IC ALTSEL0P9 CAN_4IC DP9 CAN_5IC CAN_6IC CAN_7IC MCA05499_X4 Figure 21-29 TwinCAN Implementation Specific Registers User’s Manual TwinCAN_X41, V2.1 21-83 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.3.2.1 System Registers Register CAN_PISEL allows the user to select the input pins for the two TwinCAN receive signals RXDCA and RXDCB. CAN_PISEL TwinCAN Port Input Select Register 15 14 13 12 11 10 9 Reset Value: 0000H 8 7 6 5 4 3 2 1 0 RISB RISA r rw rw 0 Field Bits Type Description RISA [2:0] rw Receive Input Selection for Node A Bitfield RISA defines the input pin for the TwinCAN receive line RXDCA for node A. 000 The input pin for RXDCA is P4.5 001 The input pin for RXDCA is P4.7 010 Reserved. 011 The input pin for RXDCA is P9.2 1XX Reserved. RISB [5:3] rw Receive Input Selection for Node B Bitfield RISB defines the input pin for the TwinCAN receive line RXDCB for node B. 000 The input pin for RXDCB is P4.4 001 The input pin for RXDCB is P9.0 010 Reserved. 011 Reserved. 1XX Reserved. 0 [15:6] r Reserved; returns ‘0’ if read; should be written with ‘0’. User’s Manual TwinCAN_X41, V2.1 21-84 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.3.2.2 Port Registers The port registers required to program to TwinCAN operation are listed as follows. ALTSEL0P4 P4 Alternate Select Register 0 15 14 13 12 11 10 Reset Value: 0000H 9 8 7 6 5 4 3 2 0 P7 P6 0 r rw rw r 1 0 Field Bit Type Description ALTSEL0 P4.y 7, 6 rw P4 Alternate Select Register 0 bit y 0 associated peripheral output is not selected as alternate function 1 associated peripheral output is selected as alternate function DP4 P4 Direction Ctrl. Register 15 14 13 12 11 Reset Value: 0000H 10 9 8 7 6 5 4 3 2 1 0 0 P7 P6 P5 P4 P3 P2 P1 P0 r rw rw rw rw rw rw rw rw Field Bit Type Description DP4.y 7…4 rw Port Direction Register DP4 Bit y 0 Port line P4.y is an input (high-impedance) 1 Port line P4.y is an output Note: Shaded bits are not related to TwinCAN operation. User’s Manual TwinCAN_X41, V2.1 21-85 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module ALTSEL0P9 P9 Alternate Select Register 0 15 14 13 12 11 10 Reset Value: 0000H 9 8 7 6 5 4 3 2 1 0 0 0 0 P3 0 P1 0 r rw rw rw rw rw rw Field Bit Type Description ALTSEL0 P9.y 3, 1 rw P9 Alternate Select Register 0 Bit y 0 associated peripheral output is not selected as alternate function 1 associated peripheral output is selected as alternate function ALTSEL1P9 P9 Alternate Select Register 1 15 14 13 12 11 10 Reset Value: 0000H 9 8 7 6 5 4 3 2 1 0 0 0 0 P3 0 P1 0 r rw rw rw rw rw rw Field Bit Type Description ALTSEL1 P9.y 3, 1 rw P9 Alternate Select Register 1 Bit y 0 associated peripheral output is not selected as alternate function 1 associated peripheral output is selected as alternate function Note: Shaded bits are not related to TwinCAN operation. User’s Manual TwinCAN_X41, V2.1 21-86 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module DP9 P9 Direction Ctrl. Register 15 14 13 12 11 Reset Value: 0000H 10 9 8 7 6 5 4 3 2 1 0 0 P5 P4 P3 P2 P1 P0 r rw rw rw rw rw rw Field Bit Type Description DP9.y 3…0 rw Port Direction Register DP9 Bit y 0 Port line P9.y is an input (high-impedance) 1 Port line P9.y is an output Note: Shaded bits are not related to TwinCAN operation. User’s Manual TwinCAN_X41, V2.1 21-87 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module Table 21-9 shows the required register setting to configure the IO lines of the TwinCAN module for operation. Table 21-9 Port Lines TwinCAN IO Selection and Setup Alternate Select Register Port Input Select Register Direction Control Register IO TwinCAN Node A P4.5 / RxDCA – CAN_PISEL[2:0] = 000 DP4.P5 = 0 Input P4.6 / TxDCA ALTSEL0P4.P6 = 1 – DP4.P6 = 1 Output P4.7 / RxDCA – CAN_PISEL[2:0] = 001 DP4.P7 = 0 Input P9.2 / RxDCA – CAN_PISEL[2:0] = 011 DP9.P2 = 0 Input P9.3 / TxDCA ALTSEL0P9.P3 = 1 and ALTSEL1P9.P3 =1 – DP9.P3 = 1 Output TwinCAN Node B P4.4 / RxDCB – CAN_PISEL[5:3] = 000 DP4.P4 = 0 Input P4.7 / TxDCB ALTSEL0P4.P7 = 1 – DP4.P7 = 1 Output P9.0 / RxDCB – CAN_PISEL[5:3] = 001 DP9.P0 = 0 Input P9.1 / TxDCB ALTSEL0P9.P1 = 1 and ALTSEL1P9.P1 =1 – DP9.P1 = 1 Output Note: The ALTSEL1 register of Port 4 is ‘don’t care’ for selecting the TwinCAN alternate output function. User’s Manual TwinCAN_X41, V2.1 21-88 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.3.2.3 Interrupt Registers The interrupts of the TwinCAN module are controlled by the following interrupt control registers: • • • • • • • • CAN_0IC CAN_1IC CAN_2IC CAN_3IC CAN_4IC CAN_5IC CAN_6IC CAN_7IC All interrupt control registers have the same structure. Refer to the System Units for its description and also details on interrupt handling and processing. User’s Manual TwinCAN_X41, V2.1 21-89 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) TwinCAN Module 21.3.3 Register Table Table 21-10 shows the system registers related to the TwinCAN module. It summarizes the addresses and reset values. In order to simplify the kernel description, the prefix ‘CAN_’ is added only in this register list. The start address for the TwinCAN module is 20’0000H, the register offsets (relative to this address) are given in the TwinCAN kernel description. See Figure 21-27. A full register listing of all CAN registers is provided in register table section and in the system book. Table 21-10 TwinCAN Module Register Summary Name Address1) Description 16-Bit Reset Value TwinCAN Module System Registers CAN_PISEL TwinCAN Port Input Select Register 20’0004H 0000H CAN_0IC TwinCAN Interrupt Control Register for the CAN interrupt node 0. F196H 0000H CAN_1IC TwinCAN Interrupt Control