MC68HC08AS32A Data Sheet M68HC08 Microcontrollers Rev. 1.1 MC68HC08AS32A/D July 14, 2005 freescale.com MC68HC08AS32A Data Sheet To provide the most up-to-date information, the revision of our documents on the World Wide Web will be the most current. Your printed copy may be an earlier revision. To verify you have the latest information available, refer to: http://freescale.com/ The following revision history table summarizes changes contained in this document. For your convenience, the page number designators have been linked to the appropriate location. Motorola and the Stylized M Logo are registered trademarks of Motorola, Inc. DigitalDNA is a trademark of Motorola, Inc. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor © Motorola, Inc., 2003 Data Sheet 3 Revision History Date Revision Level February, 2003 N/A July, 2003 1 July, 2005 1.1 Data Sheet 4 Description Initial release Page Number(s) N/A Reformatted to meet new publications guidelines. Modules updated with additional data Throughout Updated to meet Freescale identity guidelines Throughout MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — List of Sections Section 1. General Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .19 Section 2. Memory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 Section 3. Analog-to-Digital Converter (ADC) . . . . . . . . . . . . . . . . . . . 53 Section 4. Byte Data Link Controller-Digital (BDLC-D) . . . . . . . . . . . . 63 Section 5. Clock Generator Module (CGM). . . . . . . . . . . . . . . . . . . . . . 97 Section 6. Computer Operating Properly (COP) . . . . . . . . . . . . . . . . 117 Section 7. Central Processor Unit (CPU) . . . . . . . . . . . . . . . . . . . . . . 121 Section 8. External Interrupt (IRQ) . . . . . . . . . . . . . . . . . . . . . . . . . . . 135 Section 9. Low-Voltage Inhibit (LVI) . . . . . . . . . . . . . . . . . . . . . . . . . . 141 Section 10. Mask Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 145 Section 11. Programmable Interrupt Timer (PIT) . . . . . . . . . . . . . . . . 149 Section 12. Input/Output (I/O) Ports . . . . . . . . . . . . . . . . . . . . . . . . . . 155 Section 13. Serial Communications Interface (SCI). . . . . . . . . . . . . . 171 Section 14. System Integration Module (SIM) . . . . . . . . . . . . . . . . . . 199 Section 15. Serial Peripheral Interface (SPI) . . . . . . . . . . . . . . . . . . . 215 Section 16. Timer Interface (TIM). . . . . . . . . . . . . . . . . . . . . . . . . . . . . 239 Section 17. Development Support. . . . . . . . . . . . . . . . . . . . . . . . . . . . 263 Section 18. Electrical Specifications. . . . . . . . . . . . . . . . . . . . . . . . . . 277 Section 19. Ordering Information and Mechanical Specifications. . 291 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 5 Data Sheet 6 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Table of Contents Section 1. General Description 1.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 1.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 1.3 MCU Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 1.4 Pin Assignments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.4.1 Power Supply Pins (VDD and VSS) . . . . . . . . . . . . . . . . . . . . . . . . . . 1.4.2 Oscillator Pins (OSC1 and OSC2) . . . . . . . . . . . . . . . . . . . . . . . . . . 1.4.3 External Reset Pin (RST) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.4.4 External Interrupt Pin (IRQ) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.4.5 Analog Power Supply Pin (VDDA/VDDAREF) . . . . . . . . . . . . . . . . . . . 1.4.6 ADC High Reference Pin (VREFH) . . . . . . . . . . . . . . . . . . . . . . . . . . 1.4.7 Analog Ground Pin (VSSA/VREFL) . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.4.8 External Filter Capacitor Pin (CGMXFC) . . . . . . . . . . . . . . . . . . . . . 1.4.9 Port A Input/Output (I/O) Pins (PTA7–PTA0) . . . . . . . . . . . . . . . . . . 1.4.10 Port B I/O Pins (PTB7/ATD7–PTB0/ATD0) . . . . . . . . . . . . . . . . . . . 1.4.11 Port C I/O Pins (PTC4–PTC0) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.4.12 Port D I/O Pins (PTD6/ATD14/TCLKA–PTD0/ATD8) . . . . . . . . . . . . 1.4.13 Port E I/O Pins (PTE7/SPSCK–PTE0/TxD) . . . . . . . . . . . . . . . . . . . 1.4.14 Port F I/O Pins (PTF3/TCH5–PTF0/TCH2) . . . . . . . . . . . . . . . . . . . 1.4.15 J1850 Transmit Pin Digital (BDTxD). . . . . . . . . . . . . . . . . . . . . . . . . 1.4.16 J1850 Receive Pin Digital (BDRxD) . . . . . . . . . . . . . . . . . . . . . . . . . 20 23 24 24 24 24 25 25 25 25 25 25 25 25 26 26 26 Section 2. Memory 2.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 2.2 Input/Output (I/O) Section. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 2.3 Random-Access Memory (RAM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 2.4 Read-Only Memory (ROM). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 2.5 Electrically Erasable Programmable ROM (EEPROM) . . . . . . . . . . . . . 2.5.1 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.5.1.1 EEPROM Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.5.1.2 EEPROM Timebase Requirements . . . . . . . . . . . . . . . . . . . . . . . 2.5.1.3 EEPROM Program/Erase Protection . . . . . . . . . . . . . . . . . . . . . . 2.5.1.4 EEPROM Block Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.5.1.5 EEPROM Programming and Erasing . . . . . . . . . . . . . . . . . . . . . . 2.5.1.6 Program/Erase Using AUTO Bit . . . . . . . . . . . . . . . . . . . . . . . . . . 2.5.1.7 EEPROM Programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.5.1.8 EEPROM Erasing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 40 41 41 41 42 42 43 44 44 45 Data Sheet 7 2.5.2 2.5.2.1 2.5.2.2 2.5.2.3 2.5.2.4 2.5.2.5 2.5.3 2.5.3.1 2.5.3.2 EEPROM Register Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . EEPROM Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . EEPROM Array Configuration Register . . . . . . . . . . . . . . . . . . . . EEPROM Non-Volatile Register . . . . . . . . . . . . . . . . . . . . . . . . . . EEPROM Timebase Divider Register . . . . . . . . . . . . . . . . . . . . . . EEPROM Timebase Divider Non-Volatile Register. . . . . . . . . . . . Low-Power Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Wait Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Stop Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46 46 48 49 50 51 52 52 52 Section 3. Analog-to-Digital Converter (ADC) 3.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53 3.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53 3.3 3.3.1 3.3.2 3.3.3 3.3.4 3.3.5 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ADC Port I/O Pins. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Voltage Conversion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Conversion Time. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Continuous Conversion Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Accuracy and Precision . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.4 Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56 3.5 3.5.1 3.5.2 Low-Power Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56 Wait Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56 Stop Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57 3.6 3.6.1 3.6.3 I/O Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ADC Analog Power Pin (VDDA/VDDAREF)/ADC Voltage Reference Pin (VREFH) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ADC Analog Ground Pin (VSSA)/ADC Voltage Reference Low Pin (VREFL) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ADC Voltage In (ADCVIN) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.7 3.7.1 3.7.2 3.7.3 I/O Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ADC Status and Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . ADC Data Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ADC Input Clock Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.6.2 53 53 55 55 56 56 57 57 57 57 57 58 60 60 Section 4. Byte Data Link Controller-Digital (BDLC-D) 4.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63 4.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63 4.3 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3.1 BDLC Operating Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3.1.1 Power Off Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3.1.2 Reset Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3.1.3 Run Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.3.1.4 BDLC Wait Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Data Sheet 8 63 66 66 66 67 67 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 4.3.1.5 4.3.1.6 4.3.1.7 BDLC Stop Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67 Digital Loopback Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67 Analog Loopback Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68 4.4 BDLC MUX Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.4.1 Rx Digital Filter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.4.1.1 Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.4.1.2 Performance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.4.2 J1850 Frame Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.4.3 J1850 VPW Symbols . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.4.4 J1850 VPW Valid/Invalid Bits and Symbols . . . . . . . . . . . . . . . . . . . 4.4.5 Message Arbitration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68 69 69 70 70 73 75 78 4.5 BDLC Protocol Handler . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.1 Protocol Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.2 Rx and Tx Shift Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.3 Rx and Tx Shadow Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.4 Digital Loopback Multiplexer. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.5 State Machine. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.5.1 4X Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.5.2 Receiving a Message in Block Mode . . . . . . . . . . . . . . . . . . . . . . 4.5.5.3 Transmitting a Message in Block Mode . . . . . . . . . . . . . . . . . . . . 4.5.5.4 J1850 Bus Errors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.5.5 Summary. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79 80 80 80 81 81 81 82 82 82 83 4.6 4.6.1 4.6.2 4.6.3 4.6.4 4.6.5 BDLC CPU Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . BDLC Analog and Roundtrip Delay Register . . . . . . . . . . . . . . . . . . BDLC Control Register 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . BDLC Control Register 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . BDLC State Vector Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . BDLC Data Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84 84 86 88 93 95 4.7 4.7.1 4.7.2 Low-Power Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96 Wait Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96 Stop Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96 Section 5. Clock Generator Module (CGM) 5.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 5.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 5.3 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 5.3.1 Crystal Oscillator Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99 5.3.2 Phase-Locked Loop Circuit (PLL). . . . . . . . . . . . . . . . . . . . . . . . . . . 99 5.3.2.1 Circuits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100 5.3.2.2 Acquisition and Tracking Modes . . . . . . . . . . . . . . . . . . . . . . . . . 101 5.3.2.3 Automatic and Manual PLL Bandwidth Modes . . . . . . . . . . . . . . 101 5.3.2.4 Programming the PLL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102 5.3.2.5 Special Programming Exceptions . . . . . . . . . . . . . . . . . . . . . . . . 104 5.3.3 Base Clock Selector Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104 5.3.4 CGM External Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 9 5.4 5.4.1 5.4.2 5.4.3 5.4.4 5.4.5 5.4.6 5.4.7 5.4.8 I/O Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Crystal Amplifier Input Pin (OSC1) . . . . . . . . . . . . . . . . . . . . . . . . . Crystal Amplifier Output Pin (OSC2) . . . . . . . . . . . . . . . . . . . . . . . External Filter Capacitor Pin (CGMXFC) . . . . . . . . . . . . . . . . . . . . Analog Power Pin (VDDA/VDDAREF) . . . . . . . . . . . . . . . . . . . . . . . . Oscillator Enable Signal (SIMOSCEN) . . . . . . . . . . . . . . . . . . . . . . Crystal Output Frequency Signal (CGMXCLK). . . . . . . . . . . . . . . . CGM Base Clock Output (CGMOUT) . . . . . . . . . . . . . . . . . . . . . . . CGM CPU Interrupt (CGMINT). . . . . . . . . . . . . . . . . . . . . . . . . . . . 106 106 106 106 106 106 106 106 107 5.5 5.5.1 5.5.2 5.5.3 CGM Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PLL Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PLL Bandwidth Control Register. . . . . . . . . . . . . . . . . . . . . . . . . . . PLL Programming Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107 107 108 109 5.6 Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111 5.7 5.7.1 5.7.2 Special Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111 Wait Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111 Stop Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111 5.8 CGM During Break Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 112 5.9 5.9.1 5.9.2 5.9.3 5.9.4 Acquisition/Lock Time Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . Acquisition/Lock Time Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . Parametric Influences on Reaction Time . . . . . . . . . . . . . . . . . . . . Choosing a Filter Capacitor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Reaction Time Calculation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 112 112 113 114 114 Section 6. Computer Operating Properly (COP) Data Sheet 10 6.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117 6.2 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117 6.3 6.3.1 6.3.2 6.3.3 6.3.4 6.3.5 6.3.6 6.3.7 I/O Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . CGMXCLK . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . STOP Instruction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . COPCTL Write . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Internal Reset Resources . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Reset Vector Fetch . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . COPD (COP Disable) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . COPS (COP Short Timeout). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.4 COP Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119 6.5 Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119 6.6 Monitor Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120 6.7 6.7.1 6.7.2 Low-Power Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120 Wait Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120 Stop Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120 6.8 COP Module During Break Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . 120 118 118 118 119 119 119 119 119 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Section 7. Central Processor Unit (CPU) 7.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121 7.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121 7.3 7.3.1 7.3.2 7.3.3 7.3.4 7.3.5 CPU Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Accumulator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Index Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Stack Pointer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Program Counter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Condition Code Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.4 Arithmetic/Logic Unit (ALU) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126 7.5 7.5.1 7.5.2 Low-Power Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126 Wait Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126 Stop Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126 7.6 CPU During Break Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126 7.7 Instruction Set Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 127 7.8 Opcode Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 133 122 122 123 123 124 124 Section 8. External Interrupt (IRQ) 8.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 135 8.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 135 8.3 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 135 8.4 IRQ Pin . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 139 8.5 IRQ Module During Break Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . 139 8.6 IRQ Status and Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 140 Section 9. Low-Voltage Inhibit (LVI) 9.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 141 9.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 141 9.3 9.3.1 9.3.2 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 141 Polled LVI Operation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 141 Forced Reset Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 141 9.4 LVI Status Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 142 9.5 LVI Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 142 9.6 9.6.1 9.6.2 Low-Power Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 143 Wait Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 143 Stop Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 143 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 11 Section 10. Mask Options 10.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 145 10.2 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 145 10.3 Mask Option Registers (MORA and MORB) . . . . . . . . . . . . . . . . . . . . 146 Section 11. Programmable Interrupt Timer (PIT) 11.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 149 11.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 149 11.3 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 149 11.4 PIT Counter Prescaler . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150 11.5 Low-Power Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150 11.5.1 Wait Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150 11.5.2 Stop Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 151 11.6 PIT During Break Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 151 11.7 I/O Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.7.1 PIT Status and Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.7.2 PIT Counter Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.7.3 PIT Counter Modulo Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . 151 151 153 154 Section 12. Input/Output (I/O) Ports 12.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155 12.2 Port A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 156 12.2.1 Port A Data Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 156 12.2.2 Data Direction Register A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 157 12.3 Port B . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 158 12.3.1 Port B Data Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 158 12.3.2 Data Direction Register B . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 159 12.4 Port C . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 160 12.4.1 Port C Data Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 160 12.4.2 Data Direction Register C . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 161 12.5 Port D . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 162 12.5.1 Port D Data Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 162 12.5.2 Data Direction Register D . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 163 12.6 Port E . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 165 12.6.1 Port E Data Register. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 165 12.6.2 Data Direction Register E . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 166 12.7 Port F . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 168 12.7.1 Port F Data Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 168 12.7.2 Data Direction Register F . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 169 Data Sheet 12 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Section 13. Serial Communications Interface (SCI) 13.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 171 13.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 171 13.3 Pin Name Conventions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 173 13.4 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.1 Data Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.2 Transmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.2.1 Character Length . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.2.2 Character Transmission . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.2.3 Break Characters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.2.4 Idle Characters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.2.5 Inversion of Transmitted Output . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.2.6 Transmitter Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.3 Receiver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.3.1 Character Length . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.3.2 Character Reception . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.3.3 Data Sampling. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.3.4 Framing Errors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.3.5 Baud Rate Tolerance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.3.6 Receiver Wakeup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.3.7 Receiver Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.4.3.8 Error Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 173 173 175 175 176 177 177 178 178 178 178 180 180 182 182 184 185 185 13.5 Low-Power Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 185 13.5.1 Wait Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 185 13.5.2 Stop Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 186 13.6 SCI During Break Module Interrupts. . . . . . . . . . . . . . . . . . . . . . . . . . . 186 13.7 I/O Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 186 13.7.1 PTE0/TxD (Transmit Data) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 186 13.7.2 PTE1/RxD (Receive Data) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 186 13.8 I/O Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.8.1 SCI Control Register 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.8.2 SCI Control Register 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.8.3 SCI Control Register 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.8.4 SCI Status Register 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.8.5 SCI Status Register 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.8.6 SCI Data Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.8.7 SCI Baud Rate Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 187 187 189 191 192 195 196 196 Section 14. System Integration Module (SIM) 14.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 199 14.2 SIM Bus Clock Control and Generation . . . . . . . . . . . . . . . . . . . . . . . . 14.2.1 Bus Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.2.2 Clock Startup from POR or LVI Reset . . . . . . . . . . . . . . . . . . . . . . 14.2.3 Clocks in Stop Mode and Wait Mode . . . . . . . . . . . . . . . . . . . . . . . MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 202 202 202 202 Data Sheet 13 14.3 Reset and System Initialization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.3.1 External Pin Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.3.2 Active Resets from Internal Sources . . . . . . . . . . . . . . . . . . . . . . . 14.3.2.1 Power-On Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.3.2.2 Computer Operating Properly (COP) Reset . . . . . . . . . . . . . . . . 14.3.2.3 Illegal Opcode Reset. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.3.2.4 Illegal Address Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.3.2.5 Low-Voltage Inhibit (LVI) Reset . . . . . . . . . . . . . . . . . . . . . . . . . 203 203 203 204 205 205 205 205 14.4 SIM Counter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.4.1 SIM Counter During Power-On Reset . . . . . . . . . . . . . . . . . . . . . . 14.4.2 SIM Counter During Stop Mode Recovery . . . . . . . . . . . . . . . . . . . 14.4.3 SIM Counter and Reset States . . . . . . . . . . . . . . . . . . . . . . . . . . . . 206 206 206 206 14.5 Program Exception Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.5.1 Interrupts. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.5.1.1 Hardware Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.5.1.2 SWI Instruction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.5.2 Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.5.3 Break Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.5.4 Status Flag Protection in Break Mode . . . . . . . . . . . . . . . . . . . . . . 206 207 209 209 210 210 210 14.6 Low-Power Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 210 14.6.1 Wait Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 210 14.6.2 Stop Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 212 14.7 SIM Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.7.1 SIM Break Status Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.7.2 SIM Reset Status Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.7.3 SIM Break Flag Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . 213 213 213 214 Section 15. Serial Peripheral Interface (SPI) 15.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 215 15.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 215 15.3 Pin Name and Register Name Conventions . . . . . . . . . . . . . . . . . . . . . 215 15.4 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 217 15.4.1 Master Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 219 15.4.2 Slave Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 219 15.5 Transmission Formats . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.5.1 Clock Phase and Polarity Controls . . . . . . . . . . . . . . . . . . . . . . . . . 15.5.2 Transmission Format When CPHA = 0. . . . . . . . . . . . . . . . . . . . . . 15.5.3 Transmission Format When CPHA = 1. . . . . . . . . . . . . . . . . . . . . . 15.5.4 Transmission Initiation Latency . . . . . . . . . . . . . . . . . . . . . . . . . . . 220 220 221 222 223 15.6 Error Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 225 15.6.1 Overflow Error. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 225 15.6.2 Mode Fault Error. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 226 15.7 Data Sheet 14 Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 228 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 15.8 Queuing Transmission Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 228 15.9 Resetting the SPI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 230 15.10 Low-Power Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 230 15.10.1 Wait Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 230 15.10.2 Stop Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 231 15.11 SPI During Break Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 231 15.12 I/O Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.12.1 MISO (Master In/Slave Out) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.12.2 MOSI (Master Out/Slave In) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.12.3 SPSCK (Serial Clock) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.12.4 SS (Slave Select) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.12.5 VSS (Clock Ground) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 231 232 232 232 232 233 15.13 I/O Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.13.1 SPI Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.13.2 SPI Status and Control Register. . . . . . . . . . . . . . . . . . . . . . . . . . . 15.13.3 SPI Data Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 234 234 236 238 Section 16. Timer Interface (TIM) 16.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 239 16.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 239 16.3 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.3.1 TIM Counter Prescaler . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.3.2 Input Capture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.3.3 Output Compare . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.3.3.1 Unbuffered Output Compare. . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.3.3.2 Buffered Output Compare . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.3.4 Pulse Width Modulation (PWM) . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.3.4.1 Unbuffered PWM Signal Generation. . . . . . . . . . . . . . . . . . . . . . 16.3.4.2 Buffered PWM Signal Generation . . . . . . . . . . . . . . . . . . . . . . . . 16.3.4.3 PWM Initialization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.4 239 244 244 245 245 245 246 247 248 249 Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 250 16.5 Low-Power Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 251 16.5.1 Wait Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 251 16.5.2 Stop Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 251 16.6 TIM During Break Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 251 16.7 I/O Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 251 16.7.1 TIM Clock Pin (PTD6/ATD14/TCLK) . . . . . . . . . . . . . . . . . . . . . . . 252 16.7.2 TIM Channel I/O Pins (PTF3/TCH5–PTF0/TCH2 and PTE3/TCH1–PTE2/TCH0) . . . . . . . . . . . . . . . . . . . . . . . . . 252 16.8 I/O Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.8.1 TIM Status and Control Register . . . . . . . . . . . . . . . . . . . . . . . . . . 16.8.2 TIM Counter Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.8.3 TIM Counter Modulo Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 252 252 254 255 Data Sheet 15 16.8.4 16.8.5 TIM Channel Status and Control Registers . . . . . . . . . . . . . . . . . . 255 TIM Channel Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 259 Section 17. Development Support 17.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 263 17.2 Break Module (BRK). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.1 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.1.1 Flag Protection During Break Interrupts . . . . . . . . . . . . . . . . . . . 17.2.1.2 TIM During Break Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.1.3 COP During Break Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.2 Break Module Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.2.1 Break Status and Control Register . . . . . . . . . . . . . . . . . . . . . . . 17.2.2.2 Break Address Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.3 Low-Power Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 263 263 265 265 265 265 266 266 267 17.3 Monitor Module (MON) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.3.1 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.3.1.1 Monitor Mode Entry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.3.1.2 Monitor Vectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.3.1.3 Data Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.3.1.4 Break Signal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.3.1.5 Commands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.3.2 Security. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.3.3 Baud Rate. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 267 267 267 271 271 271 272 275 276 Section 18. Electrical Specifications 18.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 277 18.2 Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 277 18.3 Functional Operating Range. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 278 18.4 Thermal Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 278 18.5 5.0-Volt DC Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . 279 18.6 Control Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 280 18.7 ADC Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 281 18.8 5.0-Vdc ± 10% Serial Peripheral Interface (SPI) Timing. . . . . . . . . . . . 282 18.9 CGM Operating Conditions 18.10 CGM Component Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 285 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 285 18.11 CGM Acquisition/Lock Time Information . . . . . . . . . . . . . . . . . . . . . . 286 18.12 Timer Module Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 287 18.13 RAM Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 287 18.14 BDLC Transmitter VPW Symbol Timings . . . . . . . . . . . . . . . . . . . . . . . 288 18.15 BDLC Receiver VPW Symbol Timings . . . . . . . . . . . . . . . . . . . . . . . . . 288 18.16 BDLC Transmitter DC Electrical Characteristics . . . . . . . . . . . . . . . . . 289 Data Sheet 16 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 18.17 BDLC Receiver DC Electrical Characteristics . . . . . . . . . . . . . . . . . . . 289 18.18 EEPROM Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 290 Section 19. Ordering Information and Mechanical Specifications 19.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 291 19.2 MC Order Numbers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 291 19.3 52-Pin Plastic Leaded Chip Carrier Package (Case 778). . . . . . . . . . . 292 19.4 64-Pin Quad Flat Pack (Case 840B) . . . . . . . . . . . . . . . . . . . . . . . . . . 293 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 17 Data Sheet 18 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 1. General Description 1.1 Introduction The MC68HC08AS32A — is a member of the low-cost, high-performance M68HC08 Family of 8-bit microcontroller units (MCUs). The M68HC08 Family is based on the customer-specified integrated circuit (CSIC) design strategy. All MCUs in the family use the enhanced M68HC08 central processor unit (CPU08) and are available with a variety of modules, memory sizes and types, and package types. 1.2 Features Features of the MC68HC08AS32A — include: MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor • High-performance M68HC08 architecture • Fully upward-compatible object code with M6805, M146805, and M68HC05 Families • 8.4-MHz internal bus frequency • 32,256 bytes of read-only memory (ROM) • ROM data security • 512 bytes of on-chip electrically erasable programmable read-only memory (EEPROM) • 1024 bytes of on-chip random-access memory (RAM) • Serial peripheral interface module (SPI) • Serial communications interface module (SCI) • 16-bit, 6-channel timer interface module (TIM) • Clock generator module (CGM) • 8-bit, 15-channel analog-to-digital converter module (ADC) • SAE J1850 byte data link controller digital module (BDLC-D) • System protection features: – Computer operating properly (COP) with optional reset – Low-voltage detection with optional reset – Illegal opcode detection with optional reset – Illegal address detection with optional reset • Low-power design (fully static with stop and wait modes) Data Sheet 19 • Master reset pin and power-on reset Features of the CPU08 include: • Enhanced HC05 programming model • Extensive loop control functions • 16 addressing modes (eight more than the HC05) • 16-bit index register and stack pointer • Memory-to-memory data transfers • Fast 8 × 8 multiply instruction • Fast 16/8 divide instruction • Binary-coded decimal (BCD) instructions • Optimization for controller applications • C language support 1.3 MCU Block Diagram Figure 1-1 shows the structure of the MC68HC08AS32A —. 1.4 Pin Assignments The MC68HC08AS32A is available in a 52-pin plastic leaded chip carrier (PLCC) and a 64-pin quad flat pack (QFP). Figure 1-2 and Figure 1-3 show the pin assignments for these packages. Data Sheet 20 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor CONTROL AND STATUS REGISTERS — 69 BYTES BREAK MODULE DDRA PTA PTB ANALOG-TO-DIGITAL CONVERTER MODULE DDRB ARITHMETIC/LOGIC UNIT PTA7–PTA0 PTB7/ATD7–PTB0/ATD0 USER ROM — 32,256 BYTES PTC CPU REGISTERS VREFH DDRC MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor INTERNAL BUS M68HC08 CPU IRQ MODULE 21 Data Sheet VDDA/VDDAREF VSSA/VREFL PTF3/TCH5 PTF2/TCH4 PTF1/TCH3 PTF0/TCH2 SERIAL COMMUNICATIONS INTERFACE MODULE SERIAL PERIPHERAL INTERFACE MODULE BYTE DATA LINK CONTROLLER DIGITAL MODULE POWER-ON RESET MODULE VSS VDD PTE7/SPSCK PTE6/MOSI PTE5/MISO PTE4/SS PTE3/TCH1 PTE2/TCH0 PTE1/RxD PTE0/TxD PTF IRQ SYSTEM INTEGRATION MODULE PTD RST CLOCK GENERATOR MODULE PTD5/ATD13–PTD0/ATD8 PTE OSC1 OSC2 CGMXFC PROGRAMMABLE INTERRUPT TIMER MODULE DDRE USER ROM VECTOR SPACE — 38 BYTES PTD6/ATD14/TCLK TIMER INTERFACE MODULE BDRxD BDTxD POWER Figure 1-1. Block Diagram DDRF MONITOR ROM — 224 BYTES DDRD USER EEPROM — 512 BYTES USER RAM — 1024 BYTES PTC2/MCLK PTC1–PTC0 LOW-VOLTAGE INHIBIT MODULE COMPUTER OPERATING PROPERLY MODULE PTC4–PTC3 PTD5/ATD13 48 8 PTD4/ATD12 PTD6/ATD14/TCLK 49 47 VREFH 50 OSC2 2 VDDA/VDDAREF OSC1 3 51 PTC0 4 VSSA/VREFL PTC1 5 52 PTC2/MCLK 6 CGMXFC PTC3 7 1 PTC4 46 PTD3/ATD11 IRQ 9 45 PTD2/ATD10 RST 10 44 PTD1/ATD9 PTF0/TCH2 11 43 PTD0/ATD8 PTF1/TCH3 12 42 PTB7/ATD7 PTF2/TCH4 13 41 PTB6/ATD6 PTF3/TCH5 14 40 PTB5/ATD5 BDRxD 15 39 PTB4/ATD4 BDTxD 16 38 PTB3/ATD3 PTE0/TxD 17 37 PTB2/ATD2 PTE1/RxD 18 36 PTB1/ATD1 PTE2/TCH0 19 35 PTB0/ATD0 34 21 22 23 24 25 26 27 28 29 30 31 32 33 PTE5/MISO PTE6/MOSI PTE7/SPSCK VSS VDD PTA0 PTA1 PTA2 PTA3 PTA4 PTA5 PTA6 20 PTE4/SS PTE3/TCH1 PTA7 Figure 1-2. 52-Pin PLCC Assignments (Top View) Data Sheet 22 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor PTC2/MCLK PTC1 PTC0 OSC1 OSC2 CGMXFC VSSA VDDA VREFH NC PTD6/ATD14/TCLK PTD5 /ATD13 PTD4/ ATD12 62 61 60 59 58 57 56 55 54 53 52 51 50 1 49 NC PTC3 63 NC 64 PTC4 48 NC BDRxD 9 40 PTB6/ATD6 BDTxD 10 39 PTB5/ATD5 NC 11 38 PTB4/ATD4 NC 12 37 PTB3/ATD3 PTE0/TxD 13 36 PTB2/ATD2 PTE1/RxD 14 35 PTB1/ATD1 PTE2/TCH0 15 34 PTB0/ATD0 33 PTA7 PTA6 32 16 PTE4/SS 17 PTE3/TCH1 31 PTB7/ATD7 PTA5 41 30 8 PTA4 NC 29 PTD0/ATD8 PTA3 42 28 7 PTA2 PTF3/TCH5 27 PTD1/ATD9 PTA1 43 26 6 PTA0 PTF2/TCH4 25 NC NC 44 24 5 NC PTF1/TCH3 23 NC NC 45 22 4 VDD PTF0/TCH2 21 PTD2/ATD10 VSS 46 20 3 PTE7/SPSCK RST 19 PTD3/ATD11 PTE6/MOSI 47 18 2 PTE5/MISO IRQ Figure 1-3. 64-Pin QFP Assignments (Top View) 1.4.1 Power Supply Pins (VDD and VSS) VDD and VSS are the power supply and ground pins. The MCU operates from a single power supply. Fast signal transitions on MCU pins place high, short-duration current demands on the power supply. To prevent noise problems, take special care to provide power supply bypassing at the MCU as Figure 1-4 shows. Place the C1 bypass capacitor as close to the MCU as possible. Use a high-frequency-response ceramic capacitor for C1. C2 is an optional bulk current bypass capacitor for use in applications that require the port pins to source high current levels. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 23 MCU VSS VDD C1 0.1 µF + C2 VDD NOTE: Component values shown represent typical applications. Figure 1-4. Power Supply Bypassing VSS is also the ground for the port output buffers and the ground return for the serial clock in the serial peripheral interface module (SPI). (See Section 15. Serial Peripheral Interface (SPI).) NOTE: VSS must be grounded for proper MCU operation. 1.4.2 Oscillator Pins (OSC1 and OSC2) The OSC1 and OSC2 pins are the connections for the on-chip oscillator circuit. (See Section 5. Clock Generator Module (CGM).) 1.4.3 External Reset Pin (RST) A logic 0 on the RST pin forces the MCU to a known startup state. RST is bidirectional, allowing a reset of the entire system. It is driven low when any internal reset source is asserted. (See Section 14. System Integration Module (SIM) for more information.) 1.4.4 External Interrupt Pin (IRQ) IRQ is an asynchronous external interrupt pin. (See Section 8. External Interrupt (IRQ).) 1.4.5 Analog Power Supply Pin (VDDA/VDDAREF) VDDA/VDDAREF is the power supply pin for the analog portion of the chip. These modules are the analog-to-digital converter (ADC) and the clock generator module (CGM). (See Section 5. Clock Generator Module (CGM) and Section 3. Analog-to-Digital Converter (ADC).) Data Sheet 24 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 1.4.6 ADC High Reference Pin (VREFH) VREFH is the high reference voltage for all analog-to-digital conversions. (See Section 3. Analog-to-Digital Converter (ADC).) 1.4.7 Analog Ground Pin (VSSA/VREFL) The VSSA/VREFL analog ground pin is used only for the ground connections for the analog sections of the circuit and should be decoupled as per the VSS digital ground pin. The analog sections consist of a clock generator module (CGM) and an analog-to-digital converter (ADC). VSSA/VREFL is also the lower reference supply for the ADC. (See Section 5. Clock Generator Module (CGM) and Section 3. Analog-to-Digital Converter (ADC).) 1.4.8 External Filter Capacitor Pin (CGMXFC) CGMXFC is an external filter capacitor connection for the CGM. (See Section 5. Clock Generator Module (CGM).) 1.4.9 Port A Input/Output (I/O) Pins (PTA7–PTA0) PTA7–PTA0 are general-purpose bidirectional I/O port pins. (See Section 12. Input/Output (I/O) Ports.) 1.4.10 Port B I/O Pins (PTB7/ATD7–PTB0/ATD0) Port B is an 8-bit special function port that shares all eight pins with the analog-to-digital converter (ADC). (See Section 3. Analog-to-Digital Converter (ADC) and Section 12. Input/Output (I/O) Ports.) 1.4.11 Port C I/O Pins (PTC4–PTC0) PTC4–PTC3 and PTC1–PTC0 are general-purpose bidirectional I/O port pins. PTC2/MCLK is a special function port that shares its pin with the system clock. (See Section 12. Input/Output (I/O) Ports.) 1.4.12 Port D I/O Pins (PTD6/ATD14/TCLKA–PTD0/ATD8) Port D is a 7-bit special function port that shares all of its pins with the analog-to-digital converter module (ADC) and one of its pins with the timer interface module (TIM). (See Section 16. Timer Interface (TIM), Section 3. Analog-to-Digital Converter (ADC), and Section 12. Input/Output (I/O) Ports.) 1.4.13 Port E I/O Pins (PTE7/SPSCK–PTE0/TxD) Port E is an 8-bit special function port that shares two of its pins with the timer interface module (TIM), four of its pins with the serial peripheral interface module MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 25 (SPI), and two of its pins with the serial communication interface module (SCI). (See Section 13. Serial Communications Interface (SCI), Section 15. Serial Peripheral Interface (SPI), Section 16. Timer Interface (TIM), and Section 12. Input/Output (I/O) Ports.) 1.4.14 Port F I/O Pins (PTF3/TCH5–PTF0/TCH2) Port F is a 4-bit special function port that shares all of its pins with the timer interface module (TIM). (See Section 16. Timer Interface (TIM) and Section 12. Input/Output (I/O) Ports.) 1.4.15 J1850 Transmit Pin Digital (BDTxD) BDTxD is a serial digital output data physical interface to the J1850. (See Section 4. Byte Data Link Controller-Digital (BDLC-D).) 1.4.16 J1850 Receive Pin Digital (BDRxD) BDRxD is a serial digital input data physical interface from the J1850. (See Section 4. Byte Data Link Controller-Digital (BDLC-D).) Table 1-1. External Pins Summary Pin Name Function Driver Type Hysteresis Reset State PTA7–PTA0 General-purpose I/O Dual state No Input, Hi-Z PTB7/ATD7– PTB0/ATD0 General-purpose I/O ADC channel Dual state No Input, Hi-Z PTC4–PTC3 General-purpose I/O Dual state No Input, Hi-Z PTC2/MCLK General-purpose I/O, bus clock output Dual state No Input, Hi-Z PTC1–PTC0 General-purpose I/O Dual state No Input, Hi-Z PTD6/ATD14/TCLK General-purpose I/O ADC channel/timer external input clock Dual state No Input, Hi-Z PTD5/ATD13– PTD0/ATD8 General-purpose/O ADC channel Dual state No Input, Hi-Z PTE7/SPSCK General-purpose I/O SPI clock Dual state Open drain Yes Input, Hi-Z PTE6/MOSI General-purpose I/O SPI data path Dual state Open drain Yes Input, Hi-Z PTE5/MISO General-purpose I/O SPI data path Dual state Open drain Yes Input, Hi-Z Continued on next page Data Sheet 26 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Table 1-1. External Pins Summary (Continued) Pin Name Function Driver Type Hysteresis Reset State PTE4/SS General-purpose I/O SPI slave select Dual state Yes Input, Hi-Z PTE3/TCH1 General-purpose I/O timer channel 1 Dual state Yes Input, Hi-Z PTE2/TCH0 General-purpose I/O timer channel 0 Dual state Yes Input, Hi-Z PTE1/RxD General-purpose I/O SCI receive data Dual state Yes Input, Hi-Z PTE0/TxD General-purpose I/O SCI transmit data Dual state Yes Input, Hi-Z PTF3/TCH5 General-purpose I/O timer channel 5 Dual state Yes Input, Hi-Z PTF2/TCH4 General-purpose I/O timer channel 4 Dual state Yes Input, Hi-Z PTF1/TCH3 General-purpose I/O timer channel 3 Dual state Yes Input, Hi-Z PTF0/TCH2 General-purpose I/O timer channel 2 Dual state Yes Input, Hi-Z VDD Chip power supply N/A N/A N/A VSS Chip ground N/A N/A N/A VDDA/VDDAREF Analog power supply (CGM and ADC) N/A N/A N/A VSSA/VREFL Analog ground A/D reference voltage N/A N/A N/A VREFH A/D reference voltage N/A N/A N/A OSC1 External clock in N/A N/A Input, Hi-Z OSC2 External clock out N/A N/A Output CGMXFC PLL loop filter cap N/A N/A N/A IRQ External interrupt request N/A N/A Input, Hi-Z RST Reset N/A N/A Output low BDRxD BDLC-D serial input N/A No Input, Hi-Z BDTxD BDLC-D serial output Output No Output low MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 27 Table 1-2. Clock Source Summary Data Sheet 28 Module Clock Source ADC CGMXCLK or bus clock BDLC CGMXCLK COP CGMXCLK CPU Bus Clock EEPROM Internal RC oscillator or bus clock SPI Bus clock/SPSCK SCI CGMXCLK TIM Bus clock or PTD6/ATD14/TCLK SIM CGMOUT and CGMXCLK IRQ Bus clock BRK Bus clock LVI Bus clock CGM OSC1 and OSC2 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor -++ Data Sheet — MC68HC08AS32A — Section 2. Memory 2.1 Introduction The CPU08 can address 64 Kbytes of memory space. The memory map, shown in Figure 2-1, includes: • 32,256 bytes of user ROM • 1024 bytes of RAM • 512 bytes of EEPROM • 38 bytes of user-defined vectors • 224 bytes of monitor ROM These definitions apply to the memory map representation of reserved and unimplemented locations. • Reserved — Accessing a reserved location can have unpredictable effects on MCU operation. • Unimplemented — Accessing an unimplemented location causes an illegal address reset if illegal address resets are enabled. 2.2 Input/Output (I/O) Section Addresses $0000–$003F, shown in Figure 2-2, contain most of the control, status, and data registers. Additional I/O registers have these addresses: • $FE00, SIM break status register, SBSR • $FE01, SIM reset status register, SRSR • $FE03, SIM break flag control register, SBFCR • $FE0C and $FE0D, break address registers, BRKH and BRKL • $FE0E, break status and control register, BRKSCR • $FE0F, LVI status register, LVISR • $FE1C, EEPROM non-volatile register, EENVR • $FE1D, EEPROM control register, EECR • $FE1F, EEPROM array configuration register, EEACR • $FFFF, COP control register, COPCTL Table 2-1 is a list of vector locations. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 29 $0000 ↓ $003F I/O REGISTERS 64 BYTES $0040 ↓ UNIMPLEMENTED $004A $004B PIT STATUS AND CONTROL REGISTER (PSC) $004C PIT COUNTER REGISTER HIGH (PCNTH) $004D PIT COUNTER REGISTER LOW (PCNTL) $004E PIT COUNTER MODULO REGISTER HIGH (PMODH) $004F PIT COUNTER MODULO REGISER LOW (PMODL) $0050 ↓ $044F RAM 1024 BYTES $0450 ↓ UNIMPLEMENTED $07FF $0800 ↓ $09FF EEPROM 512 BYTES $0A00 ↓ UNIMPLEMENTED $7FFF $8000 ↓ $FDFF ROM 32,256 BYTES $FE00 SIM BREAK STATUS REGISTER (SBSR) $FE01 SIM RESET STATUS REGISTER (SRSR) $FE02 RESERVED $FE03 SIM BREAK FLAG CONTROL REGISTER (SBFCR) $FE04 ↓ RESERVED $FE08 $FE09 MASK OPTION REGISTER (MOR) $FE0A RESERVED $FE0B RESERVED $FE0C BREAK ADDRESS REGISTER HIGH (BRKH) $FE0D BREAK ADDRESS REGISTER LOW (BRKL) $FE0E BREAK STATUS AND CONTROL REGISTER (BRKSCR) Figure 2-1. Memory Map Data Sheet 30 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor $FE0F LVI STATUS REGISTER (LVISR) $FE10 EEPROM-EEDIVH NON-VOLATILE REGISTER (EEDIVHNVR) $FE11 EEPROM-EEDIVL NON-VOLATILE REGISTER (EEDIVLNVR) $FE12 ↓ RESERVED $FE19 $FE1A EEPROM-EEDIVH REGISTER (EEDIVH) $FE1B EEPROM-EEDIVL REGISTER (EEDIVL) $FE1C EEPROM NON-VOLATILE REGISTER (EENVR) $FE1D EEPROM CONTROL REGISTER (EECR) $FE1E RESERVED $FE1F EEPROM ARRAY CONFIGURATION REGISTER (EEACR) $FE20 MONITOR ROM 224 BYTES ↓ $FEFF $FF00 ↓ UNIMPLEMENTED $FFD9 $FFDA USER DEFINED VECTORS 38 BYTES ↓ $FFFF Figure 2-1. Memory Map (Continued) Addr. $0000 Register Name Port A Data Register Read: (PTA) Write: See page 156. Reset: $0001 Port B Data Register Read: (PTB) Write: See page 158. Reset: $0002 $0003 Bit 7 6 5 4 3 2 1 Bit 0 PTA7 PTA6 PTA5 PTA4 PTA3 PTA2 PTA1 PTA0 PTB2 PTB1 PTB0 PTC2 PTC1 PTC0 PTD2 PTD1 PTD0 Unaffected by reset PTB7 PTB6 PTB5 Port C Data Register Read: (PTC) Write: See page 160. Reset: 0 0 0 Port D Data Register Read: (PTD) Write: See page 162. Reset: 0 PTB4 PTB3 Unaffected by reset PTC4 PTC3 Unaffected by reset PTD6 PTD5 PTD4 PTD3 Unaffected by reset = Unimplemented R = Reserved U = Unaffected Figure 2-2. Control, Status, and Data Register (Sheet 1 of 8) MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 31 Addr. $0004 $0005 $0006 Register Name Data Direction Register A Read: (DDRA) Write: See page 157. Reset: Data Direction Register B Read: (DDRB) Write: See page 159. Reset: 6 5 4 3 2 1 Bit 0 DDRA7 DDRA6 DDRA5 DDRA4 DDRA3 DDRA2 DDRA1 DDRA0 0 0 0 0 0 0 0 0 DDRB7 DDRB6 DDRB5 DDRB4 DDRB3 DDRB2 DDRB1 DDRB0 0 0 0 0 0 0 0 0 0 0 DDRC4 DDRC3 DDRC2 DDRC1 DDRC0 0 0 0 0 0 0 0 DDRD6 DDRD5 DDRD4 DDRD3 DDR2 DDRD1 DDRD0 0 0 0 0 0 0 0 0 PTE7 PTE6 PTE5 PTE4 PTE3 PTE2 PTE1 PTE0 PTF2 PTF1 PTF0 Data Direction Register C Read: MCLKEN (DDRC) Write: See page 161. Reset: 0 $0007 Data Direction Register D Read: (DDRD) Write: See page 163. Reset: $0008 Port E Data Register Read: (PTE) Write: See page 165. Reset: $0009 Bit 7 Port F Data Register Read: (PTF) Write: See page 167. Reset: 0 Unaffected by reset 0 0 0 0 PTF3 Unaffected by reset $000A Reserved R R R R R R R R $000B Reserved R R R R R R R R DDRE7 DDRE6 DDRE5 DDRE4 DDRE3 DDRE2 DDRE1 DDRE0 0 0 0 0 0 0 0 0 0 0 0 0 DDRF3 DDRF2 DDRF1 DDRF0 $000C $000D Data Direction Register E Read: (DDRE) Write: See page 166. Reset: Data Direction Register F Read: (DDRF) Write: See page 169. Reset: 0 0 0 0 0 0 0 0 $000E Reserved R R R R R R R R $000F Reserved R R R R R R R R SPRIE R SPMSTR CPOL CPHA SPWOM SPE SPTIE 0 0 1 0 1 0 0 0 = Unimplemented R = Reserved $0010 SPI Control Register Read: (SPCR) Write: See page 234. Reset: U = Unaffected Figure 2-2. Control, Status, and Data Register (Sheet 2 of 8) Data Sheet 32 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Addr. $0011 $0012 $0013 Register Name SPI Status and Control Register Read: (SPSCR) Write: See page 236. Reset: SPI Data Register Read: (SPDR) Write: See page 238. Reset: SCI Control Register 1 Read: (SCC1) Write: See page 187. Reset: Bit 7 SPRF 6 ERRIE 5 4 3 OVRF MODF SPTE 2 1 Bit 0 MODFEN SPR1 SPR0 0 0 0 0 1 0 0 0 R7 R6 R5 R4 R3 R2 R1 R0 T7 T6 T5 T4 T3 T2 T1 T0 Unaffected by reset LOOPS ENSCI TXINV M WAKE ILTY PEN PTY 0 0 0 0 0 0 0 0 SCTIE TCIE SCRIE ILIE TE RE RWU SBK 0 0 0 0 0 0 0 0 T8 R R ORIE NEIE FEIE PEIE $0014 SCI Control Register 2 Read: (SCC2) Write: See page 189. Reset: R8 $0015 SCI Control Register 3 Read: (SCC3) Write: See page 191. Reset: U U 0 0 0 0 0 0 SCI Status Register 1 Read: (SCS1) Write: See page 192. Reset: SCTE TC SCRF IDLE OR NF FE PE 1 1 0 0 0 0 0 0 BKF RPF $0016 $0017 SCI Status Register 2 Read: (SCS2) Write: See page 195. Reset: $0018 SCI Data Register Read: (SCDR) Write: See page 196. Reset: $0019 SCI Baud Rate Register Read: (SCBR) Write: See page 196. Reset: $001A IRQ Status and Control Register Read: (ISCR) Write: See page 140. Reset: $001B $001C Reserved PLL Control Register Read: (PCTL) Write: See page 107. Reset: 0 0 0 0 0 0 0 0 R7 R6 R5 R4 R3 R2 R1 R0 T7 T6 T5 T4 T3 T2 T1 T0 Unaffected by reset SCP1 SCP0 R SCR2 SCR1 SCR0 0 0 0 IMASK MODE 0 0 0 0 0 0 0 0 0 IRQF 0 ACK 0 0 0 0 0 0 0 0 R R R R R R R R PLLON BCS 1 1 1 1 R R R R 1 0 1 1 1 1 = Unimplemented R = Reserved PLLIE 0 PLLF 0 U = Unaffected Figure 2-2. Control, Status, and Data Register (Sheet 3 of 8) MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 33 Addr. Register Name PLL Bandwidth Control Register Read: $001D (PBWC) Write: See page 108. Reset: PLL Programming Register Read: (PPG) Write: See page 110. Reset: $001E Bit 7 AUTO Timer Status and Control Read: Register (TSC) Write: See page 253. Reset: $0020 LOCK 5 4 ACQ XLD 3 2 1 Bit 0 0 0 0 0 R R R R MUL7 MUL6 MUL5 MUL4 VRS7 VRS6 VRS5 VRS4 0 0 0 0 0 0 0 0 ROMSEC LVIRST LVIPWR SSREC COPS STOP COPD PS2 PS1 PS0 Mask Option Register Read: LVISTOP (MORA) Write: See page 146. Reset: $001F 6 TOF 0 Unaffected by reset TOIE TSTOP 0 0 TRST 0 0 1 0 0 0 0 0 R R R R R R R R Timer Counter Register High Read: (TCNTH) Write: See page 254. Reset: Bit 15 14 13 12 11 10 9 Bit 8 0 0 0 0 0 0 0 0 Bit 7 6 5 4 3 2 1 Bit 0 $0023 Timer Counter Register Low Read: (TCNTL) Write: See page 254. Reset: 0 0 0 0 0 0 0 0 $0024 Timer Modulo Register High Read: (TMODH) Write: See page 255. Reset: Bit 15 14 13 12 11 10 9 Bit 8 1 1 1 1 1 1 1 1 Bit 7 6 5 4 3 2 1 Bit 0 1 1 1 1 1 1 1 1 CH0IE MS0B MS0A ELS0B ELS0A TOV0 CH0MAX 0 0 0 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 2 1 Bit 0 $0021 Reserved $0022 Timer Modulo Register Low Read: (TMODL) Write: See page 255. Reset: $0025 Timer Channel 0 Status and Read: Control Register (TSC0) Write: See page 256. Reset: $0026 $0027 Timer Channel 0 Register High Read: (TCH0H) Write: See page 260. Reset: $0028 Timer Channel 0 Register Low Read: (TCH0L) Write: See page 260. Reset: CH0F 0 Indeterminate after reset Bit 7 6 5 4 3 Indeterminate after reset = Unimplemented R = Reserved U = Unaffected Figure 2-2. Control, Status, and Data Register (Sheet 4 of 8) Data Sheet 34 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Addr. $0029 $002A $002B Register Name Timer Channel 1 Status and Read: Control Register (TSC1) Write: See page 256. Reset: Timer Channel 1 Register High Read: (TCH1H) Write: See page 260. Reset: Timer Channel 1 Register Low Read: (TCH1L) Write: See page 260. Reset: $002C Timer Channel 2 Status and Read: Control Register (TSC2) Write: See page 256. Reset: $002D Timer Channel 2 Register High Read: (TCH2H) Write: See page 260. Reset: $002E $002F Timer Channel 2 Register Low Read: (TCH2L) Write: See page 260. Reset: Timer Channel 3 Status and Read: Control Register (TSC3) Write: See page 256. Reset: $0030 Timer Channel 3 Register High Read: (TCH3H) Write: See page 260. Reset: $0031 Timer Channel 3 Register Low Read: (TCH3L Write: See page 260.) Reset: $0032 $0033 $0034 Timer Channel 4 Status and Read: Control Register (TSC4) Write: See page 256. Reset: Timer Channel 4 Register High Read: (TCH4H) Write: See page 260. Reset: Timer Channel 4 Register Low Read: (TCH4L) Write: See page 260. Reset: Bit 7 CH1F 0 6 CH1IE 5 0 4 3 2 1 Bit 0 MS1A ELS1B ELS1A TOV1 CH1MAX 0 0 0 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 2 1 Bit 0 Indeterminate after reset Bit 7 6 5 4 3 Indeterminate after reset CH2F CH2IE MS2B MS2A ELS2B ELS2A TOV2 CH2MAX 0 0 0 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 2 1 Bit 0 0 Indeterminate after reset Bit 7 6 5 4 3 Indeterminate after reset CH3F 0 CH3IE 0 MS3A ELS3B ELS3A TOV3 CH3MAX 0 0 0 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 2 1 Bit 0 Indeterminate after reset Bit 7 6 5 4 3 Indeterminate after reset CH4F CH4IE MS4B MS4A ELS4B ELS4A TOV4 CH4MAX 0 0 0 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 2 1 Bit 0 0 Indeterminate after reset Bit 7 6 5 4 3 Indeterminate after reset = Unimplemented R = Reserved U = Unaffected Figure 2-2. Control, Status, and Data Register (Sheet 5 of 8) MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 35 Addr. Register Name Timer Channel 5 Status and Read: Control Register (TSC5) Write: See page 256. Reset: $0035 $0036 $0037 Timer Channel 5 Register High Read: (TCH5H) Write: See page 260. Reset: Timer Channel 5 Register Low Read: (TCH5L) Write: See page 260. Reset: $0038 Analog-to-Digital Status and Read: Control Register (ADSCR) Write: See page 58. Reset: $0039 Analog-to-Digital Data Register Read: (ADR) Write: See page 60. Reset: $003A $003B Analog-to-Digital Input Clock Read: Register (ADICLK) Write: See page 60. Reset: BDLC Analog and Roundtrip Read: Delay Register (BARD) Write: See page 84. Reset: $003C BDLC Control Register 1 Read: (BCR1) Write: See page 86. Reset: $003D BDLC Control Register 2 Read: (BCR2) Write: See page 88. Reset: $003E $003F BDLC State Vector Register Read: (BSVR) Write: See page 93. Reset: BDLC Data Register Read: (BDR) Write: See page 95. Reset: Bit 7 CH5F 0 6 CH5IE 5 0 4 3 2 1 Bit 0 MS5A ELS5B ELS5A TOV5 CH5MAX 0 0 0 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 2 1 Bit 0 ADCH2 ADCH1 ADCH0 Indeterminate after reset Bit 7 6 5 4 3 Indeterminate after reset COCO R AIEN ADCO ADCH4 ADCH3 0 0 0 1 1 1 1 1 AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0 0 0 0 0 0 0 0 0 BO3 BO2 BO1 BO0 0 1 1 1 0 0 R R IE WCM Unaffected by reset ADIV2 ADIV1 ADIV0 ADICLK 0 0 0 0 ATE RXPOL 0 0 R R 1 1 0 0 IMSG CLKS R1 R0 1 1 1 0 0 0 0 0 ALOOP DLOOP RX4XE NBFS TEOD TSIFR TMIFR1 TMIFR0 1 1 0 0 0 0 0 0 0 0 I3 I2 I1 I0 0 0 R R R R R R R R 0 0 0 0 0 0 0 0 BD7 BD6 BD5 BD4 BD3 BD2 BD1 BD0 Unaffected by reset = Unimplemented R = Reserved U = Unaffected Figure 2-2. Control, Status, and Data Register (Sheet 6 of 8) Data Sheet 36 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Addr. $0040 ↓ $004A Register Name Bit 7 6 5 POIE PSTOP 4 3 0 0 2 1 Bit 0 PPS2 PPS1 PPS0 Unimplemented POF $004B PIT Status and Control Read: Register (PSC) Write: See page 152. Reset: 0 0 1 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 $004C PIT Counter Register High Read: (PCNTH) Write: See page 153. Reset: 0 0 0 0 0 0 0 0 PIT Counter Register Low Read: (PCNTL) Write: See page 153. Reset: Bit 7 6 5 4 3 2 1 Bit 0 0 0 0 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 1 1 1 1 1 1 1 1 Bit 7 6 5 4 3 2 1 Bit 0 1 1 1 1 1 1 1 1 R R R R R R SBSW R $004D $004E PIT Counter Modulo Register Read: High (PMODH) Write: See page 154. Reset: $004F PIT Counter Modulo Register Read: Low (PMODL) Write: See page 154. Reset: $FE00 SIM Break Status Register Read: (SBSR) Write: See page 213. Reset: $FE01 SIM Reset Status Register Read: (SRSR) Write: See page 213. Reset: SIM Break Flag Control Register Read: $FE03 (SBFCR) Write: See page 214. Reset: $FE09 $FE0C $FE0D 0 0 POR PIN COP ILOP ILAD 0 LVI 0 1 0 0 0 0 0 0 0 BCFE R R R R R R R 0 AS32A Mask Option Register 2 Read: EEDIVCLK (MORB) Write: See page 147. Reset: Break Address Register High Read: (BRKH) Write: See page 266. Reset: Break Address Register Low Read: (BRKL) Write: See page 266. Reset: PRST Unaffected by reset Bit 15 14 13 12 11 10 9 Bit 8 0 0 0 0 0 0 0 0 Bit 7 6 5 4 3 2 1 Bit 0 0 0 0 0 0 0 0 0 = Unimplemented R = Reserved U = Unaffected Figure 2-2. Control, Status, and Data Register (Sheet 7 of 8) MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 37 Addr. Register Name Break Status and Control Read: Register (BRKSCR) Write: See page 266. Reset: $FE0E LVI Status Register Read: (LVISR) Write: See page 142. Reset: $FE0F Bit 7 6 5 4 3 2 1 Bit 0 BRKE BRKA 0 0 0 0 0 0 0 0 0 0 0 0 0 0 LVIOUT 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 R R R R EEDIV10 EEDIV9 EEDIV8 EEDIV1 EEDIV0 EEDIV0 EEDIV8 EEDIV1 EEDIV0 EEBP1 EEPB0 EEEEDIV Non-Volatile Register Read: (1) DIVSECD Write: High (EEDIVHNVR) See page 49. Reset: $FE10 $FE11 EEDIV Non-Volatile Register Read: Low (EEDIVLNVR)(1) Write: See page 49. Reset: $FE1A EEEEDIV Divider Register High Read: (EEDIVH) Write: DIVSECD See page 50. Reset: EEDIV Divider Register Low Read: (EEDIVL) Write: See page 50. Reset: $FE1B $FE1C EEDIV7 Unaffected by reset; $FF when blank EEDIV6 EEDIV5 0 0 EEDIV4 EEDIV3 EEDIV2 Unaffected by reset; $FF when blank EEDIV7 EEPROM Non-Volatile Register Read: UNUSED (EENVR)(1) Write: See page 51. Reset: $FE1D EEPROM Control Register Read: UNUSED (EECR)(1) Write: See page 46. Reset: 0 $FE1F EEPROM Array Configuration Read: UNUSED Register (EEACR) Write: See page 48. Reset: 0 0 EEDIV10 Contents of EEDIVHNVR ($FE10), Bits [6:3] = 0 EEDIV6 EEDIV5 EEDIV4 EEDIV3 EEDIV2 Contents of EEDIVLNVR ($FE11) UNUSED UNUSED EEPRTCT EEBP3 EEPB2 Unaffected by reset; $FF when blank; factory programmed $F0 0 EEOFF EERAS1 EERAS0 EELAT AUTO EEPGM 0 0 0 0 0 0 0 UNUSED UNUSED EEPRTCT EEBP3 EEBP2 EEBP1 EEBP0 Contents of EENVR ($FE1C) 1. Non-volatile EEPROM register; write by programming. $FFFF COP Control Register Read: (COPCTL) Write: See page 119. Reset: Low byte of reset vector Clear COP Counter Unaffected by reset = Unimplemented R = Reserved U = Unaffected Figure 2-2. Control, Status, and Data Register (Sheet 8 of 8) Data Sheet 38 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Table 2-1. Vector Addresses High Low Address MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Vector $FFDA Periodic Interrupt Timer Vector (High) $FFDB Periodic Interrupt Timer Vector (Low) $FFDC BDLC Vector (High) $FFDD BDLC Vector (Low) $FFDE ADC Vector (High) $FFDF ADC Vector (Low) $FFE0 SCI Transmit Vector (High) $FFE1 SCI Transmit Vector (Low) $FFE2 SCI Receive Vector (High) $FFE3 SCI Receive Vector (Low) $FFE4 SCI Error Vector (High) $FFE5 SCI Error Vector (Low) $FFE6 SPI Transmit Vector (High) $FFE7 SPI Transmit Vector (Low) $FFE8 SPI Receive Vector (High) $FFE9 SPI Receive Vector (Low) $FFEA TIM Overflow Vector (High) $FFEB TIM Overflow Vector (Low) $FFEC TIM Channel 5 Vector (High) $FFED TIM Channel 5 Vector (Low) $FFEE TIM Channel 4 Vector (High) $FFEF TIM Channel 4 Vector (Low) $FFF0 TIM Channel 3 Vector (High) $FFF1 TIM Channel 3 Vector (Low) $FFF2 TIM Channel 2 Vector (High) $FFF3 TIM Channel 2 Vector (Low) $FFF4 TIM Channel 1 Vector (High) $FFF5 TIM Channel 1 Vector (Low) $FFF6 TIM Channel 0 Vector (High) $FFF7 TIM Channel 0 Vector (Low) $FFF8 PLL Vector (High) $FFF9 PLL Vector (Low) $FFFA IRQ Vector (High) $FFFB IRQ Vector (Low) $FFFC SWI Vector (High) $FFFD SWI Vector (Low) $FFFE Reset Vector (High) $FFFF Reset Vector (Low) Data Sheet 39 2.3 Random-Access Memory (RAM) Addresses $0050–$044F are RAM locations. The location of the stack RAM is programmable. The 16-bit stack pointer allows the stack to be anywhere in the 1024-byte memory space. NOTE: For correct operation, the stack pointer must point only to RAM locations. Within page zero are 176 bytes of RAM. Because the location of the stack RAM is programmable, all page zero RAM locations can be used for input/output (I/O) control and user data or code. When the stack pointer is moved from its reset location at $00FF, direct addressing mode instructions can access all page zero RAM locations efficiently. Page zero RAM, therefore, provides ideal locations for frequently accessed global variables. Before processing an interrupt, the CPU uses five bytes of the stack to save the contents of the CPU registers. NOTE: For M68HC05, M6805, and M146805 compatibility, the H register is not stacked. During a subroutine call, the CPU uses two bytes of the stack to store the return address. The stack pointer decrements during pushes and increments during pulls. NOTE: Be careful when using nested subroutines. The CPU could overwrite data in the RAM during a subroutine or during the interrupt stacking operation. 