Register for the CAN interrupt node 1. F142H 0000H CAN_2IC TwinCAN Interrupt Control Register for the CAN interrupt node 2. F144H 0000H CAN_3IC TwinCAN Interrupt Control Register for the CAN interrupt node 3. F146H 0000H CAN_4IC TwinCAN Interrupt Control Register for the CAN interrupt node 4. F148H 0000H CAN_5IC TwinCAN Interrupt Control Register for the CAN interrupt node 5. F14AH 0000H CAN_6IC TwinCAN Interrupt Control Register for the CAN interrupt node 6. F14CH 0000H CAN_7IC TwinCAN Interrupt Control Register for the CAN interrupt node 7. F14EH 0000H 1) The 8-bit short addresses are not available for the TwinCAN module kernel registers. User’s Manual TwinCAN_X41, V2.1 21-90 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set 22 Register Set This chapter summarizes all the kernel and module related external registers of the peripherals. The register list is organized into two parts - the first for PD+BUS peripherals and the second for LXBus peripherals. 22.1 PD+BUS Peripherals Note: The address space for PD+BUS peripherals is assigned to Segment 0. Table 22-1 PD+BUS Register Listing Short Name Address Physical 8-bit Description Reset Value Area Asynchronous/Synchronous Serial Interface 0 (ASC0) ASC0_CON FFB0H D8H SFR ASC0 Control Register 0000H ASC0_TBUF FEB0H 58H SFR ASC0 Transmit Buffer Register 0000H ASC0_RBUF FEB2H 59H SFR ASC0 Receive Buffer Register 0000H ASC0_ ABCON F1B8H DCH ESFR ASC0 Autobaud Control Register 0000H ASC0_ ABSTAT F0B8H 5CH ESFR ASC0 Autobaud Status Register 0000H ASC0_BG FEB4H 5AH SFR ASC0 Baud Rate Generator Reload Register 0000H ASC0_FDV FEB6H 5BH SFR ASC0 Fractional Divider Register 0000H ASC0_PMW FEAAH 55H SFR ASC0 IrDA Pulse Mode and Width 0000H Reg. ASC0_ RXFCON F0C6H 63H ESFR ASC0 Receive FIFO Control Register 0000H ASC0_ TXFCON F0C4H 62H ESFR ASC0 Transmit FIFO Control Register 0000H ASC0_FSTAT F0BAH 5DH ESFR ASC0 FIFO Status Register 0000H Asynchronous/Synchronous Serial Interface 1 (ASC1) ASC1_CON FFB8H DCH SFR ASC1 Control Register 0000H ASC1_TBUF FEB8H 5CH SFR ASC1 Transmit Buffer Register 0000H ASC1_RBUF FEBAH 5DH SFR ASC1 Receive Buffer Register 0000H ASC1_ ABCON F1BCH DEH ESFR ASC1 Autobaud Control Register User’s Manual RegSet_X41, V2.0 22-1 0000H V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-1 PD+BUS Register Listing (cont’d) Short Name Address Description Physical 8-bit Area Reset Value ASC1_ ABSTAT F0BCH 5EH ESFR ASC1 Autobaud Status Register 0000H ASC1_BG FEBCH 5EH SFR ASC1 Baud Rate Generator Reload Register 0000H ASC1_FDV FEBEH 5FH SFR ASC1 Fractional Divider Register 0000H ASC1_PMW FEACH 56H SFR ASC1 IrDA Pulse Mode and Width 0000H Reg. ASC1_ RXFCON F0A6H 53H ESFR ASC1 Receive FIFO Control Register 0000H ASC1_ TXFCON F0A4H 52H ESFR ASC1 Transmit FIFO Control Register 0000H ASC1_FSTAT F0BEH 5FH ESFR ASC1 FIFO Status Register 0000H Synchronous Serial Channel 0 (SSC0) SSC0_CON FFB2H D9H SFR SSC0 Control Register 0000H SSC0_BR F0B4H 5AH ESFR SSC0 Baudrate Timer Reload Register 0000H SSC0_TB F0B0H 58H ESFR SSC0 Transmit Buffer Reg. 0000H SSC0_RB F0B2H 59H ESFR SSC0 Receive Buffer Reg. 0000H Synchronous Serial Channel 1 (SSC1) SSC1_CON FF5EH AFH SFR SSC1 Control Register 0000H SSC1_BR F05EH 2FH ESFR SSC1 Baudrate Timer Reload Register 0000H SSC1_TB F05AH 2DH ESFR SSC1 Transmit Buffer Reg. 0000H SSC1_RB F05CH 2EH ESFR SSC1 Receive Buffer Reg. 0000H General Purpose Timer Unit (GPT12E) GPT12E_ T2CON FF40H A0H SFR GPT12E Timer 2 Control Register 0000H GPT12E_ T3CON FF42H A1H SFR GPT12E Timer 3 Control Register 0000H GPT12E_ T4CON FF44H A2H SFR GPT12E Timer 4 Control Register 0000H User’s Manual RegSet_X41, V2.0 22-2 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-1 PD+BUS Register Listing (cont’d) Short Name Address Description Reset Value Physical 8-bit Area GPT12E_ T5CON FF46H A3H SFR GPT12E Timer 5 Control Register 0000H GPT12E_ T6CON FF48H A4H SFR GPT12E Timer 6 Control Register 0000H GPT12E_ CAPREL FE4AH 25H SFR GPT12E Capture/Reload Register 0000H GPT12E_T2 FE40H 20H SFR GPT12E Timer 2 Register 0000H GPT12E_T3 FE42H 21H SFR GPT12E Timer 3 Register 0000H GPT12E_T4 FE44H 22H SFR GPT12E Timer 4 Register 0000H GPT12E_T5 FE46H 23H SFR GPT12E Timer 5 Register 0000H GPT12E_T6 FE48H 24H SFR GPT12E Timer 6 Register 0000H Real Time Clock (RTC) RTC_CON F110H 88H ESFR RTC Control Register, low word 8003H RTC_T14 F0D2H 69H ESFR Timer 14 Register UUUUH RTC_T14REL F0D0H 68H ESFR Timer 14 Reload Register UUUUH RTC_RTCL F0D4H 6AH ESFR RTC Timer Low Register UUUUH RTC_RTCH F0D6H 6BH ESFR RTC Timer High Register UUUUH RTC_RELL F0CCH 66H ESFR RTC Reload Low Register 0000H RTC_RELH F0CEH 67H ESFR RTC Reload High Register 0000H RTC_ISNC F10CH 86H ESFR RTC Interrupt Subnode Register 0000H Capture/Compare Unit 1 (CAPCOM1) CC1_M0 FF52H A9H SFR CAPCOM1 Mode Control Register 0000H 0 CC1_M1 FF54H AAH SFR CAPCOM1 Mode Control Register 0000H 1 CC1_M2 FF56H ABH SFR CAPCOM1 Mode Control Register 0000H 2 CC1_M3 FF58H ACH SFR CAPCOM1 Mode Control Register 0000H 3 CC1_SEE FE2EH 17H SFR CAPCOM1 Single Event Enable Register User’s Manual RegSet_X41, V2.0 22-3 0000H V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-1 PD+BUS Register Listing (cont’d) Short Name Address Description Reset Value 0000H Physical 8-bit Area CC1_SEM FE2CH 16H SFR CAPCOM1 Single Event Mode Register CC1_DRM FF5AH ADH SFR CAPCOM1 Double Register Mode 0000H Register CC1_OUT FF5CH AEH SFR CAPCOM1 Output Register 0000H CC1_T0 FE50H 28H SFR CAPCOM1 Timer 0 Register 0000H CC1_T0REL FE54H 2AH SFR CAPCOM1 Timer 0 Reload Register 0000H CC1_T1 FE52H 29H SFR CAPCOM1 Timer 1 Register 0000H CC1_T1REL FE56H 2BH SFR CAPCOM1 Timer 1 Reload Register 0000H CC1_T01CON FF50H A8H SFR CAPCOM1 Timer 0 and Timer 1 Control Register 0000H CC1_IOC F062H 31H ESFR CAPCOM1 I/O Control Register 0000H CC1_CC0 FE80H 40H SFR CAPCOM1 Register 0 0000H CC1_CC1 FE82H 41H SFR CAPCOM1 Register 1 0000H CC1_CC2 FE84H 42H SFR CAPCOM1 Register 2 0000H CC1_CC3 FE86H 43H SFR CAPCOM1 Register 3 0000H CC1_CC4 FE88H 44H SFR CAPCOM1 Register 4 0000H CC1_CC5 FE8AH 45H SFR CAPCOM1 Register 5 0000H CC1_CC6 FE8CH 46H SFR CAPCOM1 Register 6 0000H CC1_CC7 FE8EH 47H SFR CAPCOM1 Register 7 0000H CC1_CC8 FE90H 48H SFR CAPCOM1 Register 8 0000H CC1_CC9 FE92H 49H SFR CAPCOM1 Register 9 0000H CC1_CC10 FE94H 4AH SFR CAPCOM1 Register 10 0000H CC1_CC11 FE96H 4BH SFR CAPCOM1 Register 11 0000H CC1_CC12 FE98H 4CH SFR CAPCOM1 Register 12 0000H CC1_CC13 FE9AH 4DH SFR CAPCOM1 Register 13 0000H CC1_CC14 FE9CH 4EH SFR CAPCOM1 Register 14 0000H CC1_CC15 FE9EH 4FH SFR CAPCOM1 Register 15 0000H User’s Manual RegSet_X41, V2.0 22-4 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-1 PD+BUS Register Listing (cont’d) Short Name Address Physical 8-bit Description Reset Value Area Capture / Compare Unit 2 (CAPCOM2) CC2_M4 FF22H 91H SFR CAPCOM2 Mode Control Register 0000H 4 CC2_M5 FF24H 92H SFR CAPCOM2 Mode Control Register 0000H 5 CC2_M6 FF26H 93H SFR CAPCOM2 Mode Control Register 0000H 6 CC2_M7 FF28H 94H SFR CAPCOM2 Mode Control Register 0000H 7 CC2_SEE FE2AH 15H SFR CAPCOM2 Single Event Enable Register 0000H CC2_SEM FE28H 14H SFR CAPCOM2 Single Event Mode Register 0000H CC2_DRM FF2AH 95H SFR CAPCOM2 Double Register Mode 0000H Register CC2_OUT FF2CH 96H SFR CAPCOM2 Output Register CC2_T7 F050H 28H ESFR CAPCOM2 Timer 7 Register 0000H CC2_T8 F052H 29H ESFR CAPCOM2 Timer 8 Register 0000H CC2_T7REL F054H 2AH ESFR CAPCOM2 Timer 7 Reload Register 0000H CC2_T8REL F056H 2BH ESFR CAPCOM2 Timer 8 Reload Register 0000H CC2_T78CON FF20H 90H SFR CAPCOM2 Timer 7 and Timer 8 Control Register 0000H CC2_IOC F066H 33H ESFR CAPCOM2 I/O Control Register 0000H CC2_CC16 FE60H 30H SFR CAPCOM2 Register 16 0000H CC2_CC17 FE62H 31H SFR CAPCOM2 Register 17 0000H CC2_CC18 FE64H 32H SFR CAPCOM2 Register 18 0000H CC2_CC19 FE66H 33H SFR CAPCOM2 Register 19 0000H CC2_CC20 FE68H 34H SFR CAPCOM2 Register 20 0000H CC2_CC21 FE6AH 35H SFR CAPCOM2 Register 21 0000H CC2_CC22 FE6CH 36H SFR CAPCOM2 Register 22 0000H User’s Manual RegSet_X41, V2.0 22-5 0000H V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-1 PD+BUS Register Listing (cont’d) Short Name Address Description Reset Value Physical 8-bit Area CC2_CC23 FE6EH 37H SFR CAPCOM2 Register 23 0000H CC2_CC24 FE70H 38H SFR CAPCOM2 Register 24 0000H CC2_CC25 FE72H 39H SFR CAPCOM2 Register 25 0000H CC2_CC26 FE74H 3AH SFR CAPCOM2 Register 26 0000H CC2_CC27 FE76H 3BH SFR CAPCOM2 Register 27 0000H CC2_CC28 FE78H 3CH SFR CAPCOM2 Register 28 0000H CC2_CC29 FE7AH 3DH SFR CAPCOM2 Register 29 0000H CC2_CC30 FE7CH 3EH SFR CAPCOM2 Register 30 0000H CC2_CC31 FE7EH 3FH SFR CAPCOM2 Register 31 0000H Capture / Compare Unit 6 (CCU6) E890H – IO Timer 12 Counter Register 0000H CCU6_T12PR E892H – IO Timer 12 Period Register 0000H CCU6_ T12DTC E894H – IO Dead-Time Control Register for Timer 12 0000H CCU6_CC60R E898H – IO Capture/Compare Register (Ch. 0) 0000H CCU6_CC61R E89AH – IO Capture/Compare Register (Ch. 1) 0000H CCU6_CC62R E89CH – IO Capture/Compare Register (Ch. 2) 0000H CCU6_ CC60SR E8A0H – IO Capture/Compare Shadow Register (Ch. 0) 0000H CCU6_ CC61SR E8A2H – IO Capture/Compare Shadow Register (Ch. 1) 0000H CCU6_ CC62SR E8A4H – IO Capture/Compare Shadow Register (Ch. 2) 0000H CCU6_T13 E8B0H – IO Timer 13 Counter Register 0000H CCU6_T13PR E8B2H – IO Timer 13 Period Register 0000H CCU6_CC63R E8B4H – IO Compare Register for Timer 13 0000H CCU6_ CC63SR E8B6H – IO Compare Shadow Register for Timer 13 0000H CCU6_ CMPSTAT E8A8H – IO Compare State Register 0000H CCU6_T12 User’s Manual RegSet_X41, V2.0 22-6 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-1 PD+BUS Register Listing (cont’d) Short Name Address Description Reset Value Physical 8-bit Area E8AAH – IO Compare State Modification Register 0000H CCU6_TCTR0 E8ACH – IO Timer Control Register 0 0000H CCU6_TCTR2 E8AEH – IO Timer Control Register 2 0000H CCU6_TCTR4 E8A6H – IO Timer Control Register 4 0000H CCU6_ MODCTR E8C0H – IO Modulation Control Register 0000H CCU6_ TRPCTR E8C2H – IO Trap Control Register 0000H CCU6_PSLR E8C4H – IO Passive State Level Register 0000H CCU6_ T12MSEL E8C6H – IO T12 Capture/Compare Mode Select Register 0000H CCU6_ MCMOUTS E8CAH – IO Multi-Channel Mode Output Shadow Register 0000H CCU6_ MCMOUT E8CCH – IO Multi-Channel Mode Output Register 0000H CCU6_ MCMCTR E8CEH – IO Multi-Channel Mode Control Register 0000H CCU6_IS E8D0H – IO Capture/Compare Interrupt Status 0000H Register CCU6_ISS E8D2H – IO Capture/Compare Interrupt Status 0000H Set Register CCU6_ISR E8D4H – IO Capture/Compare Interrupt Status 0000H Reset Register CCU6_INP E8D6H – IO Capture/Compare Interrupt Node Pointer Register 3940H CCU6_IEN E8D8H – IO Capture/Compare Interrupt Node Pointer Register 0000H CCU6_ CMPMODIF A/D Converter (ADC) ADC_CON FFA0H D0H SFR A/D Converter Control Register 0000H ADC_CON1 FFA6H D3H SFR A/D Converter Control Register 0000H ADC_CTR0 FFBEH DFH SFR A/D Converter Control Register 0 1000H User’s Manual RegSet_X41, V2.0 22-7 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-1 PD+BUS Register Listing (cont’d) Short Name Physical 8-bit Area Reset Value F09CH 4EH ESFR A/D Converter Control Register 2 0000H ADC_CTR2IN F09EH 4FH ESFR A/D Converter Injection Control Register 2 0000H ADC_DAT FEA0H 50H SFR 