2.4 Read-Only Memory (ROM) The user ROM consists of 32,256 bytes of ROM from addresses $8000–$FDFF. The monitor ROM and vectors are located from $FE20–$FEFF. See Figure 2-1. Thirty-six of the user vectors, $FFDC–$FFFF, are dedicated to user-defined reset and interrupt vectors. Security has been incorporated into the MC68HC08AS32A — to prevent external viewing of the ROM contents. This feature ensures that customer-developed software remains proprietary. 2.5 Electrically Erasable Programmable ROM (EEPROM) This subsection describes the 512 bytes of electrically erasable programmable read-only memory (EEPROM) residing at address range $0800 to $09FF. See Figure 2-1. EEPROM features include: • 512 bytes non-volatile memory • Byte, block, or bulk erasable • Non-volatile EEPROM configuration and block protection options Data Sheet 40 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor • • • On-chip charge pump for programming/erasing Program/erase protection option AUTO bit driven programming/erasing time feature 2.5.1 Functional Description The 512 bytes of EEPROM are located at $0800–$09FF and can be programmed or erased without an additional external high voltage supply. The program and erase operations are enabled through the use of an internal charge pump. An internal state machine controls the program and erase timing. For each byte of EEPROM, the write/erase endurance is 10,000 cycles. 2.5.1.1 EEPROM Configuration The 8-bit EEPROM non-volatile register (EENVR) and the 16-bit EEPROM timebase divider non-volatile register (EEDIVNVR) contain the default settings for the following EEPROM configurations: • EEPROM timebase reference • EEPROM program/erase protection • EEPROM block protection EENVR and EEDIVNR are non-volatile EEPROM registers. They are programmed and erased in the same way as EEPROM bytes. The contents of these registers are loaded into their respective volatile registers during a MCU reset. The values in these read/write volatile registers define the EEPROM configurations. For EENVR, the corresponding volatile register is the EEPROM array configuration register (EEACR). For the EEDIVNVR (two 8-bit registers: EEDIVHNVR and EEDIVLNVR), the corresponding volatile register is the EEPROM divider register (EEDIV: EEDIVH and EEDIVL). 2.5.1.2 EEPROM Timebase Requirements A 35 µs timebase is required by the EEPROM control circuit for program and erase of EEPROM content. This timebase is derived from dividing the CGMXCLK or bus clock (selected by EEDIVCLK bit in mask option register B) using a timebase divider circuit controlled by the 16-bit EEPROM timebase divider EEDIV register (EEDIVH and EEDIVL). As the CGMXCLK or bus clock is user selected, the EEPROM timebase divider register must be configured with the appropriate value to obtain the 35 µs. The timebase divider value is calculated by using the following formula: EEDIV = INT [Reference Frequency (Hz) x 35 x 10–6 + 0.5] This value is written to the EEPROM timebase divider register (EEDIVH and EEDIVL) or programmed into the EEPROM timebase divider non-volatile register MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 41 prior to any EEPROM program or erase operations (see 2.5.1.1 EEPROM Configuration and 2.5.1.2 EEPROM Timebase Requirements). 2.5.1.3 EEPROM Program/Erase Protection The EEPROM has a special feature that designates the 16 bytes of addresses from $08F0 to $08FF to be permanently secured. This program/erase protect option is enabled by programming the EEPRTCT bit in the EEPROM non-volatile register (EENVR) to a logic 0. Once the EEPRTCT bit is programmed to 0 for the first time: • Programming and erasing of secured locations $08F0 to $08FF is permanently disabled. • Secured locations $08F0 to $08FF can be read as normal. • Programming and erasing of EENVR is permanently disabled. • Bulk and block erase operations are disabled for the protected locations $0800–$08EF, $0900–$09FF. • Single byte program and erase operations are still available for locations $0800–$08EF and $0900–$09FF for all bytes that are not protected by the EEPROM block protect EEBPx bits (see 2.5.1.4 EEPROM Block Protection and 2.5.2.2 EEPROM Array Configuration Register). NOTE: Once armed, the protect option is permanently enabled. As a consequence, all functions in the EENVR will remain in the state they were in immediately before the security was enabled. 2.5.1.4 EEPROM Block Protection The 512 bytes of EEPROM are divided into four 128-byte blocks. Each of these blocks can be protected from erase/program operations by setting the EEBPx bit in the EENVR. Table 2-2 shows the address ranges for the blocks. Table 2-2. EEPROM Array Address Blocks Block Number (EEBPx) Address Range EEBP0 $0800–$087F EEBP1 $0880–$08FF EEBP2 $0900–$097F EEBP3 $0980–$09FF These bits are effective after a reset or upon read of the EENVR register. The block protect configuration can be modified by erasing/programming the corresponding bits in the EENVR register and then reading the EENVR register. See 2.5.2.2 EEPROM Array Configuration Register for more information. NOTE: Data Sheet 42 Once EEDIVSECD in the EEDIVHNVR is programmed to 0 and after a system reset, the EEDIV security feature is permanently enabled because the EEDIVSECD bit in the EEDIVH is always loaded with 0 thereafter. Once this MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor security feature is armed, erase and program mode are disabled for EEDIVHNVR and EEDIVLNVR. Modifications to the EEDIVH and EEDIVL registers are also disabled. Therefore, be cautious on programming a value into the EEDIVHNVR. 2.5.1.5 EEPROM Programming and Erasing The unprogrammed or erase state of an EEPROM bit is a logic 1. The factory default for all bytes within the EEPROM array is $FF. The programming operation changes an EEPROM bit from logic 1 to logic 0 (programming cannot change a bit from logic 0 to a logic 1). In a single programming operation, the minimum EEPROM programming size is one bit; the maximum is eight bits (one byte). The erase operation changes an EEPROM bit from logic 0 to logic 1. In a single erase operation, the minimum EEPROM erase size is one byte; the maximum is the entire EEPROM array. The EEPROM can be programmed such that one or multiple bits are programmed (written to a logic 0) at a time. However, the user may never program the same bit location more than once before erasing the entire byte. In other words, the user is not allowed to program a logic 0 to a bit that is already programmed (bit state is already logic 0). For some applications it might be advantageous to track more than 10K events with a single byte of EEPROM by programming one bit at a time. For that purpose, a special selective bit programming technique is available. An example of this technique is illustrated in Table 2-3. Table 2-3. Selective Bit Programming Description Example Program Data in Binary Result in Binary N/A 1111:1111 First event is recorded by programming bit position 0 1111:1110 1111:1110 Second event is recorded by programing bit position 1 1111:1101 1111:1100 Third event is recorded by programming bit position 2 1111:1011 1111:1000 Fourth event is recorded by programming bit position 3 1111:0111 1111:0000 Description Original state of byte (erased) Events five through eight are recorded in a similar fashion NOTE: None of the bit locations are actually programmed more than once although the byte was programmed eight times. When this technique is utilized, a program/erase cycle is defined as multiple program sequences (up to eight) to a unique location followed by a single erase operation. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 43 2.5.1.6 Program/Erase Using AUTO Bit An additional feature available for EEPROM program and erase operations is the AUTO mode. When the AUTO mode is enabled, the EEPROM control circuit has a state machine which will automatically terminate the program/erase cycle and clear the EEPGM bit. See 2.5.1.7 EEPROM Programming, 2.5.1.8 EEPROM Erasing, and 2.5.2.1 EEPROM Control Register for more information. 2.5.1.7 EEPROM Programming The unprogrammed or erase state of an EEPROM bit is a logic 1. Programming changes the state to a logic 0. Only EEPROM bytes in the non-protected blocks and he EENVR register can be programmed. Use the following procedure to program a byte of EEPROM: 1. Clear EERAS1 and EERAS0 and set EELAT in the EECR.(A) NOTE: If using the AUTO mode, also set the AUTO bit during Step 1. 2. 3. 4. 5. 6. 7. 8. NOTE: Write the desired data to the desired EEPROM address.(B) Set the EEPGM bit.(C) Go to Step 6 if AUTO is set. Wait for time, tEEPGM, to program the byte. Clear EEPGM bit. Go to Step 7. Poll the EEPGM bit until it is cleared by the state machine.(D) Wait for a time, tEEFPV, for the programming voltage to fall. Go to Step 8. Clear EELAT bits.(E) A. EERAS1 and EERAS0 must be cleared for programming. Setting the EELAT bit configures the address and data buses to latch data for programming the array. Only data with a valid EEPROM address will be latched. If EELAT is set, other writes to the EECR will be allowed after a valid EEPROM write. B. If more than one valid EEPROM write occurs, the last address and data will be latched overriding the previous address and data. Once data is written to the desired address, do not read EEPROM locations other than the written location. (Reading an EEPROM location returns the latched data and causes the read address to be latched. C. The EEPGM bit cannot be set if the EELAT bit is cleared or a non-valid EEPROM address is latched. This is to ensure proper programming sequence. Once EEPGM is set, do not read any EEPROM locations; otherwise, the current program cycle will be unsuccessful. When EEPGM is set, the on-board programming sequence will be activated. Data cannot be read from the array until the programming sequence is completed. D. The delay time for the EEPGM bit to be cleared in AUTO mode is less than tEEPGM. However, on other MCUs this delay time may be different. For forward compatibility, software should not make any dependency on this delay time. Data Sheet 44 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor E. Any attempt to clear both EEPGM and EELAT bits with a single instruction will only clear EEPGM. This is to allow time for the completion of the on-board programming sequence and the removal of high voltage from the EEPROM array. F. It is proper to disable interrupts prior to performing a program cycle. If the cycle is interrupted, the data that is programmed could be corrupt. 2.5.1.8 EEPROM Erasing The programmed state of an EEPROM bit is logic 0. Erasing changes the state to a logic 1. Only EEPROM bytes in the non-protected blocks and the EENVR register can be erased. Using the following procedure to erase a byte, block or the entire EEPROM array: 1. Configure EERAS1 and EERAS0 for byte, block, or bulk erase; set EELAT in EECR.(A) NOTE: If using the AUTO mode, also set the AUTO bit in Step 1. 2. Byte erase: write any data to the desired address.(B) Block erase: write any data to an address within the desired block.(B) Bulk erase: write any data to an address within the array.(B) 3. Set the EEPGM bit.(C) Go to Step 6 if AUTO is set. 4. Wait for a time, tEEBYTE for byte erase; tEEBLOCK for block erase; tEEBULK for bulk erase. 5. Clear EEPGM bit. Go to Step 7. 6. Poll the EEPGM bit until it is cleared by the state machine.(D) 7. Wait for a time, tEEFPV, for the erasing voltage to fall. Go to Step 8. 8. Clear EELAT bits.(E) NOTE: A. Setting the EELAT bit configures the address and data buses to latch data for erasing the array. Only valid EEPROM addresses will be latched. If EELAT is set, other writes to the EECR will be allowed after a valid EEPROM write. B. If more than one valid EEPROM write occurs, the last address and data will be latched overriding the previous address and data. Once data is written to the desired address, do not read EEPROM locations other than the written location. (Reading an EEPROM location returns the latched data and causes the read address to be latched.) C. The EEPGM bit cannot be set if the EELAT bit is cleared or a non-valid EEPROM address is latched. This is to ensure proper programming sequence. Once EEPGM is set, do not read any EEPROM locations; otherwise, the current program cycle will be unsuccessful. When EEPGM is set, the on-board programming sequence will be activated. Data cannot be read from the array until the programming sequence is completed. D. The delay time for the EEPGM bit to be cleared in AUTO mode is less than tEEBYTE/tEEBLOCK/tEEBULK. However, on other MCUs this delay time may be MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 45 different. For forward compatibility, software should not make any dependency on this delay time. E. Any attempt to clear both EEPGM and EELAT bits with a single instruction will only clear EEPGM. This is to allow time for the completion of the on-board programming sequence and removal of high voltage from the EEPROM array. F. It is proper to disable interrupts prior to performing an erase cycle. If the cycle is interrupted, any/all data in the array could be erased. 2.5.2 EEPROM Register Descriptions Four I/O registers and three non-volatile registers control program, erase, and options of the EEPROM array. 2.5.2.1 EEPROM Control Register This read/write register controls programming/erasing of the array. Address: $FE1D Bit 7 Read: Write: Reset: UNUSED 0 6 0 0 5 4 3 2 1 Bit 0 EEOFF EERAS1 EERAS0 EELAT AUTO EEPGM 0 0 0 0 0 0 = Unimplemented Figure 2-3. EEPROM Control Register (EECR) Bit 7 — Unused Bit This read/write bit is software programmable but has no functionality. EEOFF — EEPROM Power Down This read/write bit disables the EEPROM module for lower power consumption. Any attempts to access the array will give unpredictable results. Reset clears this bit. 1 = Disable EEPROM array 0 = Enable EEPROM array EERAS1 and EERAS0 — Erase/Program Mode Select Bits These read/write bits set the programming/erasing modes. Reset clears these bits. NOTE: Data Sheet 46 Modifying these bits during a program/erase cycle may result in the loss of any/all data in the array. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Table 2-4. EEPROM Program/Erase Mode Select EEBPx EERAS1 EERAS0 Mode 0 0 0 Byte program 0 0 1 Byte erase 0 1 0 Block erase 0 1 1 Bulk erase 1 X X No erase/program X = don’t care EELAT — EEPROM Latch Control This read/write bit latches the address and data buses for programming the EEPROM array. EELAT cannot be cleared if EEPGM is still set. Reset clears this bit. 1 = Buses configured for EEPROM programming 0 = Buses configured for normal read operation AUTO — Automatic Termination of Program/Erase Cycle When AUTO is set, EEPGM is cleared automatically after the program/erase cycle is terminated by the state machine. See note D for 2.5.1.7 EEPROM Programming and 2.5.1.8 EEPROM Erasing. 1 = Automatic clear of EEPGM is enabled 0 = Automatic clear of EEPGM is disabled EEPGM — EEPROM Program/Erase Enable This read/write bit initiates the program/erase state machine which applies the programming/erasing voltage to the EEPROM array if the EELAT bit is set and a write to a valid EEPROM location has occurred. Once a program/erase sequence has been initiated, writing a 0 to EEPGM has no effect. The state machine sequence must complete before the program/erase voltage is removed from the array. The state machine will clear the EEPGM bit when the program/erase sequence is completed in AUTO mode. In standard mode, the EEPGM bit must be cleared to complete the sequence. Reset clears the EEPGM bit and resets the program/erase state machine. 1 = EEPROM program/erase state machine initiated and EEPROM programming/erasing power switched on 0 = No effect NOTE: Writing logic 0s to both the EELAT and EEPGM bits with a single instruction will clear only EEPGM. A subsequent write of logic 0 to EELAT must be performed to clear the bit. Both bits must be cleared to perform subsequent program/erase cycles. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 47 2.5.2.2 EEPROM Array Configuration Register The EEPROM array configuration register configures EEPROM security and EEPROM block protection. This read-only register is loaded with the contents of the EDEPROM non-volatile register (EENVR) after a reset. Address: $FE1F Read: Bit 7 6 5 4 3 2 1 Bit 0 UNUSED UNUSED UNUSED EEPRTCT EEBP3 EEBP2 EEBP1 EEBP0 Write: Reset: Contents of EENVR ($FE1C) = Unimplemented Figure 2-4. EEPROM Array Configuration Register (EEACR) Bits 7:5 — Unused Bits These read/write bits are software programmable but have no functionality. EEPRTCT — EEPROM Protection Bit The EEPRTCT bit is used to enable the security feature in the EEPROM (see 2.5.1.3 EEPROM Program/Erase Protection). 1 = EEPROM security disabled 0 = EEPROM security enabled NOTE: This feature is a write-once feature. Once the protection is enabled it may not be disabled. EEEBP[3:0] — EEPROM Block Protection Bits These bits prevent blocks of EEPROM array from being programmed or erased. 1 = EEPROM array block is protected 0 = EEPROM army block is unprotected Data Sheet 48 Block Number (EEBPx) Address Range EEBP0 $0800—$087F EEBP1 $0880–$08FF EEBP2 $0900–$097F EEBP3 $0980–$09FF MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Table 2-5. EEPROM Block Protect and Security Summary Address Range EEBPx EEPRTCT = 1 EEPRTCT = 0 EEBP0 = 0 Byte programming available Bulk, block, and byte erasing available Byte programming available Only byte erasing available EEBP0 = 1 Protected Protected EEBP1 = 0 Byte programming available Bulk, block, and byte erasing available Byte programming available Only byte erasing available EEBP1 = 1 Protected Protected EEBP1 = 0 Byte programming available Bulk, block, and byte erasing available Secured (no programming or erasing) EEBP1 = 1 Protected EEBP2 = 0 Byte programming available Bulk, block, and byte erasing available Byte programming available Only byte erasing available EEBP2 = 1 Protected Protected EEBP3 = 0 Byte programming available Bulk, block, and byte erasing available Byte programming available Only byte erasing available EEBP3 = 1 Protected Protected $0800—$087F $0880–$08EF $08F0—$08FF $0900–$097F $0980–$09FF 2.5.2.3 EEPROM Non-Volatile Register The contents of this register is loaded into the EEPROM array configuration register (EEACR) after a reset. This register is erased and programmed in the same way as an EEPROM byte. See 2.5.2.1 EEPROM Control Register for individual bit descriptions. Address: $FE1C Read: Write: Reset: Bit 7 6 5 4 3 2 1 Bit 0 UNUSED UNUSED UNUSED EEPRTCT EEBP3 EEBP2 EEBP1 EEBP0 Programmed value or 1 in the erased state Figure 2-5. EEPROM Non-Volatile Register (EENVR) NOTE: The EENVR will leave the factory programmed with $F0 such that the full array is available and unprotected. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 49 2.5.2.4 EEPROM Timebase Divider Register The 16-bit EEPROM timebase divider register consists of two 8-bit registers: EEDIVH and EEDIVL. The 11-bit value in this register is used to configure the timebase divider circuit to obtain the 35 µs timebase for EEPROM control. These two read/write registers are respectively loaded with the contents of the EEPROM timebase divider non-volatile registers (EEDIVHNVR and EEDIVLNVR) after a reset. Address: $FE1A Bit 7 Read: Write: EEDIVSECD 6 5 4 3 0 0 0 0 Reset: 2 1 Bit 0 EEDIV10 EEDIV9 EEDIV8 Contents of EEDIVHNVR ($FE10), bits [6:3] = 0 = Unimplemented Figure 2-6. EEDIV Divider High Register (EEDIVH) Address: $FE1B Read: Write: Reset: Bit 7 6 5 4 3 2 1 Bit 0 EEDIV7 EEDIV6 EEDIV5 EEDIV4 EEDIV3 EEDIV2 EEDIV1 EEDIV0 Contents of EEDIVLNVR ($FE11) Figure 2-7. EEDIV Divider Low Register (EEDIVL) EEDIVSECD — EEPROM Divider Security Disable This bit enables/disables the security feature of the EEDIV registers. When EEDIV security feature is enabled, the state of the registers EEDIVH and EEDIVL are locked (including EEDIVSECD bit). The EEDIVHNVR and EEDIVLNVR non-volatile memory registers are also protected from being erased/programmed. 1 = EEDIV security feature disabled 0 = EEDIV security feature enabled EEDIV[10:0] — EEPROM Timebase Prescaler These prescaler bits store the value of EEDIV which is used as the divisor to derive a timebase of 35 µs from the selected reference clock source (CGMXCLK or bus block in the MOR register) for the EEPROM related state machine and circuits. EEDIV[10:0] bits are readable at any time. They are writable when EELAT = 0 and EEDIVSECD = 1. The EEDIV value is calculated by the following formula: EEDIV = INT [Reference Frequency (Hz) x 35 x 10–6 + 0.5] Where the result inside the bracket is rounded down to the nearest integer value. For example, if the reference frequency is 4.9153 MHz, the EEDIV value is 172. NOTE: Data Sheet 50 Programming/erasing the EEPROM with an improper EEDIV value may result in data lost and reduce endurance of the EEPROM device. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 2.5.2.5 EEPROM Timebase Divider Non-Volatile Register The 16-bit EEPROM timebase divider non-volatile register consists of two 8-bit registers: EDIVHNVR and EEDIVLNVR. The contents of these two registers are respectively loaded into the EEPROM timebase divider registers, EEDIVH and EEDIVL, after a reset. These two registers are erased and programmed in the same way as an EEPROM byte. Address: $FE10 Read: Write: Bit 7 6 5 4 3 2 1 Bit 0 EEDIVSECD R R R R EEDIV10 EEDIV9 EEDIV8 R = Reserved Reset: Unaffected by reset; $FF when blank Figure 2-8. EEPROM Divider Non-Volatile Register High (EEDIVHNVR) Address: $FE11 Read: Write: Reset: Bit 7 6 5 4 3 2 1 Bit 0 EEDIV7 EEDIV6 EEDIV5 EEDIV4 EEDIV3 EEDIV2 EEDIV1 EEDIV0 Unaffected by reset; $FF when blank Figure 2-9. EEPROM Divider Non-Volatile Register Low (EEDIVLNVR) These two registers are protected from erase and program operations if the EEDIVSECD is set to logic 1 in the EEDIVH (see 2.5.2.4 EEPROM Timebase Divider Register) or programmed to a logic 1 in the EEDIVHNVR. NOTE: Once EEDIVSECD in the EEDIVHNVR is programmed to 0 and after a system reset, the EEDIV security feature is permanently enabled because the EEDIVSECD bit in the EEDIVH is always loaded with 0 thereafter. Once this security feature is armed, erase and program mode are disabled for EEDIVHNVR and EEDIVLNVR. Modifications to the EEDIVH and EEDIVL registers are also disabled. Therefore, care should be taken before programming a value into the EEDIVHNVR. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 51 2.5.3 Low-Power Modes The WAIT and STOP instructions can put the MCU in low power- consumption standby modes. 2.5.3.1 Wait Mode The WAIT instruction does not affect the EEPROM. It is possible to start the program or erase sequence on the EEPROM and put the MCU in wait mode. 2.5.3.2 Stop Mode The STOP instruction reduces the EEPROM power consumption to a minimum. The STOP instruction should not be executed while a programming or erasing sequence is in progress. If stop mode is entered while EELAT and EEPGM are set, the programming sequence will be stopped and the programming voltage to the EEPROM array removed.The programming sequence will be restarted after leaving stop mode; access to the EEPROM is only possible after the programming sequence has completed. If stop mode is entered while EELAT and EEPGM is cleared, the programming sequence will be terminated abruptly. In either case, the data integrity of the EEPROM is not guaranteed. Data Sheet 52 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 3. Analog-to-Digital Converter (ADC) 3.1 Introduction This section describes the 8-bit analog-to-digital converter (ADC). 3.2 Features Features of the ADC module include: • 15 channels (52-PLCC) with multiplexed input • Linear successive approximation • 8-bit resolution • Single or continuous conversion • Conversion complete flag or conversion complete interrupt • Selectable ADC clock 3.3 Functional Description Fifteen ADC channels are available for sampling external sources at pins PTD6/ATD14/TCLK–PTD0/ATD8 and PTB7/ATD7–PTB0/ATD0. An analog multiplexer allows the single ADC converter to select one of the 15 ADC channels as ADC voltage input (ADCVIN). ADCVIN is converted by the successive approximation register-based counters. When the conversion is completed, ADC places the result in the ADC data register and sets a flag or generates an interrupt. See Figure 3-2. 3.3.1 ADC Port I/O Pins PTD6/ATD14/TCLK–PTD0/ATD8 and PTB7/ATD7–PTB0/ATD0 are generalpurpose I/O pins that are shared with the ADC channels. The channel select bits (ADC status control register, $0038), define which ADC channel/port pin will be used as the input signal. The ADC overrides the port I/O logic by forcing that pin as input to the ADC. The remaining ADC channels/port pins are controlled by the port I/O logic and can be used as general-purpose I/O. Writes to the port register or DDR will not have any affect on the port pin that is selected by the ADC. Read of a port pin which is in use by the ADC will return a logic 0 if the corresponding DDR bit is at logic 0. If the DDR bit is at logic 1, the value in the port data latch is read. NOTE: Do not use ADC channel ATD14 when using the PTD6/ATD14/TCLK pin as the clock input for the TIM. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 53 CONTROL AND STATUS REGISTERS — 69 BYTES BREAK MODULE DDRA PTA PTB ANALOG-TO-DIGITAL CONVERTER MODULE DDRB ARITHMETIC/LOGIC UNIT PTA7–PTA0 PTB7/ATD7–PTB0/ATD0 DDRC CPU REGISTERS VREFH USER ROM — 32,256 BYTES PTC Data Sheet 54 INTERNAL BUS M68HC08 CPU IRQ MODULE MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor VDDA/VDDAREF VSSA/VREFL PTF3/TCH5 PTF2/TCH4 PTF1/TCH3 PTF0/TCH2 SERIAL COMMUNICATIONS INTERFACE MODULE SERIAL PERIPHERAL INTERFACE MODULE BYTE DATA LINK CONTROLLER DIGITAL MODULE POWER-ON RESET MODULE VSS VDD PTE7/SPSCK PTE6/MOSI PTE5/MISO PTE4/SS PTE3/TCH1 PTE2/TCH0 PTE1/RxD PTE0/TxD PTF IRQ SYSTEM INTEGRATION MODULE PTD RST CLOCK GENERATOR MODULE PTD5/ATD13–PTD0/ATD8 PTE OSC1 OSC2 CGMXFC PROGRAMMABLE INTERRUPT TIMER MODULE DDRE USER ROM VECTOR SPACE — 38 BYTES PTD6/ATD14/TCLK TIMER INTERFACE MODULE BDRxD BDTxD POWER Figure 3-1. Block Diagram Highlighting ADC Block and Pins DDRF MONITOR ROM — 224 BYTES DDRD USER EEPROM — 512 BYTES USER RAM — 1024 BYTES PTC2/MCLK PTC1–PTC0 LOW-VOLTAGE INHIBIT MODULE COMPUTER OPERATING PROPERLY MODULE PTC4–PTC3 INTERNAL DATA BUS READ DDRB/DDRB WRITE DDRB/DDRD RESET WRITE PTB/PTD DISABLE DDRBx/DDRDx PTBx/PTDx PTBx/PTDx ADC CHANNEL x READ PTB/PTD DISABLE ADC DATA REGISTER INTERRUPT LOGIC AIEN CONVERSION COMPLETE ADC VOLTAGE IN ADCVIN ADC CHANNEL SELECT ADCH[4:0] COCO ADC CLOCK CGMXCLK BUS CLOCK CLOCK GENERATOR ADIV[2:0] ADICLK Figure 3-2. ADC Block Diagram 3.3.2 Voltage Conversion When the input voltage to the ADC equals VREFH (see 18.7 ADC Characteristics), the ADC converts the signal to $FF (full scale). If the input voltage equals VSSA/VREFL the ADC converts it to $00. Input voltages between VREFH and VSSA/VREFL are a straight-line linear conversion. All other input voltages will result in $FF if greater than VREFH and $00 if less than VSSA/VREFL. NOTE: Input voltage should not exceed the analog supply voltages. 3.3.3 Conversion Time Sixteen ADC internal clocks are required to perform one conversion. The ADC starts a conversion on the first rising edge of the ADC internal clock immediately following a write to the ADSCR. If the ADC internal clock is selected to run at 1 MHz, then one conversion will take 16 µs to complete. But since the ADC can run almost completely asynchronously to the bus clock, (for example, the ADC is MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 55 configured to derive its internal clock from CGMXCLK and the bus clock is being derived from the PLL within the CGM [CGMOUT]), this 16-µs conversion can take up to 17 µs to complete. This worst-case could occur if the write to the ADSCR happened directly after the rising edge of the ADC internal clock causing the conversion to wait until the next rising edge of the ADC internal clock. With a 1-MHz ADC internal clock, the maximum sample rate is 59 kHz to 62 kHz. Refer to 18.7 ADC Characteristics 16 to 17 ADC Clock Cycles Conversion Time = ADC Clock Frequency Number of Bus Cycles = Conversion Time x Bus Frequency 3.3.4 Continuous Conversion Mode In the continuous conversion mode, the ADC continuously converts the selected channel, filling the ADC data register with new data after each conversion. Data from the previous conversion will be overwritten whether that data has been read or not. Conversions will continue until the ADCO bit is cleared. The COCO bit (ADC status control register, $0038) is set after each conversion and will stay set until the next read of the ADC data register. When a conversion is in process and the ADSCR is written, the current conversion data should be discarded to prevent an incorrect reading. 3.3.5 Accuracy and Precision The conversion process is monotonic and has no missing codes. Refer to 18.7 ADC Characteristics for accuracy information. 3.4 Interrupts When the AIEN bit is set, the ADC module is capable of generating a CPU interrupt after each ADC conversion. A CPU interrupt is generated if the COCO bit is at logic 0. The COCO bit is not used as a conversion complete flag when interrupts are enabled. 3.5 Low-Power Modes The following subsections describe the low-power modes. 3.5.1 Wait Mode The ADC continues normal operation during wait mode. Any enabled CPU interrupt request from the ADC can bring the MCU out of wait mode. If the ADC is not required to bring the MCU out of wait mode, power down the ADC by setting the ADCH[4:0] bits in the ADC status and control register to logic 1s before executing the WAIT instruction. Data Sheet 56 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 3.5.2 Stop Mode The ADC module is inactive after the execution of a STOP instruction. Any pending conversion is aborted. ADC conversions resume when the MCU exits stop mode. Allow one conversion cycle to stabilize the analog circuitry before attempting a new ADC conversion after exiting stop mode. 3.6 I/O Signals The ADC module has 15 channels that are shared with I/O ports B and D and one channel with an input-only port bit on port D. Refer to 18.7 ADC Characteristics for voltages referenced in the next three subsections. 3.6.1 ADC Analog Power Pin (VDDA/VDDAREF)/ADC Voltage Reference Pin (VREFH) The ADC analog portion uses VDDA/VDDAREF as its power pin. Connect the VDDA/VDDAREF pin to the same voltage potential as VDD. External filtering may be necessary to ensure clean VDDA/VDDAREF for good results. VREFH is the high reference voltage for all analog-to-digital conversions. NOTE: Route VDDA/VDDAREF carefully for maximum noise immunity and place bypass capacitors as close as possible to the package. 3.6.2 ADC Analog Ground Pin (VSSA)/ADC Voltage Reference Low Pin (VREFL) The ADC analog portion uses VSSA as its ground pin. Connect the VSSA pin to the same voltage potential as VSS. VREFL is the lower reference supply for the ADC. 3.6.3 ADC Voltage In (ADCVIN) ADCVIN is the input voltage signal from one of the 15 ADC channels to the ADC module. 3.7 I/O Registers These I/O registers control and monitor ADC operation: MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor • ADC status and control register (ADSCR) • ADC data register (ADR) • ADC input clock register (ADICLK) Data Sheet 57 3.7.1 ADC Status and Control Register The following paragraphs describe the function of the ADC status and control register. Address: $0038 Bit 7 6 5 4 3 2 1 Bit 0 AIEN ADCO ADCH4 ADCH3 ADCH2 ADCH1 ADCH0 0 1 1 1 1 1 Read: COCO Write: R Reset: 0 0 R = Reserved Figure 3-3. ADC Status and Control Register (ADSCR) COCO — Conversions Complete Bit In non-interrupt mode (AIEN = 0), COCO is a read-only bit that is set at the end of each conversion. COCO will stay set until cleared by a read of the ADC data register. Reset clears this bit. In interrupt mode (AIEN = 1), COCO is a read-only bit that is not set at the end of a conversion. It always reads as a logic 0. 1 = Conversion completed (AIEN = 0) 0 = Conversion not completed (AIEN = 0) or CPU interrupt enabled (AIEN = 1) NOTE: The write function of the COCO bit is reserved. When writing to the ADSCR register, always have a 0 in the COCO bit position. AIEN — ADC Interrupt Enable Bit When this bit is set, an interrupt is generated at the end of an ADC conversion. The interrupt signal is cleared when the data register is read or the status/control register is written. Reset clears the AIEN bit. 1 = ADC interrupt enabled 0 = ADC interrupt disabled ADCO — ADC Continuous Conversion Bit When set, the ADC will convert samples continuously and update the ADR register at the end of each conversion. Only one conversion is allowed when this bit is cleared. Reset clears the ADCO bit. 1 = Continuous ADC conversion 0 = One ADC conversion ADCH[4:0] — ADC Channel Select Bits ADCH4, ADCH3, ADCH2, ADCH1, and ADCH0 form a 5-bit field which is used to select one of the ADC channels. The five channel select bits are detailed in Table 3-1. Care should be taken when using a port pin as both an analog and a digital input simultaneously to prevent switching noise from corrupting the analog signal. (See Table 3-1.) Data Sheet 58 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Table 3-1. Mux Channel Select ADCH4 ADCH3 ADCH2 ADCH1 ADCH0 Input Select 0 0 0 0 0 PTB0/ATD0 0 0 0 0 1 PTB1/ATD1 0 0 0 1 0 PTB2/ATD2 0 0 0 1 1 PTB3/ATD3 0 0 1 0 0 PTB4/ATD4 0 0 1 0 1 PTB5/ATD5 0 0 1 1 0 PTB6/ATD6 0 0 1 1 1 PTB7/ATD7 0 1 0 0 0 PTD0/ATD8 0 1 0 0 1 PTD1/ATD9 0 1 0 1 0 PTD2/ATD10 0 1 0 1 1 PTD3/ATD11 0 1 1 0 0 PTD4/ATD12 0 1 1 0 1 PTD5/ATD13 0 1 1 1 0 PTD6/ATD14/TCLK Unused(1) Range 01111 ($0F) to 11010 ($1A) 1 1 0 1 1 Reserved 1 1 1 0 0 Unused(1) 1 1 1 0 1 VREFH(2) 1 1 1 1 0 VSSA/VREFL(2) 1 1 1 1 1 ADC Power Off 1. If any unused channels are selected, the resulting ADC conversion will be unknown. 2. The voltage levels supplied from internal reference nodes as specified in the table are used to verify the operation of the ADC converter both in production test and for user applications. The ADC subsystem is turned off when the channel select bits are all set to one. This feature allows for reduced power consumption for the MCU when the ADC is not used. Reset sets all of these bits to a logic 1. NOTE: Recovery from the disabled state requires one conversion cycle to stabilize. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 59 3.7.2 ADC Data Register One 8-bit data register is provided. This register is updated each time an ADC conversion completes. Address: Read: $0039 Bit 7 6 5 4 3 2 1 Bit 0 AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0 Write: Reset: Unaffected by reset = Unimplemented Figure 3-4. ADC Data Register (ADR) 3.7.3 ADC Input Clock Register This register selects the clock frequency for the ADC. Address: Read: Write: Reset: $003A Bit 7 6 5 4 ADIV2 ADIV1 ADIV0 ADICLK 0 0 0 0 3 2 1 Bit 0 0 0 0 0 0 0 0 0 = Unimplemented Figure 3-5. ADC Input Clock Register (ADICLK) ADIV2:ADIV0 — ADC Clock Prescaler Bits ADIV2, ADIV1, and ADIV0 form a 3-bit field which selects the divide ratio used by the ADC to generate the internal ADC clock. Table 3-2 shows the available clock configurations. The ADC clock should be set to approximately 1 MHz. Table 3-2. ADC Clock Divide Ratio ADIV2 ADIV1 ADIV0 ADC Clock Rate 0 0 0 ADC input clock ÷ 1 0 0 1 ADC input clock ÷ 2 0 1 0 ADC input clock ÷ 4 0 1 1 ADC input clock ÷ 8 1 X X ADC input clock ÷ 16 X = Don’t care Data Sheet 60 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor ADICLK — ADC Input Clock Register Bit ADICLK selects either bus clock or CGMXCLK as the input clock source to generate the internal ADC clock. Reset selects CGMXCLK as the ADC clock source. If the external clock (CGMXCLK) is equal to or greater than 1 MHz, CGMXCLK can be used as the clock source for the ADC. If CGMXCLK is less than 1 MHz, use the PLL-generated bus clock as the clock source. As long as the internal ADC clock is at approximately 1 MHz, correct operation can be guaranteed. (See 18.7 ADC Characteristics.) 1 = Internal bus clock 0 = External clock (CGMXCLK) fXCLK or Bus Frequency 1 MHz = ADIV[2:0] NOTE: During the conversion process, changing the ADC clock will result in an incorrect conversion. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 61 Data Sheet 62 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 4. Byte Data Link Controller-Digital (BDLC-D) 4.1 Introduction The byte data link controller (BDLC) provides access to an external serial communication multiplex bus, operating according to the Society of Automotive Engineers (SAE) J1850 protocol. 4.2 Features Features of the BDLC module include: • SAE J1850 class B data communications network interface compatible and ISO compatible for low speed (<125 kbps) serial data communications in automotive applications • 10.4 kbps variable pulse width (VPW) bit format • Digital noise filter • Collision detection • Hardware cyclical redundancy check (CRC) generation and checking • Two power-saving modes with automatic wakeup on network activity • Polling and CPU interrupts available • Block mode receive and transmit supported • Supports 4X receive mode, 41.6 kbps • Digital loopback mode • Analog loopback mode • In-frame response (IFR) types 0, 1, 2, and 3 supported 4.3 Functional Description Figure 4-2 shows the organization of the BDLC module. The CPU interface contains the software addressable registers and provides the link between the CPU and the buffers. The buffers provide storage for data received and data to be transmitted onto the J1850 bus. The protocol handler is responsible for the encoding and decoding of data bits and special message symbols during transmission and reception. The MUX interface provides the link between the BDLC digital section and the analog physical interface. The wave shaping, driving, and digitizing of data is performed by the physical interface. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 63 CONTROL AND STATUS REGISTERS — 69 BYTES BREAK MODULE DDRA PTA PTB ANALOG-TO-DIGITAL CONVERTER MODULE DDRB ARITHMETIC/LOGIC UNIT PTA7–PTA0 PTB7/ATD7–PTB0/ATD0 DDRC CPU REGISTERS VREFH USER ROM — 32,256 BYTES PTC Data Sheet 64 INTERNAL BUS M68HC08 CPU SYSTEM INTEGRATION MODULE IRQ IRQ MODULE MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor VDDA/VDDAREF VSSA/VREFL PTF3/TCH5 PTF2/TCH4 PTF1/TCH3 PTF0/TCH2 SERIAL COMMUNICATIONS INTERFACE MODULE SERIAL PERIPHERAL INTERFACE MODULE BYTE DATA LINK CONTROLLER DIGITAL MODULE POWER-ON RESET MODULE VSS VDD PTE7/SPSCK PTE6/MOSI PTE5/MISO PTE4/SS PTE3/TCH1 PTE2/TCH0 PTE1/RxD PTE0/TxD PTF RST PTD CLOCK GENERATOR MODULE PTD5/ATD13–PTD0/ATD8 PTE OSC1 OSC2 CGMXFC PROGRAMMABLE INTERRUPT TIMER MODULE DDRE USER ROM VECTOR SPACE — 38 BYTES PTD6/ATD14/TCLK TIMER INTERFACE MODULE BDRxD BDTxD POWER Figure 4-1. Block Diagram Highlighting BDLC Block and Pins DDRF MONITOR ROM — 224 BYTES DDRD USER EEPROM — 512 BYTES USER RAM — 1024 BYTES PTC2/MCLK PTC1–PTC0 LOW-VOLTAGE INHIBIT MODULE COMPUTER OPERATING PROPERLY MODULE PTC4–PTC3 Use of the BDLC module in message networking fully implements the SAE Standard J1850 Class B Data Communication Network Interface specification. NOTE: It is recommended that the reader be familiar with the SAE J1850 document and ISO Serial Communication document prior to proceeding with this section of the MC68HC08AS32A — specification. TO CPU CPU INTERFACE PROTOCOL HANDLER MUX INTERFACE PHYSICAL INTERFACE BDLC TO J1850 BUS Figure 4-2. BDLC Block Diagram Addr. Register Name $003B BDLC Analog and Roundtrip Read: Delay Register (BARD) Write: See page 84. Reset: $003C BDLC Control Register 1 Read: (BCR1) Write: See page 86. Reset: $003D $003E $003F BDLC Control Register 2 Read: (BCR2) Write: See page 88. Reset: BDLC State Vector Register Read: (BSVR) Write: See page 93. Reset: BDLC Data Register Read: (BDR) Write: See page 95. Reset: Bit 7 6 ATE RXPOL 1 1 5 4 0 0 R R 0 0 3 2 1 Bit 0 BO3 BO2 BO1 BO0 0 1 1 1 0 0 R R IE WCM IMSG CLKS R1 R0 1 1 1 0 0 0 0 0 ALOOP DLOOP RX4XE NBFS TEOD TSIFR TMIFR1 TMIFR0 1 1 0 0 0 0 0 0 0 0 I3 I2 I1 I0 0 0 R R R R R R R R 0 0 0 0 0 0 0 0 BD7 BD6 BD5 BD4 BD3 BD2 BD1 BD0 R = Reserved Unaffected by reset Figure 4-3. BDLC I/O Register Summary MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 65 4.3.1 BDLC Operating Modes The BDLC has five main modes of operation which interact with the power supplies, pins, and the remainder of the MCU as shown in Figure 4-4. POWER OFF VDD > VDD (MINIMUM) AND ANY MCU RESET SOURCE ASSERTED VDD ≤ VDD (MINIMUM) RESET ANY MCU RESET SOURCE ASSERTED (FROM ANY MODE) COP, ILLADDR, PU, RESET, LVR, POR NETWORK ACTIVITY OR OTHER MCU WAKEUP RUN NO MCU RESET SOURCE ASSERTED NETWORK ACTIVITY OR OTHER MCU WAKEUP BDLC WAIT BDLC STOP STOP INSTRUCTION OR WAIT INSTRUCTION AND WCM = 1 WAIT INSTRUCTION AND WCM = 0 Figure 4-4. BDLC Operating Modes State Diagram 4.3.1.1 Power Off Mode This mode is entered from reset mode whenever the BDLC supply voltage, VDD, drops below its minimum specified value for the BDLC to guarantee operation. The BDLC will be placed in reset mode by low-voltage reset (LVR) before being powered down. In this mode, the pin input and output specifications are not guaranteed. 4.3.1.2 Reset Mode This mode is entered from the power off mode whenever the BDLC supply voltage, VDD, rises above its minimum specified value (VDD –10%) and some MCU reset source is asserted. The internal MCU reset must be asserted while powering up the BDLC or an unknown state will be entered and correct operation cannot be guaranteed. Reset mode is also entered from any other mode as soon as one of Data Sheet 66 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor the MCU’s possible reset sources (such as LVR, POR, COP watchdog, and reset pin, etc.) is asserted. In reset mode, the internal BDLC voltage references are operative; VDD is supplied to the internal circuits which are held in their reset state; and the internal BDLC system clock is running. Registers will assume their reset condition. Outputs are held in their programmed reset state. Therefore, inputs and network activity are ignored. 4.3.1.3 Run Mode This mode is entered from the reset mode after all MCU reset sources are no longer asserted. Run mode is entered from the BDLC wait mode whenever activity is sensed on the J1850 bus. Run mode is entered from the BDLC stop mode whenever network activity is sensed, although messages will not be received properly until the clocks have stabilized and the CPU is in run mode also. In this mode, normal network operation takes place. The user should ensure that all BDLC transmissions have ceased before exiting this mode. 4.3.1.4 BDLC Wait Mode This power-conserving mode is entered automatically from run mode whenever the CPU executes a WAIT instruction and if the WCM bit in the BCR1 register is cleared previously. In this mode, the BDLC internal clocks continue to run. The first passive-to-active transition of the bus generates a CPU interrupt request from the BDLC which wakes up the BDLC and the CPU. In addition, if the BDLC receives a valid EOF symbol while operating in wait mode, then the BDLC also will generate a CPU interrupt request which wakes up the BDLC and the CPU. See 4.7.1 Wait Mode. 4.3.1.5 BDLC Stop Mode This power-conserving mode is entered automatically from run mode whenever the CPU executes a STOP instruction or if the CPU executes a WAIT instruction and the WCM bit in the BCR1 register is set previously. In this mode, the BDLC internal clocks are stopped but the physical interface circuitry is placed in a low-power mode and awaits network activity. If network activity is sensed, then a CPU interrupt request will be generated, restarting the BDLC internal clocks. See 4.7.2 Stop Mode. 4.3.1.6 Digital Loopback Mode When a bus fault has been detected, the digital loopback mode is used to determine if the fault condition is caused by failure in the node’s internal circuits or MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 67 elsewhere in the network, including the node’s analog physical interface. In this mode, the transmit digital output pin (BDTxD) and the receive digital input pin (BDRxD) of the digital interface are disconnected from the analog physical interface and tied together to allow the digital portion of the BDLC to transmit and receive its own messages without driving the J1850 bus. 4.3.1.7 Analog Loopback Mode Analog loopback is used to determine if a bus fault has been caused by a failure in the node’s off-chip analog transceiver or elsewhere in the network. The BCLD analog loopback mode does not modify the digital transmit or receive functions of the BDLC. It does, however, ensure that once analog loopback mode is exited, the BDLC will wait for an idle bus condition before participation in network communication resumes. If the off-chip analog transceiver has a loopback mode, it usually causes the input to the output drive stage to be looped back into the receiver, allowing the node to receive messages it has transmitted without driving the J1850 bus. In this mode, the output to the J1850 bus is typically high impedance. This allows the communication path through the analog transceiver to be tested without interfering with network activity. Using the BDLC analog loopback mode in conjunction with the analog transceiver’s loopback mode ensures that, once the off-chip analog transceiver has exited loopback mode, the BCLD will not begin communicating before a known condition exists on the J1850 bus. 4.4 BDLC MUX Interface The MUX interface is responsible for bit encoding/decoding and digital noise filtering between the protocol handler and the physical interface. TO CPU CPU INTERFACE PROTOCOL HANDLER MUX INTERFACE PHYSICAL INTERFACE BDLC TO J1850 BUS Figure 4-5. BDLC Block Diagram Data Sheet 68 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 4.4.1 Rx Digital Filter The receiver section of the BDLC includes a digital low pass filter to remove narrow noise pulses from the incoming message. An outline of the digital filter is shown in Figure 4-6. INPUT SYNC DATA LATCH 4-BIT UP/DOWN COUTER RX DATA FROM FILTERED RX DATA OUT D Q UP/DOWN OUT D Q PHYSICAL INTERFACE (BDRXD) MUX INTERFACE CLOCK Figure 4-6. BDLC Rx Digital Filter Block Diagram 4.4.1.1 Operation The clock for the digital filter is provided by the MUX interface clock (see fBDLC parameter in Table 4-3). At each positive edge of the clock signal, the current state of the receiver physical interface (BDRxD) signal is sampled. The BDRxD signal state is used to determine whether the counter should increment or decrement at the next negative edge of the clock signal. The counter will increment if the input data sample is high but decrement if the input sample is low. Therefore, the counter will thus progress either up toward 15 if, on average, the BDRxD signal remains high or progress down toward 0 if, on average, the BDRxD signal remains low. When the counter eventually reaches the value 15, the digital filter decides that the condition of the BDRxD signal is at a stable logic level 1 and the data latch is set, causing the filtered Rx data signal to become a logic level 1. Furthermore, the counter is prevented from overflowing and can only be decremented from this state. Alternatively, should the counter eventually reach the value 0, the digital filter decides that the condition of the BDRxD signal is at a stable logic level 0 and the data latch is reset, causing the filtered Rx data signal to become a logic level 0. Furthermore, the counter is prevented from underflowing and can only be incremented from this state. The data latch will retain its value until the counter next reaches the opposite end point, signifying a definite transition of the signal. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 69 4.4.1.2 Performance The performance of the digital filter is best described in the time domain rather than the frequency domain. If the signal on the BDRxD signal transitions, then there will be a delay before that transition appears at the filtered Rx data output signal. This delay will be between 15 and 16 clock periods, depending on where the transition occurs with respect to the sampling points. This filter delay must be taken into account when performing message arbitration. For example, if the frequency of the MUX interface clock (fBDLC) is 1.0486 MHz, then the period (tBDLC) is 954 ns and the maximum filter delay in the absence of noise will be 15.259 µs. The effect of random noise on the BDRxD signal depends on the characteristics of the noise itself. Narrow noise pulses on the BDRxD signal will be ignored completely if they are shorter than the filter delay. This provides a degree of low pass filtering. If noise occurs during a symbol transition, the detection of that transition can be delayed by an amount equal to the length of the noise burst. This is just a reflection of the uncertainty of where the transition is truly occurring within the noise. Noise pulses that are wider than the filter delay, but narrower than the shortest allowable symbol length, will be detected by the next stage of the BDLC’s receiver as an invalid symbol. Noise pulses that are longer than the shortest allowable symbol length will be detected normally as an invalid symbol or as invalid data when the frame’s CRC is checked. 4.4.2 J1850 Frame Format All messages transmitted on the J1850 bus are structured using the format shown in Figure 4-7. J1850 states that each message has a maximum length of 101 PWM bit times or 12 VPW bytes, excluding SOF, EOD, NB, and EOF, with each byte transmitted MSB first. All VPW symbol lengths in the following descriptions are typical values at a 10.4 kbps bit rate. DATA IDLE SOF PRIORITY (DATA0) MESSAGE ID (DATA1) DATAN CRC E O D OPTIONAL N B IFR EOF I F S IDLE Figure 4-7. J1850 Bus Message Format (VPW) Data Sheet 70 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor SOF — Start-of-Frame Symbol All messages transmitted onto the J1850 bus must begin with a long-active 200-µs period SOF symbol. This indicates the start of a new message transmission. The SOF symbol is not used in the CRC calculation. Data — In-Message Data Bytes The data bytes contained in the message include the message priority/type, message ID byte (typically the physical address of the responder), and any actual data being transmitted to the receiving node. The message format used by the BDLC is similar to the 3-byte consolidated header message format outlined by the SAE J1850 document. See SAE J1850 — Class B Data Communications Network Interface for more information about 1- and 3-byte headers. Messages transmitted by the BDLC onto the J1850 bus must contain at least one data byte and, therefore, can be as short as one data byte and one CRC byte. Each data byte in the message is eight bits in length and is transmitted MSB to LSB. CRC — Cyclical Redundancy Check Byte This byte is used by the receiver(s) of each message to determine if any errors have occurred during the transmission of the message. The BDLC calculates the CRC byte and appends it onto any messages transmitted onto the J1850 bus. It also performs CRC detection on any messages it receives from the J1850 bus. CRC generation uses the divisor polynomial X8 + X4 + X3 + X2 + 1. The remainder polynomial initially is set to all ones. Each byte in the message after the start of frame (SOF) symbol is processed serially through the CRC generation circuitry. The one’s complement of the remainder then becomes the 8-bit CRC byte, which is appended to the message after the data bytes in MSB-to-LSB order. When receiving a message, the BDLC uses the same divisor polynomial. All data bytes, excluding the SOF and end of data symbols (EOD) but including the CRC byte, are used to check the CRC. If the message is error free, the remainder polynomial will equal X7 + X6 + X2 = $C4, regardless of the data contained in the message. If the calculated CRC does not equal $C4, the BDLC will recognize this as a CRC error and set the CRC error flag in the BSVR. EOD — End-of-Data Symbol The EOD symbol is a long 200-µs passive period on the J1850 bus used to signify to any recipients of a message that the transmission by the originator has completed. No flag is set upon reception of the EOD symbol. IFR — In-Frame Response Bytes The IFR section of the J1850 message format is optional. Users desiring further definition of in-frame response should review the SAE J1850 — Class B Data Communications Network Interface specification. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 71 EOF — End-of-Frame Symbol This symbol is a long 280-µs passive period on the J1850 bus and is longer than an end-of-data (EOD) symbol, which signifies the end of a message. Since an EOF symbol is longer than a 200-µs EOD symbol, if no response is transmitted after an EOD symbol, it becomes an EOF, and the message is assumed to be completed. The EOF flag is set upon receiving the EOF symbol. IFS — Inter-Frame Separation Symbol The IFS symbol is a 20-µs passive period on the J1850 bus which allows proper synchronization between nodes during continuous message transmission. The IFS symbol is transmitted by a node after the completion of the end-of-frame (EOF) period and, therefore, is seen as a 300-µs passive period. When the last byte of a message has been transmitted onto the J1850 bus and the EOF symbol time has expired, all nodes then must wait for the IFS symbol time to expire before transmitting a start-of-frame (SOF) symbol, marking the beginning of another message. However, if the BDLC is waiting for the IFS period to expire before beginning a transmission and a rising edge is detected before the IFS time has expired, it will synchronize internally to that edge. If a write to the BDR register (for instance, to initiate transmission) occurred on or before 104 • tBDLC from the received rising edge, then the BDLC will transmit and arbitrate for the bus. If a CPU write to the BDR register occurred after 104 • tBDLC from the detection of the rising edge, then the BDLC will not transmit, but will wait for the next IFS period to expire before attempting to transmit the byte. A rising edge may occur during the IFS period because of varying clock tolerances and loading of the J1850 bus, causing different nodes to observe the completion of the IFS period at different times. To allow for individual clock tolerances, receivers must synchronize to any SOF occurring during an IFS period. BREAK — Break The BDLC cannot transmit a BREAK symbol. If the BDLC is transmitting at the time a BREAK is detected, it treats the BREAK as if a transmission error had occurred and halts transmission. If the BDLC detects a BREAK symbol while receiving a message, it treats the BREAK as a reception error and sets the invalid symbol flag in the BSVR, also ignoring the frame it was receiving. If while receiving a message in 4X mode, the BDLC detects a BREAK symbol, it treats the BREAK as a reception error, sets the invalid symbol flag, and exits 4X mode (for example, the RX4XE bit in BCR2 is cleared automatically). If bus control is required after the BREAK symbol is received and the IFS time has elapsed, the programmer must resend the transmission byte using highest priority. NOTE: Data Sheet 72 The J1850 protocol BREAK symbol is not related to the HC08 break module (see 17.2 Break Module (BRK)) MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor IDLE — Idle Bus An idle condition exists on the bus during any passive period after expiration of the IFS period (for instance, ≥ 300 µs). Any node sensing an idle bus condition can begin transmission immediately. 4.4.3 J1850 VPW Symbols Huntsinger’s variable pulse width modulation (VPW) is an encoding technique in which each bit is defined by the time between successive transitions and by the level of the bus between transitions (for instance, active or passive). Active and passive bits are used alternately. This encoding technique is used to reduce the number of bus transitions for a given bit rate. Each logic 1 or logic 0 contains a single transition and can be at either the active or passive level and one of two lengths, either 64 µs or 128 µs (tNOM at 10.4 kbps baud rate), depending upon the encoding of the previous bit. The start-of-frame (SOF), end-of-data (EOD), end-of-frame (EOF), and inter-frame separation (IFS) symbols always will be encoded at an assigned level and length. See Figure 4-8. Each message will begin with an SOF symbol an active symbol and, therefore, each data byte (including the CRC byte) will begin with a passive bit, regardless of whether it is a logic 1 or a logic 0. All VPW bit lengths stated in the following descriptions are typical values at a 10.4 kbps bit rate. Logic 0 A logic 0 is defined as either: – An active-to-passive transition followed by a passive period 64 µs in length, or – A passive-to-active transition followed by an active period 128 µs in length See Figure 4-8(a). Logic 1 A logic 1 is defined as either: – An active-to-passive transition followed by a passive period 128 µs in length, or – A passive-to-active transition followed by an active period 64 µs in length See Figure 4-8(b). Normalization Bit (NB) The NB symbol has the same property as a logic 1 or a logic 0. It is only used in IFR message responses. Break Signal (BREAK) The BREAK signal is defined as a passive-to-active transition followed by an active period of at least 240 µs (see Figure 4-8(c)). MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 73 ACTIVE 128 µs OR 64 µs OR 64 µs PASSIVE (A) LOGIC 0 ACTIVE 128 µs PASSIVE (B) LOGIC 1 ACTIVE 200 µs ≥ 240 µs 200 µs PASSIVE (D) START OF FRAME (C) BREAK (E) END OF DATA 300 µs ACTIVE 280 µs 20 µs IDLE > 300 µs PASSIVE (F) END OF FRAME (G) INTER-FRAME SEPARATION (H) IDLE Figure 4-8. J1850 VPW Symbols with Nominal Symbol Times Start-of-Frame Symbol (SOF) The SOF symbol is defined as passive-to-active transition followed by an active period 200 µs in length (see Figure 4-8(d)). This allows the data bytes which follow the SOF symbol to begin with a passive bit, regardless of whether it is a logic 1 or a logic 0. End-of-Data Symbol (EOD) The EOD symbol is defined as an active-to-passive transition followed by a passive period 200 µs in length (see Figure 4-8(e)). End-of-Frame Symbol (EOF) The EOF symbol is defined as an active-to-passive transition followed by a passive period 280 µs in length (see Figure 4-8(f)). If no IFR byte is transmitted after an EOD symbol is transmitted, after another 80 µs the EOD becomes an EOF, indicating completion of the message. Inter-Frame Separation Symbol (IFS) The IFS symbol is defined as a passive period 300 µs in length. The 20-µs IFS symbol contains no transition, since when used it always appends to an EOF symbol (see Figure 4-8(g)). Idle An idle is defined as a passive period greater than 300 µs in length. Data Sheet 74 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 4.4.4 J1850 VPW Valid/Invalid Bits and Symbols The timing tolerances for receiving data bits and symbols from the J1850 bus have been defined to allow for variations in oscillator frequencies. In many cases the maximum time allowed to define a data bit or symbol is equal to the minimum time allowed to define another data bit or symbol. Since the minimum resolution of the BDLC for determining what symbol is being received is equal to a single period of the MUX interface clock (tBDLC), an apparent separation in these maximum time/minimum time concurrences equal to one cycle of tBDLC occurs. This one clock resolution allows the BDLC to differentiate properly between the different bits and symbols. This is done without reducing the valid window for receiving bits and symbols from transmitters onto the J1850 bus which have varying oscillator frequencies. In Huntsinger’s’ variable pulse width (VPW) modulation bit encoding, the tolerances for both the passive and active data bits received and the symbols received are defined with no gaps between definitions. For example, the maximum length of a passive logic 0 is equal to the minimum length of a passive logic 1, and the maximum length of an active logic 0 is equal to the minimum length of a valid SOF symbol. Invalid Passive Bit See Figure 4-9(1). If the passive-to-active received transition beginning the next data bit or symbol occurs between the active-to-passive transition beginning the current data bit (or symbol) and a, the current bit would be invalid. 200 µs 128 µs 64 µs ACTIVE PASSIVE (1) INVALID PASSIVE BIT a ACTIVE (2) VALID PASSIVE LOGIC 0 PASSIVE ACTIVE a b (3) VALID PASSIVE LOGIC 1 PASSIVE ACTIVE PASSIVE b c (4) VALID EOD SYMBOL c d Figure 4-9. J1850 VPW Received Passive Symbol Times MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 75 Valid Passive Logic 0 See Figure 4-9(2). If the passive-to-active received transition beginning the next data bit (or symbol) occurs between a and b, the current bit would be considered a logic 0. Valid Passive Logic 1 See Figure 4-9(3). If the passive-to-active received transition beginning the next data bit (or symbol) occurs between b and c, the current bit would be considered a logic 1. Valid EOD Symbol See Figure 4-9(4). If the passive-to-active received transition beginning the next data bit (or symbol) occurs between c and d, the current symbol would be considered a valid end-of-data symbol (EOD). 300 µs 280 µs ACTIVE (1) VALID EOF SYMBOL PASSIVE a b ACTIVE (2) VALID EOF+ IFS SYMBOL PASSIVE c d Figure 4-10. J1850 VPW Received Passive EOF and IFS Symbol Times Valid EOF and IFS Symbol In Figure 4-10(1), if the passive-to-active received transition beginning the SOF symbol of the next message occurs between a and b, the current symbol will be considered a valid end-of-frame (EOF) symbol. See Figure 4-10(2). If the passive-to-active received transition beginning the SOF symbol of the next message occurs between c and d, the current symbol will be considered a valid EOF symbol followed by a valid inter-frame separation symbol (IFS). All nodes must wait until a valid IFS symbol time has expired before beginning transmission. However, due to variations in clock frequencies and bus loading, some nodes may recognize a valid IFS symbol before others and immediately begin transmitting. Therefore, any time a node waiting to transmit detects a passive-to-active transition once a valid EOF has been detected, it should immediately begin transmission, initiating the arbitration process. Data Sheet 76 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Idle Bus In Figure 4-10(2), if the passive-to-active received transition beginning the start-of-frame (SOF) symbol of the next message does not occur before d, the bus is considered to be idle, and any node wishing to transmit a message may do so immediately. 200 µs 128 µs 64 µs ACTIVE (1) INVALID ACTIVE BIT PASSIVE a ACTIVE (2) VALID ACTIVE LOGIC 1 PASSIVE a b ACTIVE (3) VALID ACTIVE LOGIC 0 PASSIVE b c ACTIVE (4) VALID SOF SYMBOL PASSIVE c d Figure 4-11. J1850 VPW Received Active Symbol Times Invalid Active Bit In Figure 4-11(1), if the active-to-passive received transition beginning the next data bit (or symbol) occurs between the passive-to-active transition beginning the current data bit (or symbol) and a, the current bit would be invalid. Valid Active Logic 1 In Figure 4-11(2), if the active-to-passive received transition beginning the next data bit (or symbol) occurs between a and b, the current bit would be considered a logic 1. Valid Active Logic 0 In Figure 4-11(3), if the active-to-passive received transition beginning the next data bit (or symbol) occurs between b and c, the current bit would be considered a logic 0. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 77 Valid SOF Symbol In Figure 4-11(4), if the active-to-passive received transition beginning the next data bit (or symbol) occurs between c and d, the current symbol would be considered a valid SOF symbol. Valid BREAK Symbol In Figure 4-12, if the next active-to-passive received transition does not occur until after e, the current symbol will be considered a valid BREAK symbol. A BREAK symbol should be followed by a start-of-frame (SOF) symbol beginning the next message to be transmitted onto the J1850 bus. See 4.4.2 J1850 Frame Format for BDLC response to BREAK symbols. 240 µs ACTIVE (2) VALID BREAK SYMBOL PASSIVE e Figure 4-12. J1850 VPW Received BREAK Symbol Times 4.4.5 Message Arbitration Message arbitration on the J1850 bus is accomplished in a non-destructive manner, allowing the message with the highest priority to be transmitted, while any transmitters which lose arbitration simply stop transmitting and wait for an idle bus to begin transmitting again. If the BDLC wants to transmit onto the J1850 bus, but detects that another message is in progress, it waits until the bus is idle. However, if multiple nodes begin to transmit in the same synchronization window, message arbitration will occur beginning with the first bit after the SOF symbol and will continue with each bit thereafter. The variable pulse width modulation (VPW) symbols and J1850 bus electrical characteristics are chosen carefully so that a logic 0 (active or passive type) will always dominate over a logic 1 (active or passive type) that is simultaneously transmitted. Hence, logic 0s are said to be dominant and logic 1s are said to be recessive. Whenever a node detects a dominant bit on BDRxD when it transmitted a recessive bit, the node loses arbitration and immediately stops transmitting. This is known as bitwise arbitration. Data Sheet 78 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 0 1 1 0 1 1 TRANSMITTER A DETECTS AN ACTIVE STATE ON THE BUS AND STOPS TRANSMITTING 1 ACTIVE TRANSMITTER A PASSIVE 0 0 ACTIVE TRANSMITTER B PASSIVE 0 1 1 0 0 DATA DATA DATA DATA DATA BIT 1 BIT 2 BIT 3 BIT 4 BIT 5 TRANSMITTER B WINS ARBITRATION AND CONTINUES TRANSMITTING ACTIVE J1850 BUS PASSIVE SOF Figure 4-13. J1850 VPW Bitwise Arbitrations Since a logic 0 dominates a logic 1, the message with the lowest value will have the highest priority and will always win arbitration. For instance, a message with priority 000 will win arbitration over a message with priority 011. This method of arbitration will work no matter how many bits of priority encoding are contained in the message. During arbitration, or even throughout the transmitting message, when an opposite bit is detected, transmission is stopped immediately unless it occurs on the 8th bit of a byte. In this case, the BDLC automatically will append up to two extra logic 1 bits and then stop transmitting. These two extra bits will be arbitrated normally and thus will not interfere with another message. The second logic 1 bit will not be sent if the first loses arbitration. If the BDLC has lost arbitration to another valid message, then the two extra logic 1s will not corrupt the current message. However, if the BDLC has lost arbitration due to noise on the bus, then the two extra logic 1s will ensure that the current message will be detected and ignored as a noise-corrupted message. 4.5 BDLC Protocol Handler The protocol handler is responsible for framing, arbitration, CRC generation/checking, and error detection. The protocol handler conforms to SAE J1850 — Class B Data Communications Network Interface. NOTE: Freescale assumes that the reader is familiar with the J1850 specification before this protocol handler description is read. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 79 TO CPU CPU INTERFACE PROTOCOL HANDLER MUX INTERFACE PHYSICAL INTERFACE BDLC TO J1850 BUS Figure 4-14. BDLC Block Diagram 4.5.1 Protocol Architecture The protocol handler contains the state machine, Rx shadow register, Tx shadow register, Rx shift register, Tx shift register, and loopback multiplexer as shown in Figure 4-15. 4.5.2 Rx and Tx Shift Registers The Rx shift register gathers received serial data bits from the J1850 bus and makes them available in parallel form to the Rx shadow register. The Tx shift register takes data, in parallel form, from the Tx shadow register and presents it serially to the state machine so that it can be transmitted onto the J1850 bus. 4.5.3 Rx and Tx Shadow Registers Immediately after the Rx shift register has completed shifting in a byte of data, this data is transferred to the Rx shadow register and RDRF or RXIFR is set (see 4.6.4 BDLC State Vector Register) and an interrupt is generated if the interrupt enable bit (IE) in BCR1 is set. After the transfer takes place, this new data byte in the Rx shadow register is available to the CPU interface, and the Rx shift register is ready to shift in the next byte of data. Data in the Rx shadow register must be retrieved by the CPU before it is overwritten by new data from the Rx shift register. Once the Tx shift register has completed its shifting operation for the current byte, the data byte in the Tx shadow register is loaded into the Tx shift register. After this transfer takes place, the Tx shadow register is ready to accept new data from the CPU when TDRE flag in BSVR is set. Data Sheet 80 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor TO PHYSICAL INTERFACE BDRxD ALOOP BDTxD CONTROL LOOPBACK MULTIPLEXER RxD DLOOP FROM BCR2 LOOPBACK CONTROL BDTxD STATE MACHINE Tx SHADOW REGISTER 8 Tx DATA Rx SHADOW REGISTER CONTROL Tx SHIFT REGISTER Rx DATA Rx SHIFT REGISTER 8 TO CPU INTERFACE AND Rx/Tx BUFFERS Figure 4-15. BDLC Protocol Handler Outline 4.5.4 Digital Loopback Multiplexer The digital loopback multiplexer connects RxD to either BDTxD or BDRxD, depending on the state of the DLOOP bit in the BCR2 register (see 4.6.3 BDLC Control Register 2). 4.5.5 State Machine All of the functions associated with performing the protocol are executed or controlled by the state machine. The state machine is responsible for framing, collision detection, arbitration, CRC generation/checking, and error detection. The following sections describe the BDLC’s actions in a variety of situations. 4.5.5.1 4X Mode The BDLC can exist on the same J1850 bus as modules which use a special 4X (41.6 kbps) mode of J1850 variable pulse width modulation (VPW) operation. The BDLC cannot transmit in 4X mode, but can receive messages in 4X mode, if the RX4X bit is set in BCR2 register. If the RX4X bit is not set in the BCR2 register, any 4X message on the J1850 bus is treated as noise by the BDLC and is ignored. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 81 4.5.5.2 Receiving a Message in Block Mode Although not a part of the SAE J1850 protocol, the BDLC does allow for a special block mode of operation of the receiver. As far as the BDLC is concerned, a block mode message is simply a long J1850 frame that contains an indefinite number of data bytes. All of the other features of the frame remain the same, including the SOF, CRC, and EOD symbols. Another node wishing to send a block mode transmission must first inform all other nodes on the network that this is about to happen. This is usually accomplished by sending a special predefined message. 4.5.5.3 Transmitting a Message in Block Mode A block mode message is transmitted inherently by simply loading the bytes one by one into the BDR register until the message is complete. The programmer should wait until the TDRE flag (see 4.6.4 BDLC State Vector Register) is set prior to writing a new byte of data into the BDR register. The BDLC does not contain any predefined maximum J1850 message length requirement. 4.5.5.4 J1850 Bus Errors The BDLC detects several types of transmit and receive errors which can occur during the transmission of a message onto the J1850 bus. Transmission Error If the message transmitted by the BDLC contains invalid bits or framing symbols on non-byte boundaries, this constitutes a transmission error. When a transmission error is detected, the BDLC immediately will cease transmitting. The error condition ($1C) is reflected in the BSVR register (see Table 4-5). If the interrupt enable bit (IE in BCR1) is set, a CPU interrupt request from the BDLC is generated. CRC Error A cyclical redundancy check (CRC) error is detected when the data bytes and CRC byte of a received message are processed and the CRC calculation result is not equal to $C4. The CRC code will detect any single and 2-bit errors, as well as all 8-bit burst errors and almost all other types of errors. The CRC error flag ($18 in BSVR) is set when a CRC error is detected. (See 4.6.4 BDLC State Vector Register.) Symbol Error A symbol error is detected when an abnormal (invalid) symbol is detected in a message being received from the J1850 bus. However, if the BDLC is transmitting when this happens, it will be treated as a loss of arbitration ($14 in BSVR) rather than a transmitter error. The ($1C) symbol invalid or the out-of-range flag is set when a symbol error is detected. Therefore, ($1C) symbol invalid flag is stacked behind the ($14) LOA flag during a transmission error process. (See 4.6.4 BDLC State Vector Register.) Data Sheet 82 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Framing Error A framing error is detected if an EOD or EOF symbol is detected on a non-byte boundary from the J1850 bus. A framing error also is detected if the BDLC is transmitting the EOD and instead receives an active symbol. The ($1C) symbol invalid or the out-of-range flag is set when a framing error is detected. (See 4.6.4 BDLC State Vector Register.) Bus Fault If a bus fault occurs, the response of the BDLC will depend upon the type of bus fault. If the bus is shorted to battery, the BDLC will wait for the bus to fall to a passive state before it will attempt to transmit a message. As long as the short remains, the BDLC will never attempt to transmit a message onto the J1850 bus. If the bus is shorted to ground, the BDLC will see an idle bus, begin to transmit the message, and then detect a transmission error ($1C in BSVR), since the short to ground would not allow the bus to be driven to the active (dominant) SOF state. The BDLC will abort that transmission and wait for the next CPU command to transmit. In any case, if the bus fault is temporary, as soon as the fault is cleared, the BDLC will resume normal operation. If the bus fault is permanent, it may result in permanent loss of communication on the J1850 bus. (See 4.6.4 BDLC State Vector Register.) BREAK — Break If a BREAK symbol is received while the BDLC is transmitting or receiving, an invalid symbol ($1C in BSVR) interrupt will be generated. Reading the BSVR register (see 4.6.4 BDLC State Vector Register) will clear this interrupt condition. The BDLC will wait for the bus to idle, then wait for a start-of-frame (SOF) symbol. The BDLC cannot transmit a BREAK symbol. It can only receive a BREAK symbol from the J1850 bus. 4.5.5.5 Summary Table 4-1. BDLC J1850 Bus Error Summary Error Condition BDLC Function Transmission error For invalid bits or framing symbols on non-byte boundaries, invalid symbol interrupt will be generated. BDLC stops transmission. Cyclical redundancy check (CRC) error CRC error interrupt will be generated. The BDLC will wait for SOF. Invalid symbol: BDLC receives invalid bits (noise) The BDLC will abort transmission immediately. Invalid symbol interrupt will be generated. Framing error Invalid symbol interrupt will be generated. The BDLC will wait for SOF. Bus short to VDD The BDLC will not transmit until the bus is idle. Bus short to GND Thermal overload will shut down physical interface. Fault condition is reflected in BSVR as an invalid symbol. BDLC receives BREAK symbol The BDLC will wait for the next valid SOF. Invalid symbol interrupt will be generated. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 83 4.6 BDLC CPU Interface The CPU interface provides the interface between the CPU and the BDLC and consists of five user registers. • BDLC analog and roundtrip delay register (BARD) • BDLC control register 1 (BCR1) • BDLC control register 2 (BCR2) • BDLC state vector register (BSVR) • BDLC data register (BDR) TO CPU CPU INTERFACE PROTOCOL HANDLER MUX INTERFACE PHYSICAL INTERFACE BDLC TO J1850 BUS Figure 4-16. BDLC Block Diagram 4.6.1 BDLC Analog and Roundtrip Delay Register This register programs the BDLC to compensate for various delays of different external transceivers. The default delay value is16 µs. Timing adjustments from 9 µs to 24 µs in steps of 1 µs are available. The BARD register can be written only once after each reset, after which they become read-only bits. The register may be read at any time. Address: Read: Write: Reset: $003B Bit 7 6 ATE RXPOL 1 1 R = Reserved 5 4 0 0 R R 0 0 3 2 1 Bit 0 BO3 BO2 BO1 BO0 0 1 1 1 Figure 4-17. BDLC Analog and Roundtrip Delay Register (BARD) Data Sheet 84 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor ATE — Analog Transceiver Enable Bit The analog transceiver enable (ATE) bit is used to select either the on-board or an off-chip analog transceiver. 1 = Select on-board analog transceiver 0 = Select off-chip analog transceiver NOTE: This device does not contain an on-board transceiver. This bit should be programmed to a logic 0 for proper operation. RXPOL — Receive Pin Polarity Bit The receive pin polarity (RXPOL) bit is used to select the polarity of an incoming signal on the receive pin. Some external analog transceivers invert the receive signal from the J1850 bus before feeding it back to the digital receive pin. 1 = Select normal/true polarity; true non-inverted signal from the J1850 bus; for example, the external transceiver does not invert the receive signal 0 = Select inverted polarity, where an external transceiver inverts the receive signal from the J1850 bus B03–B00 — BARD Offset Bits Table 4-2 shows the expected transceiver delay with respect to BARD offset values. Table 4-2. BDLC Transceiver Delay MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor BARD Offset Bits B0[3:0] Corresponding Expected Transceiver’s Delays (µs) 0000 9 0001 10 0010 11 0011 12 0100 13 0101 14 0110 15 0111 16 1000 17 1001 18 1010 19 1011 20 1100 21 1101 22 1110 23 1111 24 Data Sheet 85 4.6.2 BDLC Control Register 1 This register is used to configure and control the BDLC. Address: Read: Write: Reset: $003C Bit 7 6 5 4 IMSG CLKS R1 R0 1 1 1 0 R = Reserved 3 2 0 0 R R 0 0 1 Bit 0 IE WCM 0 0 Figure 4-18. BDLC Control Register 1 (BCR1) IMSG — Ignore Message Bit This bit is used to disable the receiver until a new start-of-frame (SOF) is detected. 1 = Disable receiver. When set, all BDLC interrupt requests will be masked and the status bits will be held in their reset state. If this bit is set while the BDLC is receiving a message, the rest of the incoming message will be ignored. 0 = Enable receiver. This bit is cleared automatically by the reception of an SOF symbol or a BREAK symbol. It will then generate interrupt requests and will allow changes of the status register to occur. However, these interrupts may still be masked by the interrupt enable (IE) bit. CLKS — Clock Bit The nominal BDLC operating frequency (fBDLC) must always be 1.048576 MHz or 1 MHz for J1850 bus communications to take place. The CLKS register bit allows the user to select the frequency (1.048576 MHz or 1 MHz) used to adjust symbol timing automatically. 1 = Binary frequency (1.048576 MHz) selected for fBDLC 0 = Integer frequency (1 MHz) selected for fBDLC R1 and R0 — Rate Select Bits These bits determine the amount by which the frequency of the MCU CGMXCLK signal is divided to form the MUX interface clock (fBDLC) which defines the basic timing resolution of the MUX interface. They may be written only once after reset, after which they become read-only bits. The nominal frequency of fBDLC must always be 1.048576 MHz or 1.0 MHz for J1850 bus communications to take place. Hence, the value programmed into these bits is dependent on the chosen MCU system clock frequency per Table 4-3. Data Sheet 86 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Table 4-3. BDLC Rate Selection fXCLK Frequency R1 R0 Division fBDLC 1.049 MHz 0 0 1 1.049 MHz 2.097 MHz 0 1 2 1.049 MHz 4.194 MHz 1 0 4 1.049 MHz 8.389 MHz 1 1 8 1.049 MHz 1.000 MHz 0 0 1 1.00 MHz 2.000 MHz 0 1 2 1.00 MHz 4.000 MHz 1 0 4 1.00 MHz 8.000 MHz 1 1 8 1.00 MHz IE— Interrupt Enable Bit This bit determines whether the BDLC will generate CPU interrupt requests in run mode. It does not affect CPU interrupt requests when exiting the BDLC stop or BDLC wait modes. Interrupt requests will be maintained until all of the interrupt request sources are cleared by performing the specified actions upon the BDLC’s registers. Interrupts that were pending at the time that this bit is cleared may be lost. 1 = Enable interrupt requests from BDLC 0 = Disable interrupt requests from BDLC If the programmer does not wish to use the interrupt capability of the BDLC, the BDLC state vector register (BSVR) can be polled periodically by the programmer to determine BDLC states. See 4.6.4 BDLC State Vector Register for a description of the BSVR. WCM — Wait Clock Mode Bit This bit determines the operation of the BDLC during CPU wait mode. See 4.7.2 Stop Mode and 4.7.1 Wait Mode for more details on its use. 1 = Stop BDLC internal clocks during CPU wait mode 0 = Run BDLC internal clocks during CPU wait mode MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 87 4.6.3 BDLC Control Register 2 This register controls transmitter operations of the BDLC. It is recommended that BSET and BCLR instructions be used to manipulate data in this register to ensure that the register’s content does not change inadvertently. Address: Read: Write: Reset: $003D Bit 7 6 5 4 3 2 1 Bit 0 ALOOP DLOOP RX4XE NBFS TEOD TSIFR TMIFR1 TMIFR0 1 1 0 0 0 0 0 0 Figure 4-19. BDLC Control Register 2 (BCR2) ALOOP — Analog Loopback Mode Bit This bit determines whether the J1850 bus will be driven by the analog physical interface’s final drive stage. The programmer can use this bit to reset the BDLC state machine to a known state after the off-chip analog transceiver is placed in loopback mode. When the user clears ALOOP, to indicate that the off-chip analog transceiver is no longer in loopback mode, the BDLC waits for an EOF symbol before attempting to transmit. 1 = Input to the analog physical interface’s final drive stage is looped back to the BDLC receiver. The J1850 bus is not driven. 0 = The J1850 bus will be driven by the BDLC. After the bit is cleared, the BDLC requires the bus to be idle for a minimum of end-of-frame symbol time (tTRV4) before message reception or a minimum of inter-frame symbol time (tTRV6) before message transmission. (See 18.15 BDLC Receiver VPW Symbol Timings.) DLOOP — Digital Loopback Mode Bit This bit determines the source to which the digital receive input (BDRxD) is connected and can be used to isolate bus fault conditions (see Figure 4-15). If a fault condition has been detected on the bus, this control bit allows the programmer to connect the digital transmit output to the digital receive input. In this configuration, data sent from the transmit buffer will be reflected back into the receive buffer. If no faults exist in the BDLC, the fault is in the physical interface block or elsewhere on the J1850 bus. 1 = When set, BDRxD is connected to BDTxD. The BDLC is now in digital loopback mode. 0 = When cleared, BDTxD is not connected to BDRxD. The BDLC is taken out of digital loopback mode and can now drive the J1850 bus normally. RX4XE — Receive 4X Enable Bit This bit determines if the BDLC operates at normal transmit and receive speed (10.4 kbps) or receive only at 41.6 kbps. This feature is useful for fast download of data into a J1850 node for diagnostic or factory programming of the node. 1 = When set, the BDLC is put in 4X receive-only operation. 0 = When cleared, the BDLC transmits and receives at 10.4 kbps. Data Sheet 88 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor NBFS — Normalization Bit Format Select Bit This bit controls the format of the normalization bit (NB). See Figure 4-20. SAE J1850 strongly encourages using an active long (logic 0) for in-frame responses containing cyclical redundancy check (CRC) and an active short (logic 1) for in-frame responses without CRC. 1 = NB that is received or transmitted is a 0 when the response part of an in-frame response (IFR) ends with a CRC byte. NB that is received or transmitted is a 1 when the response part of an in-frame response (IFR) does not end with a CRC byte. 0 = NB that is received or transmitted is a 1 when the response part of an in-frame response (IFR) ends with a CRC byte. NB that is received or transmitted is a 0 when the response part of an in-frame response (IFR) does not end with a CRC byte. TEOD — Transmit End of Data Bit This bit is set by the programmer to indicate the end of a message is being sent by the BDLC. It will append an 8-bit CRC after completing transmission of the current byte. This bit also is used to end an in-frame response (IFR). If the transmit shadow register is full when TEOD is set, the CRC byte will be transmitted after the current byte in the Tx shift register and the byte in the Tx shadow register have been transmitted. (See 4.5.3 Rx and Tx Shadow Registers for a description of the transmit shadow register.) Once TEOD is set, the transmit data register empty flag (TDRE) in the BDLC state vector register (BSVR) is cleared to allow lower priority interrupts to occur. (See 4.6.4 BDLC State Vector Register.) 1 = Transmit end-of-data (EOD) symbol 0 = The TEOD bit will be cleared automatically at the rising edge of the first CRC bit that is sent or if an error is detected. When TEOD is used to end an IFR transmission, TEOD is cleared when the BDLC receives back a valid EOD symbol or an error condition occurs. TSIFR, TMIFR1, and TMIFR0 — Transmit In-Frame Response Control Bits These three bits control the type of in-frame response being sent. The programmer should not set more than one of these control bits to a 1 at any given time. However, if more than one of these three control bits are set to 1, the priority encoding logic will force these register bits to a known value as shown in Table 4-4. For example, if 011 is written to TSIFR, TMIFR1, and TMIFR0, then internally they will be encoded as 010. However, when these bits are read back, they will read 011. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 89 Table 4-4. BDLC Transmit In-Frame Response Control Bit Priority Encoding Write/Read TSIFR Write/Read TMIFR1 Write/Read TMIFR0 Actual TSIFR Actual TMIFR1 Actual TMIFR0 0 0 0 0 0 0 1 X X 1 0 0 0 1 X 0 1 0 0 0 1 0 0 1 The BDLC supports the in-frame response (IFR) feature of J1850 by setting these bits correctly. The four types of J1850 IFR are shown below. The purpose of the in-frame response modes is to allow multiple nodes to acknowledge receipt of the data by responding with their personal ID or physical address in a concatenated manner after they have seen the EOD symbol. If transmission arbitration is lost by a node while sending its response, it continues to transmit its ID/address until observing its unique byte in the response stream. For VPW modulation, because the first bit of the IFR is always passive, a normalization bit (active) must be generated by the responder and sent prior to its ID/address byte. When there are multiple responders on the J1850 bus, only one normalization bit is sent which assists all other transmitting nodes to sync up their response. CRC CRC EOD DATA FIELD EOF EOD SOF HEADER TYPE 0 — NO IFR DATA FIELD NB EOF EOD SOF HEADER ID TYPE 1 — SINGLE BYTE TRANSMITTED FROM A SINGLE RESPONDER CRC NB ID1 ID N EOF EOD DATA FIELD EOD SOF HEADER TYPE 2 — SINGLE BYTE TRANSMITTED FROM MULTIPLE RESPONDERS CRC NB IFR DATA FIELD CRC (OPTIONAL) EOF EOD DATA FIELD EOD SOF HEADER TYPE 3 — MULTIPLE BYTES TRANSMITTED FROM A SINGLE RESPONDER NB = Normalization Bit ID = Identifier (usually the physical address of the responder(s)) Figure 4-20. Types of In-Frame Response (IFR) Data Sheet 90 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor TSIFR — Transmit Single Byte IFR with No CRC (Type 1 or 2) Bit The TSIFR bit is used to request the BDLC to transmit the byte in the BDLC data register (BDR, $003F) as a single byte IFR with no CRC. Typically, the byte transmitted is a unique identifier or address of the transmitting (responding) node. See Figure 4-20. 1 = If this bit is set prior to a valid EOD being received with no CRC error, once the EOD symbol has been received the BDLC will attempt to transmit the appropriate normalization bit followed by the byte in the BDR. 0 = The TSIFR bit will be cleared automatically, once the BDLC has successfully transmitted the byte in the BDR onto the bus, or TEOD is set, or an error is detected on the bus. If the programmer attempts to set the TSIFR bit immediately after the EOD symbol has been received from the bus, the TSIFR bit will remain in the reset state and no attempt will be made to transmit the IFR byte. If a loss of arbitration occurs when the BDLC attempts to transmit and after the IFR byte winning arbitration completes transmission, the BDLC will again attempt to transmit the BDR (with no normalization bit). The BDLC will continue transmission attempts until an error is detected on the bus, or TEOD is set, or the BDLC transmission is successful. If loss or arbitration occurs in the last two bits of the IFR byte, two additional 1 bits will not be sent out because the BDLC will attempt to retransmit the byte in the transmit shift register after the IRF byte winning arbitration completes transmission. TMIFR1 — Transmit Multiple Byte IFR with CRC (Type 3) Bit The TMIFR1 bit requests the BDLC to transmit the byte in the BDLC data register (BDR) as the first byte of a multiple byte IFR with CRC or as a single byte IFR with CRC. Response IFR bytes are still subject to J1850 message length maximums (see 4.4.2 J1850 Frame Format and Figure 4-20). If this bit is set prior to a valid EOD being received with no CRC error, once the EOD symbol has been received the BDLC will attempt to transmit the appropriate normalization bit followed by IFR bytes. The programmer should set TEOD after the last IFR byte has been written into the BDR register. After TEOD has been set and the last IFR byte has been transmitted, the CRC byte is transmitted. 0 = The TMIFR1 bit will be cleared automatically – once the BDLC has successfully transmitted the CRC byte and EOD symbol – by the detection of an error on the multiplex bus or by a transmitter underrun caused when the programmer does not write another byte to the BDR after the TDRE interrupt. If the TMIFR1 bit is set, the BDLC will attempt to transmit the normalization symbol followed by the byte in the BDR. After the byte in the BDR has been loaded into the transmit shift register, a TDRE interrupt (see 4.6.4 BDLC State Vector Register) will occur similar to the main message transmit sequence. The programmer should then load the next byte of the IFR into the BDR for MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 91 transmission. When the last byte of the IFR has been loaded into the BDR, the programmer should set the TEOD bit in the BDLC control register 2 (BCR2). This will instruct the BDLC to transmit a CRC byte once the byte in the BDR is transmitted and then transmit an EOD symbol, indicating the end of the IFR portion of the message frame. However, if the programmer wishes to transmit a single byte followed by a CRC byte, the programmer should load the byte into the BDR before the EOD symbol has been received, and then set the TMIFR1 bit. Once the TDRE interrupt occurs, the programmer should then set the TEOD bit in the BCR2. This will result in the byte in the BDR being the only byte transmitted before the IFR CRC byte, and no TDRE interrupt will be generated. If the programmer attempts to set the TMIFR1 bit immediately after the EOD symbol has been received from the bus, the TMIFR1 bit will remain in the reset state, and no attempt will be made to transmit an IFR byte. If a loss of arbitration occurs when the BDLC is transmitting any byte of a multiple byte IFR, the BDLC will go to the loss of arbitration state, set the appropriate flag, and cease transmission. If the BDLC loses arbitration during the IFR, the TMIFR1 bit will be cleared and no attempt will be made to retransmit the byte in the BDR. If loss of arbitration occurs in the last two bits of the IFR byte, two additional 1 bits will be sent out. NOTE: The extra logic 1s are an enhancement to the J1850 protocol which forces a byte boundary condition fault. This is helpful in preventing noise from going onto the J1850 bus from a corrupted message. TMIFR0 — Transmit Multiple Byte IFR without CRC (Type 3) Bit The TMIFR0 bit is used to request the BDLC to transmit the byte in the BDLC data register (BDR) as the first byte of a multiple byte IFR without CRC. Response IFR bytes are still subject to J1850 message length maximums (see 4.4.2 J1850 Frame Format and Figure 4-20). 1 = If this bit is set prior to a valid EOD being received with no CRC error, once the EOD symbol has been received the BDLC will attempt to transmit the appropriate normalization bit followed by IFR bytes. The programmer should set TEOD after the last IFR byte has been written into the BDR register. After TEOD has been set, the last IFR byte to be transmitted will be the last byte which was written into the BDR register. 0 = The TMIFR0 bit will be cleared automatically; once the BDLC has successfully transmitted the EOD symbol; by the detection of an error on the multiplex bus; or by a transmitter underrun caused when the programmer does not write another byte to the BDR after the TDRE interrupt. If the TMIFR0 bit is set, the BDLC will attempt to transmit the normalization symbol followed by the byte in the BDR. After the byte in the BDR has been loaded into the transmit shift register, a TDRE interrupt (see 4.6.4 BDLC State Vector Register) will occur similar to the main message transmit sequence. The programmer should then load the next byte of the IFR into the BDR for Data Sheet 92 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor transmission. When the last byte of the IFR has been loaded into the BDR, the programmer should set the TEOD bit in the BCR2. This will instruct the BDLC to transmit an EOD symbol once the byte in the BDR is transmitted, indicating the end of the IFR portion of the message frame. The BDLC will not append a CRC when the TMIFR0 is set. If the programmer attempts to set the TMIFR0 bit after the EOD symbol has been received from the bus, the TMIFR0 bit will remain in the reset state, and no attempt will be made to transmit an IFR byte. If a loss of arbitration occurs when the BDLC is transmitting, the TMIFR0 bit will be cleared and no attempt will be made to retransmit the byte in the BDR. If loss of arbitration occurs in the last two bits of the IFR byte, two additional 1 bits (active short bits) will be sent out. NOTE: The extra logic 1s are an enhancement to the J1850 protocol which forces a byte boundary condition fault. This is helpful in preventing noise from going onto the J1850 bus from a corrupted message. 4.6.4 BDLC State Vector Register This register is provided to substantially decrease the CPU overhead associated with servicing interrupts while under operation of a multiplex protocol. It provides an index offset that is directly related to the BDLC’s current state, which can be used with a user-supplied jump table to rapidly enter an interrupt service routine. This eliminates the need for the user to maintain a duplicate state machine in software. Address: $003E Bit 7 6 5 4 3 2 1 Bit 0 Read: 0 0 I3 I2 I1 I0 0 0 Write: R R R R R R R R 0 0 0 0 0 0 0 0 R = Reserved Reset: Figure 4-21. BDLC State Vector Register (BSVR) I0, I1, I2, and I3 — Interrupt Source Bits These bits indicate the source of the interrupt request that currently is pending. The encoding of these bits are listed in Table 4-5. Bits I0, I1, I2, and I3 are cleared by a read of the BSVR except when the BDLC data register needs servicing (RDRF, RXIFR, or TDRE conditions). RXIFR and RDRF can be cleared only by a read of the BSVR followed by a read of the BDLC data register (BDR). TDRE can either be cleared by a read of the BSVR followed by a write to the BDLC BDR or by setting the TEOD bit in BCR2. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 93 Table 4-5. BDLC Interrupt Sources BSVR I3 I2 I1 I0 Interrupt Source Priority $00 0 0 0 0 No interrupts pending 0 (lowest) $04 0 0 0 1 Received EOF 1 $08 0 0 1 0 Received IFR byte (RXIFR) 2 $0C 0 0 1 1 BDLC Rx data register full (RDRF) 3 $10 0 1 0 0 BDLC Tx data register empty (TDRE) 4 $14 0 1 0 1 Loss of arbitration 5 $18 0 1 1 0 Cyclical redundancy check (CRC) error 6 $1C 0 1 1 1 Symbol invalid or out of range 7 $20 1 0 0 0 Wakeup 8 (highest) Upon receiving a BDLC interrupt, the user can read the value within the BSVR, transferring it to the CPU’s index register. The value can then be used to index into a jump table, with entries four bytes apart, to quickly enter the appropriate service routine. For example: Service LDX BSVR Fetch State Vector Number JMP JMPTAB,X Enter service routine, * (must end in RTI) * JMPTAB JMP SERVE0 Service condition #0 SERVE1 Service condition #1 SERVE2 Service condition #2 SERVE8 Service condition #8 NOP JMP NOP JMP NOP * JMP END NOTE: The NOPs are used only to align the JMPs onto 4-byte boundaries so that the value in the BSVR can be used intact. Each of the service routines must end with an RTI instruction to guarantee correct continued operation of the device. Note also that the first entry can be omitted since it corresponds to no interrupt occurring. The service routines should clear all of the sources that are causing the pending interrupts. Note that the clearing of a high priority interrupt may still leave a lower priority interrupt pending, in which case bits I0, I1, and I2 of the BSVR will then reflect the source of the remaining interrupt request. If fewer states are used or if a different software approach is taken, the jump table can be made smaller or omitted altogether. Data Sheet 94 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 4.6.5 BDLC Data Register Address: $003F Read: Write: Reset: Bit 7 6 5 4 3 2 1 Bit 0 D7 D6 D5 D4 D3 D2 D1 D0 Unaffected by reset Figure 4-22. BDLC Data Register (BDR) This register is used to pass the data to be transmitted to the J1850 bus from the CPU to the BDLC. It is also used to pass data received from the J1850 bus to the CPU. Each data byte (after the first one) should be written only after a Tx data register empty (TDRE) state is indicated in the BSVR. Data read from this register will be the last data byte received from the J1850 bus. This received data should only be read after an Rx data register full (RDRF) interrupt has occurred. (See 4.6.4 BDLC State Vector Register.) The BDR is double buffered via a transmit shadow register and a receive shadow register. After the byte in the transmit shift register has been transmitted, the byte currently stored in the transmit shadow register is loaded into the transmit shift register. Once the transmit shift register has shifted the first bit out, the TDRE flag is set, and the shadow register is ready to accept the next data byte. The receive shadow register works similarly. Once a complete byte has been received, the receive shift register stores the newly received byte into the receive shadow register. The RDRF flag is set to indicate that a new byte of data has been received. The programmer has one BDLC byte reception time to read the shadow register and clear the RDRF flag before the shadow register is overwritten by the newly received byte. To abort an in-progress transmission, the programmer should stop loading data into the BDR. This will cause a transmitter underrun error and the BDLC automatically will disable the transmitter on the next non-byte boundary. This means that the earliest a transmission can be halted is after at least one byte plus two extra logic 1s have been transmitted. The receiver will pick this up as an error and relay it in the state vector register as an invalid symbol error. NOTE: The extra logic 1s are an enhancement to the J1850 protocol which forces a byte boundary condition fault. This is helpful in preventing noise from going onto the J1850 bus from a corrupted message. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 95 4.7 Low-Power Modes The following information concerns wait mode and stop mode. 4.7.1 Wait Mode This power-conserving mode is entered automatically from run mode whenever the CPU executes a WAIT instruction and the WCM bit in BDLC control register 1 (BCR1) is previously clear. In BDLC wait mode, the BDLC cannot drive any data. A subsequent successfully received message, including one that is in progress at the time that this mode is entered, will cause the BDLC to wake up and generate a CPU interrupt request if the interrupt enable (IE) bit in the BDLC control register 1 (BCR1) is previously set. (See 4.6.2 BDLC Control Register 1 for a better understanding of IE.) This results in less of a power saving, but the BDLC is guaranteed to receive correctly the message which woke it up, since the BDLC internal operating clocks are kept running. NOTE: Ensuring that all transmissions are complete or aborted before putting the BDLC into wait mode is important. 4.7.2 Stop Mode This power-conserving mode is entered automatically from run mode whenever the CPU executes a STOP instruction or if the CPU executes a WAIT instruction and the WCM bit in the BDLC control register 1 (BCR1) is previously set. This is the lowest power mode that the BDLC can enter. A subsequent passive-to-active transition on the J1850 bus will cause the BDLC to wake up and generate a non-maskable CPU interrupt request. When a STOP instruction is used to put the BDLC in stop mode, the BDLC is not guaranteed to correctly receive the message which woke it up, since it may take some time for the BDLC internal operating clocks to restart and stabilize. If a WAIT instruction is used to put the BDLC in stop mode, the BDLC is guaranteed to correctly receive the byte which woke it up, if and only if an end-of-frame (EOF) has been detected prior to issuing the WAIT instruction by the CPU. Otherwise, the BDLC will not correctly receive the byte that woke it up. If this mode is entered while the BDLC is receiving a message, the first subsequent received edge will cause the BDLC to wake up immediately, generate a CPU interrupt request, and wait for the BDLC internal operating clocks to restart and stabilize before normal communications can resume. Therefore, the BDLC is not guaranteed to receive that message correctly. NOTE: Data Sheet 96 It is important to ensure all transmissions are complete or aborted prior to putting the BDLC into stop mode. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 5. Clock Generator Module (CGM) 5.1 Introduction This section describes the clock generator module (CGM). The CGM generates the crystal clock signal, CGMXCLK, which operates at the frequency of the crystal. The CGM also generates the base clock signal, CGMOUT, from which the system integration module (SIM) derives the system clocks. CGMOUT is based on either the crystal clock divided by two or the phase-locked loop (PLL) clock, CGMVCLK, divided by two. The PLL is a frequency generator designed for use with 1-MHz to 8-MHz crystals or ceramic resonators. The PLL can generate an 8-MHz bus frequency without using a 32-MHz crystal. 5.2 Features Features of the CGM include: • Phase-locked loop with output frequency in integer multiples of the crystal reference • Programmable hardware voltage-controlled oscillator (VCO) for low-jitter operation • Automatic bandwidth control mode for low-jitter operation • Automatic frequency lock detector • CPU interrupt on entry or exit from locked condition 5.3 Functional Description The CGM consists of three major submodules: • Crystal oscillator circuit — The crystal oscillator circuit generates the constant crystal frequency clock, CGMXCLK. • Phase-locked loop (PLL) — The PLL generates the programmable VCO frequency clock, CGMVCLK. • Base clock selector circuit — This software-controlled circuit selects either CGMXCLK divided by two or the VCO clock, CGMVCLK, divided by two as the base clock, CGMOUT. The SIM derives the system clocks from CGMOUT. Figure 5-1 shows the structure of the CGM. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 97 CRYSTAL OSCILLATOR OSC2 CGMXCLK CLOCK SELECT CIRCUIT OSC1 ÷2 A CGMOUT B S* TO SIM, SCI, ADC, BDLC TO SIM *When S = 1, CGMOUT = B SIMOSCEN CGMRDV CGMRCLK VDDA BCS CGMXFC USER MODE VSS VRS[7:4] PTC3 MONITOR MODE PHASE DETECTOR VOLTAGE CONTROLLED OSCILLATOR LOOP FILTER PLL ANALOG LOCK DETECTOR LOCK BANDWIDTH CONTROL AUTO ACQ INTERRUPT CONTROL PLLIE CGMINT PLLF MUL[7:4] CGMVDV FREQUENCY DIVIDER CGMVCLK Figure 5-1. CGM Block Diagram Data Sheet 98 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Addr. $001C $001D $001E Register Name Bit 7 PLL Control Register Read: (PCTL) Write: See page 107. Reset: PLL Bandwidth Control Register Read: (PBWC) Write: See page 108. Reset: PLL Programming Register Read: (PPG) Write: See page 110. Reset: PLLIE 0 AUTO 6 PLLF 0 LOCK 5 4 PLLON BCS 1 0 ACQ XLD 3 2 1 Bit 0 1 1 1 1 R R R R 1 1 1 1 0 0 0 0 R R R R 0 0 0 0 0 0 0 0 MUL7 MUL6 MUL5 MUL4 VRS7 VRS6 VRS5 VRS4 0 1 1 0 0 1 1 0 = Unimplemented R = Reserved 1. When AUTO = 0, PLLIE is forced to logic 0 and is read-only. 2. When AUTO = 0, PLLF and LOCK read as logic 0. 3. When AUTO = 1, ACQ is read-only. 4. When PLLON = 0 or VRS[7:4] = $0, BCS is forced to logic 0 and is read-only. 5. When PLLON = 1, the PLL programming register is read-only. 6. When BCS = 1, PLLON is forced set and is read-only. Figure 5-2. CGM I/O Register Summary 5.3.1 Crystal Oscillator Circuit The crystal oscillator circuit consists of an inverting amplifier and an external crystal. The OSC1 pin is the input and the OSC2 pin is the output to the amplifier. The SIMOSCEN signal from the system integration module (SIM) enables the crystal oscillator circuit. The CGMXCLK signal is the output of the crystal oscillator circuit and runs at a rate equal to the crystal frequency. CGMXCLK is then buffered to produce CGMRCLK, the PLL reference clock. CGMXCLK can be used by other modules which require precise timing for operation. The duty cycle of CGMXCLK is not guaranteed to be 50% and depends on external factors, including the crystal and related external components. An externally generated clock also can feed the OSC1 pin of the crystal oscillator circuit. Connect the external clock to the OSC1 pin and let the OSC2 pin float. 5.3.2 Phase-Locked Loop Circuit (PLL) The PLL is a frequency generator that can operate in either acquisition mode or tracking mode, depending on the accuracy of the output frequency. The PLL can change between acquisition and tracking modes either automatically or manually. While reading this section, refer to 18.9 CGM Operating Conditions for operating frequencies. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 99 5.3.2.1 Circuits The PLL consists of these circuits: • Voltage-controlled oscillator (VCO) • Modulo VCO frequency divider • Phase detector • Loop filter • Lock detector The operating range of the VCO is programmable for a wide range of frequencies and for maximum immunity to external noise, including supply and CGMXFC noise. (For maximum immunity guidelines on electromagnetic compatibility, refer to document numbers AN1050/D and AN1263/D available from your Freescale sales office.) The VCO frequency is bound to a range from roughly one-half to twice the center-of-range frequency, fVRS. Modulating the voltage on the CGMXFC pin changes the frequency within this range. By design, fVRS is equal to the nominal center-of-range frequency, fNOM, 4.9152 MHz times a linear factor (L) or fNOM. CGMRCLK is the PLL reference clock, a buffered version of CGMXCLK. CGMRCLK runs at a crystal frequency, fRCLK, and is fed to the PLL through a buffer. The buffer output is the final reference clock, CGMRDV, running at a frequency equal to fRCLK. The VCO’s output clock, CGMVCLK, running at a frequency, fVCLK, is fed back through a programmable modulo divider. The modulo divider reduces the VCO clock by a factor, N (see 5.3.2.4 Programming the PLL). The divider’s output is the VCO feedback clock, CGMVDV, running at a frequency equal to fVCLK/N. See 18.9 CGM Operating Conditions for more information. The phase detector then compares the VCO feedback clock (CGMVDV) with the final reference clock (CGMRDV). A correction pulse is generated based on the phase difference between the two signals. The loop filter then slightly alters the dc voltage on the external capacitor connected to CGMXFC, based on the width and direction of the correction pulse. The filter can make fast or slow corrections, depending on its mode, described in 5.3.2.2 Acquisition and Tracking Modes. The value of the external capacitor and the reference frequency determines the speed of the corrections and the stability of the PLL. The lock detector compares the frequencies of the VCO feedback clock, CGMVDV, and the final reference clock, CGMRDV. Therefore, the speed of the lock detector is directly proportional to the final reference frequency, fRD. The circuit determines the mode of the PLL and the lock condition based on this comparison. Data Sheet 100 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 5.3.2.2 Acquisition and Tracking Modes The PLL filter is manually or automatically configurable into one of two operating modes: • Acquisition mode — In acquisition mode, the filter can make large (see 18.11 CGM Acquisition/Lock Time Information) frequency corrections to the VCO. This mode is used at PLL startup or when the PLL has suffered a severe noise hit and the VCO frequency is far off the desired frequency. When in acquisition mode, the ACQ bit is clear in the PLL bandwidth control register. (See 5.5.2 PLL Bandwidth Control Register.) • Tracking mode — In tracking mode, the filter makes only small (see 18.11 CGM Acquisition/Lock Time Information) corrections to the frequency of the VCO. PLL jitter is much lower in tracking mode, but the response to noise is also slower. The PLL enters tracking mode when the VCO frequency is nearly correct, such as when the PLL is selected as the base clock source. (See 5.3.3 Base Clock Selector Circuit.) The PLL is automatically in tracking mode when not in acquisition mode or when the ACQ bit is set. 5.3.2.3 Automatic and Manual PLL Bandwidth Modes The PLL can change the bandwidth or operational mode of the loop filter manually or automatically. In automatic bandwidth control mode (AUTO = 1), the lock detector automatically switches between acquisition and tracking modes. Automatic bandwidth control mode also is used to determine when the VCO clock, CGMVCLK, is safe to use as the source for the base clock, CGMOUT. (See 5.5.2 PLL Bandwidth Control Register.) If PLL interrupts are enabled, the software can wait for a PLL interrupt request and then check the LOCK bit. If interrupts are disabled, software can poll the LOCK bit continuously (during PLL startup, usually) or at periodic intervals. In either case, when the LOCK bit is set, the VCO clock is safe to use as the source for the base clock. (See 5.3.3 Base Clock Selector Circuit.) If the VCO is selected as the source for the base clock and the LOCK bit is clear, the PLL has suffered a severe noise hit and the software must take appropriate action, depending on the application. (See 5.6 Interrupts for information and precautions on using interrupts.) MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 101 The following conditions apply when the PLL is in automatic bandwidth control mode: • The ACQ bit (see 5.5.2 PLL Bandwidth Control Register) is a read-only indicator of the mode of the filter. (See 5.3.2.2 Acquisition and Tracking Modes.) • The ACQ bit is set when the VCO frequency is within a certain tolerance, ∆TRK, and is cleared when the VCO frequency is out of a certain tolerance, ∆UNT. (See 5.9 Acquisition/Lock Time Specifications for more information.) • The LOCK bit is a read-only indicator of the locked state of the PLL. • The LOCK bit is set when the VCO frequency is within a certain tolerance, ∆LOCK, and is cleared when the VCO frequency is out of a certain tolerance, ∆UNL. (See 5.9 Acquisition/Lock Time Specifications for more information.) • CPU interrupts can occur if enabled (PLLIE = 1) when the PLL’s lock condition changes, toggling the LOCK bit. (See 5.5.1 PLL Control Register.) The PLL also can operate in manual mode (AUTO = 0). Manual mode is used by systems that do not require an indicator of the lock condition for proper operation. Such systems typically operate well below fBUSMAX and require fast startup. The following conditions apply when in manual mode: • ACQ is a writable control bit that controls the mode of the filter. Before turning on the PLL in manual mode, the ACQ bit must be clear. • Before entering tracking mode (ACQ = 1), software must wait a given time, tACQ (see 5.9 Acquisition/Lock Time Specifications), after turning on the PLL by setting PLLON in the PLL control register (PCTL). • Software must wait a given time, tAL, after entering tracking mode before selecting the PLL as the clock source to CGMOUT (BCS = 1). • The LOCK bit is disabled. • CPU interrupts from the CGM are disabled. 5.3.2.4 Programming the PLL Use this procedure to program the PLL: 1. Choose the desired bus frequency, fBUSDES. Example: fBUSDES = 8 MHz 2. Calculate the desired VCO frequency, fVCLKDES. fVCLKDES = 4 × fBUSDES Example: fVCLKDES = 4 × 8 MHz = 32 MHz Data Sheet 102 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 3. Using a reference frequency, fRCLK, equal to the crystal frequency, calculate the VCO frequency multiplier, N. NOTE: The round function means that the result is rounded to the nearest integer. f VCLKDES N = round -------------------------- f RCLK 32 MHz 4 MHz Example: N = -------------------- = 8 4. Calculate the VCO frequency, fVCLK. f VCLK = N × f RCLK Example: fVCLK = 8 × 4 MHz = 32 MHz 5. Calculate the bus frequency, fBUS, and compare fBUS with fBUSDES. If the calculated fBUS is not within the tolerance limits of your application, select another fBUSDES or another fRCLK. f VCLK f BUS = ------------4 32 MHz Example: f BUS = -------------------- = 8 MHz 4 6. Using the value 4.9152 MHz for fNOM, calculate the VCO linear range multiplier, L. The linear range multiplier controls the frequency range of the PLL. f VCLK L = round --------------- f NOM 32 MHz Example: L = -------------------------------- = 7 4.9152 MHz 7. Calculate the VCO center-of-range frequency, fVRS. The center-of-range frequency is the midpoint between the minimum and maximum frequencies attainable by the PLL. fVRS = L × fNOM Example: fVRS = 7 × 4.9152 MHz = 34.4 MHz NOTE: Exceeding the recommended maximum bus frequency or VCO frequency can crash the MCU. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 103 For proper operation, f NOM f VRS – f VCLK ≤ ------------2 8. Program the PLL registers accordingly: a. In the upper four bits of the PLL programming register (PPG), program the binary equivalent of N. b. In the lower four bits of the PLL programming register (PPG), program the binary equivalent of L. 5.3.2.5 Special Programming Exceptions The programming method described in 5.3.2.4 Programming the PLL does not account for two possible exceptions. A value of zero for N or L is meaningless when used in the equations given. To account for these exceptions: • A zero value for N is interpreted exactly the same as a value of one. • A zero value for L disables the PLL and prevents its selection as the source for the base clock. (See 5.3.3 Base Clock Selector Circuit.) 