0000H ADC_DAT2 F0A0H 50H ESFR A/D Converter 2 Result Register 0000H ADC_CTR2 Address Description A/D Converter Result Register Interrupt Control SSC0_TIC FF72H B9H SFR SSC0 Transmit Interrupt Control Register 0000H SSC0_RIC FF74H BAH SFR SSC0 Receive Interrupt Control Register 0000H SSC0_EIC FF76H BBH SFR SSC0 Error Interrupt Control Register 0000H SSC1_TIC F1AAH D5H ESFR SSC1 Transmit Interrupt Control Register 0000H SSC1_RIC F1ACH D6H SFR 0000H SSC1_EIC F1AEH D7H ESFR SSC1 Error Interrupt Control Register 0000H ASC0_TIC FF6CH B6H SFR ASC0 Transmit Interrupt Control Register 0000H ASC0_RIC FF6EH B7H SFR ASC0 Receive Interrupt Control Register 0000H ASC0_EIC FF70H B8H SFR ASC0 Error Interrupt Control Register 0000H ASC0_TBIC F19CH CEH ESFR ASC0 Transmit Buffer Interrupt Control Register 0000H ASC0_ABIC F15CH AEH ESFR ASC0 Autobaud Interrupt Control Register 0000H ASC1_TIC F182H C1H ESFR ASC1 Transmit Interrupt Control Register 0000H ASC1_RIC F18AH C5H ESFR ASC1 Receive Interrupt Control Register 0000H User’s Manual RegSet_X41, V2.0 SSC1 Receive Interrupt Control Register 22-8 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-1 PD+BUS Register Listing (cont’d) Short Name Address Description Reset Value Physical 8-bit Area ASC1_EIC F192H C9H ESFR ASC1 Error Interrupt Control Register 0000H ASC1_TBIC F150H A8H ESFR ASC1 Transmit Buffer Interrupt Control Register 0000H ASC1_ABIC F1BAH DDH ESFR ASC1 Autobaud Interrupt Control Register 0000H GPT12E_ T2IC FF60H B0H SFR GPT12E Timer 2 Interrupt Control 0000H Register GPT12E_ T3IC FF62H B1H SFR GPT12E Timer 3 Interrupt Control 0000H Register GPT12E_ T4IC FF64H B2H SFR GPT12E Timer 4 Interrupt Control 0000H Register GPT12E_ T5IC FF66H B3H SFR GPT12E Timer 5 Interrupt Control 0000H Register GPT12E_ T6IC FF68H B4H SFR GPT12E Timer 6 Interrupt Control 0000H Register GPT12E_ CRIC FF6AH B5H SFR GPT12E CAPREL Interrupt Control Register CC1_T0IC FF9CH CEH SFR CAPCOM Timer 0 Interrupt Control 0000H Register CC1_T1IC FF9EH CFH SFR CAPCOM Timer 1 Interrupt Control 0000H Register CC2_T7IC F17AH BDH ESFR CAPCOM Timer 7 Interrupt Control 0000H Register CC2_T8IC F17CH BEH ESFR CAPCOM Timer 8 Interrupt Control 0000H Register CC1_CC0IC FF78H BCH SFR CAPCOM Register 0 Interrupt Control Register 0000H CC1_CC1IC FF7AH BDH SFR CAPCOM Register 1 Interrupt Control Register 0000H CC1_CC2IC FF7CH BEH SFR CAPCOM Register 2 Interrupt Control Register 0000H User’s Manual RegSet_X41, V2.0 22-9 0000H V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-1 PD+BUS Register Listing (cont’d) Short Name Address Description Reset Value Physical 8-bit Area CC1_CC3IC FF7EH BFH SFR CAPCOM Register 3 Interrupt Control Register 0000H CC1_CC4IC FF80H C0H SFR CAPCOM Register 4 Interrupt Control Register 0000H CC1_CC5IC FF82H C1H SFR CAPCOM Register 5 Interrupt Control Register 0000H CC1_CC6IC FF84H C2H SFR CAPCOM Register 6 Interrupt Control Register 0000H CC1_CC7IC FF86H C3H SFR CAPCOM Register 7 Interrupt Control Register 0000H CC1_CC8IC FF88H C4H SFR CAPCOM Register 8 Interrupt Control Register 0000H CC1_CC9IC FF8AH C5H SFR CAPCOM Register 9 Interrupt Control Register 0000H CC1_CC10IC FF8CH C6H SFR CAPCOM Register 10 Interrupt Control Register 0000H CC1_CC11IC FF8EH C7H SFR CAPCOM Register 11 Interrupt Control Register 0000H CC1_CC12IC FF90H C8H SFR CAPCOM Register 12 Interrupt Control Register 0000H CC1_CC13IC FF92H C9H SFR CAPCOM Register 13 Interrupt Control Register 0000H CC1_CC14IC FF94H CAH SFR CAPCOM Register 14 Interrupt Control Register 0000H CC1_CC15IC FF96H CBH SFR CAPCOM Register 15 Interrupt Control Register 0000H CC2_CC16IC F160H B0H ESFR CAPCOM Register 16 Interrupt Control Register 0000H CC2_CC17IC F162H B1H ESFR CAPCOM Register 17 Interrupt Control Register 0000H CC2_CC18IC F164H B2H ESFR CAPCOM Register 18 Interrupt Control Register 0000H User’s Manual RegSet_X41, V2.0 22-10 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-1 PD+BUS Register Listing (cont’d) Short Name Address Description Reset Value Physical 8-bit Area CC2_CC19IC F166H B3H ESFR CAPCOM Register 19 Interrupt Control Register 0000H CC2_CC20IC F168H B4H ESFR CAPCOM Register 20 Interrupt Control Register 0000H CC2_CC21IC F16AH B5H ESFR CAPCOM Register 21 Interrupt Control Register 0000H CC2_CC22IC F16CH B6H ESFR CAPCOM Register 22 Interrupt Control Register 0000H CC2_CC23IC F16EH B7H ESFR CAPCOM Register 23 Interrupt Control Register 0000H CC2_CC24IC F170H B8H ESFR CAPCOM Register 24 Interrupt Control Register 0000H CC2_CC25IC F172H B9H ESFR CAPCOM Register 25 Interrupt Control Register 0000H CC2_CC26IC F174H BAH ESFR CAPCOM Register 26 Interrupt Control Register 0000H CC2_CC27IC F176H BBH ESFR CAPCOM Register 27 Interrupt Control Register 0000H CC2_CC28IC F178H BCH ESFR CAPCOM Register 28 Interrupt Control Register 0000H CC2_CC29IC F184H C2H ESFR CAPCOM Register 29 Interrupt Control Register 0000H CC2_CC30IC F18CH C6H ESFR CAPCOM Register 30 Interrupt Control Register 0000H CC2_CC31IC F194H CAH ESFR CAPCOM Register 31 Interrupt Control Register 0000H CCU6_IC F140H A0H ESFR Interrupt Control Register for other 0000H Interrupts (module intr. node I3) CCU6_EIC F188H C4H ESFR Interrupt Control Register for Emergency Interrupts (module intr. node I2) 0000H CCU6_T12IC F190H C8H ESFR Interrupt Control Register for T12 Interrupts (module intr. node I0) 0000H User’s Manual RegSet_X41, V2.0 22-11 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-1 PD+BUS Register Listing (cont’d) Short Name Address Description Reset Value Physical 8-bit Area CCU6_T13IC F198H CCH ESFR Interrupt Control Register for T13 Interrupts (module intr. node I1) 0000H ADC_CIC FF98H CCH SFR A/D Converter End of Conversion Interrupt Control Register 0000H ADC_EIC FF9AH CDH SFR A/D Converter Overrun Error Interrupt Control Register 0000H CAN_0IC F196H CBH ESFR TwinCAN Interrupt Control Register 0 0000H CAN_1IC F142H A1H ESFR TwinCAN Interrupt Control Register 1 0000H CAN_2IC F144H A2H ESFR TwinCAN Interrupt Control Register 2 0000H CAN_3IC F146H A3H ESFR TwinCAN Interrupt Control Register 3 0000H CAN_4IC F148H A4H ESFR TwinCAN Interrupt Control Register 4 0000H CAN_5IC F14AH A5H ESFR TwinCAN Interrupt Control Register 5 0000H CAN_6IC F14CH A6H ESFR TwinCAN Interrupt Control Register 6 0000H CAN_7IC F14EH A7H ESFR TwinCAN Interrupt Control Register 7 0000H EOPIC F180H C0H ESFR End of PEC Subchannel Interrupt Control Register 0000H PLL_IC F19EH CFH ESFR PLL Interrupt Control Register 0000H RTC_IC F1A0H D0H ESFR RTC Interrupt Control Register 0000H PICON F1C4H E2H ESFR Port Input Threshold Control Register 0000H POCON0L F080H 40H ESFR P0L Output Control Register 0000H POCON0H F082H 41H ESFR P0H Output Control Register 0000H POCON1L F084H 42H ESFR P1L Output Control Register 0000H POCON1H F086H 43H ESFR P1H Output Control Register 0000H Ports User’s Manual RegSet_X41, V2.0 22-12 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-1 PD+BUS Register Listing (cont’d) Short Name Address Physical 8-bit Area Reset Value POCON2 F088H 44H ESFR P2 Output Control Register 0000H POCON3 F08AH 45H ESFR P3 Output Control Register 0000H POCON4 F08CH 46H ESFR P4 Output Control Register 0000H POCON6 F08EH 47H ESFR P6 Output Control Register 0000H POCON9 F094H 4AH ESFR P9 Output Control Register 0000H POCON20 F0AAH 55H ESFR P20 Output Control Register 0000H P0L FF00H 80H SFR PORT0 Low Register 0000H P0H FF02H 81H SFR PORT0 High Register 0000H DP0L F100H 80H ESFR P0L Direction Control Register 0000H DP0H F102H 81H ESFR P0H Direction Control Register 0000H P1L FF04H 82H SFR PORT1 Low Register 0000H P1H FF06H 83H SFR PORT1 High Register 0000H DP1L F104H 82H ESFR P1L Direction Control Register 0000H DP1H F106H 83H ESFR P1H Direction Control Register 0000H ALTSEL0P1L F130H 98H ESFR P1L Alternate Select Register 0 0000H ALTSEL0P1H F120H 90H ESFR P1H Alternate Select Register 0 0000H P2 FFC0H E0H SFR Port 2 Data Register 0000H DP2 FFC2H E1H SFR P2 Direction Control Register 0000H ODP2 F1C2H E1H ESFR P2 Open Drain Control Register 0000H ALTSEL0P2 F122H 91H ESFR P2 Alternate Select Register 0 0000H P3 FFC4H E2H SFR Port 3 Data Register 0000H DP3 FFC6H E3H SFR P3 Direction Control Register 0000H ODP3 F1C6H E3H ESFR P3 Open Drain Control Register 0000H ALTSEL0P3 F126H 93H ESFR P3 Alternate Select Register 0 0000H ALTSEL1P3 F128H 94H ESFR P3 Alternate Select Register 1 0000H P4 FFC8H E4H SFR Port 4 Data Register 0000H DP4 FFCAH E5H SFR P4 Direction Control Register 0000H ODP4 F1CAH E5H ESFR P4 Open Drain Control Register 0000H ALTSEL0P4 F12AH 95H ESFR P4 Alternate Select Register 0 0000H User’s Manual RegSet_X41, V2.0 Description 22-13 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-1 PD+BUS Register Listing (cont’d) Short Name Address Physical 8-bit Area Reset Value ALTSEL1P4 F136H 9BH ESFR P4 Alternate Select Register 1 0000H P5 FFA2H D1H SFR Port 5 Data Register 0000H P5DIDIS FFA4H D2H SFR Port 5 Digital Input Disable Register 0000H P9 FF16H 8BH SFR Port 9 Data Register 0000H DP9 FF18H 8CH SFR P9 Direction Control Register 0000H ODP9 FF1AH 8DH SFR P9 Open Drain Control Register 0000H ALTSEL0P9 F138H 9CH ESFR P9 Alternate Select Register 0 0000H ALTSEL1P9 F13AH 9DH ESFR P9 Alternate Select Register 1 0000H P20 FFB4H DAH SFR Port 20 Data Register 0000H DP20 FFB6H DBH SFR P20 Direction Control Register 0000H User’s Manual RegSet_X41, V2.0 Description 22-14 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set 22.2 LXBUS Peripherals Note: The address space for LXBUS peripherals is assigned to Segment 32; it may be changed by user SW. Table 22-2 LXBUS Register Listing Short Name Physical Address Description Reset Value CAN_PISEL 20’0004H TwinCAN Port Input Select Register 0000H CAN_ACR 20’0200H Node A Control Register 0001H CAN_ASR 20’0204H Node A Status Register 0000H CAN_AIR 20’0208H Node A Interrupt Pending Register 0000H CAN_ABTRL 20’020CH Node A Bit Timing Register Low 0000H CAN_ABTRH 20’020EH Node A Bit Timing Register High 0000H CAN_AGINP 20’0210H Node A Global Int. Node Pointer Register 0000H CAN_AFCRL 20’0214H Node A Frame Counter Register Low 0000H CAN_AFCRH 20’0216H Node A Frame Counter Register High 0000H CAN_AIMRL0 20’0218H Node A INTID Mask Register 0 Low 0000H CAN_AIMRH0 20’021AH Node A INTID Mask Register 0 High 0000H CAN_AIMR4 20’021CH Node A INTID Mask Register 4 0000H CAN_AECNTL 20’0220H Node A Error Counter Register Low 0000H CAN_AECNTH 20’0222H Node A Error Counter Register High 0060H CAN_BCR 20’0240H Node B Control Register 0001H CAN_BSR 20’0244H Node B Status Register 0000H CAN_BIR 20’0248H Node B Interrupt Pending Register 0000H CAN_BBTRL 20’024CH Node B Bit Timing Register Low 0000H CAN_BBTRH 20’024EH Node B Bit Timing Register High 0000H CAN_BGINP 20’0250H Node B Global Int. Node Pointer Register 0000H CAN_BFCRL 20’0254H Node B Frame Counter Register Low 0000H CAN_BFCRH 20’0256H Node B Frame Counter Register High 0000H CAN_BIMRL0 20’0258H Node B INTID Mask Register 0 Low 0000H CAN_BIMRH0 20’025AH Node B INTID Mask Register 0 High 0000H CAN_BIMR4 20’025CH Node B INTID Mask Register 4 0000H TwinCAN User’s Manual RegSet_X41, V2.0 22-15 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-2 LXBUS Register Listing (cont’d) Short Name Physical Address