5.3.3 Base Clock Selector Circuit This circuit is used to select either the crystal clock (CGMXCLK) or the VCO clock (CGMVCLK) as the source of the base clock (CGMOUT). The two input clocks go through a transition control circuit that waits up to three CGMXCLK cycles and three CGMVCLK cycles to change from one clock source to the other. During this time, CGMOUT is held in stasis. The output of the transition control circuit is then divided by two to correct the duty cycle. Therefore, the bus clock frequency, which is one-half of the base clock frequency, is one-fourth the frequency of the selected clock (CGMXCLK or CGMVCLK). The BCS bit in the PLL control register (PCTL) selects which clock drives CGMOUT. The VCO clock cannot be selected as the base clock source if the PLL is not turned on. The PLL cannot be turned off if the VCO clock is selected. The PLL cannot be turned on or off simultaneously with the selection or deselection of the VCO clock. The VCO clock also cannot be selected as the base clock source if the factor L is programmed to a zero. This value would set up a condition inconsistent with the operation of the PLL, so that the PLL would be disabled and the crystal clock would be forced as the source of the base clock. Data Sheet 104 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 5.3.4 CGM External Connections In its typical configuration, the CGM requires seven external components. Five of these are for the crystal oscillator and two are for the PLL. The crystal oscillator is normally connected in a Pierce oscillator configuration, as shown in Figure 5-3. Figure 5-3 shows only the logical representation of the internal components and may not represent actual circuitry. The oscillator configuration uses five components: • Crystal, X1 • Fixed capacitor, C1 • Tuning capacitor, C2, can also be a fixed capacitor • Feedback resistor, RB • Series resistor, RS, optional The series resistor (RS) is included in the diagram to follow strict Pierce oscillator guidelines and may not be required for all ranges of operation, especially with high-frequency crystals. Refer to the crystal manufacturer’s data for more information. Figure 5-3 also shows the external components for the PLL: • Bypass capacitor, CBYP • Filter capacitor, CF Routing should be done with great care to minimize signal cross talk and noise. (See 5.9 Acquisition/Lock Time Specifications for routing information and more information on the filter capacitor’s value and its effects on PLL performance.) SIMOSCEN CGMXCLK OSC1 OSC2 RS * VSS CGMXFC C1 VDD CF CBYP RB X1 VDDA/VDDAREF *RS can be 0 (shorted) when used with higher-frequency crystals. Refer to manufacturer’s data. C2 Figure 5-3. CGM External Connections MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 105 5.4 I/O Signals The following paragraphs describe the CGM input/output (I/O) signals. 5.4.1 Crystal Amplifier Input Pin (OSC1) The OSC1 pin is an input to the crystal oscillator amplifier. 5.4.2 Crystal Amplifier Output Pin (OSC2) The OSC2 pin is the output of the crystal oscillator inverting amplifier. 5.4.3 External Filter Capacitor Pin (CGMXFC) The CGMXFC pin is required by the loop filter to filter out phase corrections. A small external capacitor is connected to this pin. NOTE: To prevent noise problems, CF should be placed as close to the CGMXFC pin as possible, with minimum routing distances and no routing of other signals across the CF connection. 5.4.4 Analog Power Pin (VDDA/VDDAREF) VDDA/VDDAREF is a power pin used by the analog portions of the PLL. Connect the VDDA/VDDAREF pin to the same voltage potential as the VDD pin. NOTE: Route VDDA/VDDAREF carefully for maximum noise immunity and place bypass capacitors as close as possible to the package. 5.4.5 Oscillator Enable Signal (SIMOSCEN) The SIMOSCEN signal comes from the system integration module (SIM) and enables the oscillator and PLL. 5.4.6 Crystal Output Frequency Signal (CGMXCLK) CGMXCLK is the crystal oscillator output signal. It runs at the full speed of the crystal, fXCLK, and comes directly from the crystal oscillator circuit. Figure 5-3 shows only the logical relation of CGMXCLK to OSC1 and OSC2 and may not represent the actual circuitry. The duty cycle of CGMXCLK is unknown and may depend on the crystal and other external factors. Also, the frequency and amplitude of CGMXCLK can be unstable at startup. 5.4.7 CGM Base Clock Output (CGMOUT) CGMOUT is the clock output of the CGM. This signal goes to the SIM, which generates the MCU clocks. CGMOUT is a 50% duty cycle clock running at twice the bus frequency. CGMOUT is software programmable to be either the oscillator output, CGMXCLK, divided by two or the VCO clock, CGMVCLK, divided by two. Data Sheet 106 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 5.4.8 CGM CPU Interrupt (CGMINT) CGMINT is the interrupt signal generated by the PLL lock detector. 5.5 CGM Registers These registers control and monitor operation of the CGM: • PLL control register (PCTL) (See 5.5.1 PLL Control Register.) • PLL bandwidth control register (PBWC) (See 5.5.2 PLL Bandwidth Control Register.) • PLL programming register (PPG) (See 5.5.3 PLL Programming Register.) Figure 5-2 is a summary of the CGM registers. 5.5.1 PLL Control Register The PLL control register contains the interrupt enable and flag bits, the on/off switch, and the base clock selector bit. Address: $001C Bit 7 Read: Write: Reset: PLLIE 0 6 PLLF 0 5 4 PLLON BCS 1 = Unimplemented 3 2 1 Bit 0 1 1 1 1 R R R R 0 1 1 1 1 R = Reserved Figure 5-4. PLL Control Register (PCTL) PLLIE — PLL Interrupt Enable Bit This read/write bit enables the PLL to generate an interrupt request when the LOCK bit toggles, setting the PLL flag, PLLF. When the AUTO bit in the PLL bandwidth control register (PBWC) is clear, PLLIE cannot be written and reads as logic 0. Reset clears the PLLIE bit. 1 = PLL interrupts enabled 0 = PLL interrupts disabled PLLF — PLL Flag Bit This read-only bit is set whenever the LOCK bit toggles. PLLF generates an interrupt request if the PLLIE bit also is set. PLLF always reads as logic 0 when the AUTO bit in the PLL bandwidth control register (PBWC) is clear. Clear the PLLF bit by reading the PLL control register. Reset clears the PLLF bit. 1 = Change in lock condition 0 = No change in lock condition NOTE: Do not inadvertently clear the PLLF bit. Any read or read-modify-write operation on the PLL control register clears the PLLF bit. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 107 PLLON — PLL On Bit This read/write bit activates the PLL and enables the VCO clock, CGMVCLK. PLLON cannot be cleared if the VCO clock is driving the base clock, CGMOUT (BCS = 1). (See 5.3.3 Base Clock Selector Circuit.) Reset sets this bit so that the loop can stabilize as the MCU is powering up. 1 = PLL on 0 = PLL off BCS — Base Clock Select Bit This read/write bit selects either the crystal oscillator output, CGMXCLK, or the VCO clock, CGMVCLK, as the source of the CGM output, CGMOUT. CGMOUT frequency is one-half the frequency of the selected clock. BCS cannot be set while the PLLON bit is clear. After toggling BCS, it may take up to three CGMXCLK cycles and three CGMVCLK cycles to complete the transition from one source clock to the other. During the transition, CGMOUT is held in stasis. (See 5.3.3 Base Clock Selector Circuit.) Reset and the STOP instruction clear the BCS bit. 1 = CGMVCLK divided by two drives CGMOUT 0 = CGMXCLK divided by two drives CGMOUT NOTE: PLLON and BCS have built-in protection that prevents the base clock selector circuit from selecting the VCO clock as the source of the base clock if the PLL is off. Therefore, PLLON cannot be cleared when BCS is set, and BCS cannot be set when PLLON is clear. If the PLL is off (PLLON = 0), selecting CGMVCLK requires two writes to the PLL control register. (See 5.3.3 Base Clock Selector Circuit.) PCTL[3:0] — Unimplemented bits These bits provide no function and always read as logic 1s. 5.5.2 PLL Bandwidth Control Register The PLL bandwidth control register: • Selects automatic or manual (software-controlled) bandwidth control mode • Indicates when the PLL is locked • In automatic bandwidth control mode, indicates when the PLL is in acquisition or tracking mode • In manual operation, forces the PLL into acquisition or tracking mode Address: $001D Bit 7 Read: Write: Reset: AUTO 0 6 LOCK 0 5 4 ACQ XLD 0 0 3 2 1 Bit 0 0 0 0 0 0 0 0 0 = Unimplemented Figure 5-5. PLL Bandwidth Control Register (PBWC) Data Sheet 108 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor AUTO — Automatic Bandwidth Control Bit This read/write bit selects automatic or manual bandwidth control. When initializing the PLL for manual operation (AUTO = 0), clear the ACQ bit before turning on the PLL. Reset clears the AUTO bit. 1 = Automatic bandwidth control 0 = Manual bandwidth control LOCK — Lock Indicator Bit When the AUTO bit is set, LOCK is a read-only bit that becomes set when the VCO clock, CGMVCLK, is locked (running at the programmed frequency). When the AUTO bit is clear, LOCK reads as logic 0 and has no meaning. Reset clears the LOCK bit. 1 = VCO frequency correct or locked 0 = VCO frequency incorrect or unlocked ACQ — Acquisition Mode Bit When the AUTO bit is set, ACQ is a read-only bit that indicates whether the PLL is in acquisition mode or tracking mode. When the AUTO bit is clear, ACQ is a read/write bit that controls whether the PLL is in acquisition mode or tracking mode. In automatic bandwidth control mode (AUTO = 1), the last-written value from manual operation is stored in a temporary location and is recovered when manual operation resumes. Reset clears this bit, enabling acquisition mode. 1 = Tracking mode 0 = Acquisition mode XLD — Crystal Loss Detect Bit When the VCO output (CGMVCLK) is driving CGMOUT, this read/write bit can indicate whether the crystal reference frequency is active or not. To check the status of the crystal reference, follow these steps: 1. Write a logic 1 to XLD. 2. Wait N × 4 cycles. (N is the VCO frequency multiplier.) 3. Read XLD. 1 = Crystal reference not active 0 = Crystal reference active The crystal loss detect function works only when the BCS bit is set, selecting CGMVCLK to drive CGMOUT. When BCS is clear, XLD always reads as logic 0. PBWC[3:0] — Reserved for Test These bits enable test functions not available in user mode. To ensure software portability from development systems to user applications, software should write 0s to PBWC[3:0] whenever writing to PBWC. 5.5.3 PLL Programming Register The PLL programming register contains the programming information for the modulo feedback divider and the programming information for the hardware configuration of the VCO. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 109 Address: $001E Read: Write: Reset: Bit 7 6 5 4 3 2 1 Bit 0 MUL7 MUL6 MUL5 MUL4 VRS7 VRS6 VRS5 VRS4 0 1 1 0 0 1 1 0 Figure 5-6. PLL Programming Register (PPG) MUL[7:4] — Multiplier Select Bits These read/write bits control the modulo feedback divider that selects the VCO frequency multiplier, N. (See 5.3.2 Phase-Locked Loop Circuit (PLL).) A value of $0 in the multiplier select bits configures the modulo feedback divider the same as a value of $1. Reset initializes these bits to $6 to give a default multiply value of 6. Table 5-1. VCO Frequency Multiplier (N) Selection NOTE: MUL7:MUL6:MUL5:MUL4 VCO Frequency Multiplier (N) 0000 1 0001 1 0010 2 0011 3 1101 13 1110 14 1111 15 The multiplier select bits have built-in protection that prevents them from being written when the PLL is on (PLLON = 1). VRS[7:4] — VCO Range Select Bits These read/write bits control the hardware center-of-range linear multiplier, L, which controls the hardware center-of-range frequency, fVRS, (see 5.3.2 Phase-Locked Loop Circuit (PLL)). VRS[7:4] cannot be written when the PLLON bit in the PLL control register (PCTL) is set. (See 5.3.2.5 Special Programming Exceptions.) A value of $0 in the VCO range selects bits, disables the PLL, and clears the BCS bit in the PCTL. (See 5.3.3 Base Clock Selector Circuit and 5.3.2.5 Special Programming Exceptions for more information.) Reset initializes the bits to $6 to give a default range multiply value of 6. NOTE: The VCO range select bits have built-in protection that prevents them from being written when the PLL is on (PLLON = 1) and prevents selection of the VCO clock as the source of the base clock (BCS = 1) if the VCO range select bits are all clear. The VCO range select bits must be programmed correctly. Incorrect programming can result in failure of the PLL to achieve lock. Data Sheet 110 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 5.6 Interrupts When the AUTO bit is set in the PLL bandwidth control register (PBWC), the PLL can generate a CPU interrupt request every time the LOCK bit changes state. The PLLIE bit in the PLL control register (PCTL) enables CPU interrupts from the PLL. PLLF, the interrupt flag in the PCTL, becomes set whether interrupts are enabled or not. When the AUTO bit is clear, CPU interrupts from the PLL are disabled and PLLF reads as logic 0. Software should read the LOCK bit after a PLL interrupt request to see if the request was due to an entry into lock or an exit from lock. When the PLL enters lock, the VCO clock, CGMVCLK, divided by two can be selected as the CGMOUT source by setting BCS in the PCTL. When the PLL exits lock, the VCO clock frequency is corrupt, and appropriate precautions should be taken. If the application is not frequency sensitive, interrupts should be disabled to prevent PLL interrupt service routines from impeding software performance or from exceeding stack limitations. NOTE: Software can select the CGMVCLK divided by two as the CGMOUT source even if the PLL is not locked (LOCK = 0). Therefore, software should make sure the PLL is locked before setting the BCS bit. 5.7 Special Modes The WAIT and STOP instructions put the MCU in low-power standby modes. 5.7.1 Wait Mode The WAIT instruction does not affect the CGM. Before entering wait mode, software can disengage and turn off the PLL by clearing the BCS and PLLON bits in the PLL control register (PCTL). Less power-sensitive applications can disengage the PLL without turning it off. Applications that require the PLL to wake the MCU from wait mode also can deselect the PLL output without turning off the PLL. 5.7.2 Stop Mode When the STOP instruction executes, the SIM drives the SIMOSCEN signal low, disabling the CGM and holding low all CGM outputs (CGMXCLK, CGMOUT, and CGMINT). If the STOP instruction is executed with the VCO clock (CGMVCLK) divided by two driving CGMOUT, the PLL automatically clears the BCS bit in the PLL control register (PCTL), thereby selecting the crystal clock (CGMXCLK) divided by two as the source of CGMOUT. When the MCU recovers from STOP, the crystal clock divided by two drives CGMOUT and BCS remains clear. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 111 5.8 CGM During Break Interrupts The system integration module (SIM) controls whether status bits in other modules can be cleared during the break state. The BCFE bit in the SIM break flag control register (SBFCR) enables software to clear status bits during the break state. (See 14.7.3 SIM Break Flag Control Register.) To allow software to clear status bits during a break interrupt, write a logic 1 to the BCFE bit. If a status bit is cleared during the break state, it remains cleared when the MCU exits the break state. To protect the PLLF bit during the break state, write a logic 0 to the BCFE bit. With BCFE at logic 0 (its default state), software can read and write the PLL control register during the break state without affecting the PLLF bit. 5.9 Acquisition/Lock Time Specifications The acquisition and lock times of the PLL are, in many applications, the most critical PLL design parameters. Proper design and use of the PLL ensure the highest stability and lowest acquisition/lock times. 5.9.1 Acquisition/Lock Time Definitions Typical control systems refer to the acquisition time or lock time as the reaction time, within specified tolerances, of the system to a step input. In a PLL, the step input occurs when the PLL is turned on or when it suffers a noise hit. The tolerance usually is specified as a percent of the step input or when the output settles to the desired value plus or minus a percent of the frequency change. Therefore, the reaction time is constant in this definition, regardless of the size of the step input. For example, consider a system with a 5% acquisition time tolerance. If a command instructs the system to change from 0 Hz to 1 MHz, the acquisition time is the time taken for the frequency to reach 1 MHz ±50 kHz. 50 kHz = 5% of the 1-MHz step input. If the system is operating at 1 MHz and suffers a –100-kHz noise hit, the acquisition time is the time taken to return from 900 kHz to 1 MHz ±5 kHz. 5 kHz = 5% of the 100-kHz step input. Other systems refer to acquisition and lock times as the time the system takes to reduce the error between the actual output and the desired output to within specified tolerances. Therefore, the acquisition time or lock time vary according to the original error in the output. Minor errors may not even be registered. Typical PLL applications prefer to use this definition because the system requires the output frequency to be within a certain tolerance of the desired frequency regardless of the size of the initial error. Data Sheet 112 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor The discrepancy in these definitions makes it difficult to specify an acquisition or lock time for a typical PLL. Therefore, the definitions for acquisition and lock times for this module are: • Acquisition time, tACQ, is the time the PLL takes to reduce the error between the actual output frequency and the desired output frequency to less than the tracking mode entry tolerance, ∆TRK. Acquisition time is based on an initial frequency error, [(fDES – fORIG)/fDES], of not more than ±100%. In automatic bandwidth control mode (see 5.3.2.3 Automatic and Manual PLL Bandwidth Modes), acquisition time expires when the ACQ bit becomes set in the PLL bandwidth control register (PBWC). • Lock time, tLock, is the time the PLL takes to reduce the error between the actual output frequency and the desired output frequency to less than the lock mode entry tolerance, ∆Lock. Lock time is based on an initial frequency error, [(fDES – fORIG)/fDES], of not more than ±100%. In automatic bandwidth control mode, lock time expires when the LOCK bit becomes set in the PLL bandwidth control register (PBWC). (See 5.3.2.3 Automatic and Manual PLL Bandwidth Modes.) Obviously, the acquisition and lock times can vary according to how large the frequency error is and may be shorter or longer in many cases. 5.9.2 Parametric Influences on Reaction Time Acquisition and lock times are designed to be as short as possible while still providing the highest possible stability. These reaction times are not constant, however. Many factors directly and indirectly affect the acquisition time. The most critical parameter which affects the PLL reaction times is the reference frequency, fRDV. This frequency is the input to the phase detector and controls how often the PLL makes corrections. For stability, the corrections must be small compared to the desired frequency, so several corrections are required to reduce the frequency error. Therefore, the slower the reference the longer it takes to make these corrections. This parameter is also under user control via the choice of an external crystal frequency, fXCLK. Another critical parameter is the external filter capacitor. The PLL modifies the voltage on the VCO by adding or subtracting charge from this capacitor. Therefore, the rate at which the voltage changes for a given frequency error (thus change in charge) is proportional to the capacitor size. The size of the capacitor also is related to the stability of the PLL. If the capacitor is too small, the PLL cannot make small enough adjustments to the voltage and the system cannot lock. If the capacitor is too large, the PLL may not be able to adjust the voltage in a reasonable time. (See 5.9.3 Choosing a Filter Capacitor.) Also important is the operating voltage potential applied to the PLL analog portion potential (VDDA/VDDAREF). Typically, VDDA/VDDAREF is at the same potential as VDD. The power supply potential alters the characteristics of the PLL. A fixed value MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 113 is best. Variable supplies, such as batteries, are acceptable if they vary within a known range at very slow speeds. Noise on the power supply is not acceptable, because it causes small frequency errors which continually change the acquisition time of the PLL. Temperature and processing also can affect acquisition time because the electrical characteristics of the PLL change. The part operates as specified as long as these influences stay within the specified limits. External factors, however, can cause drastic changes in the operation of the PLL. These factors include noise injected into the PLL through the filter capacitor, filter capacitor leakage, stray impedances on the circuit board, and even humidity or circuit board contamination. 5.9.3 Choosing a Filter Capacitor As described in 5.9.2 Parametric Influences on Reaction Time, the external filter capacitor, CF, is critical to the stability and reaction time of the PLL. The PLL is also dependent on reference frequency, fRDV, and supply voltage, VDD. The value of the capacitor, therefore, must be chosen with supply potential and reference frequency in mind. For proper operation, the external filter capacitor must be chosen according to the following equation. Refer to 5.3.2 Phase-Locked Loop Circuit (PLL) for the value of fRDV and 18.10 CGM Component Information for the value of CFACT. V DDA C F = C FACT --------------- f RDV For the value of VDDA, choose the voltage potential at which the MCU is operating. If the power supply is variable, choose a value near the middle of the range of possible supply values. This equation does not always yield a commonly available capacitor size, so round to the nearest available size. If the value is between two different sizes, choose the higher value for better stability. Choosing the lower size may seem attractive for acquisition time improvement, but the PLL can become unstable. Also, always choose a capacitor with a tight tolerance (±20% or better) and low dissipation. 5.9.4 Reaction Time Calculation The actual acquisition and lock times can be calculated using the equations in this subsection. These equations yield nominal values under the following conditions: Data Sheet 114 • Correct selection of filter capacitor, CF (See 5.9.3 Choosing a Filter Capacitor.) • Room temperature operation • Negligible external leakage on CGMXFC • Negligible noise MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor The K factor in the equations is derived from internal PLL parameters. KACQ is the K factor when the PLL is configured in acquisition mode, and KTRK is the K factor when the PLL is configured in tracking mode. (See 5.3.2.2 Acquisition and Tracking Modes.) V DDA 8 t ACQ = -------------- -------------- f RDV K ACQ V DDA 4 t AL = -------------- ------------- f RDV K TRK t Lock = t ACQ + t AL NOTE: There is an inverse proportionality between the lock time and the reference frequency. In automatic bandwidth control mode, the acquisition and lock times are quantized into units based on the reference frequency. (See 5.3.2.3 Automatic and Manual PLL Bandwidth Modes.) A certain number of clock cycles, nACQ, is required to ascertain that the PLL is within the tracking mode entry tolerance, ∆TRK, before exiting acquisition mode. Additionally, a certain number of clock cycles, nTRK, is required to ascertain that the PLL is within the lock mode entry tolerance, ∆Lock. Therefore, the acquisition time, tACQ, is an integer multiple of nACQ/fRDV, and the acquisition to lock time, tAL, is an integer multiple of nTRK/fRDV. Refer to 5.3.2 Phase-Locked Loop Circuit (PLL) for the value of fRDV. Also, since the average frequency over the entire measurement period must be within the specified tolerance, the total time usually is longer than tLock as calculated above. In manual mode, it is usually necessary to wait considerably longer than tLock before selecting the PLL clock (see 5.3.3 Base Clock Selector Circuit), because the factors described in 5.9.2 Parametric Influences on Reaction Time can slow the lock time considerably. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 115 Data Sheet 116 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 6. Computer Operating Properly (COP) 6.1 Introduction This section describes the computer operating properly (COP) module, a free-running counter that generates a reset if allowed to overflow. The COP module helps software recover from runaway code. Prevent a COP reset by periodically clearing the COP counter. 6.2 Functional Description Figure 6-1 shows the structure of the COP module. The COP counter is a free-running 6-bit counter preceded by the 12-bit system integration module (SIM) counter. COP timeouts are determined strictly by the CGM crystal oscillator clock signal (CGMXCLK), not the CGMOUT signal (see Figure 5-1. CGM Block Diagram). If not cleared by software, the COP counter overflows and generates an asynchronous reset after (213 – 24) or (218 – 24) CGMXCLK cycles, depending upon COPS bit in the MORA register ($001F) (See Section 10. Mask Options.) With a 4.9152-MHz crystal and the COPS bit in the MORA register ($001F) set to a logic 1, the COP timeout period is approximately 53.3 ms. Writing any value to location $FFFF before overflow occurs clears the COP counter, clears stages 12 through 5 of the SIM counter, and prevents reset. A CPU interrupt routine can be used to clear the COP. NOTE: The COP should be serviced as soon as possible out of reset and before entering or after exiting stop mode to guarantee the maximum selected amount of time before the first timeout. A COP reset pulls the RST pin low for 32 CGMXCLK cycles and sets the COP bit in the SIM reset status register (SRSR) (see 14.7.2 SIM Reset Status Register). While the microcontroller is in monitor mode, the COP module is disabled if the RST pin or the IRQ pin is held at VTST (see 18.5 5.0-Volt DC Electrical Characteristics). During a break state, VTST on the RST pin disables the COP module. NOTE: Place COP clearing instructions in the main program and not in an interrupt subroutine. Such an interrupt subroutine could keep the COP from generating a reset even while the main program is not working properly. The one exception to this is wait mode (see 6.7.1 Wait Mode). MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 117 SIM CLEAR STAGES 12–5 STOP INSTRUCTION INTERNAL RESET SOURCES(1) RESET VECTOR FETCH 12-BIT SIM COUNTER CLEAR ALL STAGES CGMXCLK SIM RESET CIRCUIT SIM RESET STATUS REGISTER COPCTL WRITE COP MODULE COPEN (FROM SIM) COPD (FROM MORA) 6-BIT COP COUNTER RESET CLEAR COP COUNTER COPCTL WRITE COPS 1. See 14.3.2 Active Resets from Internal Sources. Figure 6-1. COP Block Diagram 6.3 I/O Signals The following paragraphs describe the signals shown in Figure 6-1. 6.3.1 CGMXCLK CGMXCLK is the crystal oscillator output signal. CGMXCLK frequency is equal to the crystal frequency. 6.3.2 STOP Instruction The STOP instruction clears the SIM counter. Data Sheet 118 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 6.3.3 COPCTL Write Writing any value to the COP control register (COPCTL) (see 6.4 COP Control Register) clears the COP counter and clears stages 12 through 5 of the SIM counter. Reading the COP control register returns the reset vector. 6.3.4 Internal Reset Resources An internal reset clears the SIM counter and the COP counter. (See 14.3.2 Active Resets from Internal Sources.) 6.3.5 Reset Vector Fetch A reset vector fetch occurs when the vector address appears on the data bus. A reset vector fetch clears the SIM counter. 6.3.6 COPD (COP Disable) The COPD bit reflects the state of the COP disable bit (COPD) in the MORA register ($001F). This signal disables COP-generated resets when asserted. (See Section 10. Mask Options.) 6.3.7 COPS (COP Short Timeout) The COPS bit selects the state of the COP short timeout bit (COPS) in the MORA register ($001F). Timeout periods can be (218 –24) or (213 –24) CGMXCLK cycles. (See 10.3 Mask Option Registers (MORA and MORB).) 6.4 COP Control Register The COP control register is located at address $FFFF and overlaps the reset vector. Writing any value to $FFFF clears the COP counter and starts a new timeout period. Reading location $FFFF returns the low byte of the reset vector. Address: $FFFF Bit 7 6 5 4 3 Read: Low byte of reset vector Write: Clear COP counter Reset: Unaffected by reset 2 1 Bit 0 Figure 6-2. COP Control Register (COPCTL) 6.5 Interrupts The COP does not generate CPU interrupt requests. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 119 6.6 Monitor Mode The COP is disabled in monitor mode when VTST (see 18.5 5.0-Volt DC Electrical Characteristics) is present on the IRQ pin or on the RST pin. 6.7 Low-Power Modes The following subsections describe the low-power modes. 6.7.1 Wait Mode The COP continues to operate during wait mode. To prevent a COP reset during wait mode, periodically clear the COP counter in a CPU interrupt routine. NOTE: If the COP is enabled in wait mode, it must be periodically refreshed. (See 6.3.6 COPD (COP Disable).) 6.7.2 Stop Mode Stop mode turns off the CGMXCLK input to the COP and clears the SIM counter. Service the COP immediately before entering or after exiting stop mode to ensure a full COP timeout period after entering or exiting stop mode. The STOP bit in the MORA register ($001F) (see Section 10. Mask Options) enables the STOP instruction. To prevent inadvertently turning off the COP with a STOP instruction, disable the STOP instruction by programming the STOP bit to logic 0. 6.8 COP Module During Break Interrupts The COP is disabled during a break interrupt when VTST (see 18.5 5.0-Volt DC Electrical Characteristics) is present on the RST pin. Data Sheet 120 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 7. Central Processor Unit (CPU) 7.1 Introduction The M68HC08 CPU (central processor unit) is an enhanced and fully object-code-compatible version of the M68HC05 CPU. The CPU08 Reference Manual (Freescale document order number CPU08RM/AD) contains a description of the CPU instruction set, addressing modes, and architecture. 7.2 Features Features of the CPU include: MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor • Object code fully upward-compatible with M68HC05 Family • 16-bit stack pointer with stack manipulation instructions • 16-bit index register with x-register manipulation instructions • 8-MHz CPU internal bus frequency • 64-Kbyte program/data memory space • 16 addressing modes • Memory-to-memory data moves without using accumulator • Fast 8-bit by 8-bit multiply and 16-bit by 8-bit divide instructions • Enhanced binary-coded decimal (BCD) data handling • Modular architecture with expandable internal bus definition for extension of addressing range beyond 64 Kbytes • Low-power stop and wait modes Data Sheet 121 7.3 CPU Registers Figure 7-1 shows the five CPU registers. CPU registers are not part of the memory map. 0 7 ACCUMULATOR (A) 0 15 H X INDEX REGISTER (H:X) 15 0 STACK POINTER (SP) 15 0 PROGRAM COUNTER (PC) 7 0 V 1 1 H I N Z C CONDITION CODE REGISTER (CCR) CARRY/BORROW FLAG ZERO FLAG NEGATIVE FLAG INTERRUPT MASK HALF-CARRY FLAG TWO’S COMPLEMENT OVERFLOW FLAG Figure 7-1. CPU Registers 7.3.1 Accumulator The accumulator is a general-purpose 8-bit register. The CPU uses the accumulator to hold operands and the results of arithmetic/logic operations. Bit 7 6 5 4 3 2 1 Bit 0 Read: Write: Reset: Unaffected by reset Figure 7-2. Accumulator (A) Data Sheet 122 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 7.3.2 Index Register The 16-bit index register allows indexed addressing of a 64-Kbyte memory space. H is the upper byte of the index register, and X is the lower byte. H:X is the concatenated 16-bit index register. In the indexed addressing modes, the CPU uses the contents of the index register to determine the conditional address of the operand. The index register can serve also as a temporary data storage location. Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 Bit 0 0 0 0 0 0 0 0 0 X X X X X X X X Read: Write: Reset: X = Indeterminate Figure 7-3. Index Register (H:X) 7.3.3 Stack Pointer The stack pointer is a 16-bit register that contains the address of the next location on the stack. During a reset, the stack pointer is preset to $00FF. The reset stack pointer (RSP) instruction sets the least significant byte to $FF and does not affect the most significant byte. The stack pointer decrements as data is pushed onto the stack and increments as data is pulled from the stack. In the stack pointer 8-bit offset and 16-bit offset addressing modes, the stack pointer can function as an index register to access data on the stack. The CPU uses the contents of the stack pointer to determine the conditional address of the operand. Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 Bit 0 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 Read: Write: Reset: Figure 7-4. Stack Pointer (SP) NOTE: The location of the stack is arbitrary and may be relocated anywhere in random-access memory (RAM). Moving the SP out of page 0 ($0000 to $00FF) frees direct address (page 0) space. For correct operation, the stack pointer must point only to RAM locations. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 123 7.3.4 Program Counter The program counter is a 16-bit register that contains the address of the next instruction or operand to be fetched. Normally, the program counter automatically increments to the next sequential memory location every time an instruction or operand is fetched. Jump, branch, and interrupt operations load the program counter with an address other than that of the next sequential location. During reset, the program counter is loaded with the reset vector address located at $FFFE and $FFFF. The vector address is the address of the first instruction to be executed after exiting the reset state. Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 Bit 0 1 Read: Write: Reset: Loaded with vector from $FFFE and $FFFF Figure 7-5. Program Counter (PC) 7.3.5 Condition Code Register The 8-bit condition code register contains the interrupt mask and five flags that indicate the results of the instruction just executed. Bits 6 and 5 are set permanently to logic 1. The following paragraphs describe the functions of the condition code register. Read: Write: Reset: Bit 7 6 5 4 3 2 1 Bit 0 V 1 1 H I N Z C X 1 1 X 1 X X X X = Indeterminate Figure 7-6. Condition Code Register (CCR) V — Overflow Flag The CPU sets the overflow flag when a two's complement overflow occurs. The signed branch instructions BGT, BGE, BLE, and BLT use the overflow flag. 1 = Overflow 0 = No overflow Data Sheet 124 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor H — Half-Carry Flag The CPU sets the half-carry flag when a carry occurs between accumulator bits 3 and 4 during an add-without-carry (ADD) or add-with-carry (ADC) operation. The half-carry flag is required for binary-coded decimal (BCD) arithmetic operations. The DAA instruction uses the states of the H and C flags to determine the appropriate correction factor. 1 = Carry between bits 3 and 4 0 = No carry between bits 3 and 4 I — Interrupt Mask When the interrupt mask is set, all maskable CPU interrupts are disabled. CPU interrupts are enabled when the interrupt mask is cleared. When a CPU interrupt occurs, the interrupt mask is set automatically after the CPU registers are saved on the stack, but before the interrupt vector is fetched. 1 = Interrupts disabled 0 = Interrupts enabled NOTE: To maintain M6805 Family compatibility, the upper byte of the index register (H) is not stacked automatically. If the interrupt service routine modifies H, then the user must stack and unstack H using the PSHH and PULH instructions. After the I bit is cleared, the highest-priority interrupt request is serviced first. A return-from-interrupt (RTI) instruction pulls the CPU registers from the stack and restores the interrupt mask from the stack. After any reset, the interrupt mask is set and can be cleared only by the clear interrupt mask software instruction (CLI). N — Negative flag The CPU sets the negative flag when an arithmetic operation, logic operation, or data manipulation produces a negative result, setting bit 7 of the result. 1 = Negative result 0 = Non-negative result Z — Zero flag The CPU sets the zero flag when an arithmetic operation, logic operation, or data manipulation produces a result of $00. 1 = Zero result 0 = Non-zero result C — Carry/Borrow Flag The CPU sets the carry/borrow flag when an addition operation produces a carry out of bit 7 of the accumulator or when a subtraction operation requires a borrow. Some instructions — such as bit test and branch, shift, and rotate — also clear or set the carry/borrow flag. 1 = Carry out of bit 7 0 = No carry out of bit 7 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 125 7.4 Arithmetic/Logic Unit (ALU) The ALU performs the arithmetic and logic operations defined by the instruction set. Refer to the CPU08 Reference Manual (Freescale document order number CPU08RM/AD) for a description of the instructions and addressing modes and more detail about the architecture of the CPU. 7.5 Low-Power Modes The WAIT and STOP instructions put the MCU in low power-consumption standby modes. 7.5.1 Wait Mode The WAIT instruction: • Clears the interrupt mask (I bit) in the condition code register, enabling interrupts. After exit from wait mode by interrupt, the I bit remains clear. After exit by reset, the I bit is set. • Disables the CPU clock 7.5.2 Stop Mode The STOP instruction: • Clears the interrupt mask (I bit) in the condition code register, enabling external interrupts. After exit from stop mode by external interrupt, the I bit remains clear. After exit by reset, the I bit is set. • Disables the CPU clock After exiting stop mode, the CPU clock begins running after the oscillator stabilization delay. 7.6 CPU During Break Interrupts If a break module is present on the MCU, the CPU starts a break interrupt by: • Loading the instruction register with the SWI instruction • Loading the program counter with $FFFC:$FFFD or with $FEFC:$FEFD in monitor mode The break interrupt begins after completion of the CPU instruction in progress. If the break address register match occurs on the last cycle of a CPU instruction, the break interrupt begins immediately. A return-from-interrupt instruction (RTI) in the break routine ends the break interrupt and returns the MCU to normal operation if the break interrupt has been deasserted. Data Sheet 126 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 7.7 Instruction Set Summary Table 7-1 provides a summary of the M68HC08 instruction set. V H I N Z C ADC #opr ADC opr ADC opr ADC opr,X ADC opr,X ADC ,X ADC opr,SP ADC opr,SP A ← (A) + (M) + (C) Add with Carry IMM DIR EXT IX2 – IX1 IX SP1 SP2 A9 B9 C9 D9 E9 F9 9EE9 9ED9 ii dd hh ll ee ff ff IMM DIR EXT IX2 – IX1 IX SP1 SP2 AB BB CB DB EB FB 9EEB 9EDB ii dd hh ll ee ff ff ff ee ff A7 ii 2 – – – – – – IMM AF ii 2 IMM DIR EXT IX2 0 – – – IX1 IX SP1 SP2 A4 B4 C4 D4 E4 F4 9EE4 9ED4 ii dd hh ll ee ff ff 2 3 4 4 3 2 4 5 0 DIR INH INH – – IX1 IX SP1 38 dd 48 58 68 ff 78 9E68 ff 4 1 1 4 3 5 C DIR INH INH – – IX1 IX SP1 37 dd 47 57 67 ff 77 9E67 ff 4 1 1 4 3 5 Add without Carry AIS #opr Add Immediate Value (Signed) to SP SP ← (SP) + (16 « M) – – – – – – IMM AIX #opr Add Immediate Value (Signed) to H:X H:X ← (H:X) + (16 « M) A ← (A) & (M) ASL opr ASLA ASLX ASL opr,X ASL ,X ASL opr,SP A ← (A) + (M) Logical AND Arithmetic Shift Left (Same as LSL) C b7 ASR opr ASRA ASRX ASR opr,X ASR opr,X ASR opr,SP Arithmetic Shift Right BCC rel Branch if Carry Bit Clear b0 b7 2 3 4 4 3 2 4 5 2 3 4 4 3 2 4 5 ADD #opr ADD opr ADD opr ADD opr,X ADD opr,X ADD ,X ADD opr,SP ADD opr,SP AND #opr AND opr AND opr AND opr,X AND opr,X AND ,X AND opr,SP AND opr,SP ff ee ff Cycles Effect on CCR Description Operand Operation Opcode Source Form Address Mode Table 7-1. Instruction Set Summary (Sheet 1 of 7) b0 PC ← (PC) + 2 + rel ? (C) = 0 Mn ← 0 ff ee ff – – – – – – REL 24 rr 3 DIR (b0) DIR (b1) DIR (b2) – – – – – – DIR (b3) DIR (b4) DIR (b5) DIR (b6) DIR (b7) 11 13 15 17 19 1B 1D 1F dd dd dd dd dd dd dd dd 4 4 4 4 4 4 4 4 BCLR n, opr Clear Bit n in M BCS rel Branch if Carry Bit Set (Same as BLO) PC ← (PC) + 2 + rel ? (C) = 1 – – – – – – REL 25 rr 3 BEQ rel Branch if Equal PC ← (PC) + 2 + rel ? (Z) = 1 – – – – – – REL 27 rr 3 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 127 Effect on CCR V H I N Z C BGE opr Branch if Greater Than or Equal To (Signed Operands) BGT opr Branch if Greater Than (Signed Operands) BHCC rel Branch if Half Carry Bit Clear PC ← (PC) + 2 + rel ? (H) = 0 BHCS rel Branch if Half Carry Bit Set BHI rel Branch if Higher BHS rel PC ← (PC) + 2 + rel ? (N ⊕ V) = 0 Cycles Description Operand Operation Opcode Source Form Address Mode Table 7-1. Instruction Set Summary (Sheet 2 of 7) – – – – – – REL 90 rr 3 PC ← (PC) + 2 + rel ? (Z) | (N ⊕ V) = 0 – – – – – – REL 92 rr 3 – – – – – – REL 28 rr 3 PC ← (PC) + 2 + rel ? (H) = 1 – – – – – – REL 29 rr PC ← (PC) + 2 + rel ? (C) | (Z) = 0 – – – – – – REL 22 rr 3 Branch if Higher or Same (Same as BCC) PC ← (PC) + 2 + rel ? (C) = 0 – – – – – – REL 24 rr 3 BIH rel Branch if IRQ Pin High PC ← (PC) + 2 + rel ? IRQ = 1 – – – – – – REL 2F rr 3 BIL rel Branch if IRQ Pin Low PC ← (PC) + 2 + rel ? IRQ = 0 – – – – – – REL 2E rr 3 (A) & (M) IMM DIR EXT 0 – – – IX2 IX1 IX SP1 SP2 A5 B5 C5 D5 E5 F5 9EE5 9ED5 ii dd hh ll ee ff ff ff ee ff 2 3 4 4 3 2 4 5 93 rr 3 BIT #opr BIT opr BIT opr BIT opr,X BIT opr,X BIT ,X BIT opr,SP BIT opr,SP Bit Test BLE opr Branch if Less Than or Equal To (Signed Operands) BLO rel Branch if Lower (Same as BCS) BLS rel PC ← (PC) + 2 + rel ? (Z) | (N ⊕ V) = 1 – – – – – – REL 3 PC ← (PC) + 2 + rel ? (C) = 1 – – – – – – REL 25 rr 3 Branch if Lower or Same PC ← (PC) + 2 + rel ? (C) | (Z) = 1 – – – – – – REL 23 rr 3 BLT opr Branch if Less Than (Signed Operands) PC ← (PC) + 2 + rel ? (N ⊕ V) =1 – – – – – – REL 91 rr 3 BMC rel Branch if Interrupt Mask Clear PC ← (PC) + 2 + rel ? (I) = 0 – – – – – – REL 2C rr 3 BMI rel Branch if Minus PC ← (PC) + 2 + rel ? (N) = 1 – – – – – – REL 2B rr 3 BMS rel Branch if Interrupt Mask Set PC ← (PC) + 2 + rel ? (I) = 1 – – – – – – REL 2D rr 3 BNE rel Branch if Not Equal PC ← (PC) + 2 + rel ? (Z) = 0 – – – – – – REL 26 rr 3 BPL rel Branch if Plus PC ← (PC) + 2 + rel ? (N) = 0 – – – – – – REL 2A rr 3 BRA rel Branch Always PC ← (PC) + 2 + rel – – – – – – REL 20 rr 3 DIR (b0) DIR (b1) DIR (b2) DIR (b3) – – – – – DIR (b4) DIR (b5) DIR (b6) DIR (b7) 01 03 05 07 09 0B 0D 0F dd rr dd rr dd rr dd rr dd rr dd rr dd rr dd rr 5 5 5 5 5 5 5 5 – – – – – – REL 21 rr 3 DIR (b0) DIR (b1) DIR (b2) – – – – – DIR (b3) DIR (b4) DIR (b5) DIR (b6) DIR (b7) 00 02 04 06 08 0A 0C 0E dd rr dd rr dd rr dd rr dd rr dd rr dd rr dd rr 5 5 5 5 5 5 5 5 BRCLR n,opr,rel Branch if Bit n in M Clear BRN rel Branch Never BRSET n,opr,rel Branch if Bit n in M Set Data Sheet 128 PC ← (PC) + 3 + rel ? (Mn) = 0 PC ← (PC) + 2 PC ← (PC) + 3 + rel ? (Mn) = 1 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Effect on CCR V H I N Z C BSET n,opr Set Bit n in M BSR rel Branch to Subroutine CBEQ opr,rel CBEQA #opr,rel CBEQX #opr,rel Compare and Branch if Equal CBEQ opr,X+,rel CBEQ X+,rel CBEQ opr,SP,rel Cycles Description Operand Operation Opcode Source Form Address Mode Table 7-1. Instruction Set Summary (Sheet 3 of 7) DIR (b0) DIR (b1) DIR (b2) DIR (b3) – – – – – – DIR (b4) DIR (b5) DIR (b6) DIR (b7) 10 12 14 16 18 1A 1C 1E dd dd dd dd dd dd dd dd 4 4 4 4 4 4 4 4 PC ← (PC) + 2; push (PCL) SP ← (SP) – 1; push (PCH) SP ← (SP) – 1 PC ← (PC) + rel – – – – – – REL AD rr 4 PC ← (PC) + 3 + rel ? (A) – (M) = $00 PC ← (PC) + 3 + rel ? (A) – (M) = $00 PC ← (PC) + 3 + rel ? (X) – (M) = $00 PC ← (PC) + 3 + rel ? (A) – (M) = $00 PC ← (PC) + 2 + rel ? (A) – (M) = $00 PC ← (PC) + 4 + rel ? (A) – (M) = $00 DIR IMM IMM – – – – – – IX1+ IX+ SP1 31 41 51 61 71 9E61 dd rr ii rr ii rr ff rr rr ff rr 5 4 4 5 4 6 Mn ← 1 CLC Clear Carry Bit C←0 – – – – – 0 INH 98 1 CLI Clear Interrupt Mask I←0 – – 0 – – – INH 9A 2 M ← $00 A ← $00 X ← $00 H ← $00 M ← $00 M ← $00 M ← $00 DIR INH INH 0 – – 0 1 – INH IX1 IX SP1 3F dd 4F 5F 8C 6F ff 7F 9E6F ff (A) – (M) IMM DIR EXT IX2 – – IX1 IX SP1 SP2 A1 B1 C1 D1 E1 F1 9EE1 9ED1 M ← (M) = $FF – (M) A ← (A) = $FF – (M) X ← (X) = $FF – (M) M ← (M) = $FF – (M) M ← (M) = $FF – (M) M ← (M) = $FF – (M) DIR INH INH 0 – – 1 IX1 IX SP1 33 dd 43 53 63 ff 73 9E63 ff (H:X) – (M:M + 1) – – IMM DIR 65 75 ii ii+1 dd 3 4 (X) – (M) IMM DIR EXT – – IX2 IX1 IX SP1 SP2 A3 B3 C3 D3 E3 F3 9EE3 9ED3 ii dd hh ll ee ff ff 2 3 4 4 3 2 4 5 U – – INH 72 CLR opr CLRA CLRX CLRH CLR opr,X CLR ,X CLR opr,SP CMP #opr CMP opr CMP opr CMP opr,X CMP opr,X CMP ,X CMP opr,SP CMP opr,SP Clear Compare A with M COM opr COMA COMX COM opr,X COM ,X COM opr,SP Complement (One’s Complement) CPHX #opr CPHX opr Compare H:X with M CPX #opr CPX opr CPX opr CPX ,X CPX opr,X CPX opr,X CPX opr,SP CPX opr,SP Compare X with M DAA Decimal Adjust A MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor (A)10 ii dd hh ll ee ff ff ff ee ff ff ee ff 3 1 1 1 3 2 4 2 3 4 4 3 2 4 5 4 1 1 4 3 5 2 Data Sheet 129 Effect on CCR V H I N Z C DBNZ opr,rel DBNZA rel DBNZX rel Decrement and Branch if Not Zero DBNZ opr,X,rel DBNZ X,rel DBNZ opr,SP,rel DEC opr DECA DECX DEC opr,X DEC ,X DEC opr,SP Decrement DIV Divide EOR #opr EOR opr EOR opr EOR opr,X EOR opr,X EOR ,X EOR opr,SP EOR opr,SP INC opr INCA INCX INC opr,X INC ,X INC opr,SP JMP opr JMP opr JMP opr,X JMP opr,X JMP ,X JSR opr JSR opr JSR opr,X JSR opr,X JSR ,X Exclusive OR M with A Increment Jump Jump to Subroutine LDA #opr LDA opr LDA opr LDA opr,X LDA opr,X LDA ,X LDA opr,SP LDA opr,SP Load A from M LDHX #opr LDHX opr Load H:X from M LDX #opr LDX opr LDX opr LDX opr,X LDX opr,X LDX ,X LDX opr,SP LDX opr,SP Data Sheet 130 Load X from M A ← (A) – 1 or M ← (M) – 1 or X ← (X) – 1 PC ← (PC) + 3 + rel ? (result) ≠ 0 DIR PC ← (PC) + 2 + rel ? (result) ≠ 0 INH PC ← (PC) + 2 + rel ? (result) ≠ 0 – – – – – – INH PC ← (PC) + 3 + rel ? (result) ≠ 0 IX1 PC ← (PC) + 2 + rel ? (result) ≠ 0 IX PC ← (PC) + 4 + rel ? (result) ≠ 0 SP1 3B 4B 5B 6B 7B 9E6B dd rr rr rr ff rr rr ff rr Cycles Description Operand Operation Opcode Source Form Address Mode Table 7-1. Instruction Set Summary (Sheet 4 of 7) 5 3 3 5 4 6 M ← (M) – 1 A ← (A) – 1 X ← (X) – 1 M ← (M) – 1 M ← (M) – 1 M ← (M) – 1 DIR INH INH – – – IX1 IX SP1 A ← (H:A)/(X) H ← Remainder – – – – INH 52 A ← (A ⊕ M) IMM DIR EXT IX2 0 – – – IX1 IX SP1 SP2 A8 B8 C8 D8 E8 F8 9EE8 9ED8 M ← (M) + 1 A ← (A) + 1 X ← (X) + 1 M ← (M) + 1 M ← (M) + 1 M ← (M) + 1 DIR INH INH – – – IX1 IX SP1 3C dd 4C 5C 6C ff 7C 9E6C ff PC ← Jump Address DIR EXT – – – – – – IX2 IX1 IX BC CC DC EC FC dd hh ll ee ff ff 2 3 4 3 2 PC ← (PC) + n (n = 1, 2, or 3) Push (PCL); SP ← (SP) – 1 Push (PCH); SP ← (SP) – 1 PC ← Unconditional Address DIR EXT – – – – – – IX2 IX1 IX BD CD DD ED FD dd hh ll ee ff ff 4 5 6 5 4 A ← (M) IMM DIR EXT 0 – – – IX2 IX1 IX SP1 SP2 A6 B6 C6 D6 E6 F6 9EE6 9ED6 ii dd hh ll ee ff ff ff ee ff 2 3 4 4 3 2 4 5 H:X ← (M:M + 1) 0 – – – IMM DIR 45 55 ii jj dd 3 4 X ← (M) IMM DIR EXT 0 – – – IX2 IX1 IX SP1 SP2 AE BE CE DE EE FE 9EEE 9EDE ii dd hh ll ee ff ff 2 3 4 4 3 2 4 5 3A dd 4A 5A 6A ff 7A 9E6A ff 4 1 1 4 3 5 7 ii dd hh ll ee ff ff ff ee ff ff ee ff 2 3 4 4 3 2 4 5 4 1 1 4 3 5 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor V H I N Z C LSL opr LSLA LSLX LSL opr,X LSL ,X LSL opr,SP Logical Shift Left (Same as ASL) LSR opr LSRA LSRX LSR opr,X LSR ,X LSR opr,SP Logical Shift Right MOV opr,opr MOV opr,X+ MOV #opr,opr MOV X+,opr Move MUL Unsigned multiply C b7 0 DIR INH – – INH IX1 IX SP1 38 dd 48 58 68 ff 78 9E68 ff 4 1 1 4 3 5 C DIR INH INH – – 0 IX1 IX SP1 34 dd 44 54 64 ff 74 9E64 ff 4 1 1 4 3 5 b0 0 b7 Cycles Effect on CCR Description Operand Operation Opcode Source Form Address Mode Table 7-1. Instruction Set Summary (Sheet 5 of 7) b0 H:X ← (H:X) + 1 (IX+D, DIX+) DD DIX+ 0 – – – IMD IX+D 4E 5E 6E 7E X:A ← (X) × (A) – 0 – – – 0 INH 42 M ← –(M) = $00 – (M) A ← –(A) = $00 – (A) X ← –(X) = $00 – (X) M ← –(M) = $00 – (M) M ← –(M) = $00 – (M) DIR INH INH – – IX1 IX SP1 (M)Destination ← (M)Source dd dd dd ii dd dd 5 4 4 4 5 30 dd 40 50 60 ff 70 9E60 ff 4 1 1 4 3 5 NEG opr NEGA NEGX NEG opr,X NEG ,X NEG opr,SP Negate (Two’s Complement) NOP No Operation None – – – – – – INH 9D 1 NSA Nibble Swap A A ← (A[3:0]:A[7:4]) – – – – – – INH 62 3 A ← (A) | (M) IMM DIR EXT IX2 0 – – – IX1 IX SP1 SP2 AA BA CA DA EA FA 9EEA 9EDA ii dd hh ll ee ff ff 2 3 4 4 3 2 4 5 ORA #opr ORA opr ORA opr ORA opr,X ORA opr,X ORA ,X ORA opr,SP ORA opr,SP Inclusive OR A and M PSHA Push A onto Stack Push (A); SP ← (SP) – 1 – – – – – – INH 87 2 PSHH Push H onto Stack Push (H); SP ← (SP) – 1 – – – – – – INH 8B 2 PSHX Push X onto Stack Push (X); SP ← (SP) – 1 – – – – – – INH 89 2 PULA Pull A from Stack SP ← (SP + 1); Pull (A) – – – – – – INH 86 2 PULH Pull H from Stack SP ← (SP + 1); Pull (H) – – – – – – INH 8A 2 PULX Pull X from Stack SP ← (SP + 1); Pull (X) – – – – – – INH 88 2 C DIR INH – – INH IX1 IX SP1 39 dd 49 59 69 ff 79 9E69 ff 4 1 1 4 3 5 DIR INH INH – – IX1 IX SP1 36 dd 46 56 66 ff 76 9E66 ff 4 1 1 4 3 5 ROL opr ROLA ROLX ROL opr,X ROL ,X ROL opr,SP Rotate Left through Carry b7 ROR opr RORA RORX ROR opr,X ROR ,X ROR opr,SP Rotate Right through Carry RSP Reset Stack Pointer C b7 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor b0 b0 SP ← $FF – – – – – – INH 9C ff ee ff 1 Data Sheet 131 Effect on CCR V H I N Z C RTI Return from Interrupt RTS Return from Subroutine Cycles Description Operand Operation Opcode Source Form Address Mode Table 7-1. Instruction Set Summary (Sheet 6 of 7) SP ← (SP) + 1; Pull (CCR) SP ← (SP) + 1; Pull (A) SP ← (SP) + 1; Pull (X) SP ← (SP) + 1; Pull (PCH) SP ← (SP) + 1; Pull (PCL) INH 80 7 SP ← SP + 1; Pull (PCH) SP ← SP + 1; Pull (PCL) – – – – – – INH 81 4 A ← (A) – (M) – (C) IMM DIR EXT IX2 – – IX1 IX SP1 SP2 A2 B2 C2 D2 E2 F2 9EE2 9ED2 ii dd hh ll ee ff ff 2 3 4 4 3 2 4 5 SBC #opr SBC opr SBC opr SBC opr,X SBC opr,X SBC ,X SBC opr,SP SBC opr,SP Subtract with Carry SEC Set Carry Bit C←1 – – – – – 1 INH 99 1 SEI Set Interrupt Mask I←1 – – 1 – – – INH 9B 2 M ← (A) DIR EXT IX2 0 – – – IX1 IX SP1 SP2 B7 C7 D7 E7 F7 9EE7 9ED7 (M:M + 1) ← (H:X) 0 – – – DIR 35 I ← 0; Stop Oscillator – – 0 – – – INH 8E M ← (X) DIR EXT IX2 0 – – – IX1 IX SP1 SP2 BF CF DF EF FF 9EEF 9EDF dd hh ll ee ff ff IMM DIR EXT IX2 – – IX1 IX SP1 SP2 A0 B0 C0 D0 E0 F0 9EE0 9ED0 ii dd hh ll ee ff ff – – 1 – – – INH 83 9 STA opr STA opr STA opr,X STA opr,X STA ,X STA opr,SP STA opr,SP Store A in M STHX opr Store H:X in M STOP Enable IRQ Pin; Stop Oscillator STX opr STX opr STX opr,X STX opr,X STX ,X STX opr,SP STX opr,SP SUB #opr SUB opr SUB opr SUB opr,X SUB opr,X SUB ,X SUB opr,SP SUB opr,SP Store X in M Subtract A ← (A) – (M) ff ee ff dd hh ll ee ff ff ff ee ff 3 4 4 3 2 4 5 dd 4 1 ff ee ff ff ee ff 3 4 4 3 2 4 5 2 3 4 4 3 2 4 5 SWI Software Interrupt PC ← (PC) + 1; Push (PCL) SP ← (SP) – 1; Push (PCH) SP ← (SP) – 1; Push (X) SP ← (SP) – 1; Push (A) SP ← (SP) – 1; Push (CCR) SP ← (SP) – 1; I ← 1 PCH ← Interrupt Vector High Byte PCL ← Interrupt Vector Low Byte TAP Transfer A to CCR CCR ← (A) INH 84 2 TAX Transfer A to X X ← (A) – – – – – – INH 97 1 TPA Transfer CCR to A A ← (CCR) – – – – – – INH 85 1 Data Sheet 132 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor V H I N Z C TST opr TSTA TSTX TST opr,X TST ,X TST opr,SP Test for Negative or Zero TSX Transfer SP to H:X TXA Transfer X to A TXS Transfer H:X to SP A C CCR dd dd rr DD DIR DIX+ ee ff EXT ff H H hh ll I ii IMD IMM INH IX IX+ IX+D IX1 IX1+ IX2 M N (A) – $00 or (X) – $00 or (M) – $00 DIR INH 0 – – – INH IX1 IX SP1 H:X ← (SP) + 1 – – – – – – INH 95 2 A ← (X) – – – – – – INH 9F 1 (SP) ← (H:X) – 1 – – – – – – INH 94 2 Accumulator Carry/borrow bit Condition code register Direct address of operand Direct address of operand and relative offset of branch instruction Direct to direct addressing mode Direct addressing mode Direct to indexed with post increment addressing mode High and low bytes of offset in indexed, 16-bit offset addressing Extended addressing mode Offset byte in indexed, 8-bit offset addressing Half-carry bit Index register high byte High and low bytes of operand address in extended addressing Interrupt mask Immediate operand byte Immediate source to direct destination addressing mode Immediate addressing mode Inherent addressing mode Indexed, no offset addressing mode Indexed, no offset, post increment addressing mode Indexed with post increment to direct addressing mode Indexed, 8-bit offset addressing mode Indexed, 8-bit offset, post increment addressing mode Indexed, 16-bit offset addressing mode Memory location Negative bit n opr PC PCH PCL REL rel rr SP1 SP2 SP U V X Z & | ⊕ () –( ) # « ← ? : — 3D dd 4D 5D 6D ff 7D 9E6D ff Cycles Effect on CCR Description Operand Operation Opcode Source Form Address Mode Table 7-1. Instruction Set Summary (Sheet 7 of 7) 3 1 1 3 2 4 Any bit Operand (one or two bytes) Program counter Program counter high byte Program counter low byte Relative addressing mode Relative program counter offset byte Relative program counter offset byte Stack pointer, 8-bit offset addressing mode Stack pointer 16-bit offset addressing mode Stack pointer Undefined Overflow bit Index register low byte Zero bit Logical AND Logical OR Logical EXCLUSIVE OR Contents of Negation (two’s complement) Immediate value Sign extend Loaded with If Concatenated with Set or cleared Not affected 7.8 Opcode Map See Table 7-2. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 133 Data Sheet 134 Table 7-2. Opcode Map Bit Manipulation DIR DIR MSB Branch REL DIR INH 3 4 0 1 2 5 BRSET0 3 DIR 5 BRCLR0 3 DIR 5 BRSET1 3 DIR 5 BRCLR1 3 DIR 5 BRSET2 3 DIR 5 BRCLR2 3 DIR 5 BRSET3 3 DIR 5 BRCLR3 3 DIR 5 BRSET4 3 DIR 5 BRCLR4 3 DIR 5 BRSET5 3 DIR 5 BRCLR5 3 DIR 5 BRSET6 3 DIR 5 BRCLR6 3 DIR 5 BRSET7 3 DIR 5 BRCLR7 3 DIR 4 BSET0 2 DIR 4 BCLR0 2 DIR 4 BSET1 2 DIR 4 BCLR1 2 DIR 4 BSET2 2 DIR 4 BCLR2 2 DIR 4 BSET3 2 DIR 4 BCLR3 2 DIR 4 BSET4 2 DIR 4 BCLR4 2 DIR 4 BSET5 2 DIR 4 BCLR5 2 DIR 4 BSET6 2 DIR 4 BCLR6 2 DIR 4 BSET7 2 DIR 4 BCLR7 2 DIR 3 BRA 2 REL 3 BRN 2 REL 3 BHI 2 REL 3 BLS 2 REL 3 BCC 2 REL 3 BCS 2 REL 3 BNE 2 REL 3 BEQ 2 REL 3 BHCC 2 REL 3 BHCS 2 REL 3 BPL 2 REL 3 BMI 2 REL 3 BMC 2 REL 3 BMS 2 REL 3 BIL 2 REL 3 BIH 2 REL Read-Modify-Write INH IX1 5 6 1 NEGX 1 INH 4 CBEQX 3 IMM 7 DIV 1 INH 1 COMX 1 INH 1 LSRX 1 INH 4 LDHX 2 DIR 1 RORX 1 INH 1 ASRX 1 INH 1 LSLX 1 INH 1 ROLX 1 INH 1 DECX 1 INH 3 DBNZX 2 INH 1 INCX 1 INH 1 TSTX 1 INH 4 MOV 2 DIX+ 1 CLRX 1 INH 4 NEG 2 IX1 5 CBEQ 3 IX1+ 3 NSA 1 INH 4 COM 2 IX1 4 LSR 2 IX1 3 CPHX 3 IMM 4 ROR 2 IX1 4 ASR 2 IX1 4 LSL 2 IX1 4 ROL 2 IX1 4 DEC 2 IX1 5 DBNZ 3 IX1 4 INC 2 IX1 3 TST 2 IX1 4 MOV 3 IMD 3 CLR 2 IX1 SP1 IX 9E6 7 Control INH INH 8 9 Register/Memory IX2 SP2 IMM DIR EXT A B C D 9ED 4 SUB 3 EXT 4 CMP 3 EXT 4 SBC 3 EXT 4 CPX 3 EXT 4 AND 3 EXT 4 BIT 3 EXT 4 LDA 3 EXT 4 STA 3 EXT 4 EOR 3 EXT 4 ADC 3 EXT 4 ORA 3 EXT 4 ADD 3 EXT 3 JMP 3 EXT 5 JSR 3 EXT 4 LDX 3 EXT 4 STX 3 EXT 4 SUB 3 IX2 4 CMP 3 IX2 4 SBC 3 IX2 4 CPX 3 IX2 4 AND 3 IX2 4 BIT 3 IX2 4 LDA 3 IX2 4 STA 3 IX2 4 EOR 3 IX2 4 ADC 3 IX2 4 ORA 3 IX2 4 ADD 3 IX2 4 JMP 3 IX2 6 JSR 3 IX2 4 LDX 3 IX2 4 STX 3 IX2 5 SUB 4 SP2 5 CMP 4 SP2 5 SBC 4 SP2 5 CPX 4 SP2 5 AND 4 SP2 5 BIT 4 SP2 5 LDA 4 SP2 5 STA 4 SP2 5 EOR 4 SP2 5 ADC 4 SP2 5 ORA 4 SP2 5 ADD 4 SP2 IX1 SP1 IX E 9EE F LSB 0 1 2 3 4 5 6 7 8 9 A B C D Freescale Semiconductor MC68HC08AS32A — Rev. 1.1 E F 4 1 NEG NEGA 2 DIR 1 INH 5 4 CBEQ CBEQA 3 DIR 3 IMM 5 MUL 1 INH 4 1 COM COMA 2 DIR 1 INH 4 1 LSR LSRA 2 DIR 1 INH 4 3 STHX LDHX 2 DIR 3 IMM 4 1 ROR RORA 2 DIR 1 INH 4 1 ASR ASRA 2 DIR 1 INH 4 1 LSL LSLA 2 DIR 1 INH 4 1 ROL ROLA 2 DIR 1 INH 4 1 DEC DECA 2 DIR 1 INH 5 3 DBNZ DBNZA 3 DIR 2 INH 4 1 INC INCA 2 DIR 1 INH 3 1 TST TSTA 2 DIR 1 INH 5 MOV 3 DD 3 1 CLR CLRA 2 DIR 1 INH INH Inherent REL Relative IMM Immediate IX Indexed, No Offset DIR Direct IX1 Indexed, 8-Bit Offset EXT Extended IX2 Indexed, 16-Bit Offset DD Direct-Direct IMD Immediate-Direct IX+D Indexed-Direct DIX+ Direct-Indexed *Pre-byte for stack pointer indexed instructions 5 3 NEG NEG 3 SP1 1 IX 6 4 CBEQ CBEQ 4 SP1 2 IX+ 2 DAA 1 INH 5 3 COM COM 3 SP1 1 IX 5 3 LSR LSR 3 SP1 1 IX 4 CPHX 2 DIR 5 3 ROR ROR 3 SP1 1 IX 5 3 ASR ASR 3 SP1 1 IX 5 3 LSL LSL 3 SP1 1 IX 5 3 ROL ROL 3 SP1 1 IX 5 3 DEC DEC 3 SP1 1 IX 6 4 DBNZ DBNZ 4 SP1 2 IX 5 3 INC INC 3 SP1 1 IX 4 2 TST TST 3 SP1 1 IX 4 MOV 2 IX+D 4 2 CLR CLR 3 SP1 1 IX SP1 Stack Pointer, 8-Bit Offset SP2 Stack Pointer, 16-Bit Offset IX+ Indexed, No Offset with Post Increment IX1+ Indexed, 1-Byte Offset with Post Increment 7 3 RTI BGE 1 INH 2 REL 4 3 RTS BLT 1 INH 2 REL 3 BGT 2 REL 9 3 SWI BLE 1 INH 2 REL 2 2 TAP TXS 1 INH 1 INH 1 2 TPA TSX 1 INH 1 INH 2 PULA 1 INH 2 1 PSHA TAX 1 INH 1 INH 2 1 PULX CLC 1 INH 1 INH 2 1 PSHX SEC 1 INH 1 INH 2 2 PULH CLI 1 INH 1 INH 2 2 PSHH SEI 1 INH 1 INH 1 1 CLRH RSP 1 INH 1 INH 1 NOP 1 INH 1 STOP * 1 INH 1 1 WAIT TXA 1 INH 1 INH 2 SUB 2 IMM 2 CMP 2 IMM 2 SBC 2 IMM 2 CPX 2 IMM 2 AND 2 IMM 2 BIT 2 IMM 2 LDA 2 IMM 2 AIS 2 IMM 2 EOR 2 IMM 2 ADC 2 IMM 2 ORA 2 IMM 2 ADD 2 IMM 3 SUB 2 DIR 3 CMP 2 DIR 3 SBC 2 DIR 3 CPX 2 DIR 3 AND 2 DIR 3 BIT 2 DIR 3 LDA 2 DIR 3 STA 2 DIR 3 EOR 2 DIR 3 ADC 2 DIR 3 ORA 2 DIR 3 ADD 2 DIR 2 JMP 2 DIR 4 4 BSR JSR 2 REL 2 DIR 2 3 LDX LDX 2 IMM 2 DIR 2 3 AIX STX 2 IMM 2 DIR MSB 0 3 SUB 2 IX1 3 CMP 2 IX1 3 SBC 2 IX1 3 CPX 2 IX1 3 AND 2 IX1 3 BIT 2 IX1 3 LDA 2 IX1 3 STA 2 IX1 3 EOR 2 IX1 3 ADC 2 IX1 3 ORA 2 IX1 3 ADD 2 IX1 3 JMP 2 IX1 5 JSR 2 IX1 5 3 LDX LDX 4 SP2 2 IX1 5 3 STX STX 4 SP2 2 IX1 4 SUB 3 SP1 4 CMP 3 SP1 4 SBC 3 SP1 4 CPX 3 SP1 4 AND 3 SP1 4 BIT 3 SP1 4 LDA 3 SP1 4 STA 3 SP1 4 EOR 3 SP1 4 ADC 3 SP1 4 ORA 3 SP1 4 ADD 3 SP1 2 SUB 1 IX 2 CMP 1 IX 2 SBC 1 IX 2 CPX 1 IX 2 AND 1 IX 2 BIT 1 IX 2 LDA 1 IX 2 STA 1 IX 2 EOR 1 IX 2 ADC 1 IX 2 ORA 1 IX 2 ADD 1 IX 2 JMP 1 IX 4 JSR 1 IX 4 2 LDX LDX 3 SP1 1 IX 4 2 STX STX 3 SP1 1 IX High Byte of Opcode in Hexadecimal LSB Low Byte of Opcode in Hexadecimal 0 5 Cycles BRSET0 Opcode Mnemonic 3 DIR Number of Bytes / Addressing Mode Data Sheet — MC68HC08AS32A — Section 8. External Interrupt (IRQ) 8.1 Introduction This section describes the non-maskable external interrupt (IRQ) input. 