Description Reset Value CAN_BECNTL 20’0260H Node B Error Counter Register Low 0000H CAN_BECNTH 20’0262H Node B Error Counter Register High 0060H CAN_RXIPNDL 20’0284H Receive Interrupt Pending Register Low 0000H CAN_RXIPNDH 20’0286H Receive Interrupt Pending Register High 0000H CAN_TXIPNDL 20’0288H Transmit Interrupt Pending Register Low 0000H CAN_TXIPNDH 20’028AH Transmit Interrupt Pending Register High 0000H CAN_0IC 00’F196H1) TwinCAN Interrupt Control Register 0 0000H CAN_1IC 00’F142H1) TwinCAN Interrupt Control Register 1 0000H CAN_2IC 00’F144H1) TwinCAN Interrupt Control Register 2 0000H CAN_3IC 00’F146H1) TwinCAN Interrupt Control Register 3 0000H CAN_4IC 00’F148H1) TwinCAN Interrupt Control Register 4 0000H CAN_5IC 00’F14AH1) TwinCAN Interrupt Control Register 5 0000H CAN_6IC 1) TwinCAN Interrupt Control Register 6 0000H 1) TwinCAN Interrupt Control Register 7 0000H Interrupt Control 00’F14CH CAN_7IC 00’F14EH 1) This register is located in the ESFR area. The base address of each Message Object n, where n = 0-31, is listed in Table 22-3. The offset address of each register in Message Object n is given in Table 22-4. Table 22-3 Base Address of Message Objects Message Object Number Base Address Message Object 0 20’0300H Message Object 1 20’0320H Message Object 2 20’0340H Message Object 3 20’0360H Message Object 4 20’0380H Message Object 5 20’03A0H Message Object 6 20’03C0H Message Object 7 20’03E0H Message Object 8 20’0400H User’s Manual RegSet_X41, V2.0 22-16 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-3 Base Address of Message Objects (cont’d) Message Object Number Base Address Message Object 9 20’0420H Message Object 10 20’0440H Message Object 11 20’0460H Message Object 12 20’0480H Message Object 13 20’04A0H Message Object 14 20’04C0H Message Object 15 20’04E0H Message Object 16 20’0500H Message Object 17 20’0520H Message Object 18 20’0540H Message Object 19 20’0560H Message Object 20 20’0580H Message Object 21 20’05A0H Message Object 22 20’05C0H Message Object 23 20’05E0H Message Object 24 20’0600H Message Object 25 20’0620H Message Object 26 20’0640H Message Object 27 20’0660H Message Object 28 20’0680H Message Object 29 20’06A0H Message Object 30 20’06C0H Message Object 31 20’06E0H User’s Manual RegSet_X41, V2.0 22-17 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Register Set Table 22-4 Offset Address of Message Object Registers Short Name Offset Address Description Reset Value CAN_ MSGDRLn0 00H Message Object n Data Register 0 Low 0000H CAN_ MSGDRHn0 02H Message Object n Data Register 0 High 0000H CAN_ MSGDRLn4 04H Message Object n Data Register 4 Low 0000H CAN_ MSGDRHn4 06H Message Object n Data Register 4 High 0000H CAN_ MSGARLn 08H Message Object n Arbitration Register Low 0000H CAN_ MSGARHn 0AH Message Object n Arbitration Register High 0000H CAN_ MSGAMRLn 0CH Message Object n Acceptance Mask Register Low 0000H CAN_ MSGAMRHn 0EH Message Object n Acceptance Mask Register High 0000H CAN_ MSGCTRLn 10H Message Object n Control Register Low 0000H CAN_ MSGCTRHn 12H Message Object n Control Register High 0000H CAN_ MSGCFGLn 14H Message Object n Configuration Register Low 0000H CAN_ MSGCFGHn 16H Message Object n Configuration Register High 0000H CAN_ MSGFGCRLn 18H Message Object n FIFO/Gateway Control 0000H Register Low CAN_ MSGFGCRHn 1AH Message Object n FIFO/Gateway Control 0000H Register High Note: n = 0 to 31 User’s Manual RegSet_X41, V2.0 22-18 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Keyword Index Keyword Index This section lists a number of keywords which refer to specific details of the XC164 in terms of its architecture, its functional units or functions. This helps to quickly find the answer to specific questions about the XC164. This User’s Manual consists of two Volumes, “System Units” and “Peripheral Units”. For your convenience this keyword index (and also the table of contents) refers to both volumes, so you can immediately find the reference to the desired section in the corresponding document ([1] or [2]). A BG 19-22 [2] RBUF 19-12 [2], 19-20 [2] TBUF 19-9 [2], 19-20 [2] Transmit FIFO 19-9 [2] ASCx_BG 19-42 [2] ASCx_CON 19-40 [2] ASCx_FDV 19-43 [2] Auto Scan conversion 16-12 [2] Autobaud Detection 19-27 [2] Acronyms 1-9 [1] Adapt Mode 6-21 [1] ADC 2-22 [1], 16-1 [2] ADC_CIC, ADC_EIC 16-21 [2] ADC_CON 16-3 [2] ADC_CON1 16-4 [2] ADC_CTR0 16-5 [2] ADC_CTR2 16-7 [2] ADC_CTR2IN 16-7 [2] Address Boundaries 3-15 [1] Mapping 3-3 [1] Segment 6-19 [1] Addressing Modes CoREG Addressing Mode 4-51 [1] DSP Addressing Modes 4-47 [1] Indirect Addressing Modes 4-45 [1] Long Addressing Modes 4-41 [1] Short Addressing Modes 4-39 [1] Alternate Port Functions 7-8 [1] ALU 4-58 [1] Analog/Digital Converter 16-1 [2] Arbitration of conversions 16-16 [2] ASC 19-1 [2] ASCx_EIC, ASCx_RIC 19-35 [2] ASCx_TIC, ASCx_TBIC 19-35 [2] Autobaud Detection 19-27 [2] Error Detection 19-34 [2] Features and Functions 19-1 [2] IrDA Frames 19-8 [2] Register User’s Manual B BANKSELx 5-33 [1] Baudrate ASC0 19-22 [2] Bootstrap Loader 10-5 [1] CAN 21-56 [2] Bit Handling 4-61 [1] Manipulation Instructions 12-2 [1] protected 2-32 [1], 4-62 [1] reserved 2-16 [1] Block Diagram ITC / PEC 5-3 [1] Bootstrap Loader 6-21 [1], 10-1 [1] Boundaries 3-15 [1] Bus ASC 19-1 [2] CAN 2-25 [1] Mode Configuration 6-20 [1] SSC 20-1 [2] C Calibration 16-17 [2] i-1 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Keyword Index CCU6xIC 18-79 [2] CCxIC 17-34 [2] Chip Select Configuration 6-19 [1] Clock generation 2-29 [1] generator modes 6-18 [1] output signal 6-38 [1] CMPMODIF 18-46 [2] CMPSTAT 18-45 [2] Command