8.2 Features Features of the IRQ include: • Dedicated external interrupt pin (IRQ) • Hysteresis buffer • Programmable edge-only or edge and level interrupt sensitivity • Automatic interrupt acknowledge 8.3 Functional Description A logic 0 applied to the external interrupt pin can latch a CPU interrupt request. Figure 8-1 shows the structure of the IRQ module. INTERNAL ADDRESS BUS ACK TO CPU FOR BIL/BIH INSTRUCTIONS VECTOR FETCH DECODER VDD IRQF D CLR Q SYNCHRONIZER CK IRQ IRQ LATCH IRQ INTERRUPT REQUEST IMASK MODE HIGH VOLTAGE DETECT TO MODE SELECT LOGIC Figure 8-1. IRQ Block Diagram MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 135 CONTROL AND STATUS REGISTERS — 69 BYTES BREAK MODULE DDRA PTA PTB ANALOG-TO-DIGITAL CONVERTER MODULE DDRB ARITHMETIC/LOGIC UNIT PTA7–PTA0 PTB7/ATD7–PTB0/ATD0 DDRC CPU REGISTERS VREFH USER ROM — 32,256 BYTES PTC Data Sheet 136 INTERNAL BUS M68HC08 CPU SYSTEM INTEGRATION MODULE IRQ IRQ MODULE MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor VDDA/VDDAREF VSSA/VREFL PTF3/TCH5 PTF2/TCH4 PTF1/TCH3 PTF0/TCH2 SERIAL COMMUNICATIONS INTERFACE MODULE SERIAL PERIPHERAL INTERFACE MODULE BYTE DATA LINK CONTROLLER DIGITAL MODULE POWER-ON RESET MODULE VSS VDD PTE7/SPSCK PTE6/MOSI PTE5/MISO PTE4/SS PTE3/TCH1 PTE2/TCH0 PTE1/RxD PTE0/TxD PTF RST PTD CLOCK GENERATOR MODULE PTD5/ATD13–PTD0/ATD8 PTE OSC1 OSC2 CGMXFC PROGRAMMABLE INTERRUPT TIMER MODULE DDRE USER ROM VECTOR SPACE — 38 BYTES PTD6/ATD14/TCLK TIMER INTERFACE MODULE BDRxD BDTxD POWER Figure 8-2. Block Diagram Highlighting IRQ Block and Pins DDRF MONITOR ROM — 224 BYTES DDRD USER EEPROM — 512 BYTES USER RAM — 1024 BYTES PTC2/MCLK PTC1–PTC0 LOW-VOLTAGE INHIBIT MODULE COMPUTER OPERATING PROPERLY MODULE PTC4–PTC3 Addr. Register Name IRQ Status and Control Register (ISCR) $001A See page 140. Read: Bit 7 6 5 4 3 2 0 0 0 0 IRQF 0 Write: Reset: ACK 0 0 0 0 0 0 1 Bit 0 IMASK MODE 0 0 = Unimplemented Figure 8-3. IRQ I/O Register Summary Interrupt signals on the IRQ pin are latched into the IRQ latch. An interrupt latch remains set until one of the following actions occurs: • Vector fetch — A vector fetch automatically generates an interrupt acknowledge signal that clears the latch that caused the vector fetch. • Software clear — Software can clear an interrupt latch by writing to the appropriate acknowledge bit in the interrupt status and control register (ISCR). Writing a 1 to the ACK bit clears the IRQ latch. • Reset — A reset automatically clears both interrupt latches. The external interrupt pin is falling-edge triggered out of reset and is softwareconfigurable to be both falling-edge and low-level triggered. The MODE bit in the ISCR controls the triggering sensitivity of the IRQ pin. When an interrupt pin is edge-triggered only (MODE = 0), the interrupt latch remains set until a vector fetch, software clear, or reset occurs. When an interrupt pin is both falling-edge and low-level triggered (MODE = 1), the interrupt latch remains set until both of the following occur: • Vector fetch or software clear • Return of the interrupt pin to logic 1 The vector fetch or software clear may occur before or after the interrupt pin returns to logic 1. As long as the pin is low, the interrupt request remains pending. A reset will clear the latch and the MODE control bit, thereby clearing the interrupt even if the pin stays low. When set, the IMASK bit in the ISCR masks all external interrupt requests. A latched interrupt request is not presented to the interrupt priority logic unless the corresponding IMASK bit is clear. NOTE: The interrupt mask (I) in the condition code register (CCR) masks all interrupt requests, including external interrupt requests. (See Figure 8-4.) MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 137 FROM RESET YES I BIT SET? NO INTERRUPT? YES NO STACK CPU REGISTERS SET I BIT LOAD PC WITH INTERRUPT VECTOR FETCH NEXT INSTRUCTION. SWI INSTRUCTION? YES NO RTI INSTRUCTION? YES UNSTACK CPU REGISTERS NO EXECUTE INSTRUCTION Figure 8-4. IRQ Interrupt Flowchart Data Sheet 138 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 8.4 IRQ Pin A falling edge on the IRQ pin latches an interrupt request into the IRQ latch. A vector fetch, software clear, or reset clears the IRQ latch. If the MODE bit is set, the IRQ pin is both falling-edge sensitive and low-level sensitive. With MODE set, both of the following actions must occur to clear the IRQ latch: • Vector fetch or software clear — A vector fetch generates an interrupt acknowledge signal to clear the latch. Software may generate the interrupt acknowledge signal by writing a 1 to the ACK bit in the interrupt status and control register (ISCR). The ACK bit is useful in applications that poll the IRQ pin and require software to clear the IRQ latch. Writing to the ACK bit can also prevent spurious interrupts due to noise. Setting ACK does not affect subsequent transitions on the IRQ pin. A falling edge on IRQ that occurs after writing to the ACK bit latches another interrupt request. If the IRQ mask bit, IMASK, is clear, the CPU loads the program counter with the vector address at locations $FFFA and $FFFB. • Return of the IRQ pin to logic 1 — As long as the IRQ pin is at logic 0, the IRQF flag remains set. The vector fetch or software clear and the return of the IRQ pin to logic 1 can occur in any order. The interrupt request remains pending as long as the IRQ pin is at logic 0. A reset will clear the latch and the MODE control bit, thereby clearing the interrupt even if the pin stays low. If the MODE bit is clear, the IRQ pin is falling-edge sensitive only. With MODE clear, a vector fetch or software clear immediately clears the IRQ latch. The IRQF bit in the ISCR register can be used to check for pending interrupts. The IRQF bit is not affected by the IMASK bit, which makes it useful in applications where polling is preferred. Use the BIH or BIL instruction to read the logic level on the IRQ pin. NOTE: When using the level-sensitive interrupt trigger, avoid false interrupts by masking interrupt requests in the interrupt routine. 8.5 IRQ Module During Break Interrupts The system integration module (SIM) controls whether the IRQ interrupt latch can be cleared during the break state. The BCFE bit in the SIM break flag control register (SBFCR) enables software to clear the latches during the break state. (See 14.7.3 SIM Break Flag Control Register.) To allow software to clear the IRQ latch during a break interrupt, write a 1 to the BCFE bit. If a latch is cleared during the break state, it remains cleared when the MCU exits the break state. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 139 To protect the latch during the break state, write a 0 to the BCFE bit. With BCFE at 0 (its default state), writing to the ACK bit in the IRQ status and control register during the break state has no effect on the IRQ latch. 8.6 IRQ Status and Control Register The IRQ status and control register (ISCR) controls and monitors operation of the IRQ module. The ISCR: • Shows the state of the IRQ interrupt flag • Clears the IRQ interrupt latch • Masks IRQ interrupt request • Controls triggering sensitivity of the IRQ interrupt pin Address: $001A Read: Bit 7 6 5 4 3 0 0 0 0 IRQF Write: Reset: 2 0 ACK 0 0 0 0 0 0 1 Bit 0 IMASK MODE 0 0 = Unimplemented Figure 8-5. IRQ Status and Control Register (ISCR) IRQF — IRQ Flag Bit This read-only status bit is high when the IRQ interrupt is pending. 1 = IRQ interrupt pending 0 = IRQ interrupt not pending ACK — IRQ Interrupt Request Acknowledge Bit Writing a 1 to this write-only bit clears the IRQ latch. ACK always reads as 0. Reset clears ACK. IMASK — IRQ Interrupt Mask Bit Writing a 1 to this read/write bit disables IRQ interrupt requests. Reset clears IMASK. 1 = IRQ interrupt requests disabled 0 = IRQ interrupt requests enabled MODE — IRQ Edge/Level Select Bit This read/write bit controls the triggering sensitivity of the IRQ pin. Reset clears MODE. 1 = IRQ interrupt requests on falling edges and low levels 0 = IRQ interrupt requests on falling edges only Data Sheet 140 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 9. Low-Voltage Inhibit (LVI) 9.1 Introduction This section describes the low-voltage inhibit module (LVI), which monitors the voltage on the VDD pin and can force a reset when the VDD voltage falls to the LVI trip voltage. 9.2 Features Features of the LVI module include: • Programmable LVI reset • Programmable power consumption 9.3 Functional Description Figure 9-1 shows the structure of the LVI module. The LVI is enabled out of reset. The LVI module contains a bandgap reference circuit and comparator. The LVI power bit, LVIPWR, enables the LVI to monitor VDD voltage. The LVI reset bit, LVIRST, enables the LVI module to generate a reset when VDD falls below a voltage, VTRIPF. LVISTOP, enables the LVI module during stop mode. This will ensure that when the STOP instruction is executed, the LVI will continue to monitor the voltage level on VDD. LVIPWR, LVISTOP, and LVIRST are in the MORA register ($001F) (see Section 10. Mask Options). Once an LVI reset occurs, the MCU remains in reset until VDD rises above a voltage, VTRIPR. The output of the comparator controls the state of the LVIOUT flag in the LVI status register (LVISR). An LVI reset also drives the RST pin low to provide low-voltage protection to external peripheral devices. 9.3.1 Polled LVI Operation In applications that can operate at VDD levels below the VTRIPF level, software can monitor VDD by polling the LVIOUT bit. In the MORA register, the LVIPWR bit must be set to enable the LVI module, and the LVIRST bit must be cleared to disable LVI resets. 9.3.2 Forced Reset Operation In applications that require VDD to remain above the VTRIPF level, enabling LVI resets allows the LVI module to reset the MCU when VDD falls to the VTRIPF level. In the MORA register, the LVIPWR and LVIRST bits must be set to enable the LVI module and to enable LVI resets. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 141 VDD STOP INSTRUCTION LVISTOP FROM MORA FROM MORA LVIRSTD LVIPWRD FROM MORA LOW VDD DETECTOR VDD > LVITrip = 0 LVI RESET VDD ≤ LVITrip = 1 LVIOUT Figure 9-1. LVI Module Block Diagram 9.4 LVI Status Register The LVI status register flags VDD voltages below the VTRIPF level. Address: Read: $FE0F Bit 7 6 5 4 3 2 1 Bit 0 LVIOUT 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Write: Reset: = Unimplemented Figure 9-2. LVI Status Register (LVISR) LVIOUT — LVI Output Bit This read-only flag becomes set when the VDD voltage falls below the VTRIPF voltage (see Table 9-1). Reset clears the LVIOUT bit. Table 9-1. LVIOUT Bit Indication VDD LVIOUT VDD > VTRIPR 0 VTRIPF < VDD < VTRIPR Previous value 9.5 LVI Interrupts The LVI module does not generate interrupt requests. Data Sheet 142 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 9.6 Low-Power Modes The STOP and WAIT instructions put the MCU in low-power standby modes. 9.6.1 Wait Mode With the LVIPWR bit in the MORA register programmed to logic 1, the LVI module is active after a WAIT instruction. With the LVIRST bit in the MORA register programmed to logic 1, the LVI module can generate a reset and bring the MCU out of wait mode. 9.6.2 Stop Mode If enabled in stop mode (LVISTOP and LVIPWR bits in the MORA register programmed to a logic 1), the LVI module remains active in stop mode. If enabled to generate resets, the LVI module can generate a reset and bring the MCU out of stop mode. NOTE: If the LVIPWR bit is at logic 1, the LVISTOP bit must be at logic 0 to meet the minimum stop mode IDD specification. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 143 Data Sheet 144 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 10. Mask Options 10.1 Introduction This section describes the mask options and the mask option registers. 10.2 Functional Description The mask options are hard-wired connections, specified at the same time as the ROM code, which allow the user to customize the MCU. The options control the enable or disable ability of the following functions: • ROM security(1) • Resets caused by the LVI module • Power to the LVI module • Stop mode recovery time (32 CGMXCLK cycles or 4096 CGMXCLK cycles) • COP timeout period (218–24 CGMXCLK cycles or 213–24 CGMXCLK cycles) • STOP instruction • Computer operating properly module (COP) • EEPROM reference clock source 1. No security feature is absolutely secure. However, Freescale’s strategy is to make reading or copying the ROM data difficult for unauthorized users. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 145 10.3 Mask Option Registers (MORA and MORB) Address: Read: $001F Bit 7 6 5 4 3 2 1 Bit 0 LVISTOP ROMSEC LVIRST LVIPWR SSREC COPS STOP COPD Write: Reset: Unaffected by reset = Unimplemented Figure 10-1. Mask Option Register (MORA) LVISTOP — LVI Stop Mode Enable Bit LVISTOP enables the LVI module in stop mode.(See Section 9. Low-Voltage Inhibit (LVI).) 1 = LVI enabled during stop mode 0 = LVI disabled during stop mode ROMSEC — ROM Security Bit ROMSEC enables the ROM security feature. Setting the ROMSEC bit prevents reading of the ROM contents. Access to the ROM is denied to unauthorized users of customer-specified software. 1 = ROM security enabled 0 = ROM security disabled LVIRST — LVI Reset Enable Bit LVIRST enables the reset signal from the LVI module. (See Section 9. Low-Voltage Inhibit (LVI).) 1 = LVI module resets enabled 0 = LVI module resets disabled LVIPWR — LVI Power Enable Bit LVIPWR enables the LVI module. (See Section 9. Low-Voltage Inhibit (LVI).) 1 = LVI module power enabled 0 = LVI module power disabled SSREC — Short Stop Recovery Bit SSREC enables the CPU to exit stop mode with a delay of 32 CGMXCLK cycles instead of a 4096-CGMXCLK cycle delay. (See 16.5.2 Stop Mode.) 1 = Stop mode recovery after 32 CGMXCLK cycles 0 = Stop mode recovery after 4096 CGMXCLK cycles NOTE: If using an external crystal oscillator, do not set the SSREC bit. COPS — COP Rate Select Timeout Bit COPS selects the short COP timeout period. (See Section 6. Computer Operating Properly (COP).) 1 = COP timeout period is 213–24 CGMXCLK cycles. 0 = COP timeout period is 218–24 CGMXCLK cycles. Data Sheet 146 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor STOP — STOP Instruction Enable Bit STOP enables the STOP instruction. 1 = STOP instruction enabled 0 = STOP instruction treated as illegal opcode COPD — COP Disable Bit COPD disables the COP module. (See Section 6. Computer Operating Properly (COP).) 1 = COP module disabled 0 = COP module enabled Address: $FE09 Bit 7 6 5 4 3 2 1 Bit 0 AS32A Read: EEDIVCLK Write: Reset: Unaffected by reset = Unimplemented Figure 10-2. Mask Option Register 2 (MORB) EEDIVCLK — EEPROM Timebase Divider Clock Select Bit EDIVCLK selects the reference clock source for the EERPOM timebase divider. See 2.5.2.4 EEPROM Timebase Divider Register. 1 = CPU bus clock drives the EEPROM timebase divider 0 = CGMXCLK drives the EEPROM timebase divider AS32A — Device Indicator This bit is used to distinguish a MC68HC08AS32A from older non-’A’ suffix versions. 1 = ‘A’ version 0 = Non ‘A’ version NOTE: Extra care should be exercised when selecting mask option registers since other M68HC08 Family parts may have different options. If in doubt, check with your local field applications representative. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 147 Data Sheet 148 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 11. Programmable Interrupt Timer (PIT) 11.1 Introduction This section describes the programmable interrupt timer (PIT) which is a periodic interrupt timer whose counter is clocked internally via software programmable options. Figure 11-1 is a block diagram of the PIT. For further information regarding timers on M68HC08 Family devices, please consult the HC08 Timer Reference Manual (Freescale document order number TIM08RM/AD). 11.2 Features Features of the PIT include: • Programmable PIT clock input • Free-running or modulo up-count operation • PIT counter stop and reset bits 11.3 Functional Description Figure 11-1 shows the structure of the PIT. The central component of the PIT is the 16-bit PIT counter that can operate as a free-running counter or a modulo up-counter. The counter provides the timing reference for the interrupt. The PIT counter modulo registers, PMODH–PMODL, control the modulo value of the counter. Software can read the counter value at any time without affecting the counting sequence. INTERNAL BUS CLOCK PRESCALER CSTOP PRESCALER SELECT PPS2 CRST PPS1 PPS0 16-BIT COUNTER POF POIE INTERRUPT LOGIC 16-BIT COMPARATOR TIMPMODH:TIMPMODL Figure 11-1. PIT Block Diagram MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 149 Addr. Register Name Bit 7 6 5 POIE PSTOP 4 3 0 0 2 1 Bit 0 PPS2 PPS1 PPS0 PIT Status and Control Read: Register (PSC) Write: See page 152. Reset: POF 0 0 1 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 $004C PIT Counter Register High Read: (PCNTH) Write: See page 153. Reset: 0 0 0 0 0 0 0 0 Bit 7 6 5 4 3 2 1 Bit 0 $004D PIT Counter Register Low Read: (PCNTL) Write: See page 153. Reset: 0 0 0 0 0 0 0 0 $004E PIT Counter Modulo Read: Register High (PMODH) Write: See page 154. Reset: Bit 15 14 13 12 11 10 9 Bit 8 1 1 1 1 1 1 1 1 Bit 7 6 5 4 3 2 1 Bit 0 1 1 1 1 1 1 1 1 $004B $004F 0 PIT Counter Modulo Read: Register Low (PMODL) Write: See page 154. Reset: PRST =Unimplemented Figure 11-2. PIT I/O Register Summary 11.4 PIT Counter Prescaler The clock source can be one of the seven prescaler outputs. The prescaler generates seven clock rates from the internal bus clock. The prescaler select bits, PPS[2:0], in the status and control register select the PIT clock source. The value in the PIT counter modulo registers and the selected prescaler output determines the frequency of the periodic interrupt. The PIT overflow flag (POF) is set when the PIT counter value reaches the modulo value programmed in the PIT counter modulo registers. The PIT interrupt enable bit, POIE, enables PIT overflow CPU interrupt requests. POF and POIE are in the PIT status and control register. 11.5 Low-Power Modes The WAIT and STOP instructions put the MCU in low power-consumption standby modes. 11.5.1 Wait Mode The PIT remains active after the execution of a WAIT instruction. In wait mode the PIT registers are not accessible by the CPU. Any enabled CPU interrupt request from the PIT can bring the MCU out of wait mode. If PIT functions are not required during wait mode, reduce power consumption by stopping the PIT before executing the WAIT instruction. Data Sheet 150 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 11.5.2 Stop Mode The PIT is inactive after the execution of a STOP instruction. The STOP instruction does not affect register conditions or the state of the PIT counter. PIT operation resumes when the MCU exits stop mode after an external interrupt. 11.6 PIT During Break Interrupts A break interrupt stops the PIT counter. The system integration module (SIM) controls whether status bits in other modules can be cleared during the break state. The BCFE bit in the SIM break flag control register (SBFCR) enables software to clear status bits during the break state (see Figure 14-20. SIM Break Flag Control Register (SBFCR)). To allow software to clear status bits during a break interrupt, write a logic 1 to the BCFE bit. If a status bit is cleared during the break state, it remains cleared when the MCU exits the break state. To protect status bits during the break state, write a logic 0 to the BCFE bit. With BCFE at logic 0 (its default state), software can read and write I/O registers during the break state without affecting status bits. Some status bits have a 2-step read/write clearing procedure. If software does the first step on such a bit before the break, the bit cannot change during the break state as long as BCFE is at logic 0. After the break, doing the second step clears the status bit. 11.7 I/O Registers The following I/O registers control and monitor operation of the PIT: • PIT status and control register (PSC) • PIT counter registers (PCNTH–PCNTL) • PIT counter modulo registers (PMODH–PMODL) 11.7.1 PIT Status and Control Register The PIT status and control register: MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor • Enables PIT interrupt • Flags PIT overflows • Stops the PIT counter • Resets the PIT counter • Prescales the PIT counter clock Data Sheet 151 Address: $004B Bit 7 Read: POF Write: 0 Reset: 0 6 5 POIE PSTOP 0 1 4 3 0 0 PRST 0 0 2 1 Bit 0 PPS2 PPS1 PPS0 0 0 0 = Unimplemented Figure 11-3. PIT Status and Control Register (PSC) POF — PIT Overflow Flag Bit This read/write flag is set when the PIT counter reaches the modulo value programmed in the PIT counter modulo registers. Clear POF by reading the PIT status and control register when POF is set and then writing a logic 0 to POF. If another PIT overflow occurs before the clearing sequence is complete, then writing logic 0 to POF has no effect. Therefore, a POF interrupt request cannot be lost due to inadvertent clearing of POF. Reset clears the POF bit. Writing a logic 1 to POF has no effect. 1 = PIT counter has reached modulo value 0 = PIT counter has not reached modulo value POIE — PIT Overflow Interrupt Enable Bit This read/write bit enables PIT overflow interrupts when the POF bit becomes set. Reset clears the POIE bit. 1 = PIT overflow interrupts enabled 0 = PIT overflow interrupts disabled PSTOP — PIT Stop Bit This read/write bit stops the PIT counter. Counting resumes when PSTOP is cleared. Reset sets the PSTOP bit, stopping the PIT counter until software clears the PSTOP bit. 1 = PIT counter stopped 0 = PIT counter active NOTE: Do not set the PSTOP bit before entering wait mode if the PIT is required to exit wait mode. PRST — PIT Reset Bit Setting this write-only bit resets the PIT counter and the PIT prescaler. Setting PRST has no effect on any other registers. Counting resumes from $0000. PRST is cleared automatically after the PIT counter is reset and always reads as logic zero. Reset clears the PRST bit. 1 = Prescaler and PIT counter cleared 0 = No effect NOTE: Data Sheet 152 Setting the PSTOP and PRST bits simultaneously stops the PIT counter at a value of $0000. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor PPS[2:0] — Prescaler Select Bits These read/write bits select one of the seven prescaler outputs as the input to the PIT counter as Table 11-1 shows. Reset clears the PPS[2:0] bits. Table 11-1. Prescaler Selection PPS[2:0] PIT Clock Source 000 Internal bus clock ÷1 001 Internal bus clock ÷ 2 010 Internal bus clock ÷ 4 011 Internal bus clock ÷ 8 100 Internal bus clock ÷ 16 101 Internal bus clock ÷ 32 110 Internal bus clock ÷ 64 111 Internal bus clock ÷ 64 11.7.2 PIT Counter Registers The two read-only PIT counter registers contain the high and low bytes of the value in the PIT counter. Reading the high byte (PCNTH) latches the contents of the low byte (PCNTL) into a buffer. Subsequent reads of PCNTH do not affect the latched PCNTL value until PCNTL is read. Reset clears the PIT counter registers. Setting the PIT reset bit (PRST) also clears the PIT counter registers. NOTE: If you read PCNTH during a break interrupt, be sure to unlatch PCNTL by reading PCNTL before exiting the break interrupt. Otherwise, PCNTL retains the value latched during the break. Address: $004C Read: Bit 7 6 5 4 3 2 1 Bit 0 Bit 15 14 13 12 11 10 9 Bit 8 0 0 0 0 0 0 0 0 Bit 7 6 5 4 3 2 1 Bit 0 Bit 15 14 13 12 11 10 9 Bit 8 0 0 0 0 0 0 0 Write: Reset: Address: $004D Read: Write: Reset: 0 = Unimplemented Figure 11-4. PIT Counter Registers (PCNTH–PCNTL) MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 153 11.7.3 PIT Counter Modulo Registers The read/write PIT modulo registers contain the modulo value for the PIT counter. When the PIT counter reaches the modulo value the overflow flag (POF) becomes set and the PIT counter resumes counting from $0000 at the next timer clock. Writing to the high byte (PMODH) inhibits the POF bit and overflow interrupts until the low byte (PMODL) is written. Reset sets the PIT counter modulo registers. Address: $004E Read: Write: Reset: Bit 7 6 5 4 3 2 1 Bit 0 Bit 15 14 13 12 11 10 9 Bit 8 1 1 1 1 1 1 1 1 Bit 7 6 5 4 3 2 1 Bit 0 Bit 7 6 5 4 3 2 1 Bit 0 1 1 1 1 1 1 1 1 Address: $004F Read: Write: Reset: Figure 11-5. PIT Counter Modulo Registers (PMODH–PMODL) NOTE: Data Sheet 154 Reset the PIT counter before writing to the PIT counter modulo registers. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 12. Input/Output (I/O) Ports 12.1 Introduction Forty bidirectional input/output (I/O) pins form six parallel ports. All I/O pins are programmable as inputs or outputs. NOTE: Addr. Connect any unused I/O pins to an appropriate logic level, either VDD or VSS. Although the I/O ports do not require termination for proper operation, termination reduces excess current consumption and the possibility of electrostatic damage. Register Name $0000 Port A Data Register Read: (PTA) Write: See page 156. Reset: $0001 Port B Data Register Read: (PTB) Write: See page 158. Reset: $0002 $0003 5 4 3 2 1 Bit 0 PTA7 PTA6 PTA5 PTA4 PTA3 PTA2 PTA1 PTA0 PTB2 PTB1 PTB0 PTC2 PTC1 PTC0 PTD2 PTD1 PTD0 Unaffected by reset PTB7 Port D Data Register Read: (PTD) Write: See page 162. Reset: 0 $0005 Data Direction Register B Read: (DDRB) Write: See page 159. Reset: PTB5 PTB4 PTB3 0 0 PTC4 PTC3 Unaffected by reset PTD6 PTD5 PTD4 PTD3 Unaffected by reset DDRA7 DDRA6 DDRA5 DDRA4 DDRA3 DDRA2 DDRA1 DDRA0 0 0 0 0 0 0 0 0 DDRB7 DDRB6 DDRB5 DDRB4 DDRB3 DDRB2 DDRB1 DDRB0 0 0 0 0 0 0 0 0 0 0 DDRC4 DDRC3 DDRC2 DDRC1 DDRC0 0 0 0 0 0 0 0 DDRD6 DDRD5 DDRD4 DDRD3 DDR2 DDRD1 DDRD0 0 0 0 0 0 0 0 Data Direction Register C Read: MCLKEN (DDRC) Write: See page 161. Reset: 0 Data Direction Register D Read: (DDRD) Write: See page 163. Reset: PTB6 Unaffected by reset 0 $0004 $0007 6 Port C Data Register Read: (PTC) Write: See page 160. Reset: Data Direction Register A Read: (DDRA) Write: See page 157. Reset: $0006 Bit 7 0 0 = Unimplemented Figure 12-1. I/O Port Register Summary MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 155 Addr. Register Name Port E Data Register Read: (PTE) Write: See page 165. Reset: $0008 $000D 6 5 4 3 2 1 Bit 0 PTE7 PTE6 PTE5 PTE4 PTE3 PTE2 PTE1 PTE0 PTF2 PTF1 PTF0 Unaffected by reset Port F Data Register Read: (PTF) Write: See page 167. Reset: $0009 $000C Bit 7 0 0 0 0 PTF3 Unaffected by reset Data Direction Register E Read: (DDRE) Write: See page 166. Reset: DDRE7 DDRE6 DDRE5 DDRE4 DDRE3 DDRE2 DDRE1 DDRE0 0 0 0 0 0 0 0 0 0 0 0 0 DDRF3 DDRF2 DDRF1 DDRF0 0 0 0 0 0 0 0 Data Direction Register F Read: (DDRF) Write: See page 169. Reset: 0 = Unimplemented Figure 12-1. I/O Port Register Summary (Continued) 12.2 Port A Port A is an 8-bit general-purpose bidirectional I/O port. 12.2.1 Port A Data Register The port A data register contains a data latch for each of the eight port A pins. Address: $0000 Read: Write: Reset: Bit 7 6 5 4 3 2 1 Bit 0 PTA7 PTA6 PTA5 PTA4 PTA3 PTA2 PTA1 PTA0 Unaffected by reset Figure 12-2. Port A Data Register (PTA) PTA[7:0] — Port A Data Bits These read/write bits are software programmable. Data direction of each port A pin is under the control of the corresponding bit in data direction register A. Reset has no effect on port A data. Data Sheet 156 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 12.2.2 Data Direction Register A Data direction register A determines whether each port A pin is an input or an output. Writing a logic 1 to a DDRA bit enables the output buffer for the corresponding port A pin; a logic 0 disables the output buffer. Address: Read: Write: Reset: $0004 Bit 7 6 5 4 3 2 1 Bit 0 DDRA7 DDRA6 DDRA5 DDRA4 DDRA3 DDRA2 DDRA1 DDRA0 0 0 0 0 0 0 0 0 Figure 12-3. Data Direction Register A (DDRA) DDRA[7:0] — Data Direction Register A Bits These read/write bits control port A data direction. Reset clears DDRA[7:0], configuring all port A pins as inputs. 1 = Corresponding port A pin configured as output 0 = Corresponding port A pin configured as input NOTE: Avoid glitches on port A pins by writing to the port A data register before changing data direction register A bits from 0 to 1. Figure 12-4 shows the port A I/O logic. READ DDRA ($0004) INTERNAL DATA BUS WRITE DDRA ($0004) RESET WRITE PTA ($0000) DDRAx PTAx PTAx READ PTA ($0000) Figure 12-4. Port A I/O Circuit When bit DDRAx is a logic 1, reading address $0000 reads the PTAx data latch. When bit DDRAx is a logic 0, reading address $0000 reads the voltage level on the pin. The data latch can always be written, regardless of the state of its data direction bit. Table 12-1 summarizes the operation of the port A pins. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 157 Table 12-1. Port A Pin Functions DDRA Bit PTA Bit Accesses to DDRA I/O Pin Mode Accesses to PTA Read/Write Read Write 0 X Input, Hi-Z DDRA[7:0] Pin PTA[7:0](1) 1 X Output DDRA[7:0] PTA[7:0] PTA[7:0] X = Don’t Care Hi-Z = High Impedance 1. Writing affects data register, but does not affect input. 12.3 Port B Port B is an 8-bit special-function port that shares all of its pins with the analog-to-digital converter (ADC). 12.3.1 Port B Data Register The port B data register contains a data latch for each of the eight port B pins. Address: Read: Write: $0001 Bit 7 6 5 4 3 2 1 Bit 0 PTB7 PTB6 PTB5 PTB4 PTB3 PTB2 PTB1 PTB0 ATD2 ATD1 ATD0 Reset: Alternate Functions: Unaffected by reset ATD7 ATD6 ATD5 ATD4 ATD3 Figure 12-5. Port B Data Register (PTB) PTB[7:0] — Port B Data Bits These read/write bits are software programmable. Data direction of each port B pin is under the control of the corresponding bit in data direction register B. Reset has no effect on port B data. ATD[7:0] — ADC Channels PTB7/ATD7–PTB0/ATD0 are eight of the 15 analog-to-digital converter channels. The ADC channel select bits, CH[4:0], determine whether the PTB7/ATD7–PTB0/ATD0 pins are ADC channels or general-purpose I/O pins. If an ADC channel is selected and a read of this corresponding bit in the port B data register occurs, the data will be 0 if the data direction for this bit is programmed as an input. Otherwise, the data will reflect the value in the data latch. (See Section 3. Analog-to-Digital Converter (ADC).) Data direction register B (DDRB) does not affect the data direction of port B pins that are being used by the ADC. However, the DDRB bits always determine whether reading port B returns to the states of the latches or logic 0. Data Sheet 158 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 12.3.2 Data Direction Register B Data direction register B determines whether each port B pin is an input or an output. Writing a logic 1 to a DDRB bit enables the output buffer for the corresponding port B pin; a logic 0 disables the output buffer. Address: Read: Write: Reset: $0005 Bit 7 6 5 4 3 2 1 Bit 0 DDRB7 DDRB6 DDRB5 DDRB4 DDRB3 DDRB2 DDRB1 DDRB0 0 0 0 0 0 0 0 0 Figure 12-6. Data Direction Register B (DDRB) DDRB[7:0] — Data Direction Register B Bits These read/write bits control port B data direction. Reset clears DDRB[7:0], configuring all port B pins as inputs. 1 = Corresponding port B pin configured as output 0 = Corresponding port B pin configured as input NOTE: Avoid glitches on port B pins by writing to the port B data register before changing data direction register B bits from 0 to 1. Figure 12-7 shows the port B I/O logic. READ DDRB ($0005) INTERNAL DATA BUS WRITE DDRB ($0005) RESET WRITE PTB ($0001) DDRBx PTBx PTBx READ PTB ($0001) Figure 12-7. Port B I/O Circuit When bit DDRBx is a logic 1, reading address $0001 reads the PTBx data latch. When bit DDRBx is a logic 0, reading address $0001 reads the voltage level on the pin, or logic 0 if that particular bit is in use by the ADC. The data latch can always be written, regardless of the state of its data direction bit. Table 12-2 summarizes the operation of the port B pins. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 159 Table 12-2. Port B Pin Functions DDRB Bit PTB Bit Bit in Use by ADC Accesses to DDRB I/O Pin Mode Accesses to PTB Read/Write Read Write 0 X No Input, Hi-Z DDRB[7:0] Pin PTB[7:0](1) 1 X No Output DDRB[7:0] PTB[7:0] PTB[7:0] 0 X Yes Input, Hi-Z DDRB[7:0] 0 PTB[7:0](1) 1 X Yes Input, Hi-Z DDRB[7:0] PTB[7:0] PTB[7:0] X = Don’t Care Hi-Z = High Impedance 1. Writing affects data register, but does not affect input. 12.4 Port C Port C is a 5-bit general-purpose bidirectional I/O port that shares one of its pins with the bus clock (MCLK). 12.4.1 Port C Data Register The port C data register contains a data latch for each of the five port C pins. Address: Read: $0002 Bit 7 6 5 0 0 0 Write: Reset: 4 3 2 1 Bit 0 PTC4 PTC3 PTC2 PTC1 PTC0 Unaffected by Reset = Unimplemented Alternate Functions: MCLK Figure 12-8. Port C Data Register (PTC) PTC[4:0] — Port C Data Bits These read/write bits are software-programmable. Data direction of each port C pin is under the control of the corresponding bit in data direction register C. Reset has no effect on port C data. MCLK — T12 System Bus Clock Bit The bus clock (MCLK) is driven out of PTC2 when enabled by the MCLKEN bit in PTCDDR7. Data Sheet 160 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 12.4.2 Data Direction Register C Data direction register C determines whether each port C pin is an input or an output. Writing a logic 1 to a DDRC bit enables the output buffer for the corresponding port C pin; a logic 0 disables the output buffer. Address: $0006 Bit 7 Read: Write: Reset: MCLKEN 0 6 5 0 0 0 0 4 3 2 1 Bit 0 DDRC4 DDRC3 DDRC2 DDRC1 DDRC0 0 0 0 0 0 = Unimplemented Figure 12-9. Data Direction Register C (DDRC) MCLKEN — MCLK Enable Bit This read/write bit enables MCLK to be an output signal on PTC2. If MCLK is enabled, PTC2 is under the control of MCLKEN. Reset clears this bit. 1 = MCLK output enabled 0 = MCLK output disabled DDRC[4:0] — Data Direction Register C Bits These read/write bits control port C data direction. Reset clears DDRC[7:0], configuring all port C pins as inputs. 1 = Corresponding port C pin configured as output 0 = Corresponding port C pin configured as input NOTE: Avoid glitches on port C pins by writing to the port C data register before changing data direction register C bits from 0 to 1. Figure 12-10 shows the port C I/O logic. READ DDRC ($0006) INTERNAL DATA BUS WRITE DDRC ($0006) RESET WRITE PTC ($0002) DDRCx PTCx PTCx READ PTC ($0002) Figure 12-10. Port C I/O Circuit When bit DDRCx is a logic 1, reading address $0002 reads the PTCx data latch. When bit DDRCx is a logic 0, reading address $0002 reads the voltage level on the MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 161 pin. The data latch can always be written, regardless of the state of its data direction bit. Table 12-3 summarizes the operation of the port C pins. Table 12-3. Port C Pin Functions DDRC Bit PTC Bit Accesses to DDRC I/O Pin Mode Accesses to PTC Read/Write Read Write [7] = 0 PTC2 Input, Hi-Z DDRC[7] 0 PTC2 [7] = 1 PTC2 Output, MCLK DDRC[7] Data Latch — 0 X Input, Hi-Z DDRC[4:0] Pin PTC[4:3, 1:0](1) 1 X Output DDRC[4:0] PTC[4:0] PTC[4:3, 1:0] X = Don’t Care Hi-Z = High Impedance 1. Writing affects data register, but does not affect input. 12.5 Port D Port D is an 8-bit special-function I/O port that shares all of its pins with the analog-to-digital converter (ADC). 12.5.1 Port D Data Register The port D data register contains a data latch for the seven port D pins. Address: $0003 Bit 7 Read: Write: 0 6 5 4 3 2 1 Bit 0 PTD6 PTD5 PTD4 PTD3 PTD2 PTD1 PTD0 ATD10 ATD9 ATD8 Reset: Alternate Functions: Unaffected by Reset ATD14/ TCLK ATD13 ATD12 ATD11 = Unimplemented Figure 12-11. Port D Data Register (PTD) PTD[6:0] — Port D Data Bits PTD[6:0] are read/write, software programmable bits. Data direction of PTD[6:0] pins are under the control of the corresponding bit in data direction register D. ATD[14:8] — ADC Channel Status Bits PTD6/ATD14/TCLK–PTD0/ATD8 are seven of the 15 analog-to-digital converter channels. The ADC channel select bits, CH[4:0], determine whether the PTD6/ATD14/TCLK–PTD0/ATD8 pins are ADC channels or general-purpose I/O pins. If an ADC channel is selected and a read of this Data Sheet 162 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor corresponding bit in the port B data register occurs, the data will be 0 if the data direction for this bit is programmed as an input. Otherwise, the data will reflect the value in the data latch. (See Section 3. Analog-to-Digital Converter (ADC).) NOTE: Data direction register D (DDRD) does not affect the data direction of port D pins that are being used by the ADC. However, the DDRD bits always determine whether reading port D returns the states of the latches or logic 0. TCLK — Timer Clock Input Bit The PTD6/ATD14/TCLK pin is the external clock input for the TIM. The prescaler select bits, PS[2:0], select PTD6/ATD14/TCLK as the TIM clock input. (See 16.8.1 TIM Status and Control Register.) When not selected as the TIM clock, PTD6/ATD14/TCLK is available for general-purpose I/O or as an ADC channel. NOTE: Do not use ADC channel ATD14 when using the PTD6/ATD14/TCLK pin as the clock input for the TIM. 12.5.2 Data Direction Register D Data direction register D determines whether each port D pin is an input or an output. Writing a logic 1 to a DDRD bit enables the output buffer for the corresponding port D pin; a logic 0 disables the output buffer. Address: $0007 Bit 7 Read: 0 Write: Reset: 0 6 5 4 3 2 1 Bit 0 DDRD6 DDRD5 DDRD4 DDRD3 DDRD2 DDRD1 DDRD0 0 0 0 0 0 0 0 = Unimplemented Figure 12-12. Data Direction Register D (DDRD) DDRD[6:0] — Data Direction Register D Bits These read/write bits control port D data direction. Reset clears DDRD[6:0], configuring all port D pins as inputs. 1 = Corresponding port D pin configured as output 0 = Corresponding port D pin configured as input NOTE: Avoid glitches on port D pins by writing to the port D data register before changing data direction register D bits from 0 to 1. Figure 12-13 shows the port D I/O logic. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 163 READ DDRD ($0007) INTERNAL DATA BUS WRITE DDRD ($0007) DDRDx RESET WRITE PTD ($0003) PTDx PTDx READ PTD ($0003) Figure 12-13. Port D I/O Circuit When bit DDRDx is a logic 1, reading address $0003 reads the PTDx data latch. When bit DDRDx is a logic 0, reading address $0003 reads the voltage level on the pin. The data latch can always be written, regardless of the state of its data direction bit. Table 12-4 summarizes the operation of the port D pins. Table 12-4. Port D Pin Functions DDRD Bit PTD Bit Bit in Use by ADC I/O Pin Mode Accesses to DDRD Accesses to PTD Read/Write Read Write 0 X No Input, Hi-Z DDRD[6:0] Pin PTD[6:0](1) 1 X No Output DDRD[6:0] PTD[6:0] PTD[6:0] 0 X Yes Input, Hi-Z DDRD[6:0] 0 PTD[6:0](1) 1 X Yes Input, Hi-Z DDRD[6:0] PTD[6:0] PTD[6:0] X = Don’t Care Hi-Z = High Impedance 1. Writing affects data register, but does not affect input. Data Sheet 164 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 12.6 Port E Port E is an 8-bit special-function port that shares two of its pins with the timer interface module (TIM), two of its pins with the serial communications interface module (SCI), and four of its pins with the serial peripheral interface module (SPI). 12.6.1 Port E Data Register The port E data register contains a data latch for each of the eight port E pins. Address: Read: Write: $0008 Bit 7 6 5 4 3 2 1 Bit 0 PTE7 PTE6 PTE5 PTE4 PTE3 PTE2 PTE1 PTE0 TCH0 RxD TxD Reset: Alternate Function: Unaffected by reset SPSCK MOSI MISO SS TCH1 Figure 12-14. Port E Data Register (PTE) PTE[7:0] — Port E Data Bits PTE[7:0] are read/write, software programmable bits. Data direction of each port E pin is under the control of the corresponding bit in data direction register E. SPSCK — SPI Serial Clock Bit The PTE7/SPSCK pin is the serial clock input of an SPI slave module and serial clock output of an SPI master module. When the SPE bit is clear, the PTE7/SPSCK pin is available for general-purpose I/O. MOSI — Master Out/Slave In Bit The PTE6/MOSI pin is the master out/slave in terminal of the SPI module. When the SPE bit is clear, the PTE6/MOSI pin is available for general-purpose I/O. (See 15.13.1 SPI Control Register.) MISO — Master In/Slave Out Bit The PTE5/MISO pin is the master in/slave out terminal of the SPI module. When the SPI enable bit, SPE, is clear, the SPI module is disabled, and the PTE5/MISO pin is available for general-purpose I/O. (See 15.13.1 SPI Control Register.) SS — Slave Select Bit The PTE4/SS pin is the slave select input of the SPI module. When the SPE bit is clear or when the SPI master bit, SPMSTR, is set and MODFEN bit is low, the PTE4/SS pin is available for general-purpose I/O. (See 15.12.4 SS (Slave Select).) When the SPI is enabled as a slave, the DDRE4 bit in data direction register E (DDRE) has no effect on the PTE4/SS pin. NOTE: Data direction register E (DDRE) does not affect the data direction of port E pins that are being used by the SPI module. However, the DDRE bits always determine MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 165 whether reading port E returns the states of the latches or the states of the pins. (See Table 12-5.) TCH[1:0] — Timer Channel I/O Bits The PTE3/TCH1–PTE2/TCH0 pins are the TIM input capture/output compare pins. The edge/level select bits, ELSxB:ELSxA, determine whether the PTE3/TCH1–PTE2/TCH0 pins are timer channel I/O pins or general-purpose I/O pins. (See 16.8.4 TIM Channel Status and Control Registers.) NOTE: Data direction register E (DDRE) does not affect the data direction of port E pins that are being used by the TIM. However, the DDRE bits always determine whether reading port E returns the states of the latches or the states of the pins. (See Table 12-5.) RxD — SCI Receive Data Input Bit The PTE1/RxD pin is the receive data input for the SCI module. When the enable SCI bit, ENSCI, is clear, the SCI module is disabled, and the PTE1/RxD pin is available for general-purpose I/O. (See 13.8.1 SCI Control Register 1.) TxD — SCI Transmit Data Output The PTE0/TxD pin is the transmit data output for the SCI module. When the enable SCI bit, ENSCI, is clear, the SCI module is disabled, and the PTE0/TxD pin is available for general-purpose I/O. (See 13.8.1 SCI Control Register 1.) NOTE: Data direction register E (DDRE) does not affect the data direction of port E pins that are being used by the SCI module. However, the DDRE bits always determine whether reading port E returns the states of the latches or the states of the pins. (See Table 12-5.) 12.6.2 Data Direction Register E Data direction register E determines whether each port E pin is an input or an output. Writing a logic 1 to a DDRE bit enables the output buffer for the corresponding port E pin; a logic 0 disables the output buffer. Address: $000C Read: Write: Reset: Bit 7 6 5 4 3 2 1 Bit 0 DDRE7 DDRE6 DDRE5 DDRE4 DDRE3 DDRE2 DDRE1 DDRE0 0 0 0 0 0 0 0 0 Figure 12-15. Data Direction Register E (DDRE) DDRE[7:0] — Data Direction Register E Bits These read/write bits control port E data direction. Reset clears DDRE[7:0], configuring all port E pins as inputs. 1 = Corresponding port E pin configured as output 0 = Corresponding port E pin configured as input Data Sheet 166 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor NOTE: Avoid glitches on port E pins by writing to the port E data register before changing data direction register E bits from 0 to 1. Figure 12-16 shows the port E I/O logic. READ DDRE ($000C) INTERNAL DATA BUS WRITE DDRE ($000C) DDREx RESET WRITE PTE ($0008) PTEx PTEx READ PTE ($0008) Figure 12-16. Port E I/O Circuit When bit DDREx is a logic 1, reading address $0008 reads the PTEx data latch. When bit DDREx is a logic 0, reading address $0008 reads the voltage level on the pin. The data latch can always be written, regardless of the state of its data direction bit. Table 12-5 summarizes the operation of the port E pins. Table 12-5. Port E Pin Functions DDRE Bit PTE Bit I/O Pin Mode Accesses to DDRE Accesses to PTE Read/Write Read Write 0 X Input, Hi-Z DDRE[7:0] Pin PTE[7:0](1) 1 X Output DDRE[7:0] PTE[7:0] PTE[7:0] X = Don’t Care Hi-Z = High Impedance 1. Writing affects data register, but does not affect input. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 167 12.7 Port F Port F is a 4-bit special-function port that shares four of its pins with the timer interface module (TIM). 12.7.1 Port F Data Register The port F data register contains a data latch for each of the four port F pins. Address: Read: $0009 Bit 7 6 5 4 0 0 0 0 Write: 3 2 1 Bit 0 PTF3 PTF2 PTF1 PTF0 TCH4 TCH3 TCH2 Reset: Unaffected by reset Alternate Function: TCH5 = Unimplemented Figure 12-17. Port F Data Register (PTF) PTF[3:0] — Port F Data Bits These read/write bits are software programmable. Data direction of each port F pin is under the control of the corresponding bit in data direction register F. Reset has no effect on PTF[3:0]. TCH[5:2] — Timer Channel I/O Bits The PTF3/TCH5–PTF0/TCH2 pins are the TIM input capture/output compare pins. The edge/level select bits, ELSxB–ELSxA, determine whether the PTF3/TCH5–PTF0/TCH2 pins are timer channel I/O pins or general-purpose I/O pins. (See 16.8.4 TIM Channel Status and Control Registers.) NOTE: Data Sheet 168 Data direction register F (DDRF) does not affect the data direction of port F pins that are being used by the TIM. However, the DDRF bits always determine whether reading port F returns the states of the latches or the states of the pins. (See Table 12-6.) MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 12.7.2 Data Direction Register F Data direction register F determines whether each port F pin is an input or an output. Writing a logic 1 to a DDRF bit enables the output buffer for the corresponding port F pin; a logic 0 disables the output buffer. Address: Read: $000D Bit 7 6 5 4 0 0 0 0 0 0 0 0 Write: Reset: 3 2 1 Bit 0 DDRF3 DDRF2 DDRF1 DDRF0 0 0 0 0 = Unimplemented Figure 12-18. Data Direction Register F (DDRF) DDRF[3:0] — Data Direction Register F Bits These read/write bits control port F data direction. Reset clears DDRF[3:0], configuring all port F pins as inputs. 1 = Corresponding port F pin configured as output 0 = Corresponding port F pin configured as input NOTE: Avoid glitches on port F pins by writing to the port F data register before changing data direction register F bits from 0 to 1. Figure 12-19 shows the port F I/O logic. READ DDRF ($000D) INTERNAL DATA BUS WRITE DDRF ($000D) RESET WRITE PTF ($0009) DDRFx PTFx PTFx READ PTF ($0009) Figure 12-19. Port F I/O Circuit When bit DDRFx is a logic 1, reading address $0009 reads the PTFx data latch. When bit DDRFx is a logic 0, reading address $0009 reads the voltage level on the pin. The data latch can always be written, regardless of the state of its data direction bit. Table 12-6 summarizes the operation of the port F pins. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 169 Table 12-6. Port F Pin Functions DDRF Bit PTF Bit I/O Pin Mode Accesses to DDRF Accesses to PTF Read/Write Read Write 0 X Input, Hi-Z DDRF[3:0] Pin PTF[3:0](1) 1 X Output DDRF[3:0] PTF[3:0] PTF[3:0] X = Don’t Care Hi-Z = High Impedance 1. Writing affects data register, but does not affect input. Data Sheet 170 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 13. Serial Communications Interface (SCI) 13.1 Introduction This section describes the serial communications interface module (SCI, Version D), which allows high-speed asynchronous communications with peripheral devices and other MCUs. 13.2 Features Features of the SCI module include: MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor • Full duplex operation • Standard mark/space non-return-to-zero (NRZ) format • 32 programmable baud rates • Programmable 8-bit or 9-bit character length • Separately enabled transmitter and receiver • Separate receiver and transmitter CPU interrupt requests • Programmable transmitter output polarity • Two receiver wakeup methods: – Idle line wakeup – Address mark wakeup • Interrupt-driven operation with eight interrupt flags: – Transmitter empty – Transmission complete – Receiver full – Idle receiver input – Receiver overrun – Noise error – Framing error – Parity error • Receiver framing error detection • Hardware parity checking • 1/16 bit-time noise detection Data Sheet 171 CONTROL AND STATUS REGISTERS — 69 BYTES BREAK MODULE DDRA PTA PTB ANALOG-TO-DIGITAL CONVERTER MODULE DDRB ARITHMETIC/LOGIC UNIT PTA7–PTA0 PTB7/ATD7–PTB0/ATD0 DDRC CPU REGISTERS VREFH USER ROM — 32,256 BYTES PTC Data Sheet 172 INTERNAL BUS M68HC08 CPU SYSTEM INTEGRATION MODULE IRQ IRQ MODULE MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor VDDA/VDDAREF VSSA/VREFL PTF3/TCH5 PTF2/TCH4 PTF1/TCH3 PTF0/TCH2 SERIAL COMMUNICATIONS INTERFACE MODULE SERIAL PERIPHERAL INTERFACE MODULE BYTE DATA LINK CONTROLLER DIGITAL MODULE POWER-ON RESET MODULE VSS VDD PTE7/SPSCK PTE6/MOSI PTE5/MISO PTE4/SS PTE3/TCH1 PTE2/TCH0 PTE1/RxD PTE0/TxD PTF RST PTD CLOCK GENERATOR MODULE PTD5/ATD13–PTD0/ATD8 PTE OSC1 OSC2 CGMXFC PROGRAMMABLE INTERRUPT TIMER MODULE DDRE USER ROM VECTOR SPACE — 38 BYTES PTD6/ATD14/TCLK TIMER INTERFACE MODULE BDRxD BDTxD POWER Figure 13-1. Block Diagram Highlighting SCI Block and Pins DDRF MONITOR ROM — 224 BYTES DDRD USER EEPROM — 512 BYTES USER RAM — 1024 BYTES PTC2/MCLK PTC1–PTC0 LOW-VOLTAGE INHIBIT MODULE COMPUTER OPERATING PROPERLY MODULE PTC4–PTC3 13.3 Pin Name Conventions The generic names of the SCI I/O pins are: • RxD (receive data) • TxD (transmit data) SCI I/O (input/output) lines are implemented by sharing parallel I/O port pins. The full name of an SCI input or output reflects the name of the shared port pin. Table 13-1 shows the full names and the generic names of the SCI I/O pins. The generic pin names appear in the text of this section. Table 13-1. Pin Name Conventions Generic Pin Names: Full Pin Names: RxD TxD PTE1/RxD PTE0/TxD 13.4 Functional Description Figure 13-3 shows the structure of the SCI module. The SCI allows full-duplex, asynchronous, NRZ serial communication among the MCU and remote devices, including other MCUs. The transmitter and receiver of the SCI operate independently, although they use the same baud rate generator. During normal operation, the CPU monitors the status of the SCI, writes the data to be transmitted, and processes received data. The baud rate clock source for the SCI can be selected via the configuration bit, SCIBDSRC, of the MOR2 register ($001E). Source selection values are shown in Figure 13-3. 13.4.1 Data Format The SCI uses the standard non-return-to-zero mark/space data format illustrated in Figure 13-2. 8-BIT DATA FORMAT BIT M IN SCC1 CLEAR START BIT START BIT BIT 0 BIT 1 BIT 2 BIT 3 BIT 4 BIT 5 PARITY BIT BIT 6 BIT 7 9-BIT DATA FORMAT BIT M IN SCC1 SET BIT 0 BIT 1 BIT 2 BIT 3 BIT 4 BIT 5 STOP BIT NEXT START BIT PARITY BIT BIT 6 BIT 7 BIT 8 STOP BIT NEXT START BIT Figure 13-2. SCI Data Formats MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 173 INTERNAL BUS SCI DATA REGISTER ERROR INTERRUPT CONTROL RECEIVE SHIFT REGISTER PTE1/RxD RECEIVER INTERRUPT CONTROL TRANSMITTER INTERRUPT CONTROL SCI DATA REGISTER TRANSMIT SHIFT REGISTER PTE0/TxD TXINV SCTIE R8 TCIE T8 SCRIE ILIE TE SCTE RE TC RWU SCRF SBK IDLE OR ORIE NF NEIE FE FEIE PE PEIE LOOPS LOOPS FLAG CONTROL RECEIVE CONTROL WAKEUP CONTROL ENSCI ENSCI TRANSMIT CONTROL BKF M RPF WAKE ILTY CGMXCLK ÷4 PRESCALER BAUD DIVIDER ÷16 PEN PTY DATA SELECTION CONTROL Figure 13-3. SCI Module Block Diagram Data Sheet 174 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Addr. $0013 $0014 $0015 $0016 Register Name SCI Control Register 1 Read: (SCC1) Write: See page 187. Reset: SCI Control Register 2 Read: (SCC2) Write: See page 189. Reset: 6 5 4 3 2 1 Bit 0 LOOPS ENSCI TXINV M WAKE ILTY PEN PTY 0 0 0 0 0 0 0 0 SCTIE TCIE SCRIE ILIE TE RE RWU SBK 0 0 0 0 0 0 0 0 T8 R R ORIE NEIE FEIE PEIE SCI Control Register 3 Read: (SCC3) Write: See page 191. Reset: R8 U U 0 0 0 0 0 0 SCI Status Register 1 Read: (SCS1) Write: See page 192. Reset: SCTE TC SCRF IDLE OR NF FE PE 1 1 0 0 0 0 0 0 BKF RPF $0017 SCI Status Register 2 Read: (SCS2) Write: See page 195. Reset: $0018 SCI Data Register Read: (SCDR) Write: See page 196. Reset: $0019 Bit 7 SCI Baud Rate Register Read: (SCBR) Write: See page 196. Reset: 0 0 0 0 0 0 0 0 R7 R6 R5 R4 R3 R2 R1 R0 T7 T6 T5 T4 T3 T2 T1 T0 Unaffected by reset 0 0 SCP1 SCP0 R SCR2 SCR1 SCR0 0 0 0 0 0 0 R = Reserved = Unimplemented U = Unaffected Figure 13-4. SCI I/O Register Summary 13.4.2 Transmitter Figure 13-5 shows the structure of the SCI transmitter. The baud rate clock source for the SCI can be selected via the configuration bit, SCIBDSRC. Source selection values are shown in Figure 13-5. 13.4.2.1 Character Length The transmitter can accommodate either 8-bit or 9-bit data. The state of the M bit in SCI control register 1 (SCC1) determines character length. When transmitting 9-bit data, bit T8 in SCI control register 3 (SCC3) is the ninth bit (bit 8). MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 175 INTERNAL BUS ÷4 PRESCALER BAUD DIVIDER ÷ 16 SCI DATA REGISTER SCP1 11-BIT TRANSMIT SHIFT REGISTER STOP SCP0 SCR2 H SCR1 7 6 5 4 3 2 1 0 L PTE0/TxD MSB SCR0 8 START CGMXCLK TXINV T8 BREAK ALL 0s TRANSMITTER CPU INTERRUPT REQUEST PARITY GENERATION PREAMBLE ALL 1s PTY SHIFT ENABLE PEN LOAD FROM SCDR M TRANSMITTER CONTROL LOGIC SCTE SCTIE TC TCIE SCTE SCTIE SBK LOOPS TC ENSCI TCIE TE Figure 13-5. SCI Transmitter 13.4.2.2 Character Transmission During an SCI transmission, the transmit shift register shifts a character out to the PTE0/TxD pin. The SCI data register (SCDR) is the write-only buffer between the internal data bus and the transmit shift register. To initiate an SCI transmission: 1. Enable the SCI by writing a logic 1 to the enable SCI bit (ENSCI) in SCI control register 1 (SCC1). 2. Enable the transmitter by writing a logic 1 to the transmitter enable bit (TE) in SCI control register 2 (SCC2). 3. Clear the SCI transmitter empty bit by first reading SCI status register 1 (SCS1) and then writing to the SCDR. 4. Repeat step 3 for each subsequent transmission. At the start of a transmission, transmitter control logic automatically loads the transmit shift register with a preamble of logic 1s. After the preamble shifts out, control logic transfers the SCDR data into the transmit shift register. A logic 0 start Data Sheet 176 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor bit automatically goes into the least significant bit position of the transmit shift register. A logic 1 stop bit goes into the most significant bit position. The SCI transmitter empty bit, SCTE, in SCS1 becomes set when the SCDR transfers a byte to the transmit shift register. The SCTE bit indicates that the SCDR can accept new data from the internal data bus. If the SCI transmit interrupt enable bit, SCTIE, in SCC2 is also set, the SCTE bit generates a transmitter CPU interrupt request. When the transmit shift register is not transmitting a character, the PTE0/TxD pin goes to the idle condition, logic 1. If at any time software clears the ENSCI bit in SCI control register 1 (SCC1), the transmitter and receiver relinquish control of the port E pins. 13.4.2.3 Break Characters Writing a logic 1 to the send break bit, SBK, in SCC2 loads the transmit shift register with a break character. A break character contains all logic 0s and has no start, stop, or parity bit. Break character length depends on the M bit in SCC1. As long as SBK is at logic 1, transmitter logic continuously loads break characters into the transmit shift register. After software clears the SBK bit, the shift register finishes transmitting the last break character and then transmits at least one logic 1. The automatic logic 1 at the end of a break character guarantees the recognition of the start bit of the next character. The SCI recognizes a break character when a start bit is followed by eight or nine logic 0 data bits and a logic 0 where the stop bit should be. Receiving a break character has these effects on SCI registers: • Sets the framing error bit (FE) in SCS1 • Sets the SCI receiver full bit (SCRF) in SCS1 • Clears the SCI data register (SCDR) • Clears the R8 bit in SCC3 • Sets the break flag bit (BKF) in SCS2 • May set the overrun (OR), noise flag (NF), parity error (PE), or reception in progress flag (RPF) bits 13.4.2.4 Idle Characters An idle character contains all logic 1s and has no start, stop, or parity bit. Idle character length depends on the M bit in SCC1. The preamble is a synchronizing idle character that begins every transmission. If the TE bit is cleared during a transmission, the PTE0/TxD pin becomes idle after completion of the transmission in progress. Clearing and then setting the TE bit during a transmission queues an idle character to be sent after the character currently being transmitted. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 177 NOTE: When a break sequence is followed immediately by an idle character, this SCI design exhibits a condition in which the break character length is reduced by one half bit time. In this instance, the break sequence will consist of a valid start bit, eight or nine data bits (as defined by the M bit in SCC1) of logic 0 and one half data bit length of logic 0 in the stop bit position followed immediately by the idle character. To ensure a break character of the proper length is transmitted, always queue up a byte of data to be transmitted while the final break sequence is in progress. When queueing an idle character, return the TE bit to logic 1 before the stop bit of the current character shifts out to the TxD pin. Setting TE after the stop bit appears on TxD causes data previously written to the SCDR to be lost. Toggle the TE bit for a queued idle character when the SCTE bit becomes set and just before writing the next byte to the SCDR. 13.4.2.5 Inversion of Transmitted Output The transmit inversion bit (TXINV) in SCI control register 1 (SCC1) reverses the polarity of transmitted data. All transmitted values, including idle, break, start, and stop bits, are inverted when TXINV is at logic 1. See 13.8.1 SCI Control Register 1. 13.4.2.6 Transmitter Interrupts These conditions can generate CPU interrupt requests from the SCI transmitter: • SCI transmitter empty (SCTE) — The SCTE bit in SCS1 indicates that the SCDR has transferred a character to the transmit shift register. SCTE can generate a transmitter CPU interrupt request. Setting the SCI transmit interrupt enable bit, SCTIE, in SCC2 enables the SCTE bit to generate transmitter CPU interrupt requests. • Transmission complete (TC) — The TC bit in SCS1 indicates that the transmit shift register and the SCDR are empty and that no break or idle character has been generated. The transmission complete interrupt enable bit, TCIE, in SCC2 enables the TC bit to generate transmitter CPU interrupt requests. 13.4.3 Receiver Figure 13-6 shows the structure of the SCI receiver. 13.4.3.1 Character Length The receiver can accommodate either 8-bit or 9-bit data. The state of the M bit in SCI control register 1 (SCC1) determines character length. When receiving 9-bit data, bit R8 in SCI control register 2 (SCC2) is the ninth bit (bit 8). When receiving 8-bit data, bit R8 is a copy of the eighth bit (bit 7). Data Sheet 178 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor INTERNAL BUS SCR2 SCP0 SCR0 ÷4 PRESCALER BAUD DIVIDER SCI DATA REGISTER ÷ 16 DATA RECOVERY PTE1/RxD H 11-BIT RECEIVE SHIFT REGISTER 8 7 6 M WAKE PTY CPU INTERRUPT REQUEST 3 SCRF WAKEUP LOGIC PARITY CHECKING IDLE ILIE SCRF SCRIE ERROR CPU INTERRUPT REQUEST 4 2 1 0 L ALL 1s MSB RPF PEN 5 ALL 0s BKF ILTY START SCR1 STOP CGMXCLK SCP1 OR ORIE NF NEIE FE FEIE PE PEIE RWU IDLE R8 ILIE SCRIE OR ORIE NF NEIE FE FEIE PE PEIE Figure 13-6. SCI Receiver Block Diagram MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 179 13.4.3.2 Character Reception During an SCI reception, the receive shift register shifts characters in from the PTE1/RxD pin. The SCI data register (SCDR) is the read-only buffer between the internal data bus and the receive shift register. After a complete character shifts into the receive shift register, the data portion of the character transfers to the SCDR. The SCI receiver full bit, SCRF, in SCI status register 1 (SCS1) becomes set, indicating that the received byte can be read. If the SCI receive interrupt enable bit, SCRIE, in SCC2 is also set, the SCRF bit generates a receiver CPU interrupt request. 13.4.3.3 Data Sampling The receiver samples the PTE1/RxD pin at the RT clock rate. The RT clock is an internal signal with a frequency 16 times the baud rate. To adjust for baud rate mismatch, the RT clock is resynchronized at the following times (see Figure 13-7): • After every start bit • After the receiver detects a data bit change from logic 1 to logic 0 (after the majority of data bit samples at RT8, RT9, and RT10 returns a valid logic 1 and the majority of the next RT8, RT9, and RT10 samples returns a valid logic 0) To locate the start bit, data recovery logic does an asynchronous search for a logic 0 preceded by three logic 1s. When the falling edge of a possible start bit occurs, the RT clock begins to count to 16. LSB START BIT PTE1/RxD START BIT QUALIFICATION SAMPLES START BIT VERIFICATION DATA SAMPLING RT4 RT3 RT2 RT1 RT16 RT15 RT14 RT13 RT12 RT11 RT10 RT9 RT8 RT7 RT6 RT5 RT4 RT3 RT2 RT1 RT1 RT1 RT1 RT1 RT1 RT1 RT1 RT CLOCK STATE RT1 RT CLOCK RT CLOCK RESET Figure 13-7. Receiver Data Sampling Data Sheet 180 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor To verify the start bit and to detect noise, data recovery logic takes samples at RT3, RT5, and RT7. Table 13-2 summarizes the results of the start bit verification samples. Table 13-2. Start Bit Verification RT3, RT5, and RT7 Samples Start Bit Verification Noise Flag 000 Yes 0 001 Yes 1 010 Yes 1 011 No 0 100 Yes 1 101 No 0 110 No 0 111 No 0 Start bit verification is not successful if any two of the three verification samples are logic 1s. If start bit verification is not successful, the RT clock is reset and a new search for a start bit begins. To determine the value of a data bit and to detect noise, recovery logic takes samples at RT8, RT9, and RT10. Table 13-3 summarizes the results of the data bit samples. Table 13-3. Data Bit Recovery NOTE: Data Bit Determination Noise Flag 000 0 0 001 0 1 010 0 1 011 1 1 100 0 1 101 1 1 110 1 1 111 1 0 The RT8, RT9, and RT10 samples do not affect start bit verification. If any or all of the RT8, RT9, and RT10 start bit samples are logic 1s following a successful start bit verification, the noise flag (NF) is set and the receiver assumes that the bit is a start bit. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor RT8, RT9, and RT10 Samples Data Sheet 181 To verify a stop bit and to detect noise, recovery logic takes samples at RT8, RT9, and RT10. Table 13-4 summarizes the results of the stop bit samples. Table 13-4. Stop Bit Recovery RT8, RT9, and RT10 Samples Framing Error Flag Noise Flag 000 1 0 001 1 1 010 1 1 011 0 1 100 1 1 101 0 1 110 0 1 111 0 0 13.4.3.4 Framing Errors If the data recovery logic does not detect a logic 1 where the stop bit should be in an incoming character, it sets the framing error bit, FE, in SCS1. A break character also sets the FE bit because a break character has no stop bit. The FE bit is set at the same time that the SCRF bit is set. 13.4.3.5 Baud Rate Tolerance A transmitting device may be operating at a baud rate below or above the receiver baud rate. Accumulated bit time misalignment can cause one of the three stop bit data samples to fall outside the actual stop bit. Then a noise error occurs. If more than one of the samples is outside the stop bit, a framing error occurs. In most applications, the baud rate tolerance is much more than the degree of misalignment that is likely to occur. As the receiver samples an incoming character, it resynchronizes the RT clock on any valid falling edge within the character. Resynchronization within characters corrects misalignments between transmitter bit times and receiver bit times. Slow Data Tolerance Figure 13-8 shows how much a slow received character can be misaligned without causing a noise error or a framing error. The slow stop bit begins at RT8 instead of RT1 but arrives in time for the stop bit data samples at RT8, RT9, and RT10. For an 8-bit character, data sampling of the stop bit takes the receiver 9 bit times × 16 RT cycles + 10 RT cycles = 154 RT cycles. With the misaligned character shown in Figure 13-8, the receiver counts 154 RT cycles at the point when the count of the transmitting device is 9 bit times × 16 RT cycles + 3 RT cycles = 147 RT cycles. Data Sheet 182 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor MSB STOP RT16 RT15 RT14 RT13 RT12 RT11 RT10 RT9 RT8 RT7 RT6 RT5 RT4 RT3 RT2 RT1 RECEIVER RT CLOCK DATA SAMPLES Figure 13-8. Slow Data The maximum percent difference between the receiver count and the transmitter count of a slow 8-bit character with no errors is 154 – 147 -------------------------- × 100 = 4.54% 154 For a 9-bit character, data sampling of the stop bit takes the receiver 10 bit times × 16 RT cycles + 10 RT cycles = 170 RT cycles. With the misaligned character shown in Figure 13-8, the receiver counts 170 RT cycles at the point when the count of the transmitting device is 10 bit times × 16 RT cycles + 3 RT cycles = 163 RT cycles. The maximum percent difference between the receiver count and the transmitter count of a slow 9-bit character with no errors is 170 – 163 -------------------------- × 100 = 4.12% 170 Fast Data Tolerance Figure 13-9 shows how much a fast received character can be misaligned without causing a noise error or a framing error. The fast stop bit ends at RT10 instead of RT16 but is still there for the stop bit data samples at RT8, RT9, and RT10. STOP IDLE OR NEXT CHARACTER RT16 RT15 RT14 RT13 RT12 RT11 RT10 RT9 RT8 RT7 RT6 RT5 RT4 RT3 RT2 RT1 RECEIVER RT CLOCK DATA SAMPLES Figure 13-9. Fast Data For an 8-bit character, data sampling of the stop bit takes the receiver 9 bit times × 16 RT cycles + 10 RT cycles = 154 RT cycles. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 183 With the misaligned character shown in Figure 13-9, the receiver counts 154 RT cycles at the point when the count of the transmitting device is 10 bit times × 16 RT cycles = 160 RT cycles. The maximum percent difference between the receiver count and the transmitter count of a fast 8-bit character with no errors is · 154 – 160 -------------------------- × 100 = 3.90% 154 For a 9-bit character, data sampling of the stop bit takes the receiver 10 bit times × 16 RT cycles + 10 RT cycles = 170 RT cycles. With the misaligned character shown in Figure 13-9, the receiver counts 170 RT cycles at the point when the count of the transmitting device is 11 bit times × 16 RT cycles = 176 RT cycles. The maximum percent difference between the receiver count and the transmitter count of a fast 9-bit character with no errors is 170 – 176 × 100 = 3.53% -------------------------170 13.4.3.6 Receiver Wakeup So that the MCU can ignore transmissions intended only for other receivers in multiple-receiver systems, the receiver can be put into a standby state. Setting the receiver wakeup bit, RWU, in SCC2 puts the receiver into a standby state during which receiver interrupts are disabled. Depending on the state of the WAKE bit in SCC1, either of two conditions on the PTE1/RxD pin can bring the receiver out of the standby state: NOTE: Data Sheet 184 • Address mark — An address mark is a logic 1 in the most significant bit position of a received character. When the WAKE bit is set, an address mark wakes the receiver from the standby state by clearing the RWU bit. The address mark also sets the SCI receiver full bit, SCRF. Software can then compare the character containing the address mark to the user-defined address of the receiver. If they are the same, the receiver remains awake and processes the characters that follow. If they are not the same, software can set the RWU bit and put the receiver back into the standby state. • Idle input line condition — When the WAKE bit is clear, an idle character on the PTE1/RxD pin wakes the receiver from the standby state by clearing the RWU bit. The idle character that wakes the receiver does not set the receiver idle bit, IDLE, or the SCI receiver full bit, SCRF. The idle line type bit, ILTY, determines whether the receiver begins counting logic 1s as idle character bits after the start bit or after the stop bit. With the WAKE bit clear, setting the RWU bit after the RxD pin has been idle may cause the receiver to wake up immediately. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 13.4.3.7 Receiver Interrupts The following sources can generate CPU interrupt requests from the SCI receiver: • SCI receiver full (SCRF) — The SCRF bit in SCS1 indicates that the receive shift register has transferred a character to the SCDR. SCRF can generate a receiver CPU interrupt request. Setting the SCI receive interrupt enable bit, SCRIE, in SCC2 enables the SCRF bit to generate receiver CPU interrupts. • Idle input (IDLE) — The IDLE bit in SCS1 indicates that 10 or 11 consecutive logic 1s shifted in from the PTE1/RxD pin. The idle line interrupt enable bit, ILIE, in SCC2 enables the IDLE bit to generate CPU interrupt requests. 13.4.3.8 Error Interrupts The following receiver error flags in SCS1 can generate CPU interrupt requests: • Receiver overrun (OR) — The OR bit indicates that the receive shift register shifted in a new character before the previous character was read from the SCDR. The previous character remains in the SCDR, and the new character is lost. The overrun interrupt enable bit, ORIE, in SCC3 enables OR to generate SCI error CPU interrupt requests. • Noise flag (NF) — The NF bit is set when the SCI detects noise on incoming data or break characters, including start, data, and stop bits. The noise error interrupt enable bit, NEIE, in SCC3 enables NF to generate SCI error CPU interrupt requests. • Framing error (FE) — The FE bit in SCS1 is set when a logic 0 occurs where the receiver expects a stop bit. The framing error interrupt enable bit, FEIE, in SCC3 enables FE to generate SCI error CPU interrupt requests. • Parity error (PE) — The PE bit in SCS1 is set when the SCI detects a parity error in incoming data. The parity error interrupt enable bit, PEIE, in SCC3 enables PE to generate SCI error CPU interrupt requests. 13.5 Low-Power Modes The WAIT and STOP instructions put the MCU in low power- consumption standby modes. 13.5.1 Wait Mode The SCI module remains active after the execution of a WAIT instruction. In wait mode, the SCI module registers are not accessible by the CPU. Any enabled CPU interrupt request from the SCI module can bring the MCU out of wait mode. If SCI module functions are not required during wait mode, reduce power consumption by disabling the module before executing the WAIT instruction. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 185 13.5.2 Stop Mode The SCI module is inactive after the execution of a STOP instruction. The STOP instruction does not affect SCI register states. SCI module operation resumes after an external interrupt. Because the internal clock is inactive during stop mode, entering stop mode during an SCI transmission or reception results in invalid data. 13.6 SCI During Break Module Interrupts The system integration module (SIM) controls whether status bits in other modules can be cleared during the break state. The BCFE bit in the SIM break flag control register (SBFCR) enables software to clear status bits during the break state. To allow software to clear status bits during a break interrupt, write a logic 1 to the BCFE bit. If a status bit is cleared during the break state, it remains cleared when the MCU exits the break state. To protect status bits during the break state, write a logic 0 to the BCFE bit. With BCFE at logic 0 (its default state), software can read and write I/O registers during the break state without affecting status bits. Some status bits have a 2-step read/write clearing procedure. If software does the first step on such a bit before the break, the bit cannot change during the break state as long as BCFE is at logic 0. After the break, doing the second step clears the status bit. 13.7 I/O Signals Port E shares two of its pins with the SCI module. The two SCI I/O pins are: • PTE0/TxD — Transmit data • PTE1/RxD — Receive data 13.7.1 PTE0/TxD (Transmit Data) The PTE0/TxD pin is the serial data output from the SCI transmitter. The SCI shares the PTE0/TxD pin with port E. When the SCI is enabled, the PTE0/TxD pin is an output regardless of the state of the DDRE2 bit in data direction register E (DDRE). 13.7.2 PTE1/RxD (Receive Data) The PTE1/RxD pin is the serial data input to the SCI receiver. The SCI shares the PTE1/RxD pin with port E. When the SCI is enabled, the PTE1/RxD pin is an input regardless of the state of the DDRE1 bit in data direction register E (DDRE). Data Sheet 186 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 13.8 I/O Registers These I/O registers control and monitor SCI operation: • SCI control register 1 (SCC1) • SCI control register 2 (SCC2) • SCI control register 3 (SCC3) • SCI status register 1 (SCS1) • SCI status register 2 (SCS2) • SCI data register (SCDR) • SCI baud rate register (SCBR) 13.8.1 SCI Control Register 1 SCI control register 1: • Enables loop mode operation • Enables the SCI • Controls output polarity • Controls character length • Controls SCI wakeup method • Controls idle character detection • Enables parity function • Controls parity type Address: Read: Write: Reset: $0013 Bit 7 6 5 4 3 2 1 Bit 0 LOOPS ENSCI TXINV M WAKE ILTY PEN PTY 0 0 0 0 0 0 0 0 Figure 13-10. SCI Control Register 1 (SCC1) LOOPS — Loop Mode Select Bit This read/write bit enables loop mode operation. In loop mode the PTE1/RxD pin is disconnected from the SCI, and the transmitter output goes into the receiver input. Both the transmitter and the receiver must be enabled to use loop mode. Reset clears the LOOPS bit. 1 = Loop mode enabled 0 = Normal operation enabled ENSCI — Enable SCI Bit This read/write bit enables the SCI and the SCI baud rate generator. Clearing ENSCI sets the SCTE and TC bits in SCI status register 1 and disables transmitter interrupts. Reset clears the ENSCI bit. 1 = SCI enabled 0 = SCI disabled MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 187 TXINV — Transmit Inversion Bit This read/write bit reverses the polarity of transmitted data. Reset clears the TXINV bit. 1 = Transmitter output inverted 0 = Transmitter output not inverted NOTE: Setting the TXINV bit inverts all transmitted values, including idle, break, start, and stop bits. M — Mode (Character Length) Bit This read/write bit determines whether SCI characters are eight or nine bits long. See Table 13-5. The ninth bit can serve as an extra stop bit, as a receiver wakeup signal, or as a parity bit. Reset clears the M bit. 1 = 9-bit SCI characters 0 = 8-bit SCI characters WAKE — Wakeup Condition Bit This read/write bit determines which condition wakes up the SCI: a logic 1 (address mark) in the most significant bit position of a received character or an idle condition on the PTE1/RxD pin. Reset clears the WAKE bit. 1 = Address mark wakeup 0 = Idle line wakeup ILTY — Idle Line Type Bit This read/write bit determines when the SCI starts counting logic 1s as idle character bits. The counting begins either after the start bit or after the stop bit. If the count begins after the start bit, then a string of logic 1s preceding the stop bit may cause false recognition of an idle character. Beginning the count after the stop bit avoids false idle character recognition, but requires properly synchronized transmissions. Reset clears the ILTY bit. 1 = Idle character bit count begins after stop bit 0 = Idle character bit count begins after start bit PEN — Parity Enable Bit This read/write bit enables the SCI parity function. See Table 13-5. When enabled, the parity function inserts a parity bit in the most significant bit position. See Figure 13-2. Reset clears the PEN bit. 1 = Parity function enabled 0 = Parity function disabled PTY — Parity Bit This read/write bit determines whether the SCI generates and checks for odd parity or even parity. See Table 13-5. Reset clears the PTY bit. 1 = Odd parity 0 = Even parity NOTE: Data Sheet 188 Changing the PTY bit in the middle of a transmission or reception can generate a parity error. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Table 13-5. Character Format Selection Control Bits Character Format M PEN and PTY Start Bits Data Bits Parity Stop Bits Character Length 0 0X 1 8 None 1 10 bits 1 0X 1 9 None 1 11 bits 0 10 1 7 Even 1 10 bits 0 11 1 7 Odd 1 10 bits 1 10 1 8 Even 1 11 bits 1 11 1 8 Odd 1 11 bits 13.8.2 SCI Control Register 2 SCI control register 2: • Enables the following CPU interrupt requests: – Enables the SCTE bit to generate transmitter CPU interrupt requests – Enables the TC bit to generate transmitter CPU interrupt requests – Enables the SCRF bit to generate receiver CPU interrupt requests – Enables the IDLE bit to generate receiver CPU interrupt requests • Enables the transmitter • Enables the receiver • Enables SCI wakeup • Transmits SCI break characters Address: Read: Write: Reset: $0014 Bit 7 6 5 4 3 2 1 Bit 0 SCTIE TCIE SCRIE ILIE TE RE RWU SBK 0 0 0 0 0 0 0 0 Figure 13-11. SCI Control Register 2 (SCC2) SCTIE — SCI Transmit Interrupt Enable Bit This read/write bit enables the SCTE bit to generate SCI transmitter CPU interrupt requests. Reset clears the SCTIE bit. 1 = SCTE enabled to generate CPU interrupt 0 = SCTE not enabled to generate CPU interrupt TCIE — Transmission Complete Interrupt Enable Bit This read/write bit enables the TC bit to generate SCI transmitter CPU interrupt requests. Reset clears the TCIE bit. 1 = TC enabled to generate CPU interrupt requests 0 = TC not enabled to generate CPU interrupt requests MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 189 SCRIE — SCI Receive Interrupt Enable Bit This read/write bit enables the SCRF bit to generate SCI receiver CPU interrupt requests. Reset clears the SCRIE bit. 1 = SCRF enabled to generate CPU interrupt 0 = SCRF not enabled to generate CPU interrupt ILIE — Idle Line Interrupt Enable Bit This read/write bit enables the IDLE bit to generate SCI receiver CPU interrupt requests. Reset clears the ILIE bit. 1 = IDLE enabled to generate CPU interrupt requests 0 = IDLE not enabled to generate CPU interrupt requests TE — Transmitter Enable Bit Setting this read/write bit begins the transmission by sending a preamble of 10 or 11 logic 1s from the transmit shift register to the PTE0/TxD pin. If software clears the TE bit, the transmitter completes any transmission in progress before the PTE0/TxD returns to the idle condition (logic 1). Clearing and then setting TE during a transmission queues an idle character to be sent after the character currently being transmitted. Reset clears the TE bit. 1 = Transmitter enabled 0 = Transmitter disabled NOTE: Writing to the TE bit is not allowed when the enable SCI bit (ENSCI) is clear. ENSCI is in SCI control register 1. RE — Receiver Enable Bit Setting this read/write bit enables the receiver. Clearing the RE bit disables the receiver but does not affect receiver interrupt flag bits. Reset clears the RE bit. 1 = Receiver enabled 0 = Receiver disabled NOTE: Writing to the RE bit is not allowed when the enable SCI bit (ENSCI) is clear. ENSCI is in SCI control register 1. RWU — Receiver Wakeup Bit This read/write bit puts the receiver in a standby state during which receiver interrupts are disabled. The WAKE bit in SCC1 determines whether an idle input or an address mark brings the receiver out of the standby state and clears the RWU bit. Reset clears the RWU bit. 1 = Standby state 0 = Normal operation SBK — Send Break Bit Setting and then clearing this read/write bit transmits a break character followed by a logic 1. The logic 1 after the break character guarantees recognition of a valid start bit. If SBK remains set, the transmitter continuously transmits break characters with no logic 1s between them. Reset clears the SBK bit. 1 = Transmit break characters 0 = No break characters being transmitted Data Sheet 190 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor NOTE: Do not toggle the SBK bit immediately after setting the SCTE bit. Toggling SBK before the preamble begins causes the SCI to send a break character instead of a preamble. 13.8.3 SCI Control Register 3 SCI control register 3: • Stores the ninth SCI data bit received and the ninth SCI data bit to be transmitted • Enables these interrupts: – Receiver overrun interrupts – Noise error interrupts – Framing error interrupts – Parity error interrupts Address: $0015 Bit 7 Read: R8 Write: Reset: U 6 5 4 3 2 1 Bit 0 T8 R R ORIE NEIE FEIE PEIE U 0 0 0 0 0 0 R = Reserved = Unimplemented U = Unaffected Figure 13-12. SCI Control Register 3 (SCC3) R8 — Received Bit 8 When the SCI is receiving 9-bit characters, R8 is the read-only ninth bit (bit 8) of the received character. R8 is received at the same time that the SCDR receives the other 8 bits. When the SCI is receiving 8-bit characters, R8 is a copy of the eighth bit (bit 7). Reset has no effect on the R8 bit. T8 — Transmitted Bit 8 When the SCI is transmitting 9-bit characters, T8 is the read/write ninth bit (bit 8) of the transmitted character. T8 is loaded into the transmit shift register at the same time that the SCDR is loaded into the transmit shift register. Reset has no effect on the T8 bit. ORIE — Receiver Overrun Interrupt Enable Bit This read/write bit enables SCI error CPU interrupt requests generated by the receiver overrun bit, OR. 1 = SCI error CPU interrupt requests from OR bit enabled 0 = SCI error CPU interrupt requests from OR bit disabled NEIE — Receiver Noise Error Interrupt Enable Bit This read/write bit enables SCI error CPU interrupt requests generated by the noise error bit, NE. Reset clears NEIE. 1 = SCI error CPU interrupt requests from NE bit enabled 0 = SCI error CPU interrupt requests from NE bit disabled MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 191 FEIE — Receiver Framing Error Interrupt Enable Bit This read/write bit enables SCI error CPU interrupt requests generated by the framing error bit, FE. Reset clears FEIE. 1 = SCI error CPU interrupt requests from FE bit enabled 0 = SCI error CPU interrupt requests from FE bit disabled PEIE — Receiver Parity Error Interrupt Enable Bit This read/write bit enables SCI error CPU interrupt requests generated by the parity error bit, PE. See 13.8.4 SCI Status Register 1. Reset clears PEIE. 1 = SCI error CPU interrupt requests from PE bit enabled 0 = SCI error CPU interrupt requests from PE bit disabled 13.8.4 SCI Status Register 1 SCI status register 1 (SCS1) contains flags to signal these conditions: • Transfer of SCDR data to transmit shift register complete • Transmission complete • Transfer of receive shift register data to SCDR complete • Receiver input idle • Receiver overrun • Noisy data • Framing error • Parity error Address: Read: $0016 Bit 7 6 5 4 3 2 1 Bit 0 SCTE TC SCRF IDLE OR NF FE PE 1 0 0 0 0 0 0 Write: Reset: 1 = Unimplemented Figure 13-13. SCI Status Register 1 (SCS1) SCTE — SCI Transmitter Empty Bit This clearable, read-only bit is set when the SCDR transfers a character to the transmit shift register. SCTE can generate an SCI transmitter CPU interrupt request. When the SCTIE bit in SCC2 is set, SCTE generates an SCI transmitter CPU interrupt request. In normal operation, clear the SCTE bit by reading SCS1 with SCTE set and then writing to SCDR. Reset sets the SCTE bit. 1 = SCDR data transferred to transmit shift register 0 = SCDR data not transferred to transmit shift register TC — Transmission Complete Bit This read-only bit is set when the SCTE bit is set, and no data, preamble, or break character is being transmitted. TC generates an SCI transmitter CPU interrupt request if the TCIE bit in SCC2 is also set. TC is automatically cleared Data Sheet 192 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor when data, preamble or break is queued and ready to be sent. There may be up to 1.5 transmitter clocks of latency between queueing data, preamble, and break and the transmission actually starting. Reset sets the TC bit. 1 = No transmission in progress 0 = Transmission in progress SCRF — SCI Receiver Full Bit This clearable, read-only bit is set when the data in the receive shift register transfers to the SCI data register. SCRF can generate an SCI receiver CPU interrupt request. When the SCRIE bit in SCC2 is set, SCRF generates a CPU interrupt request. In normal operation, clear the SCRF bit by reading SCS1 with SCRF set and then reading the SCDR. Reset clears SCRF. 1 = Received data available in SCDR 0 = Data not available in SCDR IDLE — Receiver Idle Bit This clearable, read-only bit is set when 10 or 11 consecutive logic 1s appear on the receiver input. IDLE generates an SCI receiver CPU interrupt request if the ILIE bit in SCC2 is also set. Clear the IDLE bit by reading SCS1 with IDLE set and then reading the SCDR. After the receiver is enabled, it must receive a valid character that sets the SCRF bit before an idle condition can set the IDLE bit. Also, after the IDLE bit has been cleared, a valid character must again set the SCRF bit before an idle condition can set the IDLE bit. Reset clears the IDLE bit. 1 = Receiver input idle 0 = Receiver input active (or idle since the IDLE bit was cleared) OR — Receiver Overrun Bit This clearable, read-only bit is set when software fails to read the SCDR before the receive shift register receives the next character. The OR bit generates an SCI error CPU interrupt request if the ORIE bit in SCC3 is also set. The data in the shift register is lost, but the data already in the SCDR is not affected. Clear the OR bit by reading SCS1 with OR set and then reading the SCDR. Reset clears the OR bit. 1 = Receive shift register full and SCRF = 1 0 = No receiver overrun Software latency may allow an overrun to occur between reads of SCS1 and SCDR in the flag-clearing sequence. Figure 13-14 shows the normal flag-clearing sequence and an example of an overrun caused by a delayed flag-clearing sequence. The delayed read of SCDR does not clear the OR bit because OR was not set when SCS1 was read. Byte 2 caused the overrun and is lost. The next flag-clearing sequence reads byte 3 in the SCDR instead of byte 2. In applications that are subject to software latency or in which it is important to know which byte is lost due to an overrun, the flag-clearing routine can check the OR bit in a second read of SCS1 after reading the data register. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 193 NF — Receiver Noise Flag Bit This clearable, read-only bit is set when the SCI detects noise on the PTE1/RxD pin. NF generates an SCI error CPU interrupt request if the NEIE bit in SCC3 is also set. Clear the NF bit by reading SCS1 and then reading the SCDR. Reset clears the NF bit. 1 = Noise detected 0 = No noise detected FE — Receiver Framing Error Bit This clearable, read-only bit is set when a logic 0 is accepted as the stop bit. FE generates an SCI error CPU interrupt request if the FEIE bit in SCC3 also is set. Clear the FE bit by reading SCS1 with FE set and then reading the SCDR. Reset clears the FE bit. 1 = Framing error detected 0 = No framing error detected PE — Receiver Parity Error Bit This clearable, read-only bit is set when the SCI detects a parity error in incoming data. PE generates an SCI error CPU interrupt request if the PEIE bit in SCC3 is also set. Clear the PE bit by reading SCS1 with PE set and then reading the SCDR. Reset clears the PE bit. 1 = Parity error detected 0 = No parity error detected BYTE 1 BYTE 2 BYTE 3 SCRF = 0 SCRF = 1 SCRF = 0 SCRF = 1 SCRF = 0 SCRF = 1 NORMAL FLAG CLEARING SEQUENCE BYTE 4 READ SCS1 SCRF = 1 OR = 0 READ SCS1 SCRF = 1 OR = 0 READ SCS1 SCRF = 1 OR = 0 READ SCDR BYTE 1 READ SCDR BYTE 2 READ SCDR BYTE 3 BYTE 1 BYTE 2 BYTE 3 SCRF = 0 OR = 0 SCRF = 1 OR = 1 SCRF = 0 OR = 1 SCRF = 1 SCRF = 1 OR = 1 DELAYED FLAG CLEARING SEQUENCE BYTE 4 READ SCS1 SCRF = 1 OR = 0 READ SCS1 SCRF = 1 OR = 1 READ SCDR BYTE 1 READ SCDR BYTE 3 Figure 13-14. Flag Clearing Sequence Data Sheet 194 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 13.8.5 SCI Status Register 2 SCI status register 2 contains flags to signal the following conditions: • Break character detected • Incoming data Address: $0017 Bit 7 6 5 4 3 2 Read: 1 Bit 0 BKF RPF 0 0 Write: Reset: 0 0 0 0 0 0 = Unimplemented Figure 13-15. SCI Status Register 2 (SCS2) BKF — Break Flag Bit This clearable, read-only bit is set when the SCI detects a break character on the PTE1/RxD pin. In SCS1, the FE and SCRF bits are also set. In 9-bit character transmissions, the R8 bit in SCC3 is cleared. BKF does not generate a CPU interrupt request. Clear BKF by reading SCS2 with BKF set and then reading the SCDR. Once cleared, BKF can become set again only after logic 1s again appear on the PTE1/RxD pin followed by another break character. Reset clears the BKF bit. 1 = Break character detected 0 = No break character detected RPF — Reception in Progress Flag Bit This read-only bit is set when the receiver detects a logic 0 during the RT1 time period of the start bit search. RPF does not generate an interrupt request. RPF is reset after the receiver detects false start bits (usually from noise or a baud rate mismatch) or when the receiver detects an idle character. Polling RPF before disabling the SCI module or entering stop mode can show whether a reception is in progress. 1 = Reception in progress 0 = No reception in progress MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 195 13.8.6 SCI Data Register The SCI data register (SCDR) is the buffer between the internal data bus and the receive and transmit shift registers. Reset has no effect on data in the SCI data register. Address: $0018 Bit 7 6 5 4 3 2 1 Bit 0 Read: R7 R6 R5 R4 R3 R2 R1 R0 Write: T7 T6 T5 T4 T3 T2 T1 T0 Reset: Unaffected by reset Figure 13-16. SCI Data Register (SCDR) R7/T7–R0/T0 — Receive/Transmit Data Bits Reading the SCDR accesses the read-only received data bits, R7:R0. Writing to the SCDR writes the data to be transmitted, T7:T0. Reset has no effect on the SCDR. NOTE: Do not use read/modify/write instructions on the SCI data register. 13.8.7 SCI Baud Rate Register The baud rate register (SCBR) selects the baud rate for both the receiver and the transmitter. Address: $0019 Bit 7 6 Read: Write: Reset: 0 5 4 3 2 1 Bit 0 SCP1 SCP0 R SCR2 SCR1 SCR0 0 0 0 0 0 0 R = Reserved 0 = Unimplemented Figure 13-17. SCI Baud Rate Register (SCBR) SCP1 and SCP0 — SCI Baud Rate Prescaler Bits These read/write bits select the baud rate prescaler divisor as shown in Table 13-6. Reset clears SCP1 and SCP0. Table 13-6. SCI Baud Rate Prescaling Data Sheet 196 SCP1 and SCP0 Prescaler Divisor (PD) 00 1 01 3 10 4 11 13 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor SCR2–SCR0 — SCI Baud Rate Select Bits These read/write bits select the SCI baud rate divisor as shown in Table 13-7. Reset clears SCR2–SCR0. Table 13-7. SCI Baud Rate Selection SCR2, SCR1, and SCR0 Baud Rate Divisor (BD) 000 1 001 2 010 4 011 8 100 16 101 32 110 64 111 128 Use this formula to calculate the SCI baud rate: fxclk Baud rate = 64 x PD x BD where: fxclk = crystal frequency PD = prescaler divisor BD = baud rate divisor Table 13-8 shows the SCI baud rates that can be generated with a 4.9152-MHz bus clock when fBUS is selected as SCI clock source. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 197 Table 13-8. SCI Baud Rate Selection Examples SCP1 and SCP0 Prescaler Divisor (PD) SCR2, SCR1, and SCR0 Baud Rate Divisor (BD) Baud Rate (fxclk = 4.9152 MHz) 00 1 000 1 76,800 00 1 001 2 38,400 00 1 010 4 19,200 00 1 011 8 9600 00 1 100 16 4800 00 1 101 32 2400 00 1 110 64 1200 00 1 111 128 600 01 3 000 1 25,600 01 3 001 2 12,800 01 3 010 4 6400 01 3 011 8 3200 01 3 100 16 1600 01 3 101 32 800 01 3 110 64 400 01 3 111 128 200 10 4 000 1 19,200 10 4 001 2 9600 10 4 010 4 4800 10 4 011 8 2400 10 4 100 16 1200 10 4 101 32 600 10 4 110 64 300 10 4 111 128 150 11 13 000 1 5908 11 13 001 2 2954 11 13 010 4 1477 11 13 011 8 739 11 13 100 16 369 11 13 101 32 185 11 13 110 64 92 11 13 111 128 46 Data Sheet 198 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 14. System Integration Module (SIM) 14.1 Introduction This section describes the system integration module (SIM), which supports up to 24 external and/or internal interrupts. The SIM is a system state controller that coordinates CPU and exception timing. Together with the central processor unit (CPU), the SIM controls all MCU activities. The SIM is responsible for: • Bus clock generation and control for CPU and peripherals: – Stop/wait/reset/break entry and recovery – Internal clock control • Master reset control, including power-on reset (POR) and computer operating properly (COP) timeout • Interrupt control – Acknowledge timing – Arbitration control timing – Vector address generation • CPU enable/disable timing • Modular architecture expandable to 128 interrupt sources A block diagram of the SIM is shown in Figure 14-2. Figure 14-3 is a summary of the SIM input/output (I/O) registers. Table 14-1 shows the internal signal names used in this section. Table 14-1. Signal Name Conventions Signal Name Description CGMXCLK Buffered version of OSC1 from clock generator module (CGM) CGMVCLK PLL output CGMOUT PLL-based or OSC1-based clock output from CGM module (Bus clock = CGMOUT divided by two) IAB Internal address bus IDB Internal data bus PORRST Signal from the power-on reset module to the SIM IRST Internal reset signal R/W Read/write signal MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 199 CONTROL AND STATUS REGISTERS — 69 BYTES BREAK MODULE DDRA PTA PTB ANALOG-TO-DIGITAL CONVERTER MODULE DDRB ARITHMETIC/LOGIC UNIT PTA7–PTA0 PTB7/ATD7–PTB0/ATD0 DDRC CPU REGISTERS VREFH USER ROM — 32,256 BYTES PTC Data Sheet 200 INTERNAL BUS M68HC08 CPU SYSTEM INTEGRATION MODULE IRQ IRQ MODULE MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor VDDA/VDDAREF VSSA/VREFL PTF3/TCH5 PTF2/TCH4 PTF1/TCH3 PTF0/TCH2 SERIAL COMMUNICATIONS INTERFACE MODULE SERIAL PERIPHERAL INTERFACE MODULE BYTE DATA LINK CONTROLLER DIGITAL MODULE POWER-ON RESET MODULE VSS VDD PTE7/SPSCK PTE6/MOSI PTE5/MISO PTE4/SS PTE3/TCH1 PTE2/TCH0 PTE1/RxD PTE0/TxD PTF RST PTD CLOCK GENERATOR MODULE PTD5/ATD13–PTD0/ATD8 PTE OSC1 OSC2 CGMXFC PROGRAMMABLE INTERRUPT TIMER MODULE DDRE USER ROM VECTOR SPACE — 38 BYTES PTD6/ATD14/TCLK TIMER INTERFACE MODULE BDRxD BDTxD POWER Figure 14-1. Block Diagram Highlighting SIM Block and Pin DDRF MONITOR ROM — 224 BYTES DDRD USER EEPROM — 512 BYTES USER RAM — 1024 BYTES PTC2/MCLK PTC1–PTC0 LOW-VOLTAGE INHIBIT MODULE COMPUTER OPERATING PROPERLY MODULE PTC4–PTC3 MODULE STOP MODULE WAIT CPU STOP FROM CPU CPU WAIT FROM CPU STOP/WAIT CONTROL SIMOSCEN TO CGM SIM COUNTER COP CLOCK CGMXCLK FROM CGM CGMOUT FROM CGM ÷2 CLOCK CONTROL RESET PIN LOGIC INTERNAL CLOCKS CLOCK GENERATORS LVI FROM LVI MODULE POR CONTROL MASTER RESET CONTROL RESET PIN CONTROL ILLEGAL OPCODE FROM CPU ILLEGAL ADDRESS FROM ADDRESS MAP DECODERS COP FROM COP MODULE SIM RESET STATUS REGISTER RESET INTERRUPT SOURCES INTERRUPT CONTROL AND PRIORITY DECODE CPU INTERFACE Figure 14-2. SIM Block Diagram Addr. Register Name $FE00 SIM Break Status Register Read: (SBSR) Write: See page 213. Reset: $FE01 $FE03 Bit 7 6 5 4 3 2 1 Bit 0 R R R R R R SBSW R 0 SIM Reset Status Register Read: (SRSR) Write: See page 213. Reset: POR PIN COP ILOP ILAD 0 LVI 0 R R R R R R R R 1 0 0 0 0 0 0 0 SIM Break Flag Control Register Read: (SBFCR) Write: See page 213. Reset: POR PIN COP ILOP ILAD 0 LVI 0 R R R R R R R R 1 0 0 0 0 0 0 0 R = Reserved Figure 14-3. SIM I/O Register Summary MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 201 14.2 SIM Bus Clock Control and Generation The bus clock generator provides system clock signals for the CPU and peripherals on the MCU. The system clocks are generated from an incoming clock, CGMOUT, as shown in Figure 14-4. This clock can come from either an external oscillator or from the on-chip PLL. (See Section 5. Clock Generator Module (CGM).) 14.2.1 Bus Timing In user mode, the internal bus frequency is either the crystal oscillator output (CGMXCLK) divided by four or the PLL output (CGMVCLK) divided by four. (See Section 5. Clock Generator Module (CGM).) 14.2.2 Clock Startup from POR or LVI Reset When the power-on reset (POR) module or the low-voltage inhibit (LVI) module generates a reset, the clocks to the CPU and peripherals are inactive and held in an inactive phase until after 4096 CGMXCLK cycles. The RST pin is driven low by the SIM during this entire period. The bus clocks start upon completion of the timeout. 14.2.3 Clocks in Stop Mode and Wait Mode Upon exit from stop mode by an interrupt or reset, the SIM allows CGMXCLK to clock the SIM counter. The CPU and peripheral clocks do not become active until after the stop delay timeout. This timeout is selectable as 4096 or 32 CGMXCLK cycles. (See 14.6.2 Stop Mode.) In wait mode, the CPU clocks are inactive. However, some modules can be programmed to be active in wait mode. Refer to the wait mode subsection of each module to see if the module is active or inactive in wait mode. CGMXCLK OSC1 CGMVCLK PLL CLOCK SELECT CIRCUIT ÷2 A CGMOUT B S* *When S = 1, CGMOUT = B SIM COUNTER BUS CLOCK GENERATORS ÷2 SIM BCS PTC3 MONITOR MODE USER MODE CGM Figure 14-4. CGM Clock Signals Data Sheet 202 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 14.3 Reset and System Initialization The MCU has these reset sources: • Power-on reset module (POR) • External reset pin (RST) • Computer operating properly module (COP) • Low-voltage inhibit module (LVI) • Illegal opcode • Illegal address Each of these resets produces the vector $FFFE–FFFF ($FEFE–FEFF in monitor mode) and asserts the internal reset signal (IRST). IRST causes all registers to be returned to their default values and all modules to be returned to their reset states. An internal reset clears the SIM counter (see 14.4 SIM Counter), but an external reset does not. Each of the resets sets a corresponding bit in the SIM reset status register (SRSR). (See 14.7 SIM Registers.) 14.3.1 External Pin Reset Pulling the asynchronous RST pin low halts all processing. The PIN bit of the SIM reset status register (SRSR) is set as long as RST is held low for at least the minimum tRL time. Figure 14-5 shows the relative timing. CGMOUT RST IAB VECT H PC VECT L Figure 14-5. External Reset Timing 14.3.2 Active Resets from Internal Sources All internal reset sources actively pull the RST pin low for 32 CGMXCLK cycles to allow resetting of external peripherals. The internal reset signal IRST continues to be asserted for an additional 32 cycles. See Figure 14-6. An internal reset can be caused by an illegal address, illegal opcode, COP timeout, LVI, or POR. See Figure 14-7. Note that for LVI or POR resets, the SIM cycles through 4096 CGMXCLK cycles during which the SIM forces the RST pin low. The internal reset signal then follows the sequence from the falling edge of RST shown in Figure 14-6. The COP reset is asynchronous to the bus clock. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 203 The active reset feature allows the part to issue a reset to peripherals and other chips within a system built around the MCU. IRST RST RST PULLED LOW BY MCU 32 CYCLES 32 CYCLES CGMXCLK IAB VECTOR HIGH Figure 14-6. Internal Reset Timing ILLEGAL ADDRESS RST ILLEGAL OPCODE RST COPRST LVI POR INTERNAL RESET Figure 14-7. Sources of Internal Reset Table 14-2. Reset Recovery Timing Reset Recovery Type Actual Number of Cycles POR/LVI 4163 (4096 + 64 + 3) All Others 67 (64 + 3) 14.3.2.1 Power-On Reset When power is first applied to the MCU, the power-on reset module (POR) generates a pulse to indicate that power-on has occurred. The external reset pin (RST) is held low while the SIM counter counts out 4096 CGMXCLK cycles. Another 64 CGMXCLK cycles later, the CPU and memories are released from reset to allow the reset vector sequence to occur. See Figure 14-8. At power-on, these events occur: • A POR pulse is generated. • The internal reset signal is asserted. • The SIM enables CGMOUT. • Internal clocks to the CPU and modules are held inactive for 4096 CGMXCLK cycles to allow stabilization of the oscillator. • The RST pin is driven low during the oscillator stabilization time. • The POR bit of the SIM reset status register (SRSR) is set. Data Sheet 204 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor OSC1 PORRST 4096 CYCLES 32 CYCLES 32 CYCLES CGMXCLK CGMOUT RST $FFFE IAB $FFFF Figure 14-8. POR Recovery 14.3.2.2 Computer Operating Properly (COP) Reset The overflow of the COP counter causes an internal reset and sets the COP bit in the SIM reset status register (SRSR) if the COPD bit in the MORA register is at logic 0. (See Section 6. Computer Operating Properly (COP).) 14.3.2.3 Illegal Opcode Reset The SIM decodes signals from the CPU to detect illegal instructions. An illegal instruction sets the ILOP bit in the SIM reset status register (SRSR) and causes a reset. NOTE: A $9E opcode (pre-byte for SP instructions) followed by an $8E opcode (stop instruction) generates a stop mode recovery reset. If the stop enable bit, STOP, in the MORA register is logic 0, the SIM treats the STOP instruction as an illegal opcode and causes an illegal opcode reset. 14.3.2.4 Illegal Address Reset An opcode fetch from an unmapped address generates an illegal address reset. The SIM verifies that the CPU is fetching an opcode prior to asserting the ILAD bit in the SIM reset status register (SRSR) and resetting the MCU. A data fetch from an unmapped address does not generate a reset. 14.3.2.5 Low-Voltage Inhibit (LVI) Reset The low-voltage inhibit (LVI) module asserts its output to the SIM when the VDD voltage falls to the VTRIPF voltage. The LVI bit in the SIM reset status register (SRSR) is set and a chip reset is asserted if the LVIPWR and LVIRST bits in the MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 205 MORA register are at logic 1. The RST pin will be held low until the SIM counts 4096 CGMXCLK cycles after VDD rises above VTRIPR. Another 64 CGMXCLK cycles later, the CPU is released from reset to allow the reset vector sequence to occur. (See Section 9. Low-Voltage Inhibit (LVI).) 14.4 SIM Counter The SIM counter is used by the power-on reset module (POR) and in stop mode recovery to allow the oscillator time to stabilize before enabling the internal bus (IBUS) clocks. The SIM counter also serves as a prescaler for the computer operating properly (COP) module. The SIM counter overflow supplies the clock for the COP module. The SIM counter is 12 bits long and is clocked by the falling edge of CGMXCLK. 14.4.1 SIM Counter During Power-On Reset The power-on reset module (POR) detects power applied to the MCU. At power-on, the POR circuit asserts the signal PORRST. Once the SIM is initialized, it enables the clock generation module (CGM) to drive the bus clock state machine. 14.4.2 SIM Counter During Stop Mode Recovery The SIM counter also is used for stop mode recovery. The STOP instruction clears the SIM counter. After an interrupt, break, or reset, the SIM senses the state of the short stop recovery bit, SSREC, in the MORA register. If the SSREC bit is a logic 1, then the stop recovery is reduced from the normal delay of 4096 CGMXCLK cycles down to 32 CGMXCLK cycles. This is ideal for applications using canned oscillators that do not require long startup times from stop mode. External crystal applications should use the full stop recovery time with SSREC cleared. 14.4.3 SIM Counter and Reset States External reset has no effect on the SIM counter. (See 14.6.2 Stop Mode for details.) The SIM counter is free-running after all reset states. (See 14.3.2 Active Resets from Internal Sources for counter control and internal reset recovery sequences.) 14.5 Program Exception Control Normal, sequential program execution can be changed in three different ways: Data Sheet 206 • Interrupts: – Maskable hardware CPU interrupts – Non-maskable software interrupt instruction (SWI) • Reset • Break interrupts MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 14.5.1 Interrupts At the beginning of an interrupt, the CPU saves the CPU register contents on the stack and sets the interrupt mask (I bit) to prevent additional interrupts. At the end of an interrupt, the RTI instruction recovers the CPU register contents from the stack so that normal processing can resume. Figure 14-9 shows interrupt entry timing. Figure 14-10 shows interrupt recovery timing. Interrupts are latched, and arbitration is performed in the SIM at the start of interrupt processing. The arbitration result is a constant that the CPU uses to determine which vector to fetch. Once an interrupt is latched by the SIM, no other interrupt can take precedence, regardless of priority, until the latched interrupt is serviced or the I bit is cleared. (See Figure 14-11.) MODULE INTERRUPT I BIT IAB IDB SP DUMMY DUMMY SP – 1 PC – 1[7:0] SP – 2 PC–1[15:8] SP – 3 X SP – 4 A VECT H CCR VECT L V DATA H START ADDR V DATA L OPCODE R/W Figure 14-9. Hardware Interrupt Entry MODULE INTERRUPT I BIT IAB IDB SP – 4 SP – 3 CCR SP – 2 A SP – 1 X SP PC – 1 [15:8] PC PC–1[7:0] PC + 1 OPCODE OPERAND R/W Figure 14-10. Hardware Interrupt Recovery MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 207 FROM RESET BREAK INTERRUPT? I BIT SET? YES NO YES I BIT SET? NO IRQ0 INTERRUPT? YES NO IRQ1 INTERRUPT? YES NO STACK CPU REGISTERS SET I BIT LOAD PC WITH INTERRUPT VECTOR AS MANY INTERRUPTS AS EXIST ON CHIP FETCH NEXT INSTRUCTION SWI INSTRUCTION? YES NO RTI INSTRUCTION? YES UNSTACK CPU REGISTERS NO EXECUTE INSTRUCTION Figure 14-11. Interrupt Processing Data Sheet 208 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 14.5.1.1 Hardware Interrupts A hardware interrupt does not stop the current instruction. Processing of a hardware interrupt begins after completion of the current instruction. When the current instruction is complete, the SIM checks all pending hardware interrupts. If interrupts are not masked (I bit clear in the condition code register) and if the corresponding interrupt enable bit is set, the SIM proceeds with interrupt processing; otherwise, the next instruction is fetched and executed. If more than one interrupt is pending at the end of an instruction execution, the highest priority interrupt is serviced first. Figure 14-12 demonstrates what happens when two interrupts are pending. If an interrupt is pending upon exit from the original interrupt service routine, the pending interrupt is serviced before the LDA instruction is executed. CLI BACKGROUND ROUTINE LDA #$FF INT1 PSHH INT1 INTERRUPT SERVICE ROUTINE PULH RTI INT2 PSHH INT2 INTERRUPT SERVICE ROUTINE PULH RTI Figure 14-12. Interrupt Recognition Example The LDA opcode is prefetched by both the INT1 and INT2 RTI instructions. However, in the case of the INT1 RTI prefetch, this is a redundant operation. NOTE: To maintain compatibility with the M68HC05, M6805, and M146805 Families, the H register is not pushed on the stack during interrupt entry. If the interrupt service routine modifies the H register or uses the indexed addressing mode, software should save the H register and then restore it prior to exiting the routine. 14.5.1.2 SWI Instruction The SWI instruction is a non-maskable instruction that causes an interrupt regardless of the state of the interrupt mask (I bit) in the condition code register. NOTE: A software interrupt pushes PC onto the stack. A software interrupt does not push PC – 1, as a hardware interrupt does. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 209 14.5.2 Reset All reset sources always have higher priority than interrupts and cannot be arbitrated. 14.5.3 Break Interrupts The break module can stop normal program flow at a software-programmable break point by asserting its break interrupt output. (See 17.2 Break Module (BRK).) The SIM puts the CPU into the break state by forcing it to the SWI vector location. Refer to the break interrupt subsection of each module to see how the break state affects each module. 14.5.4 Status Flag Protection in Break Mode The SIM controls whether status flags contained in other modules can be cleared during break mode. The user can select to protect flags from being cleared by properly initializing the break clear flag enable bit (BCFE) in the SIM break flag control register (SBFCR). (See 14.7.3 SIM Break Flag Control Register.) Protecting flags in break mode ensures that set flags will not be cleared while in break mode. This protection allows registers to be freely read and written during break mode without losing status flag information. Setting the BCFE bit enables the clearing mechanisms. Once cleared in break mode, a flag remains cleared even when break mode is exited. Status flags with a 2-step clearing mechanism — for example, a read of one register followed by the read or write of another — are protected, even when the first step is accomplished prior to entering break mode. Upon leaving break mode, execution of the second step will clear the flag as usual. 14.6 Low-Power Modes Executing the WAIT or STOP instruction puts the MCU in a low-power mode for standby situations. The SIM holds the CPU in a non-clocked state. The operation of each of these modes is described below. Both STOP and WAIT clear the interrupt mask (I) in the condition code register, allowing interrupts to occur. 14.6.1 Wait Mode In wait mode, the CPU clocks are inactive while one set of peripheral clocks continues to run. Figure 14-13 shows the timing for wait mode entry. A module that is active during wait mode can wake up the CPU with an interrupt if the interrupt is enabled. Stacking for the interrupt begins one cycle after the WAIT instruction during which the interrupt occurred. Refer to the wait mode subsection of each module to see if the module is active or inactive in wait mode. Some modules can be programmed to be active in wait mode. Data Sheet 210 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Wait mode also can be exited by a reset (or break in emulation mode). A break interrupt during wait mode sets the SIM break stop/wait bit, SBSW, in the SIM break status register (SBSR). If the COP disable bit, COPD, in the mask option register (MORA $001F) is logic 0, then the computer operating properly module (COP) is enabled and remains active in wait mode. IAB WAIT ADDR + 1 WAIT ADDR IDB PREVIOUS DATA SAME SAME NEXT OPCODE SAME SAME R/W NOTE: Previous data can be operand data or the WAIT opcode, depending on the last instruction. Figure 14-13. Wait Mode Entry Timing Figure 14-14 and Figure 14-15 show the timing for wait recovery. IAB $6E0B IDB $A6 $A6 $6E0C $A6 $01 $00FF $00FE $0B $00FD $00FC $6E EXITSTOPWAIT NOTE: EXITSTOPWAIT = RST pin or CPU interrupt Figure 14-14. Wait Recovery from Interrupt 32 CYCLES $6E0B IAB IDB $A6 $A6 32 CYCLES RSTVCTH RST VCTL $A6 RST CGMXCLK Figure 14-15. Wait Recovery from Internal Reset MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 211 14.6.2 Stop Mode In stop mode, the SIM counter is reset and the system clocks are disabled. An interrupt request from a module can cause an exit from stop mode. Stacking for interrupts begins after the selected stop recovery time has elapsed. Reset or break also causes an exit from stop mode. The SIM disables the clock generator module outputs (CGMOUT and CGMXCLK) in stop mode, stopping the CPU and peripherals. Stop recovery time is selectable using the short stop recovery (SSREC) bit in the MORA register ($001F). If SSREC is set, stop recovery is reduced from the normal delay of 4096 CGMXCLK cycles down to 32. This is ideal for applications using canned oscillators that do not require long startup times from stop mode. NOTE: External crystal applications should use the full stop recovery time by clearing the SSREC bit. A break interrupt during stop mode sets the SIM break stop/wait bit (SBSW) in the SIM break status register (SBSR). The SIM counter is held in reset from the execution of the STOP instruction until the beginning of stop recovery. It is then used to time the recovery period. Figure 14-16 shows stop mode entry timing. CPUSTOP IAB IDB STOP ADDR STOP ADDR + 1 PREVIOUS DATA SAME NEXT OPCODE SAME SAME SAME R/W NOTE: Previous data can be operand data or the STOP opcode, depending on the last instruction. Figure 14-16. Stop Mode Entry Timing STOP RECOVERY PERIOD CGMXCLK INTERRUPT IAB STOP +1 STOP + 2 STOP + 2 SP SP – 1 SP – 2 SP – 3 Figure 14-17. Stop Mode Recovery from Interrupt Data Sheet 212 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 14.7 SIM Registers The SIM has three memory mapped registers. 14.7.1 SIM Break Status Register The SIM break status register contains a flag to indicate that a break caused an exit from wait mode. This register is only used in emulation mode. Address: $FE00 Bit 7 6 5 4 3 2 1 Bit 0 R R R R R R SBSW R Read: Write: Reset: 0 R = Reserved Figure 14-18. SIM Break Status Register (SBSR) SBSW — SIM Break Stop/Wait Bit SBSW can be read within the break state SWI routine. The user can modify the return address on the stack by subtracting one from it. 1 = Wait mode exited by break interrupt 0 = Wait mode not exited by break interrupt 14.7.2 SIM Reset Status Register This register contains six flags that show the source of the last reset. The status register will clear automatically after reading it. A power-on reset sets the POR bit and clears all other bits in the register. Address: Read: $FE01 Bit 7 6 5 4 3 2 1 Bit 0 POR PIN COP ILOP ILAD 0 LVI 0 1 0 0 0 0 0 0 0 Write: Reset: = Unimplemented Figure 14-19. SIM Reset Status Register (SRSR) POR — Power-On Reset Bit 1 = Last reset caused by POR circuit 0 = Read of SRSR PIN — External Reset Bit 1 = Last reset caused by external reset pin (RST) 0 = POR or read of SRSR COP — Computer Operating Properly Reset Bit 1 = Last reset caused by COP counter 0 = POR or read of SRSR MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 213 ILOP — Illegal Opcode Reset Bit 1 = Last reset caused by an illegal opcode 0 = POR or read of SRSR ILAD — Illegal Address Reset Bit (opcode fetches only) 1 = Last reset caused by an opcode fetch from an illegal address 0 = POR or read of SRSR LVI — Low-Voltage Inhibit Reset Bit 1 = Last reset was caused by the LVI circuit 0 = POR or read of SRSR 14.7.3 SIM Break Flag Control Register The SIM break control register contains a bit that enables software to clear status bits while the MCU is in a break state. Address: $FE03 Read: Write: Reset: Bit 7 6 5 4 3 2 1 Bit 0 BCFE R R R R R R R 0 R = Reserved Figure 14-20. SIM Break Flag Control Register (SBFCR) BCFE — Break Clear Flag Enable Bit In some module registers, this read/write bit will enable software to clear status bits by accessing status registers only while the MCU is in a break state. To clear status bits during the break state, the BCFE bit must be set. This operation is important for modules with status bits which can be cleared only by being read. See the register descriptions in each module for additional details. 1 = Status bits clearable during break 0 = Status bits not clearable during break Data Sheet 214 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 15. Serial Peripheral Interface (SPI) 15.1 Introduction This section describes the serial peripheral interface (SPI) module, which allows full-duplex, synchronous, serial communications with peripheral devices. 15.2 Features Features of the SPI module include: • Full-duplex operation • Master mode and slave mode • Double-buffered operation with separate transmit and receive registers • Four master mode frequencies (maximum = bus frequency ÷ 2) • Maximum slave mode frequency = bus frequency • Serial clock with programmable polarity and phase • Two separately enabled interrupts with CPU service: • SPRF (SPI receiver full) • SPTE (SPI transmitter empty) • Mode fault error flag with cpu interrupt capability • Overflow error flag with CPU interrupt capability • Programmable wired-OR mode • I2C (inter-integrated circuit) compatibility 15.3 Pin Name and Register Name Conventions The generic names of the SPI input/output (I/O) pins are: • SS (slave select) • SPSCK (SPI serial clock) • MOSI (master out/slave in) • MISO (master in/slave out) The SPI shares four I/O pins with a parallel I/O port. The full name of an SPI pin reflects the name of the shared port pin. Table 15-1 shows the full names of the SPI I/O pins. The generic pin names appear in the text that follows. Table 15-1. Pin Name Conventions SPI Generic Pin Name: Full SPI Pin Name: MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor MISO MOSI SS SPSCK PTE5/MISO PTE6/MOSI PTE4/SS PTE7/SPSCK Data Sheet 215 CONTROL AND STATUS REGISTERS — 69 BYTES BREAK MODULE DDRA PTA PTB ANALOG-TO-DIGITAL CONVERTER MODULE DDRB ARITHMETIC/LOGIC UNIT PTA7–PTA0 PTB7/ATD7–PTB0/ATD0 DDRC CPU REGISTERS VREFH USER ROM — 32,256 BYTES PTC Data Sheet 216 INTERNAL BUS M68HC08 CPU SYSTEM INTEGRATION MODULE IRQ IRQ MODULE MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor VDDA/VDDAREF VSSA/VREFL PTF3/TCH5 PTF2/TCH4 PTF1/TCH3 PTF0/TCH2 SERIAL COMMUNICATIONS INTERFACE MODULE SERIAL PERIPHERAL INTERFACE MODULE BYTE DATA LINK CONTROLLER DIGITAL MODULE POWER-ON RESET MODULE VSS VDD PTE7/SPSCK PTE6/MOSI PTE5/MISO PTE4/SS PTE3/TCH1 PTE2/TCH0 PTE1/RxD PTE0/TxD PTF RST PTD CLOCK GENERATOR MODULE PTD5/ATD13–PTD0/ATD8 PTE OSC1 OSC2 CGMXFC PROGRAMMABLE INTERRUPT TIMER MODULE DDRE USER ROM VECTOR SPACE — 38 BYTES PTD6/ATD14/TCLK TIMER INTERFACE MODULE BDRxD BDTxD POWER Figure 15-1. Block Diagram Highlighting SPI Block and Pins DDRF MONITOR ROM — 224 BYTES DDRD USER EEPROM — 512 BYTES USER RAM — 1024 BYTES PTC2/MCLK PTC1–PTC0 LOW-VOLTAGE INHIBIT MODULE COMPUTER OPERATING PROPERLY MODULE PTC4–PTC3 The generic names of the SPI I/O registers are: • SPI control register (SPCR) • SPI status and control register (SPSCR) • SPI data register (SPDR) Table 15-2 shows the names and the addresses of the SPI I/O registers. Table 15-2. I/O Register Addresses Register Name Address SPI control register $0010 SPI status and control register $0011 SPI data register $0012 15.4 Functional Description Figure 15-2 summarizes the SPI I/O registers and Figure 15-3 shows the structure of the SPI module. The SPI module allows full-duplex, synchronous, serial communication between the MCU and peripheral devices, including other MCUs. Software can poll the SPI status flags or SPI operation can be interrupt-driven. All SPI interrupts can be serviced by the CPU. The following paragraphs describe the operation of the SPI module. Addr. $0010 Register Name SPI Control Register Read: (SPCR) Write: See page 234. Reset: $0011 SPI Status and Control Register Read: (SPSCR) Write: See page 236. Reset: $0012 SPI Data Register Read: (SPDR) Write: See page 238. Reset: Bit 7 6 5 4 3 2 1 Bit 0 SPRIE R SPMSTR CPOL CPHA SPWOM SPE SPTIE 0 0 1 0 1 0 0 0 OVRF MODF SPTE MODFEN SPR1 SPR0 SPRF ERRIE 0 0 0 0 1 0 0 0 R7 R6 R5 R4 R3 R2 R1 R0 T7 T6 T5 T4 T3 T2 T1 T0 Unaffected by reset = Unimplemented Figure 15-2. SPI I/O Register Summary MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 217 INTERNAL BUS TRANSMIT DATA REGISTER SHIFT REGISTER BUS CLOCK 7 6 5 4 3 2 1 MISO 0 ÷2 CLOCK DIVIDER MOSI ÷8 RECEIVE DATA REGISTER ÷ 32 PIN CONTROL LOGIC ÷ 128 SPMSTR SPE CLOCK SELECT SPR1 SPSCK M CLOCK LOGIC S SPR0 SPMSTR TRANSMITTER CPU INTERRUPT REQUEST CPHA MODFEN SS CPOL SPWOM ERRIE SPI CONTROL SPTIE RECEIVER/ERROR CPU INTERRUPT REQUEST SPRIE SPE SPRF SPTE OVRF MODF Figure 15-3. SPI Module Block Diagram Data Sheet 218 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 15.4.1 Master Mode The SPI operates in master mode when the SPI master bit, SPMSTR (SPCR $0010), is set. NOTE: Configure the SPI modules as master and slave before enabling them. Enable the master SPI before enabling the slave SPI. Disable the slave SPI before disabling the master SPI. (See 15.13.1 SPI Control Register.) Only a master SPI module can initiate transmissions. Software begins the transmission from a master SPI module by writing to the SPI data register. If the shift register is empty, the byte immediately transfers to the shift register, setting the SPI transmitter empty bit, SPTE (SPSCR $0011). The byte begins shifting out on the MOSI pin under the control of the serial clock. (See Figure 15-4.) The SPR1 and SPR0 bits control the baud rate generator and determine the speed of the shift register. (See 15.13.2 SPI Status and Control Register.) Through the SPSCK pin, the baud rate generator of the master also controls the shift register of the slave peripheral. MASTER MCU SHIFT REGISTER SLAVE MCU MISO MISO MOSI MOSI SPSCK BAUD RATE GENERATOR SS SHIFT REGISTER SPSCK VDD SS Figure 15-4. Full-Duplex Master-Slave Connections As the byte shifts out on the MOSI pin of the master, another byte shifts in from the slave on the master’s MISO pin. The transmission ends when the receiver full bit, SPRF (SPSCR), becomes set. At the same time that SPRF becomes set, the byte from the slave transfers to the receive data register. In normal operation, SPRF signals the end of a transmission. Software clears SPRF by reading the SPI status and control register and then reading the SPI data register. Writing to the SPI data register clears the SPTE bit. 15.4.2 Slave Mode The SPI operates in slave mode when the SPMSTR bit (SPCR $0010) is clear. In slave mode the SPSCK pin is the input for the serial clock from the master MCU. Before a data transmission occurs, the SS pin of the slave MCU must be at logic 0. SS must remain low until the transmission is complete. See 15.6.2 Mode Fault Error. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 219 In a slave SPI module, data enters the shift register under the control of the serial clock from the master SPI module. After a byte enters the shift register of a slave SPI, it is transferred to the receive data register, and the SPRF bit (SPSCR) is set. To prevent an overflow condition, slave software then must read the SPI data register before another byte enters the shift register. The maximum frequency of the SPSCK for an SPI configured as a slave is the bus clock speed, which is twice as fast as the fastest master SPSCK clock that can be generated. The frequency of the SPSCK for an SPI configured as a slave does not have to correspond to any SPI baud rate. The baud rate only controls the speed of the SPSCK generated by an SPI configured as a master. Therefore, the frequency of the SPSCK for an SPI configured as a slave can be any frequency less than or equal to the bus speed. When the master SPI starts a transmission, the data in the slave shift register begins shifting out on the MISO pin. The slave can load its shift register with a new byte for the next transmission by writing to its transmit data register. The slave must write to its transmit data register at least one bus cycle before the master starts the next transmission. Otherwise, the byte already in the slave shift register shifts out on the MISO pin. Data written to the slave shift register during a a transmission remains in a buffer until the end of the transmission. When the clock phase bit (CPHA) is set, the first edge of SPSCK starts a transmission. When CPHA is clear, the falling edge of SS starts a transmission. See 15.5 Transmission Formats. If the write to the data register is late, the SPI transmits the data already in the shift register from the previous transmission. NOTE: To prevent SPSCK from appearing as a clock edge, SPSCK must be in the proper idle state before the slave is enabled. 15.5 Transmission Formats During an SPI transmission, data is simultaneously transmitted (shifted out serially) and received (shifted in serially). A serial clock line synchronizes shifting and sampling on the two serial data lines. A slave select line allows individual selection of a slave SPI device; slave devices that are not selected do not interfere with SPI bus activities. On a master SPI device, the slave select line can be used optionally to indicate a multiple-master bus contention. 15.5.1 Clock Phase and Polarity Controls Software can select any of four combinations of serial clock (SCK) phase and polarity using two bits in the SPI control register (SPCR). The clock polarity is specified by the CPOL control bit, which selects an active high or low clock and has no significant effect on the transmission format. Data Sheet 220 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor The clock phase (CPHA) control bit (SPCR) selects one of two fundamentally different transmission formats. The clock phase and polarity should be identical for the master SPI device and the communicating slave device. In some cases, the phase and polarity are changed between transmissions to allow a master device to communicate with peripheral slaves having different requirements. NOTE: Before writing to the CPOL bit or the CPHA bit (SPCR), disable the SPI by clearing the SPI enable bit (SPE). 15.5.2 Transmission Format When CPHA = 0 Figure 15-5 shows an SPI transmission in which CPHA (SPCR) is logic 0. The figure should not be used as a replacement for data sheet parametric information.Two waveforms are shown for SCK: one for CPOL = 0 and another for CPOL = 1. The diagram may be interpreted as a master or slave timing diagram since the serial clock (SCK), master in/slave out (MISO), and master out/slave in (MOSI) pins are directly connected between the master and the slave. The MISO signal is the output from the slave, and the MOSI signal is the output from the master. The SS line is the slave select input to the slave. The slave SPI drives its MISO output only when its slave select input (SS) is at logic 0, so that only the selected slave drives to the master. The SS pin of the master is not shown but is assumed to be inactive. The SS pin of the master must be high or must be reconfigured as general-purpose I/O not affecting the SPI. (See 15.6.2 Mode Fault Error.) When CPHA = 0, the first SPSCK edge is the MSB capture strobe. Therefore, the slave must begin driving its data before the first SPSCK edge, and a falling edge on the SS pin is used to start the transmission. The SS pin must be toggled high and then low again between each byte transmitted as shown in Figure 15-6. SCK CYCLE # FOR REFERENCE 1 2 3 4 5 6 7 8 MSB BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 LSB BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 LSB SCK CPOL = 0 SCK CPOL = 1 MOSI FROM MASTER MISO FROM SLAVE MSB SS TO SLAVE CAPTURE STROBE Figure 15-5. Transmission Format (CPHA = 0) MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 221 MISO/MOSI BYTE 1 BYTE 2 BYTE 3 MASTER SS SLAVE SS CPHA = 0 SLAVE SS CPHA = 1 Figure 15-6. CPHA/SS Timing When CPHA = 0 for a slave, the falling edge of SS indicates the beginning of the transmission. This causes the SPI to leave its idle state and begin driving the MISO pin with the MSB of its data. Once the transmission begins, no new data is allowed into the shift register from the transmit data register. Therefore, the SPI data register of the slave must be loaded with transmit data before the falling edge of SS. Any data written after the falling edge is stored in the transmit data register and transferred to the shift register after the current transmission. 15.5.3 Transmission Format When CPHA = 1 Figure 15-7 shows an SPI transmission in which CPHA (SPCR) is logic 1. The figure should not be used as a replacement for data sheet parametric information. Two waveforms are shown for SCK: one for CPOL = 0 and another for CPOL = 1. The diagram may be interpreted as a master or slave timing diagram since the serial clock (SCK), master in/slave out (MISO), and master out/slave in (MOSI) pins are directly connected between the master and the slave. The MISO signal is the output from the slave, and the MOSI signal is the output from the master. The SS line is the slave select input to the slave. The slave SPI drives its MISO output only when its slave select input (SS) is at logic 0, so that only the selected slave drives to the master. The SS pin of the master is not shown but is assumed to be inactive. The SS pin of the master must be high or must be reconfigured as general-purpose I/O not affecting the SPI. (See 15.6.2 Mode Fault Error.) When CPHA = 1, the master begins driving its MOSI pin on the first SPSCK edge. Therefore, the slave uses the first SPSCK edge as a start transmission signal. The SS pin can remain low between transmissions. This format may be preferable in systems having only one master and only one slave driving the MISO data line. When CPHA = 1 for a slave, the first edge of the SPSCK indicates the beginning of the transmission. This causes the SPI to leave its idle state and begin driving the MISO pin with the MSB of its data. Once the transmission begins, no new data is allowed into the shift register from the transmit data register. Therefore, the SPI data register of the slave must be loaded with transmit data before the first edge of SPSCK. Any data written after the first edge is stored in the transmit data register and transferred to the shift register after the current transmission. Data Sheet 222 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor SCK CYCLE # FOR REFERENCE 1 2 3 4 5 6 7 8 MOSI FROM MASTER MSB BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 LSB MISO FROM SLAVE MSB BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 SCK CPOL = 0 SCK CPOL =1 LSB SS TO SLAVE CAPTURE STROBE Figure 15-7. Transmission Format (CPHA = 1) 15.5.4 Transmission Initiation Latency When the SPI is configured as a master (SPMSTR = 1), transmissions are started by a software write to the SPDR ($0012). CPHA has no effect on the delay to the start of the transmission, but it does affect the initial state of the SCK signal. When CPHA = 0, the SCK signal remains inactive for the first half of the first SCK cycle. When CPHA = 1, the first SCK cycle begins with an edge on the SCK line from its inactive to its active level. The SPI clock rate (selected by SPR1–SPR0) affects the delay from the write to SPDR and the start of the SPI transmission. (See Figure 15-8.) The internal SPI clock in the master is a free-running derivative of the internal MCU clock. It is only enabled when both the SPE and SPMSTR bits (SPCR) are set to conserve power. SCK edges occur halfway through the low time of the internal MCU clock. Since the SPI clock is free-running, it is uncertain where the write to the SPDR will occur relative to the slower SCK. This uncertainty causes the variation in the initiation delay shown in Figure 15-8. This delay will be no longer than a single SPI bit time. That is, the maximum delay between the write to SPDR and the start of the SPI transmission is two MCU bus cycles for DIV2, eight MCU bus cycles for DIV8, 32 MCU bus cycles for DIV32, and 128 MCU bus cycles for DIV128. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 223 WRITE TO SPDR INITIATION DELAY BUS CLOCK MOSI MSB BIT 6 BIT 5 SCK CPHA = 1 SCK CPHA = 0 SCK CYCLE NUMBER 1 2 3 INITIATION DELAY FROM WRITE SPDR TO TRANSFER BEGIN WRITE TO SPDR BUS CLOCK EARLIEST LATEST BUS CLOCK WRITE TO SPDR EARLIEST BUS CLOCK WRITE TO SPDR EARLIEST BUS CLOCK WRITE TO SPDR EARLIEST SCK = INTERNAL CLOCK ÷ 2; 2 POSSIBLE START POINTS SCK = INTERNAL CLOCK ÷ 8; 8 POSSIBLE START POINTS LATEST SCK = INTERNAL CLOCK ÷ 32; 32 POSSIBLE START POINTS LATEST SCK = INTERNAL CLOCK ÷ 128; 128 POSSIBLE START POINTS LATEST Figure 15-8. Transmission Start Delay (Master) Data Sheet 224 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 15.6 Error Conditions Two flags signal SPI error conditions: 1. Overflow (OVRFin SPSCR) — Failing to read the SPI data register before the next byte enters the shift register sets the OVRF bit. The new byte does not transfer to the receive data register, and the unread byte still can be read by accessing the SPI data register. OVRF is in the SPI status and control register. 2. Mode fault error (MODF in SPSCR) — The MODF bit indicates that the voltage on the slave select pin (SS) is inconsistent with the mode of the SPI. MODF is in the SPI status and control register. 15.6.1 Overflow Error The overflow flag (OVRF in SPSCR) becomes set if the SPI receive data register still has unread data from a previous transmission when the capture strobe of bit 1 of the next transmission occurs. (See Figure 15-5 and Figure 15-7.) If an overflow occurs, the data being received is not transferred to the receive data register so that the unread data can still be read. Therefore, an overflow error always indicates the loss of data. OVRF generates a receiver/error CPU interrupt request if the error interrupt enable bit (ERRIE in SPSCR) is also set. MODF and OVRF can generate a receiver/error CPU interrupt request. (See Figure 15-11.) It is not possible to enable only MODF or OVRF to generate a receiver/error CPU interrupt request. However, leaving MODFEN low prevents MODF from being set. If an end-of-block transmission interrupt was meant to pull the MCU out of wait, having an overflow condition without overflow interrupts enabled causes the MCU to hang in wait mode. If the OVRF is enabled to generate an interrupt, it can pull the MCU out of wait mode instead. If the CPU SPRF interrupt is enabled and the OVRF interrupt is not, watch for an overflow condition. Figure 15-9 shows how it is possible to miss an overflow. The first part of Figure 15-9 shows how to read the SPSCR and SPDR to clear the SPRF without problems. However, as illustrated by the second transmission example, the OVRF flag can be set in between the time that SPSCR and SPDR are read. In this case, an overflow can be easily missed. Since no more SPRF interrupts can be generated until this OVRF is serviced, it will not be obvious that bytes are being lost as more transmissions are completed. To prevent this, either enable the OVRF interrupt or do another read of the SPSCR after the read of the SPDR. This ensures that the OVRF was not set before the SPRF was cleared and that future transmissions will complete with an SPRF interrupt. Figure 15-10 illustrates this process. Generally, to avoid this second SPSCR read, enable the OVRF to the CPU by setting the ERRIE bit (SPSCR). MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 225 BYTE 1 1 BYTE 2 4 BYTE 3 6 BYTE 4 8 SPRF OVRF 2 READ SPSCR 5 3 READ SPDR 1 BYTE 1 SETS SPRF BIT. 2 CPU READS SPSCR WITH SPRF BIT SET AND OVRF BIT CLEAR. CPU READS BYTE 1 IN SPDR, CLEARING SPRF BIT. BYTE 2 SETS SPRF BIT. 3 4 5 7 8 CPU READS SPSCR WITH SPRF BIT SET AND OVRF BIT CLEAR. BYTE 3 SETS OVRF BIT. BYTE 3 IS LOST. 6 7 BYTE 4 FAILS TO SET SPRF BIT BECAUSE OVRF BIT IS SET. BYTE 4 IS LOST. CPU READS BYTE 2 IN SPDR, CLEARING SPRF BIT, BUT NOT OVRF BIT. Figure 15-9. Missed Read of Overflow Condition BYTE 1 BYTE 2 BYTE 3 BYTE 4 1 5 7 11 SPI RECEIVE COMPLETE SPRF OVRF 2 READ SPSCR 4 6 3 READ SPDR 9 8 12 10 14 13 1 BYTE 1 SETS SPRF BIT. 5 BYTE 2 SETS SPRF BIT. 2 CPU READS SPSCR WITH SPRF BIT SET AND OVRF BIT CLEAR. CPU READS BYTE 1 IN SPDR, CLEARING SPRF BIT. 6 CPU READS SPSCR WITH SPRF BIT SET AND OVRF BIT CLEAR. 7 BYTE 3 SETS OVRF BIT. BYTE 3 IS LOST. 12 CPU READS SPSCR. 8 CPU READS BYTE 2 IN SPDR, CLEARING SPFR BIT. 9 CPU READS SPSCR AGAIN TO CHECK OVRF BIT. 13 CPU READS BYTE 4 IN SPDR, CLEARING SPRF BIT. 3 4 CPU READS SPSCR AGAIN TO CHECK OVRF BIT. 10 CPU READS BYTE 2 SPDR, CLEARING OVRF BIT. 11 BYTE 4 SETS SPRF BIT. 14 CPU READS SPSCR AGAIN TO CHECK OVRF BIT. Figure 15-10. Clearing SPRF When OVRF Interrupt Is Not Enabled 15.6.2 Mode Fault Error For the MODF flag (in SPSCR) to be set, the mode fault error enable bit (MODFEN in SPSCR) must be set. Clearing the MODFEN bit does not clear the MODF flag but does prevent MODF from being set again after MODF is cleared. MODF generates a receiver/error CPU interrupt request if the error interrupt enable bit (ERRIE in SPSCR) is also set. The SPRF, MODF, and OVRF interrupts share Data Sheet 226 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor the same CPU interrupt vector. MODF and OVRF can generate a receiver/error CPU interrupt request. (See Figure 15-11.) It is not possible to enable only MODF or OVRF to generate a receiver/error CPU interrupt request. However, leaving MODFEN low prevents MODF from being set. In a master SPI with the mode fault enable bit (MODFEN) set, the mode fault flag (MODF) is set if SS goes to logic 0. A mode fault in a master SPI causes the following events to occur: • If ERRIE = 1, the SPI generates an SPI receiver/error CPU interrupt request. • The SPE bit is cleared. • The SPTE bit is set. • The SPI state counter is cleared. • The data direction register of the shared I/O port regains control of port drivers. NOTE: To prevent bus contention with another master SPI after a mode fault error, clear all data direction register (DDR) bits associated with the SPI shared port pins. NOTE: Setting the MODF flag (SPSCR) does not clear the SPMSTR bit. Reading SPMSTR when MODF = 1 will indicate that a MODE fault error occurred in either master mode or slave mode. When configured as a slave (SPMSTR = 0), the MODF flag is set if SS goes high during a transmission. When CPHA = 0, a transmission begins when SS goes low and ends once the incoming SPSCK returns to its idle level after the shift of the eighth data bit. When CPHA = 1, the transmission begins when the SPSCK leaves its idle level and SS is already low. The transmission continues until the SPSCK returns to its IDLE level after the shift of the last data bit. (See 15.5 Transmission Formats.) NOTE: When CPHA = 0, a MODF occurs if a slave is selected (SS is at logic 0) and later unselected (SS is at logic 1) even if no SPSCK is sent to that slave. This happens because SS at logic 0 indicates the start of the transmission (MISO driven out with the value of MSB) for CPHA = 0. When CPHA = 1, a slave can be selected and then later unselected with no transmission occurring. Therefore, MODF does not occur since a transmission was never begun. In a slave SPI (MSTR = 0), the MODF bit generates an SPI receiver/error CPU interrupt request if the ERRIE bit is set. The MODF bit does not clear the SPE bit or reset the SPI in any way. Software can abort the SPI transmission by toggling the SPE bit of the slave. NOTE: A logic 1 voltage on the SS pin of a slave SPI puts the MISO pin in a high impedance state. Also, the slave SPI ignores all incoming SPSCK clocks, even if a transmission has begun. To clear the MODF flag, read the SPSCR and then write to the SPCR register. This entire clearing procedure must occur with no MODF condition existing or else the flag will not be cleared. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 227 15.7 Interrupts Four SPI status flags can be enabled to generate CPU interrupt requests, as shown in Table 15-3. Table 15-3. SPI Interrupts Flag Request SPTE (transmitter empty) SPI transmitter CPU interrupt request (SPTIE = 1) SPRF (receiver full) SPI receiver CPU interrupt request (SPRIE = 1) OVRF (overflow) SPI receiver/error interrupt request (ERRIE = 1) MODF (mode fault) SPI receiver/error interrupt request (ERRIE = 1, MODFEN = 1) The SPI transmitter interrupt enable bit (SPTIE) enables the SPTE flag to generate transmitter CPU interrupt requests. The SPI receiver interrupt enable bit (SPRIE) enables the SPRF bit to generate receiver CPU interrupt, provided that the SPI is enabled (SPE = 1). The error interrupt enable bit (ERRIE) enables both the MODF and OVRF flags to generate a receiver/error CPU interrupt request. The mode fault enable bit (MODFEN) can prevent the MODF flag from being set so that only the OVRF flag is enabled to generate receiver/error CPU interrupt requests. Two sources in the SPI status and control register can generate CPU interrupt requests: 1. SPI receiver full bit (SPRF) — The SPRF bit becomes set every time a byte transfers from the shift register to the receive data register. If the SPI receiver interrupt enable bit, SPRIE, is also set, SPRF can generate an SPI receiver/error CPU interrupt request. 2. SPI transmitter empty (SPTE) — The SPTE bit becomes set every time a byte transfers from the transmit data register to the shift register. If the SPI transmit interrupt enable bit, SPTIE, is also set, SPTE can generate an SPTE CPU interrupt request. 15.8 Queuing Transmission Data The double-buffered transmit data register allows a data byte to be queued and transmitted. For an SPI configured as a master, a queued data byte is transmitted immediately after the previous transmission has completed. The SPI transmitter empty flag (SPTE in SPSCR) indicates when the transmit data buffer is ready to accept new data. Write to the SPI data register only when the SPTE bit is high. Figure 15-12 shows the timing associated with doing back-to-back transmissions with the SPI (SPSCK has CPHA–CPOL = 1–0). Data Sheet 228 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor SPTE SPTIE SPE SPI TRANSMITTER CPU INTERRUPT REQUEST SPRIE SPRF SPI RECEIVER/ERROR CPU INTERRUPT REQUEST ERRIE MODF OVRF Figure 15-11. SPI Interrupt Request Generation WRITE TO SPDR 1 SPTE 3 2 8 5 10 SPSCK (CPHA:CPOL = 1:0) MSB BIT BIT BIT BIT BIT BIT LSB MSB BIT BIT BIT BIT BIT BIT LSB MSB BIT BIT BIT 6 5 4 3 2 1 6 5 4 3 2 1 6 5 4 BYTE 1 BYTE 2 BYTE 3 MOSI 9 4 SPRF 6 READ SPSCR 11 7 READ SPDR 1 CPU WRITES BYTE 1 TO SPDR, CLEARING SPTE BIT. 2 BYTE 1 TRANSFERS FROM TRANSMIT DATA REGISTER TO SHIFT REGISTER, SETTING SPTE BIT. 3 CPU WRITES BYTE 2 TO SPDR, QUEUEING BYTE 2 AND CLEARING SPTE BIT. 4 FIRST INCOMING BYTE TRANSFERS FROM SHIFT SHIFT REGISTER TO RECEIVE DATA REGISTER, SETTING SPRF BIT. 5 12 10 BYTE 3 TRANSFERS FROM TRANSMIT DATA REGISTER TO SHIFT REGISTER, SETTING SPTE BIT. BYTE 2 TRANSFERS FROM TRANSMIT DATA REGISTER TO SHIFT REGISTER, SETTING SPTE BIT. 6 CPU READS SPSCR WITH SPRF BIT SET. 11 CPU READS SPSCR WITH SPRF BIT SET. 7 CPU READS SPDR, CLEARING SPRF BIT. 12 CPU READS SPDR, CLEARING SPRF BIT. 8 CPU WRITES BYTE 3 TO SPDR, QUEUEING BYTE 3 AND CLEARING SPTE BIT. 9 SECOND INCOMING BYTE TRANSFERS FROM SHIFT REGISTER TO RECEIVE DATA REGISTER, SETTING SPRF BIT. Figure 15-12. SPRF/SPTE CPU Interrupt Timing The transmit data buffer allows back-to-back transmissions without the slave precisely timing its writes between transmissions as in a system with a single data buffer. Also, if no new data is written to the data buffer, the last value contained in the shift register is the next data word to be transmitted. For an idle master or idle slave that has no data loaded into its transmit buffer, the SPTE is set again no more than two bus cycles after the transmit buffer empties MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 229 into the shift register. This allows the user to queue up a 16-bit value to send. For an already active slave, the load of the shift register cannot occur until the transmission is completed. This implies that a back-to-back write to the transmit data register is not possible. The SPTE indicates when the next write can occur. 15.9 Resetting the SPI Any system reset completely resets the SPI. Partial resets occur whenever the SPI enable bit (SPE) is low. Whenever SPE is low, the following occurs: • The SPTE flag is set. • Any transmission currently in progress is aborted. • The shift register is cleared. • The SPI state counter is cleared, making it ready for a new complete transmission. • All the SPI port logic is defaulted back to being general-purpose I/O. These additional items are reset only by a system reset: • All control bits in the SPCR register • All control bits in the SPSCR register (MODFEN, ERRIE, SPR1, and SPR0) • The status flags SPRF, OVRF, and MODF By not resetting the control bits when SPE is low, the user can clear SPE between transmissions without having to reset all control bits when SPE is set back to high for the next transmission. By not resetting the SPRF, OVRF, and MODF flags, the user can still service these interrupts after the SPI has been disabled. The user can disable the SPI by writing 0 to the SPE bit. The SPI also can be disabled by a mode fault occurring in an SPI that was configured as a master with the MODFEN bit set. 15.10 Low-Power Modes The WAIT and STOP instructions put the MCU in low-power standby modes. 15.10.1 Wait Mode The SPI module remains active after the execution of a WAIT instruction. In wait mode, the SPI module registers are not accessible by the CPU. Any enabled CPU interrupt request from the SPI module can bring the MCU out of wait mode. If SPI module functions are not required during wait mode, reduce power consumption by disabling the SPI module before executing the WAIT instruction. Data Sheet 230 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor To exit wait mode when an overflow condition occurs, enable the OVRF bit to generate CPU interrupt requests by setting the error interrupt enable bit (ERRIE). (See 15.7 Interrupts.) 15.10.2 Stop Mode The SPI module is inactive after the execution of a STOP instruction. The STOP instruction does not affect register conditions. SPI operation resumes after the MCU exits stop mode. If stop mode is exited by reset, any transfer in progress is aborted and the SPI is reset. 15.11 SPI During Break Interrupts The system integration module (SIM) controls whether status bits in other modules can be cleared during the break state. The BCFE bit in the SIM break flag control register (SBFCR, $FE03) enables software to clear status bits during the break state. (See 14.7.3 SIM Break Flag Control Register.) To allow software to clear status bits during a break interrupt, write a logic 1 to the BCFE bit. If a status bit is cleared during the break state, it remains cleared when the MCU exits the break state. To protect status bits during the break state, write a logic 0 to the BCFE bit. With BCFE at logic 0 (its default state), software can read and write I/O registers during the break state without affecting status bits. Some status bits have a 2-step read/write clearing procedure. If software does the first step on such a bit before the break, the bit cannot change during the break state as long as BCFE is at logic 0. After the break, doing the second step clears the status bit. Since the SPTE bit cannot be cleared during a break with the BCFE bit cleared, a write to the data register in break mode will not initiate a transmission nor will this data be transferred into the shift register. Therefore, a write to the SPDR in break mode with the BCFE bit cleared has no effect. 15.12 I/O Signals The SPI module has five I/O pins and shares four of them with a parallel I/O port. • MISO — Data received • MOSI — Data transmitted • SPSCK — Serial clock • SS — Slave select • VSS — Clock ground The SPI has limited inter-integrated circuit (I2C) capability (requiring software support) as a master in a single-master environment. To communicate with I2C peripherals, MOSI becomes an open-drain output when the SPWOM bit in the SPI MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 231 control register is set. In I2C communication, the MOSI and MISO pins are connected to a bidirectional pin from the I2C peripheral and through a pullup resistor to VDD. 15.12.1 MISO (Master In/Slave Out) MISO is one of the two SPI module pins that transmit serial data. In full duplex operation, the MISO pin of the master SPI module is connected to the MISO pin of the slave SPI module. The master SPI simultaneously receives data on its MISO pin and transmits data from its MOSI pin. Slave output data on the MISO pin is enabled only when the SPI is configured as a slave. The SPI is configured as a slave when its SPMSTR bit is logic 0 and its SS pin is at logic 0. To support a multiple-slave system, a logic 1 on the SS pin puts the MISO pin in a high-impedance state. When enabled, the SPI controls data direction of the MISO pin regardless of the state of the data direction register of the shared I/O port. 15.12.2 MOSI (Master Out/Slave In) MOSI is one of the two SPI module pins that transmit serial data. In full duplex operation, the MOSI pin of the master SPI module is connected to the MOSI pin of the slave SPI module. The master SPI simultaneously transmits data from its MOSI pin and receives data on its MISO pin. When enabled, the SPI controls data direction of the MOSI pin regardless of the state of the data direction register of the shared I/O port. 15.12.3 SPSCK (Serial Clock) The serial clock synchronizes data transmission between master and slave devices. In a master MCU, the SPSCK pin is the clock output. In a slave MCU, the SPSCK pin is the clock input. In full-duplex operation, the master and slave MCUs exchange a byte of data in eight serial clock cycles. When enabled, the SPI controls data direction of the SPSCK pin regardless of the state of the data direction register of the shared I/O port. 15.12.4 SS (Slave Select) The SS pin has various functions depending on the current state of the SPI. For an SPI configured as a slave, the SS is used to select a slave. For CPHA = 0, the SS is used to define the start of a transmission. (See 15.5 Transmission Formats.) Since it is used to indicate the start of a transmission, the SS must be toggled high and low between each byte transmitted for the CPHA = 0 format. However, it can remain low throughout the transmission for the CPHA = 1 format. See Figure 15-13. Data Sheet 232 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor MISO/MOSI BYTE 1 BYTE 2 BYTE 3 MASTER SS SLAVE SS CPHA = 0 SLAVE SS CPHA = 1 Figure 15-13. CPHA/SS Timing When an SPI is configured as a slave, the SS pin is always configured as an input. It cannot be used as a general-purpose I/O regardless of the state of the MODFEN control bit. However, the MODFEN bit can still prevent the state of the SS from creating a MODF error. sEE 15.13.2 SPI Status and Control Register. NOTE: A logic 1 voltage on the SS pin of a slave SPI puts the MISO pin in a high-impedance state. The slave SPI ignores all incoming SPSCK clocks, even if a transmission already has begun. When an SPI is configured as a master, the SS input can be used in conjunction with the MODF flag to prevent multiple masters from driving MOSI and SPSCK. (See 15.6.2 Mode Fault Error.) For the state of the SS pin to set the MODF flag, the MODFEN bit in the SPSCK register must be set. If the MODFEN bit is low for an SPI master, the SS pin can be used as a general-purpose I/O under the control of the data direction register of the shared I/O port. With MODFEN high, it is an input-only pin to the SPI regardless of the state of the data direction register of the shared I/O port. The CPU can always read the state of the SS pin by configuring the appropriate pin as an input and reading the data register. See Table 15-4. Table 15-4. SPI Configuration SPE SPMSTR MODFEN SPI Configuration State of SS Logic 0 X X Not enabled General-purpose I/O; SS ignored by SPI 1 0 X Slave Input-only to SPI 1 1 0 Master without MODF General-purpose I/O; SS ignored by SPI 1 1 1 Master with MODF Input-only to SPI X = don’t care 15.12.5 VSS (Clock Ground) VSS is the ground return for the serial clock pin, SPSCK, and the ground for the port output buffers. To reduce the ground return path loop and minimize radio frequency (RF) emissions, connect the ground pin of the slave to the VSS pin. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 233 15.13 I/O Registers Three registers control and monitor SPI operation: • SPI control register (SPCR, $0010) • SPI status and control register (SPSCR, $0011) • SPI data register (SPDR, $0012) 15.13.1 SPI Control Register The SPI control register: • Enables SPI module interrupt requests • Selects CPU interrupt requests • Configures the SPI module as master or slave • Selects serial clock polarity and phase • Configures the SPSCK, MOSI, and MISO pins as open-drain outputs • Enables the SPI module Address: Read: Write: Reset: $0010 Bit 7 6 5 4 3 2 1 Bit 0 SPRIE R SPMSTR CPOL CPHA SPWOM SPE SPTIE 0 1 0 1 0 0 0 0 = Unimplemented Figure 15-14. SPI Control Register (SPCR) SPRIE — SPI Receiver Interrupt Enable Bit This read/write bit enables CPU interrupt requests generated by the SPRF bit. The SPRF bit is set when a byte transfers from the shift register to the receive data register. Reset clears the SPRIE bit. 1 = SPRF CPU interrupt requests enabled 0 = SPRF CPU interrupt requests disabled SPMSTR — SPI Master Bit This read/write bit selects master mode operation or slave mode operation. Reset sets the SPMSTR bit. 1 = Master mode 0 = Slave mode CPOL — Clock Polarity Bit This read/write bit determines the logic state of the SPSCK pin between transmissions. (See Figure 15-5 and Figure 15-7.) To transmit data between SPI modules, the SPI modules must have identical CPOL bits. Reset clears the CPOL bit. Data Sheet 234 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor CPHA — Clock Phase Bit This read/write bit controls the timing relationship between the serial clock and SPI data. (See Figure 15-5 and Figure 15-7.) To transmit data between SPI modules, the SPI modules must have identical CPHA bits. When CPHA = 0, the SS pin of the slave SPI module must be set to logic 1 between bytes. (See Figure 15-13.) Reset sets the CPHA bit. When CPHA = 0 for a slave, the falling edge of SS indicates the beginning of the transmission. This causes the SPI to leave its idle state and begin driving the MISO pin with the MSB of its data. Once the transmission begins, no new data is allowed into the shift register from the data register. Therefore, the slave data register must be loaded with the desired transmit data before the falling edge of SS. Any data written after the falling edge is stored in the data register and transferred to the shift register at the current transmission. When CPHA = 1 for a slave, the first edge of the SPSCK indicates the beginning of the transmission. The same applies when SS is high for a slave. The MISO pin is held in a high-impedance state, and the incoming SPSCK is ignored. In certain cases, it may also cause the MODF flag to be set. (See 15.6.2 Mode Fault Error.) A logic 1 on the SS pin does not in any way affect the state of the SPI state machine. SPWOM — SPI Wired-OR Mode Bit This read/write bit disables the pullup devices on pins SPSCK, MOSI, and MISO so that those pins become open-drain outputs. 1 = Wired-OR SPSCK, MOSI, and MISO pins 0 = Normal push-pull SPSCK, MOSI, and MISO pins SPE — SPI Enable Bit This read/write bit enables the SPI module. Clearing SPE causes a partial reset of the SPI. (See 15.9 Resetting the SPI.) Reset clears the SPE bit. 1 = SPI module enabled 0 = SPI module disabled SPTIE— SPI Transmit Interrupt Enable Bit This read/write bit enables CPU interrupt requests generated by the SPTE bit. SPTE is set when a byte transfers from the transmit data register to the shift register. Reset clears the SPTIE bit. 1 = SPTE CPU interrupt requests enabled 0 = SPTE CPU interrupt requests disabled MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 235 15.13.2 SPI Status and Control Register The SPI status and control register contains flags to signal the following conditions: • Receive data register full • Failure to clear SPRF bit before next byte is received (overflow error) • Inconsistent logic level on SS pin (mode fault error) • Transmit data register empty The SPI status and control register also contains bits that perform these functions: • Enable error interrupts • Enable mode fault error detection • Select master SPI baud rate Address: $0011 Bit 7 Read: SPRF Write: Reset: 6 ERRIE 0 0 R = Reserved 5 4 3 OVRF MODF SPTE 0 0 1 2 1 Bit 0 MODFEN SPR1 SPR0 0 0 0 Figure 15-15. SPI Status and Control Register (SPSCR) SPRF — SPI Receiver Full Bit This clearable, read-only flag is set each time a byte transfers from the shift register to the receive data register. SPRF generates a CPU interrupt request if the SPRIE bit in the SPI control register is set also. During an SPRF CPU interrupt, the CPU clears SPRF by reading the SPI status and control register with SPRF set and then reading the SPI data register. Any read of the SPI data register clears the SPRF bit, and reset also clears the SPRF bit. 1 = Receive data register full 0 = Receive data register not full ERRIE — Error Interrupt Enable Bit This bit enables the MODF and OVRF flags to generate CPU interrupt requests. Reset clears the ERRIE bit. 1 = MODF and OVRF can generate CPU interrupt requests 0 = MODF and OVRF cannot generate CPU interrupt requests OVRF — Overflow Bit This clearable, read-only flag is set if software does not read the byte in the receive data register before the next byte enters the shift register. In an overflow condition, the byte already in the receive data register is unaffected, and the byte that shifted in last is lost. Clear the OVRF bit by reading the SPI status and Data Sheet 236 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor control register with OVRF set and then reading the SPI data register. Reset clears the OVRF flag. 1 = Overflow 0 = No overflow MODF — Mode Fault Bit This clearable, ready-only flag is set in a slave SPI if the SS pin goes high during a transmission. In a master SPI, the MODF flag is set if the SS pin goes low at any time. Clear the MODF bit by reading the SPI status and control register with MODF set and then writing to the SPI control register. Reset clears the MODF bit. 1 = SS pin at inappropriate logic level 0 = SS pin at appropriate logic level SPTE — SPI Transmitter Empty Bit This clearable, read-only flag is set each time the transmit data register transfers a byte into the shift register. SPTE generates an SPTE CPU interrupt request if the SPTIE bit in the SPI control register is set also. NOTE: Do not write to the SPI data register unless the SPTE bit is high. For an idle master or idle slave that has no data loaded into its transmit buffer, the SPTE will be set again within two bus cycles since the transmit buffer empties into the shift register. This allows the user to queue up a 16-bit value to send. For an already active slave, the load of the shift register cannot occur until the transmission is completed. This implies that a back-to-back write to the transmit data register is not possible. The SPTE indicates when the next write can occur. Reset sets the SPTE bit. 1 = Transmit data register empty 0 = Transmit data register not empty MODFEN — Mode Fault Enable Bit This read/write bit, when set to 1, allows the MODF flag to be set. If the MODF flag is set, clearing the MODFEN does not clear the MODF flag. If the SPI is enabled as a master and the MODFEN bit is low, then the SS pin is available as a general-purpose I/O. If the MODFEN bit is set, then this pin is not available as a general-purpose I/O. When the SPI is enabled as a slave, the SS pin is not available as a general-purpose I/O regardless of the value of MODFEN. (See 15.12.4 SS (Slave Select).) If the MODFEN bit is low, the level of the SS pin does not affect the operation of an enabled SPI configured as a master. For an enabled SPI configured as a slave, having MODFEN low only prevents the MODF flag from being set. It does not affect any other part of SPI operation. (See 15.6.2 Mode Fault Error.) SPR1 and SPR0 — SPI Baud Rate Select Bits In master mode, these read/write bits select one of four baud rates as shown in Table 15-5. SPR1 and SPR0 have no effect in slave mode. Reset clears SPR1 and SPR0. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 237 Table 15-5. SPI Master Baud Rate Selection SPR1:SPR0 Baud Rate Divisor (BD) 00 2 01 8 10 32 11 128 Use this formula to calculate the SPI baud rate: CGMOUT Baud rate = -------------------------2 × BD where: CGMOUT = base clock output of the clock generator module (CGM), see Section 5. Clock Generator Module (CGM). BD = baud rate divisor 15.13.3 SPI Data Register The SPI data register is the read/write buffer for the receive data register and the transmit data register. Writing to the SPI data register writes data into the transmit data register. Reading the SPI data register reads data from the receive data register. The transmit data and receive data registers are separate buffers that can contain different values. See Figure 15-3. Address: $0012 Bit 7 6 5 4 3 2 1 Bit 0 Read: R7 R6 R5 R4 R3 R2 R1 R0 Write: T7 T6 T5 T4 T3 T2 T1 T0 Reset: Unaffected by reset Figure 15-16. SPI Data Register (SPDR) R7–R0/T7–T0 — Receive/Transmit Data Bits NOTE: Data Sheet 238 Do not use read-modify-write instructions on the SPI data register since the buffer read is not the same as the buffer written. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 16. Timer Interface (TIM) 16.1 Introduction This section describes the timer interface module (TIM6). The TIM is a 6-channel timer that provides a timing reference with input capture, output compare, and pulse-width-modulation functions. Figure 16-2 is a block diagram of the TIM. 16.2 Features Features of the TIM include: • Six input capture/output compare channels: – Rising-edge, falling-edge, or any-edge input capture trigger – Set, clear, or toggle output compare action • Buffered and unbuffered pulse width modulation (PWM) signal generation • Programmable TIM clock input – 7-frequency internal bus clock prescaler selection – External TIM clock input (4-MHz maximum frequency) • Free-running or modulo up-count operation • Toggle any channel pin on overflow • TIM counter stop and reset bits 16.3 Functional Description Figure 16-2 shows the TIM structure. The central component of the TIM is the 16-bit TIM counter that can operate as a free-running counter or a modulo up-counter. The TIM counter provides the timing reference for the input capture and output compare functions. The TIM counter modulo registers, TMODH–TMODL, control the modulo value of the TIM counter. Software can read the TIM counter value at any time without affecting the counting sequence. The six TIM channels are programmable independently as input capture or output compare channels. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 239 CONTROL AND STATUS REGISTERS — 69 BYTES BREAK MODULE DDRA PTA PTB ANALOG-TO-DIGITAL CONVERTER MODULE DDRB ARITHMETIC/LOGIC UNIT PTA7–PTA0 PTB7/ATD7–PTB0/ATD0 DDRC CPU REGISTERS VREFH USER ROM — 32,256 BYTES PTC Data Sheet 240 INTERNAL BUS M68HC08 CPU IRQ MODULE MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor VDDA/VDDAREF VSSA/VREFL PTF3/TCH5 PTF2/TCH4 PTF1/TCH3 PTF0/TCH2 SERIAL COMMUNICATIONS INTERFACE MODULE SERIAL PERIPHERAL INTERFACE MODULE BYTE DATA LINK CONTROLLER DIGITAL MODULE POWER-ON RESET MODULE VSS VDD PTE7/SPSCK PTE6/MOSI PTE5/MISO PTE4/SS PTE3/TCH1 PTE2/TCH0 PTE1/RxD PTE0/TxD PTF IRQ SYSTEM INTEGRATION MODULE PTD RST CLOCK GENERATOR MODULE PTD5/ATD13–PTD0/ATD8 PTE OSC1 OSC2 CGMXFC PROGRAMMABLE INTERRUPT TIMER MODULE DDRE USER ROM VECTOR SPACE — 38 BYTES PTD6/ATD14/TCLK TIMER INTERFACE MODULE BDRxD BDTxD POWER Figure 16-1. Block Diagram Highlighting TIM Block and Pins DDRF MONITOR ROM — 224 BYTES DDRD USER EEPROM — 512 BYTES USER RAM — 1024 BYTES PTC2/MCLK PTC1–PTC0 LOW-VOLTAGE INHIBIT MODULE COMPUTER OPERATING PROPERLY MODULE PTC4–PTC3 TCLK PTD6/ATD14/TCLK INTERNAL BUS CLOCK PRESCALER SELECT PRESCALER TSTOP PS2 TRST PS1 PS0 16-BIT COUNTER TOF TOIE INTERRUPT LOGIC 16-BIT COMPARATOR TMODH–TMODL CHANNEL 0 ELS0B ELS0A TOV0 CH0MAX 16-BIT COMPARATOR TCH0H–TCH0L CH0F 16-BIT LATCH MS0A CHANNEL 1 ELS1B MS0B ELS1A TOV1 CH1MAX 16-BIT COMPARATOR TCH1H–TCH1L CH1F 16-BIT LATCH CH1IE MS1A CHANNEL 2 ELS2B ELS2A TOV2 CH2MAX 16-BIT COMPARATOR TCH2H–TCH2L CH2F 16-BIT LATCH MS2A CHANNEL 3 ELS3B MS2B ELS3A TCH3H–TCH3L CH3F 16-BIT LATCH CH3IE MS3A ELS4B ELS4A TOV4 CH5MAX 16-BIT COMPARATOR TCH4H–TCH4L CH4F 16-BIT LATCH MS4A CHANNEL 5 CH2IE TOV3 CH3MAX 16-BIT COMPARATOR CHANNEL 4 CH0IE ELS5B MS4B ELS5A TOV5 CH5MAX 16-BIT COMPARATOR TCH5H–TCH5L CH4IE CH5F 16-BIT LATCH MS5A CH5IE PTE2 LOGIC PTE2/TCH0 INTERRUPT LOGIC PTE3 LOGIC PTE3/TCH1 INTERRUPT LOGIC PTF0 LOGIC PTF0/TCH2 INTERRUPT LOGIC PTF1 LOGIC PTF1/TCH3 INTERRUPT LOGIC PTF2 LOGIC PTF2/TCH4 INTERRUPT LOGIC PTF3 LOGIC PTF3/TCH5 INTERRUPT LOGIC Figure 16-2. TIM Block Diagram MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 241 Addr. Register Name Bit 7 6 5 TOIE TSTOP 4 3 0 0 2 1 Bit 0 PS2 PS1 PS0 Timer Status and Control Read: Register (TSC) Write: See page 253. Reset: TOF 0 0 1 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 $0022 Timer Counter Register High Read: (TCNTH) Write: See page 254. Reset: 0 0 0 0 0 0 0 0 Bit 7 6 5 4 3 2 1 Bit 0 $0023 Timer Counter Register Low Read: (TCNTL) Write: See page 254. Reset: 0 0 0 0 0 0 0 0 $0024 Timer Modulo Register High Read: (TMODH) Write: See page 255. Reset: Bit 15 14 13 12 11 10 9 Bit 8 1 1 1 1 1 1 1 1 Bit 7 6 5 4 3 2 1 Bit 0 1 1 1 1 1 1 1 1 CH0IE MS0B MS0A ELS0B ELS0A TOV0 CH0MAX 0 0 0 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 2 1 Bit 0 $0020 Timer Modulo Register Low Read: (TMODL) Write: See page 255. Reset: $0025 Timer Channel 0 Status and Read: Control Register (TSC0) Write: See page 256. Reset: $0026 $0027 Timer Channel 0 Register High Read: (TCH0H) Write: See page 260. Reset: $0028 Timer Channel 0 Register Low Read: (TCH0L) Write: See page 260. Reset: Timer Channel 1 Status and Read: Control Register (TSC1) Write: See page 256. Reset: $0029 $002A Timer Channel 1 Register High Read: (TCH1H) Write: See page 260. Reset: $002B Timer Channel 1 Register Low Read: (TCH1L) Write: See page 260. Reset: $002C Timer Channel 2 Status and Read: Control Register (TSC2) Write: See page 256. Reset: 0 CH0F 0 TRST Indeterminate after reset Bit 7 6 5 4 3 Indeterminate after reset CH1F 0 CH1IE 0 MS1A ELS1B ELS1A TOV1 CH1MAX 0 0 0 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 2 1 Bit 0 Indeterminate after reset Bit 7 6 5 4 3 Indeterminate after reset CH2F 0 0 CH2IE MS2B MS2A ELS2B ELS2A TOV2 CH2MAX 0 0 0 0 0 0 0 = Unimplemented Figure 16-3. TIM I/O Register Summary Data Sheet 242 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Addr. $002D $002E $002F Register Name Timer Channel 2 Register High Read: (TCH2H) Write: See page 260. Reset: Timer Channel 2 Register Low Read: (TCH2L) Write: See page 260. Reset: Timer Channel 3 Status and Read: Control Register (TSC3) Write: See page 256. Reset: $0030 Timer Channel 3 Register High Read: (TCH3H) Write: See page 260. Reset: $0031 Timer Channel 3 Register Low Read: (TCH3L Write: See page 260.) Reset: $0032 $0033 Timer Channel 4 Status and Read: Control Register (TSC4) Write: See page 256. Reset: Timer Channel 4 Register High Read: (TCH4H) Write: See page 260. Reset: $0034 Timer Channel 4 Register Low Read: (TCH4L) Write: See page 260. Reset: $0035 Timer Channel 5 Status and Read: Control Register (TSC5) Write: See page 256. Reset: $0036 $0037 Timer Channel 5 Register High Read: (TCH5H) Write: See page 260. Reset: Timer Channel 5 Register Low Read: (TCH5L) Write: See page 260. Reset: Bit 7 6 5 4 3 2 1 Bit 0 Bit 15 14 13 12 11 10 9 Bit 8 2 1 Bit 0 Indeterminate after reset Bit 7 6 5 4 3 Indeterminate after reset CH3F 0 CH3IE 0 MS3A ELS3B ELS3A TOV3 CH3MAX 0 0 0 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 2 1 Bit 0 Indeterminate after reset Bit 7 6 5 4 3 Indeterminate after reset CH4F CH4IE MS4B MS4A ELS4B ELS4A TOV4 CH4MAX 0 0 0 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 2 1 Bit 0 0 Indeterminate after reset Bit 7 6 5 4 3 Indeterminate after reset CH5F 0 CH5IE 0 MS5A ELS5B ELS5A TOV5 CH5MAX 0 0 0 0 0 0 0 0 Bit 15 14 13 12 11 10 9 Bit 8 2 1 Bit 0 Indeterminate after reset Bit 7 6 5 4 3 Indeterminate after reset = Unimplemented Figure 16-3. TIM I/O Register Summary (Continued) MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 243 16.3.1 TIM Counter Prescaler The TIM clock source can be one of the seven prescaler outputs or the TIM clock pin, PTD6/ATD14/TCLK. The prescaler generates seven clock rates from the internal bus clock. The prescaler select bits, PS[2–0], in the TIM status and control register select the TIM clock source. 16.3.2 Input Capture An input capture function has three basic parts: edge select logic, an input capture latch, and a 16-bit counter. Two 8-bit registers, which make up the 16-bit input capture register, are used to latch the value of the free-running counter after the corresponding input capture edge detector senses a defined transition. The polarity of the active edge is programmable. The level transition which triggers the counter transfer is defined by the corresponding input edge bits (ELSxB and ELSxA in TSC0 through TSC5 control registers with x referring to the active channel number). When an active edge occurs on the pin of an input capture channel, the TIM latches the contents of the TIM counter into the TIM channel registers, TCHxH–TCHxL. Input captures can generate TIM CPU interrupt requests. Software can determine that an input capture event has occurred by enabling input capture interrupts or by polling the status flag bit. The free-running counter contents are transferred to the TIM channel registers (TCHxH–TCHxL) (see 16.8.5 TIM Channel Registers) on each proper signal transition regardless of whether the TIM channel flag (CH0F–CH5F in TSC0–TSC5 registers) is set or clear. When the status flag is set, a CPU interrupt is generated if enabled. The value of the count latched or “captured” is the time of the event. Because this value is stored in the input capture register when the actual event occurs, user software can respond to this event at a later time and determine the actual time of the event. However, this must be done prior to another input capture on the same pin; otherwise, the previous time value will be lost. By recording the times for successive edges on an incoming signal, software can determine the period and/or pulse width of the signal. To measure a period, two successive edges of the same polarity are captured. To measure a pulse width, two alternate polarity edges are captured. Software should track the overflows at the 16-bit module counter to extend its range. Another use for the input capture function is to establish a time reference. In this case, an input capture function is used in conjunction with an output compare function. For example, to activate an output signal a specified number of clock cycles after detecting an input event (edge), use the input capture function to record the time at which the edge occurred. A number corresponding to the desired delay is added to this captured value and stored to an output compare register (see 16.8.5 TIM Channel Registers). Because both input captures and output compares are referenced to the same 16-bit modulo counter, the delay can be controlled to the resolution of the counter independent of software latencies. Data Sheet 244 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Reset does not affect the contents of the input capture channel (TCHxH–TCHxL) registers. 16.3.3 Output Compare With the output compare function, the TIM can generate a periodic pulse with a programmable polarity, duration, and frequency. When the counter reaches the value in the registers of an output compare channel, the TIM can set, clear, or toggle the channel pin. Output compares can generate TIM CPU interrupt requests. 16.3.3.1 Unbuffered Output Compare Any output compare channel can generate unbuffered output compare pulses as described in 16.3.3 Output Compare. The pulses are unbuffered because changing the output compare value requires writing the new value over the old value currently in the TIM channel registers. An unsynchronized write to the TIM channel registers to change an output compare value could cause incorrect operation for up to two counter overflow periods. For example, writing a new value before the counter reaches the old value but after the counter reaches the new value prevents any compare during that counter overflow period. Also, using a TIM overflow interrupt routine to write a new, smaller output compare value may cause the compare to be missed. The TIM may pass the new value before it is written. Use the following methods to synchronize unbuffered changes in the output compare value on channel x: • When changing to a smaller value, enable channel x output compare interrupts and write the new value in the output compare interrupt routine. The output compare interrupt occurs at the end of the current output compare pulse. The interrupt routine has until the end of the counter overflow period to write the new value. • When changing to a larger output compare value, enable TIM overflow interrupts and write the new value in the TIM overflow interrupt routine. The TIM overflow interrupt occurs at the end of the current counter overflow period. Writing a larger value in an output compare interrupt routine (at the end of the current pulse) could cause two output compares to occur in the same counter overflow period. 16.3.3.2 Buffered Output Compare Channels 0 and 1 can be linked to form a buffered output compare channel whose output appears on the PTE2/TCH0 pin. The TIM channel registers of the linked pair alternately control the output. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 245 Setting the MS0B bit in TIM channel 0 status and control register (TSC0) links channel 0 and channel 1. The output compare value in the TIM channel 0 registers initially controls the output on the PTE2/TCH0 pin. Writing to the TIM channel 1 registers enables the TIM channel 1 registers to synchronously control the output after the TIM overflows. At each subsequent overflow, the TIM channel registers (0 or 1) that control the output are the ones written to last. TSC0 controls and monitors the buffered output compare function, and TIM channel 1 status and control register (TSC1) is unused. While the MS0B bit is set, the channel 1 pin, PTE3/TCH1, is available as a general-purpose I/O pin. Channels 2 and 3 can be linked to form a buffered output compare channel whose output appears on the PTF0/TCH2 pin. The TIM channel registers of the linked pair alternately control the output. Setting the MS2B bit in TIM channel 2 status and control register (TSC2) links channel 2 and channel 3. The output compare value in the TIM channel 2 registers initially controls the output on the PTF0/TCH2 pin. Writing to the TIM channel 3 registers enables the TIM channel 3 registers to synchronously control the output after the TIM overflows. At each subsequent overflow, the TIM channel registers (2 or 3) that control the output are the ones written to last. TSC2 controls and monitors the buffered output compare function, and TIM channel 3 status and control register (TSC3) is unused. While the MS2B bit is set, the channel 3 pin, PTF1/TCH3, is available as a general-purpose I/O pin. Channels 4 and 5 can be linked to form a buffered output compare channel whose output appears on the PTF2/TCH4 pin. The TIM channel registers of the linked pair alternately control the output. Setting the MS4B bit in TIM channel 4 status and control register (TSC4) links channel 4 and channel 5. The output compare value in the TIM channel 4 registers initially controls the output on the PTF2/TCH4 pin. Writing to the TIM channel 5 registers enables the TIM channel 5 registers to synchronously control the output after the TIM overflows. At each subsequent overflow, the TIM channel registers (4 or 5) that control the output are the ones written to last. TSC4 controls and monitors the buffered output compare function, and TIM channel 5 status and control register (TSC5) is unused. While the MS4B bit is set, the channel 5 pin, PTF3/TCH5, is available as a general-purpose I/O pin. NOTE: In buffered output compare operation, do not write new output compare values to the currently active channel registers. User software should track the currently active channel to prevent writing a new value to the active channel. Writing to the active channel registers is the same as generating unbuffered output compares. 16.3.4 Pulse Width Modulation (PWM) By using the toggle-on-overflow feature with an output compare channel, the TIM can generate a PWM signal. The value in the TIM counter modulo registers determines the period of the PWM signal. The channel pin toggles when the Data Sheet 246 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor counter reaches the value in the TIM counter modulo registers. The time between overflows is the period of the PWM signal. As Figure 16-4 shows, the output compare value in the TIM channel registers determines the pulse width of the PWM signal. The time between overflow and output compare is the pulse width. Program the TIM to clear the channel pin on output compare if the polarity of the PWM pulse is logic 1 (ELSxA = 0). Program the TIM to set the pin if the polarity of the PWM pulse is logic 0 (ELSxA = 1). OVERFLOW OVERFLOW OVERFLOW PERIOD POLARITY = 1 (ELSxA = 0) TCHx PULSE WIDTH POLARITY = 0 (ELSxA = 1) TCHx OUTPUT COMPARE OUTPUT COMPARE OUTPUT COMPARE Figure 16-4. PWM Period and Pulse Width The value in the TIM counter modulo registers and the selected prescaler output determines the frequency of the PWM output. The frequency of an 8-bit PWM signal is variable in 256 increments. Writing $00FF (255) to the TIM counter modulo registers produces a PWM period of 256 times the internal bus clock period if the prescaler select value is $000 (see 16.8.1 TIM Status and Control Register). The value in the TIM channel registers determines the pulse width of the PWM output. The pulse width of an 8-bit PWM signal is variable in 256 increments. Writing $0080 (128) to the TIM channel registers produces a duty cycle of 128/256 or 50%. 16.3.4.1 Unbuffered PWM Signal Generation Any output compare channel can generate unbuffered PWM pulses as described in 16.3.4 Pulse Width Modulation (PWM). The pulses are unbuffered because changing the pulse width requires writing the new pulse width value over the value currently in the TIM channel registers. An unsynchronized write to the TIM channel registers to change a pulse width value could cause incorrect operation for up to two PWM periods. For example, writing a new value before the counter reaches the old value but after the counter reaches the new value prevents any compare during that PWM period. Also, using a TIM overflow interrupt routine to write a new, smaller pulse width value may MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 247 cause the compare to be missed. The TIM may pass the new value before it is written to the timer channel (TCHxH/TCHxL) registers. Use the following methods to synchronize unbuffered changes in the PWM pulse width on channel x: NOTE: • When changing to a shorter pulse width, enable channel x output compare interrupts and write the new value in the output compare interrupt routine. The output compare interrupt occurs at the end of the current pulse. The interrupt routine has until the end of the PWM period to write the new value. • When changing to a longer pulse width, enable TIM overflow interrupts and write the new value in the TIM overflow interrupt routine. The TIM overflow interrupt occurs at the end of the current PWM period. Writing a larger value in an output compare interrupt routine (at the end of the current pulse) could cause two output compares to occur in the same PWM period. In PWM signal generation, do not program the PWM channel to toggle on output compare. Toggling on output compare prevents reliable 0% duty cycle generation and removes the ability of the channel to self-correct in the event of software error or noise. Toggling on output compare also can cause incorrect PWM signal generation when changing the PWM pulse width to a new, much larger value. 16.3.4.2 Buffered PWM Signal Generation Channels 0 and 1 can be linked to form a buffered PWM channel whose output appears on the PTE2/TCH0 pin. The TIM channel registers of the linked pair alternately control the pulse width of the output. Setting the MS0B bit in TIM channel 0 status and control register (TSC0) links channel 0 and channel 1. The TIM channel 0 registers initially control the pulse width on the PTE2/TCH0 pin. Writing to the TIM channel 1 registers enables the TIM channel 1 registers to synchronously control the pulse width at the beginning of the next PWM period. At each subsequent overflow, the TIM channel registers (0 or 1) that control the pulse width are the ones written to last. TSC0 controls and monitors the buffered PWM function, and TIM channel 1 status and control register (TSC1) is unused. While the MS0B bit is set, the channel 1 pin, PTE3/TCH1, is available as a general-purpose I/O pin. Channels 2 and 3 can be linked to form a buffered PWM channel whose output appears on the PTF0/TCH2 pin. The TIM channel registers of the linked pair alternately control the pulse width of the output. Setting the MS2B bit in TIM channel 2 status and control register (TSC2) links channel 2 and channel 3. The TIM channel 2 registers initially control the pulse width on the PTF0/TCH2 pin. Writing to the TIM channel 3 registers enables the TIM channel 3 registers to synchronously control the pulse width at the beginning of the next PWM period. At each subsequent overflow, the TIM channel registers (2 or 3) that control the pulse width are the ones written to last. TSC2 controls and monitors the buffered PWM function, and TIM channel 3 status and control register Data Sheet 248 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor (TSC3) is unused. While the MS2B bit is set, the channel 3 pin, PTF1/TCH3, is available as a general-purpose I/O pin. Channels 4 and 5 can be linked to form a buffered PWM channel whose output appears on the PTF2/TCH4 pin. The TIM channel registers of the linked pair alternately control the pulse width of the output. Setting the MS4B bit in TIM channel 4 status and control register (TSC4) links channel 4 and channel 5. The TIM channel 4 registers initially control the pulse width on the PTF2/TCH4 pin. Writing to the TIM channel 5 registers enables the TIM channel 5 registers to synchronously control the pulse width at the beginning of the next PWM period. At each subsequent overflow, the TIM channel registers (4 or 5) that control the pulse width are the ones written to last. TSC4 controls and monitors the buffered PWM function, and TIM channel 5 status and control register (TSC5) is unused. While the MS4B bit is set, the channel 5 pin, PTF3/TCH5, is available as a general-purpose I/O pin. NOTE: In buffered PWM signal generation, do not write pulse width values to the currently active channel registers. User software should track the currently active channel to prevent writing a new value to the active channel. Writing to the active channel registers is the same as generating unbuffered PWM signals. 