sequences (Flash) 3-19 [1] (ROM) 3-39 [1] Concatenation of Timers 14-22 [2], 14-45 [2] Configuration Address 6-19 [1] Bus Mode 6-20 [1] Chip Select 6-19 [1] default 6-23 [1] PLL 6-18 [1] Reset 6-14 [1] Reset Output 6-22 [1] special modes 6-21 [1] Write Control 6-20 [1] Context Pointer Updating 4-34 [1] Switch 4-33 [1] Switching 5-32 [1] Conversion analog/digital 16-1 [2] Arbitration 16-16 [2] Auto Scan 16-12 [2] timing control 16-18 [2] Count direction 14-6 [2], 14-35 [2] Counter 14-20 [2], 14-43 [2] Counter Mode (GPT1) 14-10 [2], 14-39 [2] CP 4-36 [1] CPU 2-2 [1], 4-1 [1] CPUCON1 4-26 [1] CPUCON2 4-27 [1] CRIC 14-55 [2] CSP 4-38 [1] CAN acceptance filtering 21-16 [2] analysing mode 21-7 [2] arbitration 21-16 [2] baudrate 21-56 [2] bit timing 21-9 [2], 21-56 [2] bus off recovery sequence 21-4 [2] status bit 21-51 [2] CAN siehe TwinCAN 21-1 [2] error counters 21-55 [2] error handling 21-11 [2] error warning level 21-55 [2] frame counter/time stamp 21-55 [2], 21-58 [2] Interface 2-25 [1] single data transfer 21-23 [2] CAPCOM 2-18 [1] CAPCOM12 2-16 [1] Capture Mode 17-13 [2] Counter Mode 17-8 [2] CAPREL 14-54 [2] Capture Mode GPT1 14-26 [2] GPT2 (CAPREL) 14-46 [2] Capture/Compare Registers 17-10 [2] CC1_DRM, CC2_DRM 17-23 [2] CC1_IOC, CC2_IOC 17-29 [2] CC1_M0-3 17-10 [2] CC1_OUT, CC2_OUT 17-25 [2] CC1_SEE, CC2_SEE 17-28 [2] CC1_SEM, CC2_SEM 17-27 [2] CC1_T01CON 17-5 [2] CC1_T0IC 17-9 [2] CC1_T1IC 17-9 [2] CC2_M4-7 17-11 [2] CC2_T78CON 17-5 [2] CC2_T7IC 17-9 [2] CC2_T8IC 17-9 [2] CC63R 18-40 [2] CC63SR 18-40 [2] CC6xR 18-18 [2] CC6XSR 18-19 [2] User’s Manual i-2 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Keyword Index D EXISEL0 5-38 [1] EXISEL1 5-38 [1] External Bus 2-13 [1] Fast interrupts 5-37 [1] Interrupt pulses 5-40 [1] Interrupt source control 5-37 [1] Interrupts 5-35 [1] Interrupts during sleep mode 5-39 [1] Data Management Unit (Introduction) 2-9 [1] Data Page 4-42 [1] boundaries 3-15 [1] Data SRAM 3-9 [1] Default startup configuration 6-23 [1] Development Support 1-8 [1] Direction count 14-6 [2], 14-35 [2] Disable Interrupt 5-29 [1] Division 4-63 [1] Double-Register Compare 17-22 [2] DP0L, DP0H 7-10 [1] DP1L, DP1H 7-14 [1] DP20 7-60 [1] DP3 7-25 [1] DP4 7-38 [1], 21-85 [2] DP9 7-51 [1], 21-87 [2] DPP 4-42 [1] Driver characteristic (ports) 7-4 [1] DSTPx 5-23 [1] Dual-Port RAM 3-9 [1] F Fast external interrupts 5-37 [1] FINT0ADDR 5-16 [1] FINT0CSP 5-17 [1] FINT1ADDR 5-16 [1] FINT1CSP 5-17 [1] Flags 4-57 [1]–4-60 [1] Flash command sequences 3-19 [1] memory 3-11 [1] memory mapping 3-16 [1] waitstates 3-43 [1] FOCON 6-39 [1] Frequency output signal 6-38 [1] FSR 3-32 [1] E EBC Bus Signals 9-3 [1] Memory Table 9-23 [1] EBCMOD0 9-12 [1] Edge characteristic (ports) 7-5 [1] EMUCON 6-47 [1] Enable Interrupt 5-29 [1] End of PEC Interrupt Sub Node 5-28 [1] EOPIC 5-27 [1] Erase command (Flash) 3-21 [1] Error correction 3-25 [1] Error Detection ASC 19-34 [2] SSC 20-14 [2] EXICON 5-37 [1] User’s Manual G Gated timer mode (GPT1) 14-9 [2] Gated timer mode (GPT2) 14-38 [2] GPR 3-6 [1] GPT 2-19 [1] GPT1 14-2 [2] GPT12E_CAPREL 14-54 [2] GPT12E_T2,-T3,-T4 14-29 [2] GPT12E_T2CON 14-15 [2] GPT12E_T2IC,-T3IC,-T4IC 14-30 [2] GPT12E_T3CON 14-4 [2] GPT12E_T4CON 14-15 [2] GPT12E_T5,-T6 14-54 [2] GPT12E_T5CON 14-40 [2] GPT12E_T5IC,-T6IC,-CRIC 14-55 [2] GPT12E_T6CON 14-33 [2] i-3 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Keyword Index Node Sharing 5-34 [1] Priority 5-7 [1] Processing 5-1 [1] RTC 15-12 [2] source control 5-37 [1] Sources 5-12 [1] System 2-8 [1], 5-2 [1] Vectors 5-12 [1] Interrupt Handling CAN transfer 21-6 [2] IP 4-38 [1] IrDA Frames ASC 19-8 [2] IS 18-72 [2] ISR 18-76 [2] ISS 18-75 [2] GPT2 14-31 [2] H Hardware Traps 5-43 [1] I IDCHIP 6-63 [1] Idle Mode 6-53 [1] IDMANUF 6-63 [1] IDMEM 6-64 [1] IDPROG 6-64 [1] IDX0, IDX1 4-47 [1] IEN 18-77 [2] IMB block diagram 3-40 [1] control functions 3-45 [1] memories address map 3-41 [1] wait states 3-45 [1] IMBCTR 3-45 [1] Incremental Interface Mode (GPT1) 14-11 [2] Indication of reset source 6-45 [1] INP 18-78 [2] Instruction 12-1 [1] Bit Manipulation 12-2 [1] Pipeline 4-11 [1] protected 12-6 [1] Interface ASC 19-1 [2] CAN 2-25 [1] External Bus 9-1 [1] SSC 20-1 [2] Interrupt Arbitration 5-4 [1] during sleep mode 5-39 [1] Enable/Disable 5-29 [1] External 5-35 [1] Fast external 5-37 [1] input timing 5-40 [1] Jump Table Cache 5-16 [1] Latency 5-41 [1] User’s Manual L Latency Interrupt, PEC 5-41 [1] LXBus 2-13 [1] M MAH, MAL 4-69 [1] MAR 3-26 [1] Margin check 3-25 [1] MCMCTR 18-60 [2] MCMOUT 18-58 [2] MCMOUTS 18-57 [2] MCW 4-66 [1] MDC 4-64 [1] MDH 4-63 [1] MDL 4-64 [1] Memory 2-10 [1] Areas (Data) 3-8 [1] Areas (Program) 3-10 [1] DPRAM 3-9 [1] DSRAM 3-9 [1] External 3-14 [1] Flash 3-11 [1] Program Flash 3-16 [1] Program ROM 3-37 [1] PSRAM 3-11 [1] MODCTR 18-49 [2] i-4 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Keyword Index Pipeline 4-11 [1] PLL 6-18 [1], 6-26 [1] PLL_IC 6-37 [1] PLLCON 6-31 [1] POCON* 7-6 [1] Port 2-27 [1] Ports Alternate Port Functions 7-8 [1] Driver characteristic 7-4 [1] Edge characteristic 7-5 [1] Power Management 2-29 [1], 6-53 [1] PROCON 3-28 [1] Program Management Unit (Introduction) 2-9 [1] Programming command (Flash) 3-21 [1] Protected Bits 2-32 [1], 4-62 [1] instruction 12-6 [1] Protection commands (Flash) 3-23 [1] features (Flash) 3-27 [1] features (ROM) 3-37 [1] PSLR 18-68 [2] PSW 4-57 [1] MRW 4-72 [1] MSW 4-70 [1] Multiplication 4-63 [1] N NMI 5-1 [1], 5-48 [1] Noise filter (Ext. Interrupts) 5-39 [1] O OCDS Requests 5-40 [1] ODP3 7-26 [1] ODP4 7-39 [1] ODP9 7-52 [1] ONES 4-74 [1] Open Drain Mode 7-3 [1] OPSEN 6-48 [1] Oscillator circuitry 6-27 [1] measurement 6-27 [1] Watchdog 6-22 [1], 6-37 [1] P P0L, P0H 7-9 [1] P1L, P1H 7-13 [1] P3 7-25 [1] P4 7-38 [1] P5 7-47 [1], 7-48 [1] P8 7-51 [1], 7-60 [1] PEC 2-10 [1], 5-18 [1] Latency 5-41 [1] Transfer Count 5-19 [1] PEC pointers 3-7 [1] PECCx 5-19 [1] PECISNC 5-27 [1] PECSEGx 5-23 [1] Peripheral Event Controller --> PEC 5-18 [1] Register Set 22-1 [2] Summary 2-14 [1] Phase Locked Loop (->PLL) 6-26 [1] PICON 7-2 [1] Pins 8-1 [1] User’s Manual Q QR0 4-46 [1] QR1 4-46 [1] QX0, QX1 4-48 [1] R RAM data SRAM 3-9 [1] dual ported 3-9 [1] program/data 3-11 [1] status after reset 6-7 [1] Real Time Clock (->RTC) 2-21 [1], 15-1 [2] Register Areas 3-4 [1] Register map TwinCAN module 21-47 [2] Register Table LXBUS Peripherals 22-15 [2] PD+BUS Peripherals 22-1 [2] i-5 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Keyword Index SP 4-54 [1] Special operation modes (config.) 6-21 [1] SPSEG 4-54 [1] SRAM Data 3-9 [1] SRCPx 5-23 [1] SSC 20-1 [2] Baudrate generation 20-12 [2] Block diagram 20-3 [2] Continous transfer operation 20-12 [2] Error detection 20-14 [2] Full duplex operation 20-8 [2] General Operation 20-1 [2] Half duplex operation 20-11 [2] Interrupts 20-14 [2] SSCx_CON 20-4 [2], 20-5 [2] Stack 3-12 [1], 4-53 [1] Startup Configuration 6-14 [1] STKOV 4-56 [1] STKUN 4-56 [1] SYSCON0 6-42 [1] SYSCON1 6-43 [1] SYSCON3 6-57 [1] SYSSTAT 6-44 [1] RELH, RELL 15-9 [2] Reserved bits 2-16 [1] Reset 6-2 [1] Configuration 6-14 [1] Output 6-9 [1] Source indication 6-45 [1] Values 6-6 [1] ROM 3-37 [1] command sequences 3-39 [1] RSTCFG 6-16 [1] RSTCON 6-24 [1] RTC 2-21 [1], 15-1 [2] RTC_CON 15-5 [2] RTC_IC 15-13 [2] RTC_ISNC 15-13 [2] RTCH, RTCL 15-8 [2] S SCUSLC 6-51 [1] SCUSLS 6-50 [1] Security features (Flash) 3-27 [1] features (ROM) 3-37 [1] Segment Address 6-19 [1] boundaries 3-15 [1] Segmentation 4-37 [1] Self-calibration 16-17 [2] Serial Interface 2-23 [1], 2-24 [1] ASC 19-1 [2] Asynchronous 19-5 [2] CAN 2-25 [1] SSC 20-1 [2] Synchronous 19-19 [2] SFR 3-5 [1] Sharing Interrupt Nodes 5-34 [1] Sleep mode 6-55 [1] Software Traps 5-43 [1] Source Interrupt 5-12 [1] Reset 6-45 [1] User’s Manual T T0IC 17-9 [2] T12 18-6 [2] T12DTC 18-23 [2] T12MSEL 18-20 [2] T12PR 18-6 [2] T13 18-31 [2] T13PR 18-31 [2] T1IC 17-9 [2] T2, T3, T4 14-29 [2] T2CON 14-15 [2] T2IC, T3IC, T4IC 14-30 [2] T3CON 14-4 [2] T4CON 14-15 [2] T5, T6 14-54 [2] T5CON 14-40 [2] T5IC, T6IC 14-55 [2] T6CON 14-33 [2] i-6 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Keyword Index 21-5 [2] loop-back mode 21-44 [2] message handling 21-15 [2] FIFO 21-24 [2] gateway overview 21-28 [2] gateway+FIFO 21-33 [2] normal gateway 21-29 [2] shared gateway 21-36 [2] transfer control 21-41 [2] message interrupts 21-13 [2] message object configuration 21-71 [2] control bits 21-68 [2] interrupt indication 21-13 [2] interrupts 21-13 [2] register description 21-64 [2] transfer handling 21-17 [2] node control 21-7 [2] node interrupts 21-11 [2], 21-12 [2] node selection 21-71 [2] overview 21-1 [2] register map 21-47 [2] registers (global) receive interrupt pending 21-80 [2] transmit interrupt pending 21-81 [2] registers (message specific) acceptance mask 21-67 [2] arbitration (identifier) 21-66 [2] configuration 21-71 [2] control 21-68 [2] data 21-64 [2] registers (node specific) bit timing 21-56 [2] control 21-49 [2] error counter 21-55 [2] frame counter 21-58 [2] global interrupt node pointer 21-61 [2] interrupt pending 21-53 [2] INTID mask 21-62 [2] status 21-51 [2] single transmission 21-45 [2] single-shot mode 21-23 [2] T7IC 17-9 [2] T8IC 17-9 [2] TCTR0 18-41 [2] TCTR2 18-43 [2] TCTR4 18-44 [2] TFR 5-45 [1] Timer 14-2 [2], 14-31 [2] Auxiliary Timer 14-15 [2], 14-40 [2] Concatenation 14-22 [2], 14-45 [2] Core Timer 14-4 [2], 14-33 [2] Counter Mode (GPT1) 14-10 [2], 14-39 [2] Gated Mode (GPT1) 14-9 [2] Gated Mode (GPT2) 14-38 [2] Incremental Interface Mode (GPT1) 14-11 [2] Mode (GPT1) 14-8 [2] Mode (GPT2) 14-37 [2] Tools 1-8 [1] Transmit FIFO ASC 19-9 [2] Traps 5-43 [1] TRPCTR 18-63 [2] TwinCAN FIFO base object 21-24 [2] circular buffer 21-26 [2] configuration 21-73 [2] for CAN messages 21-24 [2] gateway control 21-73 [2] slave objects 21-26 [2] frames counter 21-8 [2] handling 21-17 [2] gateway configuration 21-73 [2] normal mode 21-29 [2] shared mode 21-36 [2] with FIFO 21-33 [2] initialization 21-40 [2] interrupts indication/INTID 21-13 [2], 21-53 [2] node pointer/request compressor User’s Manual i-7 V2.1, 2004-03 XC164-16 Derivatives Peripheral Units (Vol. 2 of 2) Keyword Index RXIPNDL 21-80 [2] TXIPNDH 21-81 [2] TXIPNDL 21-81 [2] transfer interrupts 21-6 [2] TwinCAN Registers (short names) ABTRH 21-56 [2] ABTRL 21-56 [2] ACR 21-49 [2] AECNTH 21-54 [2] AECNTL 21-54 [2] AFCRH 21-58 [2] AFCRL 21-58 [2] AGINP 21-61 [2] AIMR0H 21-62 [2] AIMR0L 21-62 [2] AIMR4 21-63 [2] AIR 21-53 [2] ASR 21-51 [2] BBTRH 21-56 [2] BBTRL 21-56 [2] BCR 21-49 [2] BECNTH 21-54 [2] BECNTL 21-54 [2] BFCRH 21-58 [2] BFCRL 21-58 [2] BGINP 21-61 [2] BIMR0H 21-62 [2] BIMR0L 21-62 [2] BIMR4 21-63 [2] BIR 21-53 [2] BSR 21-51 [2] MSGAMRHn 21-67 [2] MSGAMRLn 21-67 [2] MSGARHn 21-66 [2] MSGARLn 21-66 [2] MSGCFGHn 21-71 [2] MSGCFGLn 21-71 [2] MSGCTRHn 21-68 [2] MSGCTRLn 21-68 [2] MSGDRH0 21-64 [2] MSGDRH4 21-65 [2] MSGDRL0 21-64 [2] MSGDRL4 21-65 [2] MSGFGCRHn 21-74 [2] MSGFGCRLn 21-74 [2] RXIPNDH 21-80 [2] User’s Manual V VECSEG 5-11 [1] W Waitstates Flash 3-43 [1] Watchdog 2-26 [1], 6-58 [1] after reset 6-7 [1] Oscillator 6-22 [1], 6-37 [1] WDT 6-59 [1] WDTCON 6-61 [1] Z ZEROS 4-74 [1] i-8 V2.1, 2004-03 w w w . i n f i n e o n . c o m Published by Infineon Technologies AG