16.3.4.3 PWM Initialization To ensure correct operation when generating unbuffered or buffered PWM signals, use the following initialization procedure: 1. In the TIM status and control register (TSC): a. Stop the TIM counter by setting the TIM stop bit, TSTOP. b. Reset the TIM counter and prescaler by setting the TIM reset bit, TRST. 2. In the TIM counter modulo registers (TMODH–TMODL), write the value for the required PWM period. 3. In the TIM channel x registers (TCHxH–TCHxL), write the value for the required pulse width. 4. In TIM channel x status and control register (TSCx): a. Write 0–1 (for unbuffered output compare or PWM signals) or 1–0 (for buffered output compare or PWM signals) to the mode select bits, MSxB–MSxA. See Table 16-2. b. Write 1 to the toggle-on-overflow bit, TOVx. c. Write 1–0 (polarity 1 — clear output on compare) or 1–1 (polarity 0 — set output on compare) to the edge/level select bits, ELSxB–ELSxA. The output action on compare must force the output to the complement of the pulse width level. See Table 16-2. NOTE: In PWM signal generation, do not program the PWM channel to toggle on output compare. Toggling on output compare prevents reliable 0% duty cycle generation MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 249 and removes the ability of the channel to self-correct in the event of software error or noise. Toggling on output compare can also cause incorrect PWM signal generation when changing the PWM pulse width to a new, much larger value. 5. In the TIM status control register (TSC), clear the TIM stop bit, TSTOP. Setting MS0B links channels 0 and 1 and configures them for buffered PWM operation. The TIM channel 0 registers (TCH0H–TCH0L) initially control the buffered PWM output. TIM status control register 0 (TSC0) controls and monitors the PWM signal from the linked channels. MS0B takes priority over MS0A. Setting MS2B links channels 2 and 3 and configures them for buffered PWM operation. The TIM channel 2 registers (TCH2H–TCH2L) initially control the buffered PWM output. TIM status control register 2 (TSC2) controls and monitors the PWM signal from the linked channels. MS2B takes priority over MS2A. Setting MS4B links channels 4 and 5 and configures them for buffered PWM operation. The TIM channel 4 registers (TCH4H–TCH4L) initially control the buffered PWM output. TIM status control register 4 (TSC4) controls and monitors the PWM signal from the linked channels. MS4B takes priority over MS4A. Clearing the toggle-on-overflow bit, TOVx, inhibits output toggles on TIM overflows. Subsequent output compares try to force the output to a state it is already in and have no effect. The result is a 0% duty cycle output. Setting the channel x maximum duty cycle bit (CHxMAX) and setting the TOVx bit generates a 100% duty cycle output. See 16.8.4 TIM Channel Status and Control Registers. 16.4 Interrupts The following TIM sources can generate interrupt requests: Data Sheet 250 • TIM overflow flag (TOF) — The TOF bit is set when the TIM counter reaches the modulo value programmed in the TIM counter modulo registers. The TIM overflow interrupt enable bit, TOIE, enables TIM overflow interrupt requests. TOF and TOIE are in the TIM status and control register. • TIM channel flags (CH5F–CH0F) — The CHxF bit is set when an input capture or output compare occurs on channel x. Channel x TIM CPU interrupt requests are controlled by the channel x interrupt enable bit, CHxIE. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 16.5 Low-Power Modes The WAIT and STOP instructions put the MCU in low-power standby modes. 16.5.1 Wait Mode The TIM remains active after the execution of a WAIT instruction. In wait mode, the TIM registers are not accessible by the CPU. Any enabled CPU interrupt request from the TIM can bring the MCU out of wait mode. If TIM functions are not required during wait mode, reduce power consumption by stopping the TIM before executing the WAIT instruction. 16.5.2 Stop Mode The TIM is inactive after the execution of a STOP instruction. The STOP instruction does not affect register conditions or the state of the TIM counter. TIM operation resumes when the MCU exits stop mode. 16.6 TIM During Break Interrupts A break interrupt stops the TIM counter. The system integration module (SIM) controls whether status bits in other modules can be cleared during the break state. The BCFE bit in the SIM break flag control register (SBFCR) enables software to clear status bits during the break state. (See 14.7.3 SIM Break Flag Control Register.) To allow software to clear status bits during a break interrupt, write a logic 1 to the BCFE bit. If a status bit is cleared during the break state, it remains cleared when the MCU exits the break state. To protect status bits during the break state, write a logic 0 to the BCFE bit. With BCFE at logic 0 (its default state), software can read and write I/O registers during the break state without affecting status bits. Some status bits have a 2-step read/write clearing procedure. If software does the first step on such a bit before the break, the bit cannot change during the break state as long as BCFE is at logic 0. After the break, doing the second step clears the status bit. 16.7 I/O Signals Port D shares one of its pins with the TIM. Port E shares two of its pins with the TIM and port F shares four of its pins with the TIM. PTD6/ATD14/TCLK is an external clock input to the TIM prescaler. The six TIM channel I/O pins are PTE2/TCH0, PTE3/TCH1, PTF0/TCH2, PTF1/TCH3, PTF2/TCH4, and PTF3/TCH5. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 251 16.7.1 TIM Clock Pin (PTD6/ATD14/TCLK) PTD6/ATD14/TCLK is an external clock input that can be the clock source for the TIM counter instead of the prescaled internal bus clock. Select the PTD6/ATD14/TCLK input by writing logic 1s to the three prescaler select bits, PS[2–0]. (See 16.8.1 TIM Status and Control Register.) The minimum TCLK pulse width is specified in 18.12 Timer Module Characteristics. The maximum TCLK frequency is the least: 4 MHz or bus frequency ÷ 2. PTD6/ATD14/TCLK is available as a general-purpose I/O pin or ADC channel when not used as the TIM clock input. When the PTD6/ATD14/TCLK pin is the TIM clock input, it is an input regardless of the state of the DDRD6 bit in data direction register D. 16.7.2 TIM Channel I/O Pins (PTF3/TCH5–PTF0/TCH2 and PTE3/TCH1–PTE2/TCH0) Each channel I/O pin is programmable independently as an input capture pin or an output compare pin. PTE2/TCH0, PTE6/TCH2, and PTF2/TCH4 can be configured as buffered output compare or buffered PWM pins. 16.8 I/O Registers These I/O registers control and monitor TIM operation: • TIM status and control register (TSC) • TIM control registers (TCNTH–TCNTL) • TIM counter modulo registers (TMODH–TMODL) • TIM channel status and control registers (TSC0, TSC1, TSC2, TSC3, TSC4, and TSC5) • TIM channel registers (TCH0H–TCH0L, TCH1H–TCH1L, TCH2H–TCH2L, TCH3H–TCH3L, TCH4H–TCH4L, and TCH5H–TCH5L) 16.8.1 TIM Status and Control Register The TIM status and control register: Data Sheet 252 • Enables TIM overflow interrupts • Flags TIM overflows • Stops the TIM counter • Resets the TIM counter • Prescales the TIM counter clock MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Address: $0020 Bit 7 Read: TOF Write: 0 Reset: 0 6 5 TOIE TSTOP 0 1 4 3 0 0 TRST 0 0 2 1 Bit 0 PS2 PS1 PS0 0 0 0 = Unimplemented Figure 16-5. TIM Status and Control Register (TSC) TOF — TIM Overflow Flag Bit This read/write flag is set when the TIM counter resets reaches the modulo value programmed in the TIM counter modulo registers. Clear TOF by reading the TIM status and control register when TOF is set and then writing a logic 0 to TOF. If another TIM overflow occurs before the clearing sequence is complete, then writing logic 0 to TOF has no effect. Therefore, a TOF interrupt request cannot be lost due to inadvertent clearing of TOF. Reset clears the TOF bit. Writing a logic 1 to TOF has no effect. 1 = TIM counter has reached modulo value 0 = TIM counter has not reached modulo value TOIE — TIM Overflow Interrupt Enable Bit This read/write bit enables TIM overflow interrupts when the TOF bit becomes set. Reset clears the TOIE bit. 1 = TIM overflow interrupts enabled 0 = TIM overflow interrupts disabled TSTOP — TIM Stop Bit This read/write bit stops the TIM counter. Counting resumes when TSTOP is cleared. Reset sets the TSTOP bit, stopping the TIM counter until software clears the TSTOP bit. 1 = TIM counter stopped 0 = TIM counter active NOTE: Do not set the TSTOP bit before entering wait mode if the TIM is required to exit wait mode. Also when the TSTOP bit is set and the timer is configured for input capture operation, input captures are inhibited until the TSTOP bit is cleared. TRST — TIM Reset Bit Setting this write-only bit resets the TIM counter and the TIM prescaler. Setting TRST has no effect on any other registers. Counting resumes from $0000. TRST is cleared automatically after the TIM counter is reset and always reads as logic 0. Reset clears the TRST bit. 1 = Prescaler and TIM counter cleared 0 = No effect NOTE: Setting the TSTOP and TRST bits simultaneously stops the TIM counter at a value of $0000. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 253 PS[2–0] — Prescaler Select Bits These read/write bits select either the PTD6/ATD14/TCLK pin or one of the seven prescaler outputs as the input to the TIM counter as Table 16-1 shows. Reset clears the PS[2–0] bits. Table 16-1. Prescaler Selection PS[2–0] TIM Clock Source 000 Internal bus clock ÷1 001 Internal bus clock ÷ 2 010 Internal bus clock ÷ 4 011 Internal bus clock ÷ 8 100 Internal bus clock ÷ 16 101 Internal bus clock ÷ 32 110 Internal bus clock ÷ 64 111 PTD6/ATD14/TCLK 16.8.2 TIM Counter Registers The two read-only TIM counter registers contain the high and low bytes of the value in the TIM counter. Reading the high byte (TCNTH) latches the contents of the low byte (TCNTL) into a buffer. Subsequent reads of TCNTH do not affect the latched TCNTL value until TCNTL is read. Reset clears the TIM counter registers. Setting the TIM reset bit (TRST) also clears the TIM counter registers. NOTE: If TCNTH is read during a break interrupt, be sure to unlatch TCNTL by reading TCNTL before exiting the break interrupt. Otherwise, TCNTL retains the value latched during the break. Register Name and Address Read: TCNTH — $0022 Bit 7 6 5 4 3 2 1 Bit 0 BIT 15 BIT 14 BIT 13 BIT 12 BIT 11 BIT 10 BIT 9 BIT 8 0 0 0 0 0 0 0 Write: Reset: 0 = Unimplemented Register Name and Address Bit 7 Read: TCNTL — $0023 5 4 3 2 1 Bit 0 BIT 7 6 BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 BIT 0 0 0 0 0 0 0 0 0 Write: Reset: = Unimplemented Figure 16-6. TIM Counter Registers (TCNTH and TCNTL) Data Sheet 254 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 16.8.3 TIM Counter Modulo Registers The read/write TIM modulo registers contain the modulo value for the TIM counter. When the TIM counter reaches the modulo value, the overflow flag (TOF) becomes set, and the TIM counter resumes counting from $0000 at the next timer clock. Writing to the high byte (TMODH) inhibits the TOF bit and overflow interrupts until the low byte (TMODL) is written. Reset sets the TIM counter modulo registers. Register Name and Address Read: Write: Reset: TMODH — $0024 Bit 7 6 5 4 3 2 1 Bit 0 BIT 15 BIT 14 BIT 13 BIT 12 BIT 11 BIT 10 BIT 9 BIT 8 1 1 1 1 1 1 1 1 Register Name and Address Read: Write: Reset: TMODL — $0025 Bit 7 6 5 4 3 2 1 Bit 0 BIT 7 BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 BIT 0 1 1 1 1 1 1 1 1 Figure 16-7. TIM Counter Modulo Registers (TMODH and TMODL) NOTE: Reset the TIM counter before writing to the TIM counter modulo registers. 16.8.4 TIM Channel Status and Control Registers Each of the TIM channel status and control registers: MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor • Flags input captures and output compares • Enables input capture and output compare interrupts • Selects input capture, output compare, or PWM operation • Selects high, low, or toggling output on output compare • Selects rising edge, falling edge, or any edge as the active input capture trigger • Selects output toggling on TIM overflow • Selects 0% and 100% PWM duty cycle • Selects buffered or unbuffered output compare/PWM operation Data Sheet 255 Register Name and Address Bit 7 Read: CH0F Write: 0 Reset: 0 TSC0 — $0026 6 5 4 3 2 1 Bit 0 CH0IE MS0B MS0A ELS0B ELS0A TOV0 CH0MAX 0 0 0 0 0 0 0 4 3 2 1 Bit 0 MS1A ELS1B ELS1A TOV1 CH1MAX 0 0 0 0 0 Register Name and Address Bit 7 Read: CH1F Write: 0 Reset: 0 TSC1 — $0029 6 CH1IE 0 Register Name and Address Bit 7 Read: CH2F Write: 0 Reset: 0 Bit 7 CH3F Write: 0 Reset: 0 Read: CH4F Write: 0 Reset: 0 5 4 3 2 1 Bit 0 CH2IE MS2B MS2A ELS2B ELS2A TOV2 CH2MAX 0 0 0 0 0 0 0 4 3 2 1 Bit 0 MS3A ELS3B ELS3A TOV3 CH3MAX 0 0 0 0 0 TSC3 — $002F 6 CH3IE 0 Bit 7 CH5F Write: 0 Reset: 0 5 0 0 TSC4 — $0032 6 5 4 3 2 1 Bit 0 CH4IE MS4B MS4A ELS4B ELS4A TOV4 CH4MAX 0 0 0 0 0 0 0 4 3 2 1 Bit 0 MS5A ELS5B ELS5A TOV5 CH5MAX 0 0 0 0 0 Register Name and Address Read: 0 6 Register Name and Address Bit 7 0 TSC2 — $002C Register Name and Address Read: 5 TSC5 — $0035 6 CH5IE 0 5 0 0 = Unimplemented Figure 16-8. TIM Channel Status and Control Registers (TSC0–TSC5) Data Sheet 256 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor CHxF — Channel x Flag Bit When channel x is an input capture channel, this read/write bit is set when an active edge occurs on the channel x pin. When channel x is an output compare channel, CHxF is set when the value in the TIM counter registers matches the value in the TIM channel x registers. When CHxIE = 1, clear CHxF by reading TIM channel x status and control register with CHxF set, and then writing a logic 0 to CHxF. If another interrupt request occurs before the clearing sequence is complete, then writing logic 0 to CHxF has no effect. Therefore, an interrupt request cannot be lost due to inadvertent clearing of CHxF. Reset clears the CHxF bit. Writing a logic 1 to CHxF has no effect. 1 = Input capture or output compare on channel x 0 = No input capture or output compare on channel x CHxIE — Channel x Interrupt Enable Bit This read/write bit enables TIM CPU interrupts on channel x. Reset clears the CHxIE bit. 1 = Channel x CPU interrupt requests enabled 0 = Channel x CPU interrupt requests disabled MSxB — Mode Select Bit B This read/write bit selects buffered output compare/PWM operation. MSxB exists only in the TIM channel 0, TIM channel 2, and TIM channel 4 status and control registers. Setting MS0B disables the channel 1 status and control register and reverts TCH1 pin to general-purpose I/O. Setting MS2B disables the channel 3 status and control register and reverts TCH3 pin to general-purpose I/O. Setting MS4B disables the channel 5 status and control register and reverts TCH5 pin to general-purpose I/O. Reset clears the MSxB bit. 1 = Buffered output compare/PWM operation enabled 0 = Buffered output compare/PWM operation disabled MSxA — Mode Select Bit A When ELSxB–ELSxA ≠ 00, this read/write bit selects either input capture operation or unbuffered output compare/PWM operation. (See Table 16-2.) 1 = Unbuffered output compare/PWM operation 0 = Input capture operation When ELSxB–ELSxA = 00, this read/write bit selects the initial output level of the TCHx pin once PWM, input capture, or output compare operation is enabled. (See Table 16-2.) Reset clears the MSxA bit. 1 = Initial output level low 0 = Initial output level high NOTE: Before changing a channel function by writing to the MSxB or MSxA bit, set the TSTOP and TRST bits in the TIM status and control register (TSC). MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 257 ELSxB and ELSxA — Edge/Level Select Bits When channel x is an input capture channel, these read/write bits control the active edge-sensing logic on channel x. When channel x is an output compare channel, ELSxB and ELSxA control the channel x output behavior when an output compare occurs. When ELSxB and ELSxA are both clear, channel x is not connected to port E or port F, and pin PTEx/TCHx or pin PTFx/TCHx is available as a general-purpose I/O pin. However, channel x is at a state determined by these bits and becomes transparent to the respective pin when PWM, input capture, or output compare mode is enabled. Table 16-2 shows how ELSxB and ELSxA work. Reset clears the ELSxB and ELSxA bits. Table 16-2. Mode, Edge, and Level Selection MSxB–MSxA ELSxB–ELSxA X0 00 Mode Configuration Pin under Port Control; Initialize Timer Output Level High Output Preset NOTE: X1 00 Pin under Port Control; Initialize Timer Output Level Low 00 01 Capture on Rising Edge Only 00 10 00 11 01 01 01 10 01 11 1X 01 1X 10 1X 11 Input Capture Capture on Falling Edge Only Capture on Rising or Falling Edge Toggle Output on Compare Output Compare or PWM Clear Output on Compare Set Output on Compare Buffered Output Compare or Buffered PWM Toggle Output on Compare Clear Output on Compare Set Output on Compare Before enabling a TIM channel register for input capture operation, make sure that the PTEx/TCHx pin or PTFx/TCHx pin is stable for at least two bus clocks. TOVx — Toggle-On-Overflow Bit When channel x is an output compare channel, this read/write bit controls the behavior of the channel x output when the TIM counter overflows. When channel x is an input capture channel, TOVx has no effect. Reset clears the TOVx bit. 1 = Channel x pin toggles on TIM counter overflow. 0 = Channel x pin does not toggle on TIM counter overflow. NOTE: Data Sheet 258 When TOVx is set, a TIM counter overflow takes precedence over a channel x output compare if both occur at the same time. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor CHxMAX — Channel x Maximum Duty Cycle Bit When the TOVx bit is at logic 1 and clear output on compare is selected, setting the CHxMAX bit forces the duty cycle of buffered and unbuffered PWM signals to 100%. As Figure 16-9 shows, the CHxMAX bit takes effect in the cycle after it is set or cleared. The output stays at 100% duty cycle level until the cycle after CHxMAX is cleared. NOTE: The 100% PWM duty cycle is defined as a continuous high level if the PWM polarity is 1 and a continuous low level if the PWM polarity is 0. Conversely, a 0% PWM duty cycle is defined as a continuous low level if the PWM polarity is 1 and a continuous high level if the PWM polarity is 0. OVERFLOW OVERFLOW OVERFLOW OVERFLOW OVERFLOW PERIOD TCHx OUTPUT COMPARE OUTPUT COMPARE OUTPUT COMPARE OUTPUT COMPARE CHxMAX Figure 16-9. CHxMAX Latency 16.8.5 TIM Channel Registers These read/write registers contain the captured TIM counter value of the input capture function or the output compare value of the output compare function. The state of the TIM channel registers after reset is unknown. In input capture mode (MSxB–MSxA = 0–0), reading the high byte of the TIM channel x registers (TCHxH) inhibits input captures until the low byte (TCHxL) is read. In output compare mode (MSxB–MSxA ≠ 0–0), writing to the high byte of the TIM channel x registers (TCHxH) inhibits output compares until the low byte (TCHxL) is written. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 259 Register Name and Address Read: Write: TCH0H — $0027 Bit 7 6 5 4 3 2 1 Bit 0 Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8 Reset: Indeterminate after reset Register Name and Address Read: Write: TCH0L — $0028 Bit 7 6 5 4 3 2 1 Bit 0 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset: Indeterminate after reset Register Name and Address Read: Write: TCH1H — $002A Bit 7 6 5 4 3 2 1 Bit 0 Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8 Reset: Indeterminate after reset Register Name and Address Read: Write: TCH1L — $002B Bit 7 6 5 4 3 2 1 Bit 0 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset: Indeterminate after reset Register Name and Address Read: Write: TCH2H — $002D Bit 7 6 5 4 3 2 1 Bit 0 Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8 Reset: Indeterminate after reset Register Name and Address Read: Write: Reset: TCH2L — $002E Bit 7 6 5 4 3 2 1 Bit 0 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Indeterminate after reset Figure 16-10. TIM Channel Registers (TCH0H/L–TCH3H/L) Data Sheet 260 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Register Name and Address Read: Write: TCH3H — $0030 Bit 7 6 5 4 3 2 1 Bit 0 Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8 Reset: Indeterminate after reset Register Name and Address Read: Write: TCH3L — $0031 Bit 7 6 5 4 3 2 1 Bit 0 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset: Indeterminate after reset Register Name and Address Read: Write: TCH4H — $0033 Bit 7 6 5 4 3 2 1 Bit 0 Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8 Reset: Indeterminate after reset Register Name and Address Read: Write: TCH4L — $0034 Bit 7 6 5 4 3 2 1 Bit 0 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Reset: Indeterminate after reset Register Name and Address Read: Write: TCH5H — $0036 Bit 7 6 5 4 3 2 1 Bit 0 Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8 Reset: Indeterminate after reset Register Name and Address Read: Write: Reset: TCH5L — $0037 Bit 7 6 5 4 3 2 1 Bit 0 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Indeterminate after reset Figure 16-10. TIM Channel Registers (TCH0H/L–TCH3H/L) (Continued) MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 261 Data Sheet 262 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 17. Development Support 17.1 Introduction This section describes the break module, the monitor read-only memory (MON), and the monitor mode entry methods. 17.2 Break Module (BRK) This section describes the break module (break). The break module can generate a break interrupt that stops normal program flow at a defined address to enter a background program. Features of the break module include: • Accessible I/O registers during the break interrupt • CPU-generated break interrupts • Software-generated break interrupts • COP disabling during break interrupts 17.2.1 Functional Description When the internal address bus matches the value written in the break address registers, the break module issues a breakpoint signal (BKPT) to the SIM. The SIM then causes the CPU to load the instruction register with a software interrupt instruction (SWI). The program counter vectors to $FFFC and $FFFD ($FEFC and $FEFD in monitor mode). These events can cause a break interrupt to occur: • A CPU-generated address (the address in the program counter) matches the contents of the break address registers • Software writes a logic 1 to the BRKA bit in the break status and control register. When a CPU-generated address matches the contents of the break address registers, the break interrupt is generated. A return-from-interrupt instruction (RTI) in the break routine ends the break interrupt and returns the MCU to normal operation. Figure 17-1 shows the structure of the break module. Figure 17-2 provides a summary of the I/O registers. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 263 IAB[15:8] BREAK ADDRESS REGISTER HIGH 8-BIT COMPARATOR IAB[15:0] BKPT TO SIM CONTROL 8-BIT COMPARATOR BREAK ADDRESS REGISTER LOW IAB[7:0] Figure 17-1. Break Module Block Diagram Addr. Register Name $FE0C Break Address Register High (BRKH) See page 266. $FE0D Break Address Register Low (BRKL) See page 266. $FE0E Break Status and Control Register (BRKSCR) See page 266. Read: Write: Reset: Read: Write: Reset: Read: Write: Reset: Bit 7 6 5 4 3 2 1 Bit 0 Bit 15 14 13 12 11 10 9 Bit 8 0 0 0 0 0 0 0 0 Bit 7 6 5 4 3 2 1 Bit 0 0 0 0 0 0 0 0 0 BRKE BRKA 0 0 0 0 0 0 0 0 0 0 0 0 0 0 = Unimplemented Figure 17-2. Break I/O Register Summary When the internal address bus matches the value written in the break address registers or when software writes a logic 1 to the BRKA bit in the break status and control register, the CPU starts a break interrupt by: Data Sheet 264 • Loading the instruction register with the SWI instruction • Loading the program counter with $FFFC and $FFFD ($FEFC and $FEFD in monitor mode) MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor The break interrupt timing is: • When a break address is placed at the address of the instruction opcode, the instruction is not executed until after completion of the break interrupt routine. • When a break address is placed at an address of an instruction operand, the instruction is executed before the break interrupt. • When software writes a logic 1 to the BRKA bit, the break interrupt occurs just before the next instruction is executed. By updating a break address and clearing the BRKA bit in a break interrupt routine, a break interrupt can be generated continuously. CAUTION: A break address should be placed at the address of the instruction opcode. When software does not change the break address and clears the BRKA bit in the first break interrupt routine, the next break interrupt will not be generated after exiting the interrupt routine even when the internal address bus matches the value written in the break address registers. 17.2.1.1 Flag Protection During Break Interrupts The system integration module (SIM) controls whether module status bits can be cleared during the break state. The BCFE bit in the SIM break flag control register (SBFCR) enables software to clear status bits during the break state. (See 14.7.3 SIM Break Flag Control Register and the Break Interrupts subsection for each module.) 17.2.1.2 TIM During Break Interrupts A break interrupt stops the timer counter. 17.2.1.3 COP During Break Interrupts The COP is disabled during a break interrupt when VTST is present on the RST pin. For VTST, see 18.5 5.0-Volt DC Electrical Characteristics. 17.2.2 Break Module Registers Three registers control and monitor operation of the break module: MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor • Break status and control register (BRKSCR) • Break address register high (BRKH) • Break address register low (BRKL) Data Sheet 265 17.2.2.1 Break Status and Control Register The break status and control register contains break module enable and status bits. Address: $FE0E Read: Write: Bit 7 6 BRKE BRKA Reset: 0 0 R = Reserved 5 4 3 2 1 Bit 0 0 0 0 0 0 0 R R R R R R 0 0 0 0 0 0 Figure 17-3. Break Status and Control Register (BRKSCR) BRKE — Break Enable Bit This read/write bit enables breaks on break address register matches. Clear BRKE by writing a logic 0 to bit 7. Reset clears the BRKE bit. 1 = Breaks enabled on 16-bit address match 0 = Breaks disabled on 16-bit address match BRKA — Break Active Bit This read/write status and control bit is set when a break address match occurs. Writing a logic 1 to BRKA generates a break interrupt. Clear BRKA by writing a logic 0 to it before exiting the break routine. Reset clears the BRKA bit. 1 = Break address match 0 = No break address match 17.2.2.2 Break Address Registers The break address registers contain the high and low bytes of the desired breakpoint address. Reset clears the break address registers. Address: Read: Write: Reset: $FE0C Bit 7 6 5 4 3 2 1 Bit 0 BIT 15 BIT 13 BIT 13 BIT 12 BIT 11 BIT 10 BIT 9 BIT 8 0 0 0 0 0 0 0 0 Figure 17-4. Break Address Register (BRKH) Address: Read: Write: Reset: $FE0D Bit 7 6 5 4 3 2 1 Bit 0 BIT 7 BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 BIT 0 0 0 0 0 0 0 0 0 Figure 17-5. Break Address Register (BRKL) Data Sheet 266 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 17.2.3 Low-Power Modes The WAIT and STOP instructions put the MCU in low-power standby modes. If enabled, the break module will remain enabled in wait and stop modes. However, since the internal address bus does not increment in these modes, a break interrupt will never be triggered. 17.3 Monitor Module (MON) This subsection describes the monitor module (MON) and the monitor mode entry methods. The monitor allows debugging and programming of the microcontroller unit (MCU) through a single-wire interface with a host computer. Features include: • Normal user-mode pin functionality on most pins • One pin dedicated to serial communication between MCU and host computer • Standard non-return-to-zero (NRZ) communication with host computer • 4800 Baud to 28.8 kBaud communication with host computer • Execution of code in random-access memory (RAM) or FLASH 17.3.1 Functional Description Figure 17-6 shows a simplified diagram of monitor mode entry. The monitor module receives and executes commands from a host computer. Figure 17-7 shows an example circuit used to enter monitor mode and communicate with a host computer via a standard RS-232 interface. Simple monitor commands can access any memory address. In monitor mode, the MCU can execute code downloaded into RAM by a host computer while most MCU pins retain normal operating mode functions. All communication between the host computer and the MCU is through the PTA0 pin. A level-shifting and multiplexing interface is required between PTA0 and the host computer. PTA0 is used in a wired-OR configuration and requires a pullup resistor. 17.3.1.1 Monitor Mode Entry Table 17-1 shows the pin conditions for entering monitor mode. As specified in the table, monitor mode may be entered after a power-on reset (POR) and will allow communication provided the pin and clock conditions are met. The rising edge of the internal RST signal latches the monitor mode. Once monitor mode is latched, the values on PTC0, PTC1, and PTC3 pins can be changed. Once out of reset, the MCU waits for the host to send eight security bytes (see 17.3.2 Security). After the security bytes, the MCU sends a break signal (10 consecutive logic 0s) to the host, indicating that it is ready to receive a command. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 267 POR RESET NO IRQ = VTST? YES CONDITIONS FROM Table 17-1 PTA0 = 1, PTC0 = 1, AND PTC1 = 0? NO YES NORMAL USER MODE NORMAL MONITOR MODE INVALID USER MODE HOST SENDS 8 SECURITY BYTES IS RESET POR? YES NO YES ARE ALL SECURITY BYTES CORRECT? NO DISABLE ROM ENABLE ROM MONITOR MODE ENTRY DEBUGGING AND EEPROM PROGRAMMING (IF EEPROM IS ENABLED) EXECUTE MONITOR CODE YES DOES RESET OCCUR? NO Figure 17-6. Simplified Monitor Mode Entry Flowchart Data Sheet 268 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor VDD MC68HC08AS32A VDD 10 k RST 47 pF OSC2 MAX232 1 1 µF + 3 4 1 µF + C1+ C1– C2+ 5 C2– VDD VCC + 3 4.9152 MHz GND 15 + 10 8 9 5 10 k 1 kΩ VDD + 1 µF 74HC125 5 6 74HC125 3 2 VDD OSC1 PTC3 V– 6 7 0.1 µF 1 µF V+ 2 DB9 2 1 µF VDDA 10 MΩ 27 pF 16 VDD PTC0 10 k IRQ 10 k PTC1 10 kΩ PTA0 4 VSSA VSS 1 Figure 17-7. Normal Monitor Mode Circuit MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 269 Table 17-1. Mode Selection Serial Comm. Mode IRQ Mode Selection Communication Speed RST PLL COP Comments External Bus Clock Frequency PTA0 PTC0 VDD or VTST 1 1 VDD VTST or VTST 1 1 0 1 Off Disabled 4.9152 MHz 1.2288 MHz 4800 VDD or VSS X X X X X Enabled X X X VTST Monitor User VDD MON08 V RST Function TST [4] [6] [Pin No.] PTC1 PTC3 Baud Rate 0 0 Off Disabled 4.9152 MHz 2.4576 MHz 9600 PTC3 determines frequency divider COM [10] MOD0 MOD1 DIV4 [12] [14] [16] OSC1 [13] 1. PTA0 must have a pullup resistor to VDD in monitor mode. 2. Communication speed in the table is an example to obtain a baud rate of 4800 or 9600. Baud rate using external oscillator is bus frequency / 256. 3. External clock is a 4.9152 MHz crystal on OSC1 and OSC2 or a 4.9152 or 9.8304 MHz canned oscillator on OSC1. 4. X = don’t care 5. MON08 pin refers to P&E Microcomputer Systems’ MON08-Cyclone 2 by 8-pin connector. Data Sheet 270 NC 1 2 GND NC 3 4 RST NC 5 6 IRQ NC 7 8 NC NC 9 10 PTA0 NC 11 12 PTC0 OSC1 13 14 PTC1 VDD 15 16 PTC3 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 17.3.1.2 Monitor Vectors In monitor mode, the MCU uses different vectors for reset, SWI (software interrupt), and break interrupt than those for user mode. The alternate vectors are in the $FE page instead of the $FF page and allow code execution from the internal monitor firmware instead of user code. The COP module is disabled in monitor mode as long as VTST is applied to either the IRQ pin or the RST pin. Table 17-2 summarizes the differences between user mode and monitor mode regarding vectors. Table 17-2. Mode Differences Functions COP Reset Vector High Reset Vector Low Break Vector High Break Vector Low SWI Vector High SWI Vector Low User Enabled $FFFE $FFFF $FFFC $FFFD $FFFC $FFFD Monitor Disabled(1) $FEFE $FEFF $FEFC $FEFD $FEFC $FEFD Modes 1. If the high voltage (VTST) is removed from the IRQ pin while in monitor mode, the SIM asserts its COP enable output. The COP is a mask option enabled or disabled by the COPD bit in the configuration register. (See 18.5 5.0-Volt DC Electrical Characteristics.) 17.3.1.3 Data Format Communication with the monitor ROM is in standard non-return-to-zero (NRZ) mark/space data format. Transmit and receive baud rates must be identical. START BIT BIT 0 BIT 1 BIT 2 BIT 3 BIT 4 BIT 5 BIT 6 BIT 7 STOP BIT NEXT START BIT Figure 17-8. Monitor Data Format 17.3.1.4 Break Signal A start bit (logic 0) followed by nine logic 0 bits is a break signal. When the monitor receives a break signal, it drives the PTA0 pin high for the duration of two bits and then echoes back the break signal. MISSING STOP BIT 2-STOP BIT DELAY BEFORE ZERO ECHO 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 Figure 17-9. Break Transaction MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 271 17.3.1.5 Commands The monitor ROM firmware uses these commands: • READ (read memory) • WRITE (write memory) • IREAD (indexed read) • IWRITE (indexed write) • READSP (read stack pointer) • RUN (run user program) The monitor ROM firmware echoes each received byte back to the PTA0 pin for error checking. An 11-bit delay at the end of each command allows the host to send a break character to cancel the command. A delay of two bit times occurs before each echo and before READ, IREAD, or READSP data is returned. The data returned by a read command appears after the echo of the last byte of the command. NOTE: Wait one bit time after each echo before sending the next byte. FROM HOST READ 4 ADDRESS HIGH READ 4 1 ADDRESS HIGH 1 ADDRESS LOW 4 ECHO Notes: 1 = Echo delay, approximately 2 bit times 2 = Data return delay, approximately 2 bit times ADDRESS LOW DATA 1 3, 2 4 RETURN 3 = Cancel command delay, 11 bit times 4 = Wait 1 bit time before sending next byte. Figure 17-10. Read Transaction FROM HOST 3 ADDRESS HIGH WRITE WRITE 1 3 ADDRESS HIGH 1 ADDRESS LOW 3 ADDRESS LOW 1 DATA 3 DATA 1 2, 3 ECHO Notes: 1 = Echo delay, approximately 2 bit times 2 = Cancel command delay, 11 bit times 3 = Wait 1 bit time before sending next byte. Figure 17-11. Write Transaction A brief description of each monitor mode command is given in Table 17-3 through Table 17-8. Data Sheet 272 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Table 17-3. READ (Read Memory) Command Description Read byte from memory Operand 2-byte address in high-byte:low-byte order Data Returned Returns contents of specified address Opcode $4A Command Sequence SENT TO MONITOR ADDRESS ADDRESS ADDRESS HIGH HIGH LOW READ READ ADDRESS LOW DATA ECHO RETURN Table 17-4. WRITE (Write Memory) Command Description Operand Data Returned Opcode Write byte to memory 2-byte address in high-byte:low-byte order; low byte followed by data byte None $49 Command Sequence FROM HOST WRITE WRITE ADDRESS HIGH ADDRESS HIGH ADDRESS LOW ADDRESS LOW DATA DATA ECHO Table 17-5. IREAD (Indexed Read) Command Description Operand Data Returned Opcode Read next 2 bytes in memory from last address accessed 2-byte address in high byte:low byte order Returns contents of next two addresses $1A Command Sequence FROM HOST IREAD ECHO MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor IREAD DATA DATA RETURN Data Sheet 273 Table 17-6. IWRITE (Indexed Write) Command Description Operand Data Returned Opcode Write to last address accessed + 1 Single data byte None $19 Command Sequence FROM HOST IWRITE IWRITE DATA DATA ECHO A sequence of IREAD or IWRITE commands can access a block of memory sequentially over the full 64-Kbyte memory map. Table 17-7. READSP (Read Stack Pointer) Command Description Operand Data Returned Opcode Reads stack pointer None Returns incremented stack pointer value (SP + 1) in high-byte:low-byte order $0C Command Sequence FROM HOST READSP SP HIGH READSP ECHO SP LOW RETURN Table 17-8. RUN (Run User Program) Command Description Executes PULH and RTI instructions Operand None Data Returned None Opcode $28 Command Sequence FROM HOST RUN RUN ECHO Data Sheet 274 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor The MCU executes the SWI and PSHH instructions when it enters monitor mode. The RUN command tells the MCU to execute the PULH and RTI instructions. Before sending the RUN command, the host can modify the stacked CPU registers to prepare to run the host program. The READSP command returns the incremented stack pointer value, SP + 1. The high and low bytes of the program counter are at addresses SP + 5 and SP + 6. SP HIGH BYTE OF INDEX REGISTER SP + 1 CONDITION CODE REGISTER SP + 2 ACCUMULATOR SP + 3 LOW BYTE OF INDEX REGISTER SP + 4 HIGH BYTE OF PROGRAM COUNTER SP + 5 LOW BYTE OF PROGRAM COUNTER SP + 6 SP + 7 Figure 17-12. Stack Pointer at Monitor Mode Entry 17.3.2 Security A security feature discourages unauthorized reading of ROM locations while in monitor mode. The host can bypass the security feature at monitor mode entry by sending eight security bytes that match the bytes at locations $FFF6–$FFFD. Locations $FFF6–$FFFD contain user-defined data. NOTE: Do not leave locations $FFF6–$FFFD blank. For security reasons, program locations $FFF6–$FFFD even if they are not used for vectors. During monitor mode entry, the MCU waits after the power-on reset for the host to send the eight security bytes on pin PTA0. If the received bytes match those at locations $FFF6–$FFFD, the host bypasses the security feature and can read all ROM locations and execute code from ROM. Security remains bypassed until a power-on reset occurs. If the reset was not a power-on reset, security remains bypassed and security code entry is not required. See Figure 17-13. Upon power-on reset, if the received bytes of the security code do not match the data at locations $FFF6–$FFFD, the host fails to bypass the security feature. The MCU remains in monitor mode, but reading a ROM location returns an invalid value and trying to execute code from ROM causes an illegal address reset. After receiving the eight security bytes from the host, the MCU transmits a break character, signifying that it is ready to receive a command. NOTE: The MCU does not transmit a break character until after the host sends the eight security bytes. If the security sequence fails, the device should be reset by a power-on reset and brought up in monitor mode to attempt another entry. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 275 VDD 4096 + 32 CGMXCLK CYCLES COMMAND BYTE 8 FROM HOST BYTE 2 BYTE 1 RST PA0 Notes: 1 = Echo delay, approximately 2 bit times 2 = Data return delay, approximately 2 bit times 3 = Wait 1 bit time before sending next byte 4 = Wait until clock is stable and monitor runs 3 2 1 COMMAND ECHO 1 BYTE 8 ECHO BYTE 1 ECHO FROM MCU 1 BREAK 3 1 BYTE 2 ECHO 4 Figure 17-13. Monitor Mode Entry Timing 17.3.3 Baud Rate With a 4.9152-MHz crystal and the PTC3 pin at logic 1 during reset, data is transferred between the monitor and host at 4800 baud. If the PTC3 pin is at logic 0 during reset, the monitor baud rate is 9600. When the CGM output, CGMOUT, is driven by the PLL, the baud rate is determined by the MUL[7:4] bits in the PLL programming register (PPG). See Section 5. Clock Generator Module (CGM). Table 17-9. Monitor Baud Rate Selection VCO Frequency Multiplier (N) 1 2 3 4 5 6 Monitor Baud Rate (4.9152 MHz) 4800 9600 14,400 19,200 24,000 28,800 Monitor Baud Rate (4.194 MHz) 4096 8192 12,288 16,384 20,480 24,576 Data Sheet 276 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 18. Electrical Specifications 18.1 Introduction This section contains electrical and timing specifications. 18.2 Absolute Maximum Ratings Maximum ratings are the extreme limits to which the microcontroller unit (MCU) can be exposed without permanently damaging it. NOTE: This device is not guaranteed to operate properly at the maximum ratings. Refer to 18.5 5.0-Volt DC Electrical Characteristics for guaranteed operating conditions. Rating(1) Symbol Value Unit Supply voltage VDD –0.3 to +6.0 V Input voltage VIN VSS –0.3 to VDD +0.3 V I ± 25 mA Storage temperature TSTG –55 to +150 °C Maximum current out of VSS IMVSS 100 mA Maximum current into VDD IMVDD 100 mA Reset and IRQ input voltage VTST VSS –0.3 to 9.1 V Maximum current per pin excluding VDD and VSS 1. Voltages are references to VSS. NOTE: This device contains circuitry to protect the inputs against damage due to high static voltages or electric fields; however, it is advised that normal precautions be taken to avoid application of any voltage higher than maximum-rated voltages to this high-impedance circuit. For proper operation, it is recommended that VIN and VOUT be constrained to the range VSS ≤ (VIN or VOUT) ≤ VDD. Reliability of operation is enhanced if unused inputs are connected to an appropriate logic voltage level (for example, either VSS or VDD.) MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 277 18.3 Functional Operating Range Rating Symbol Value Unit TA –40 to 125 °C VDD 5.0 ± 10% V Symbol Value Unit Thermal resistance PLCC (52 pins) QFP (64 pins) θJA 50 70 °C/W I/O pin power dissipation PI/O User determined W Power dissipation(1) PD PD = (IDD x VDD) + PI/O = K/(TJ + 273°C) W Constant(2) K Average junction temperature TJ Operating temperature range Operating voltage range 18.4 Thermal Characteristics Characteristic Maximum junction temperature TJM PD x (TA + 273°C) + (PD2 x θJA) TA = PD × θJA 150 W/°C °C °C 1. Power dissipation is a function of temperature 2. K is a constant unique to the device. K can be determined from a known TA and measured PD. With this value of K, PD and TJ can be determined for any value of TA. Data Sheet 278 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 18.5 5.0-Volt DC Electrical Characteristics Characteristic(1) Symbol Min Typ(2) Max Unit Output high voltage (ILoad = –2.0 mA) All Ports, RST VOH VDD –0.8 — — V Output low voltage (ILoad = 1.6 mA) All Ports, RST VOL — — 0.4 V Input high voltage All Ports, IRQs, RST, OSC1 VIH 0.7 x VDD — VDD V Input low voltage All Ports, IRQs, RST, OSC1 VIL VSS — 0.3 x VDD V — — — — 30 15 mA mA — — — — — — — — 5 50 100 400 500 µA µA µA µA µA VDD + VDDA/VDDAREF supply current Run(3) Wait(4) Stop(5) 25 °C –40 °C to +105 °C –40 °C to +125 °C 25 °C with LVI enabled –40 °C to +105 °C with LVI enabled IDD I/O ports Hi-Z leakage current IL –1 — 1 µA Input current IIN –1 — 1 µA Capacitance Ports (as input or output) COUT CIN — — — — 12 8 pF Low-voltage inhibit voltage (trip) VTRIPF 3.8 — — V Low-voltage inhibit voltage (recover) VTRIPR — — 4.49 V POR rearm voltage(6) VPOR 0 — 200 mV POR reset voltage(7) VPORRST 0 — 800 mV POR rise time ramp rate(8) RPOR 0.02 — — V/ms Monitor mode entry and COP disable voltage(9) VTST VDD + 2.5 — 9.1 V 1. VDD = 5.0 Vdc ± 10%, VSS = 0 Vdc, TA = –40°C to +105°C, unless otherwise noted. 2. Typical values reflect average measurements at midpoint of voltage range, 25 °C only. 3. Run (Operating) IDD measured using external square wave clock source (fOP = 8.4 MHz). All inputs 0.2 V from rail. No dc loads. Less than 100 pF on all outputs. CL = 20 pF on OSC2. All ports configured as inputs. OSC2 capacitance linearly affects run IDD. Measured with all modules enabled. 4. Wait IDD measured using external square wave clock source (fOP = 8.4 MHz). All inputs 0.2 Vdc from rail. No dc loads. Less than 100 pF on all outputs, CL = 20 pF on OSC2. All ports configured as inputs. OSC2 capacitance linearly affects wait IDD. Measured with all modules enabled. 5. Stop IDD measured with OSC1 = VSS. All inputs 0.2 V from rail. No dc loads. Less than 100 pF on all outputs. All ports configured as inputs. 6. Maximum is highest voltage that POR is guaranteed. 7. Maximum is highest voltage that POR is possible. 8. If minimum VDD is not reached before the internal POR reset is released, RST must be driven low externally until minimum VDD is reached. 9. See 6.8 COP Module During Break Interrupts. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 279 18.6 Control Timing Characteristic(1) Symbol Min Max Unit Bus operating frequency fBUS — 8.4 MHz Internal clock period (1/fBus) tCYC 119 — ns RST pulse width low tRL 50 — ns IRQ interrupt pulse width low (edge-triggered) tILIH 50 — ns IRQ interrupt pulse period tILIL (2) — tCYC 1. VDD = 5.0 Vdc ± 10%, VSS = 0 Vdc, TA = –40°C to +105°C, unless otherwise noted. 2. The minimum period is the number of cycles it takes to execute the interrupt service routine plus 1 tCYC. tRL RST tILIL tILIH IRQ Figure 18-1. RST and IRQ Timing Data Sheet 280 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 18.7 ADC Characteristics Characteristic Min Max Unit Resolution 8 8 Bits Absolute accuracy (VREFL = 0 V, VDDA = VREFH = 5 V ± 10%) –1 +1 LSB Includes quantization VREFL VREFH V VREFL = VSSA 16 17 µs Conversion time period –1 1 µA 16 17 ADC clock cycles Conversion range(1) (see note 1) Power-up time (2) Input leakage Ports B and D (see note 3) Conversion Time Monotonicity Comments Includes sampling time Inherent within total error Zero input reading 00 01 Hex VIN = VREFL Full-scale reading FE FF Hex VIN = VREFH Sample time(3) (see Note 2) 5 — ADC Clock Cycles Input capacitance — 8 pF Not tested ADC internal clock 500 k 1.048 M Hz Tested only at 1 MHz Analog input voltage –0.3 VDD + 0.3 V 1. VDD = 5.0 Vdc ± 10%, VSS = 0 Vdc, VDDA/VDDAREF = 5.0 Vdc ± 10%, VSSA = 0 Vdc, VREFH = 5.0 Vdc ± 10% 2. The external system error caused by input leakage current is approximately equal to the product of R source and input current. 3. Source impedances greater than 10 kΩ adversely affect internal RC charging time during input sampling. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 281 18.8 5.0-Vdc ± 10% Serial Peripheral Interface (SPI) Timing Num(1) Characteristic(2) Symbol Min Max Unit Operating frequency(3) Master Slave fBUS(M) fBUS(S) fBUS/128 dc fBUS/2 fBUS MHz 1 Cycle time Master Slave tCYC(M) tCYC(S) 2 1 128 — tCYC 2 Enable lead time tLEAD 15 — ns 3 Enable lag time tLAG 15 — ns 4 Clock (SCK) high time Master Slave tW(SCKH)M tW(SCKH)S 100 50 — — ns 5 Clock (SCK) low time Master Slave tW(SCKL)M tW(SCKL)S 100 50 — — ns 6 Data setup time, inputs Master Slave tSU(M) tSU(S) 45 5 — — ns 7 Data hold time, inputs Master Slave tH(M) tH(S) 0 15 — — ns Access time, slave(4) CPHA = 0 CPHA = 1 tA(CP0) tA(CP1) 0 0 40 20 ns tDIS — 25 ns 8 9 Slave disable time, hold time to high-impedance state 10 Enable edge lead time to data valid(5) Master Slave tEV(M) tEV(S) — — 10 40 ns 11 Enable edge lead time to data invalid Master Slave tEI(M) tEI(S) 0 5 — — ns 12 Data valid Master (before capture edge) tV(M) 90 --- ns 13 Data hold time (outputs) Master (after capture edge) tHO(M) 100 --- ns 1. Item numbers refer to dimensions in Figure 18-2 and Figure 18-3. 2. All timing is shown with respect to 30% VDD and 70% VDD, unless otherwise noted; assumes 100 pF load on all SPI pins. 3. fBUS = the currently active bus frequency for the microcontroller. 4. Time to data active from high-impedance state 5. With 100 pF on all SPI pins Data Sheet 282 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor SS (INPUT) SS pin of master held high. 1 SCK (CPOL = 0) (OUTPUT) NOTE SCK (CPOL = 1) (OUTPUT) NOTE 5 4 5 4 6 MISO (INPUT) MSB IN BITS 6–1 10 11 MOSI (OUTPUT) MASTER MSB OUT 7 LSB IN 10 11 BITS 6–1 MASTER LSB OUT 13 12 NOTE: This first clock edge is generated internally, but is not seen at the SCK pin. a) SPI Master Timing (CPHA = 0) SS (INPUT) SS pin of master held high. 1 SCK (CPOL = 0) (OUTPUT) SCK (CPOL = 1) (OUTPUT) 5 NOTE 4 5 NOTE 4 6 MISO (INPUT) MSB IN 10 MOSI (OUTPUT) BITS 6–1 11 MASTER MSB OUT 12 7 LSB IN 10 BITS 6–1 11 MASTER LSB OUT 13 NOTE: This last clock edge is generated internally, but is not seen at the SCK pin. b) SPI Master Timing (CPHA = 1) Figure 18-2. SPI Master Timing MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 283 SS (INPUT) 3 1 SCK (CPOL = 0) (INPUT) 11 5 4 2 SCK (CPOL = 1) (INPUT) 5 4 9 8 MISO (INPUT) SLAVE MSB OUT 6 MOSI (OUTPUT) BITS 6–1 7 NOTE 11 11 10 MSB IN SLAVE LSB OUT BITS 6–1 LSB IN NOTE: Not defined but normally MSB of character just received a) SPI Slave Timing (CPHA = 0) SS (INPUT) 1 SCK (CPOL = 0) (INPUT) 5 4 2 3 SCK (CPOL = 1) (INPUT) 8 MISO (OUTPUT) MOSI (INPUT) 5 4 10 NOTE 9 SLAVE MSB OUT 6 7 BITS 6–1 11 10 MSB IN SLAVE LSB OUT BITS 6–1 LSB IN NOTE: Not defined but normally LSB of character previously transmitted b) SPI Slave Timing (CPHA = 1) Figure 18-3. SPI Slave Timing Data Sheet 284 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 18.9 CGM Operating Conditions Characteristic Symbol Min Typ Max Unit Crystal reference frequency fxclk 1 — 8 MHz Range nominal multiplier fnom — 4.9152 — MHz 4.9152 — 32.8 MHz 4.9152 — 16.4 MHz VCO center-of-range frequency(1) fvrs Medium voltage VCO center-of-range frequency VCO frequency multiplier N 1 — 15 — VCO center-of-range multiplier L 1 — 15 — fvclk fvrsmin — fvrsmax MHz VCO operating frequency 1. 5.0 V ± 10% VDD only 18.10 CGM Component Information Characteristic Symbol Min Typ Max Unit fxclk 1 4.9152 8 MHz Crystal load capacitance(2) CL — 20 — pF Crystal fixed capacitance(2) C1 — 2 × CL — pF Crystal tuning capacitance(2) C2 — 2 × CL — pF Feedback bias resistor RB — 1 10 MΩ Series resistor(3) RS 0 — 3.3 kΩ Filter capacitor CF — CFact × (VDDA/fxclk) — nF Cbyp — 0.1 — µF Crystal (X1) frequency (MHz)(1) Bypass capacitor(4) 1. Fundamental mode crystals only 2. Consult crystal manufacturer’s data. 3. Not required 4. Cbyp must provide low AC impedance from f = fxclk/100 to 100 × fvclk, so series resistance must be considered. MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 285 18.11 CGM Acquisition/Lock Time Information Description Symbol Min Typ Max Unit Filter capacitor multiply factor Cfact — 0.0154 — F/sV Acquisition mode time factor Kacq — 0.1135 — V Tracking mode time factor Ktrk — 0.0174 — V Manual mode time to stable(1) tacq — 8 × V DDA ----------------------------f xclk × K acq — s tal — 4 × V DDA --------------------------f xclk × K trk — s tLock — tacq + tal — s Tracking mode entry frequency tolerance ∆trk 0 — ± 3.6% — Acquisition mode entry frequency tolerance ∆acq ±6.3 — ± 7.2% — LOCK entry frequency tolerance ∆Lock 0 — ± 0.9% — LOCK exit frequency tolerance ∆unl ±0.9 — ± 1.8% — Reference cycles per acquisition mode measurement nacq — 32 — Cyc Reference cycles per tracking mode measurement ntrk — 128 — Cyc Automatic mode time to stable(1) tacq n acq ----------f xclk 8 × V DDA ----------------------------f xclk × K acq — s tal n trk ---------f xclk 4 × V DDA --------------------------f xclk × K trk — s tLock — tacq + tal — s fJ 0 — Manual stable to lock time(1) Manual acquisition time Automatic stable to lock time(1) Automatic lock time % % ± fcrys × PLL jitter(2) 0.025% × 2PN/4 Hz 1. If CF chosen correctly 2. Deviation of average bus frequency over 2 ms, N = VCO frequency multiplier Data Sheet 286 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 18.12 Timer Module Characteristics Characteristic Symbol Min Max Unit tTH, tTL 2 — tCYC tTLTL Note(1) — tCYC tTCL, tTCH tCYC + 5 — ns Timer input capture pulse width Timer input capture period Timer input clock pulse width 1. The minimum period is the number of cycles it takes to execute the interrupt service routine plus 1 tCYC. tTLTL tTH INPUT CAPTURE RISING EDGE tTLTL tTL INPUT CAPTURE FALLING EDGE tTLTL tTH tTL INPUT CAPTURE BOTH EDGES tTCH TCLK tTCL Figure 18-4. Timer Input Timing 18.13 RAM Characteristics Characteristic RAM data retention voltage MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Symbol Min Max Unit VRDR 1.3 — V Data Sheet 287 18.14 BDLC Transmitter VPW Symbol Timings Characteristic(1), (2) Number Symbol Min Typ Max Unit Passive logic 0 10 tTVP1 62 64 66 µs Passive logic 1 11 tTVP2 126 128 130 µs Active logic 0 12 tTVA1 126 128 130 µs Active logic 1 13 tTVA2 62 64 66 µs Start-of-frame (SOF) 14 tTVA3 198 200 202 µs End-of-data (EOD) 15 tTVP3 198 200 202 µs End-of-frame (EOF) 16 tTV4 278 280 282 µs Inter-frame separator (IFS) 17 tTV6 298 300 302 µs 1. fBDLC = 1.048576 or 1.0 MHz, VDD = 5.0 V ± 10%, VSS = 0 V 2. See Figure 18-5. 18.15 BDLC Receiver VPW Symbol Timings Characteristic(1), (2), (3) Number Symbol Min Typ Max Unit Passive logic 0 10 tTRVP1 34 64 96 µs Passive logic 1 11 tTRVP2 96 128 163 µs Active logic 0 12 tTRVA1 96 128 163 µs Active logic 1 13 tTRVA2 34 64 96 µs Start-of-frame (SOF) 14 tTRVA3 163 200 239 µs End-of-data (EOD) 15 tTRVP3 163 200 239 µs End-of-frame (EOF) 16 tTRV4 239 280 320 µs Break 18 tTRV6 280 — — µs 1. fBDLC = 1.048576 or 1.0 MHz, VDD = 5.0 V ± 10%, VSS = 0 V 2. The receiver symbol timing boundaries are subject to an uncertainty of 1 tBDLC µs due to sampling considerations. 3. See Figure 18-5. Data Sheet 288 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 13 11 1 1 14 10 12 SOF 0 0 15 0 EOD 16 EOF 18 BRK Figure 18-5. BDLC Variable Pulse Width Modulation (VPW) Symbol Timing 18.16 BDLC Transmitter DC Electrical Characteristics Characteristic(1) Symbol Min Max Unit BDTxD output low voltage (IBDTxD = 1.6 mA) VOLTX — 0.4 V BDTxD output high voltage (IBDTx = –800 µA) VOHTX VDD –0.8 — V o o 1. VDD = 5.0 Vdc + 10%, VSS = 0 Vdc, TA = –40 C to +125 C, unless otherwise noted 18.17 BDLC Receiver DC Electrical Characteristics Characteristic(1) Symbol Min Max Unit BDRxD input low voltage VILRX VSS 0.3 x VDD V BDRxD input high voltage VIHRX 0.7 x VDD VDD V BDRxD input low current IILBDRXI –1 +1 µA BDRxD input high current IHBDRX –1 +1 µA 1. VDD = 5.0 Vdc + 10%, VSS = 0 Vdc, TA = –40 oC to +125 oC, unless otherwise noted MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 289 18.18 EEPROM Characteristics Characteristic Symbol Min Typ Max Unit EEPROM programming time per byte AUTO mode Standard mode tEEPGM — 10 0.25 10 — — ms EEPROM erasing time per byte AUTO mode Standard mode tEEBYTE — 10 8.5 10 — — ms EEPROM erasing time per block AUTO mode Standard mode tEEBLOCK — 10 8.5 10 — — ms EEPROM erasing time per bulk AUTO mode Standard mode tEEBULK — 10 8.5 10 — — ms EEPROM programming voltage discharge period (standard mode only) tEEFPV 100 100 — µs Number of programming operations to the same EERPROM byte before erase(1) — — — 8 — EEPROM endurance(2) — 10K >100K — Cycles EEPROM data retention(3) — 15 >100 — Years 1. Programming a byte more times than the specified maximum may affect the data integrity of that byte. The byte must be erased before it can be programming again. 2. Typical endurance was evaluated for this product family. For additional information on how Freescale defines Typical Endurance, please refer to Engineering Bulletin EB619. 3. Typical data retention values are based on intrinsic capability of the technology measured at high temperature and de-rated to 25°C using the Arrhenius equation. For additional information on how Freescale defines Typical Data Retention, please refer to Engineering Bulletin EB618. Data Sheet 290 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet — MC68HC08AS32A — Section 19. Ordering Information and Mechanical Specifications 19.1 Introduction This section provides ordering information for the MC68HC08AS32A along with the dimensions for: • 52-pin plastic leaded chip carrier (PLCC) • 64-pin quad flat pack (QFP) The following figures show the latest package drawings at the time of this publication. To make sure that you have the latest package specifications, contact your local Freescale sales office 19.2 MC Order Numbers These part numbers are generic numbers only. To place an order, ROM code must be submitted to the ROM Processing Center (RPC). Table 19-1. MC Order Numbers MC Order Number Operating Temperature Range MC68HC08AS32AFN(1) 0°C to + 70°C MC68HC08AS32CAFN –40°C to + 85°C MC68HC08AS32VAFN –40°C to + 105°C MC68HC08AS32AFU(2) 0°C to + 70°C MC68HC08AS32ACFU –40°C to + 85°C MC68HC08AS32AVFU –40°C to + 105°C 1. FN = plastic leaded chip carrier 2. FU = quad flat pack MC68HC08AS32AXXX FAMILY PACKAGE DESIGNATOR TEMPERATURE RANGE Figure 19-1. Device Numbering System MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor Data Sheet 291 19.3 52-Pin Plastic Leaded Chip Carrier Package (Case 778) 0.007 (0.18) B Y BRK –N– M T L–M 0.007 (0.18) U M S N S T L–M S N S D Z –M– –L– W D 52 1 V A 0.007 (0.18) M T L–M S N S R 0.007 (0.18) M T L–M S N S E C 0.004 (0.100) –T– SEATING J VIEW S G PLANE G1 0.010 (0.25) T L–M S H N S 0.007 (0.18) M T L–M S N S K1 K F VIEW S Data Sheet 292 S T L–M S N S VIEW D–D Z S G1 0.010 (0.25) X 0.007 (0.18) M T L–M S N S NOTES: 1. DATUMS –L–, –M–, AND –N– DETERMINED WHERE TOP OF LEAD SHOULDER EXITS PLASTIC BODY AT MOLD PARTING LINE. 2. DIMENSION G1, TRUE POSITION TO BE MEASURED AT DATUM –T–, SEATING PLANE. 3. DIMENSIONS R AND U DO NOT INCLUDE MOLD FLASH. ALLOWABLE MOLD FLASH IS 0.010 (0.250) PER SIDE. 4. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 5. CONTROLLING DIMENSION: INCH. 6. THE PACKAGE TOP MAY BE SMALLER THAN THE PACKAGE BOTTOM BY UP TO 0.012 (0.300). DIMENSIONS R AND U ARE DETERMINED AT THE OUTERMOST EXTREMES OF THE PLASTIC BODY EXCLUSIVE OF MOLD FLASH, TIE BAR BURRS, GATE BURRS AND INTERLEAD FLASH, BUT INCLUDING ANY MISMATCH BETWEEN THE TOP AND BOTTOM OF THE PLASTIC BODY. 7. DIMENSION H DOES NOT INCLUDE DAMBAR PROTRUSION OR INTRUSION. THE DAMBAR PROTRUSION(S) SHALL NOT CAUSE THE H DIMENSION TO BE GREATER THAN 0.037 (0.940). THE DAMBAR INTRUSION(S) SHALL NOT CAUSE THE H DIMENSION TO BE SMALLER THAN 0.025 (0.635). DIM A B C E F G H J K R U V W X Y Z G1 K1 INCHES MIN MAX 0.785 0.795 0.785 0.795 0.165 0.180 0.090 0.110 0.013 0.019 0.050 BSC 0.026 0.032 0.020 ––– 0.025 ––– 0.750 0.756 0.750 0.756 0.042 0.048 0.042 0.048 0.042 0.056 ––– 0.020 2_ 10 _ 0.710 0.730 0.040 ––– MILLIMETERS MIN MAX 19.94 20.19 19.94 20.19 4.20 4.57 2.29 2.79 0.33 0.48 1.27 BSC 0.66 0.81 0.51 ––– 0.64 ––– 19.05 19.20 19.05 19.20 1.07 1.21 1.07 1.21 1.07 1.42 ––– 0.50 2_ 10 _ 18.04 18.54 1.02 ––– MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor 19.4 64-Pin Quad Flat Pack (Case 840B) L 48 33 S D S S V 0.20 (0.008) M B DETAIL A H A–B C L P B M –B– B 0.20 (0.008) –A– C A–B H S D 32 0.05 (0.002) A–B D 49 –A–, –B–, –D– DETAIL A 64 17 1 F 16 –D– A H A–B C S D S 0.05 (0.002) A–B S C A–B 0.20 (0.008) M H S D S 0.20 (0.008) M J N E BASE METAL D M DETAILC 0.20 (0.008) 0.02 (0.008) M C A–B S D S SECTION B-B C –H– –C– SEATING PLANE M H 0.10 (0.004) (0.004) 0.01 G U T R –H– DATUM PLANE DATUM PLANE Q K W X DETAIL C MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor NOTES: 1. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 2. CONTROLLING DIMENSION: MILLIMETER. 3. DATUM PLANE –H– IS LOCATED AT BOTTOM OF LEAD AND IS COINCIDENT WITH THE LEAD WHERE THE LEAD EXITS THE PLASTIC BODY AT THE BOTTOM OF THE PARTING LINE. 4. DATUMS –A–, –B– AND –D– TO BE DETERMINED AT DATUM PLANE –H–. 5. DIMENSIONS S AND V TO BE DETERMINED AT SEATING PLANE –C–. 6. DIMENSIONS A AND B DO NOT INCLUDE MOLD PROTRUSION. ALLOWABLE PROTRUSION IS 0.25 (0.010) PER SIDE. DIMENSIONS A AND B DO INCLUDE MOLD MISMATCH AND ARE DETERMINED AT DATUM PLANE –H–. 7. DIMENSION D DOES NOT INCLUDE DAMBAR PROTRUSION. ALLOWABLE DAMBAR PROTRUSION SHALL BE 0.08 (0.003) PER SIDE. TOTAL IN EXCESS OF THE D DIMENSION AT MAXIMUM MATERIAL CONDITION. DAMBAR CANNOT BE LOCATED ON THE LOWER RADIUS OR THE FOOT. DIM A B C D E F G H J K L M N P Q R S T U V W X MILLIMETERS MIN MAX 13.90 14.10 13.90 14.10 2.15 2.45 0.30 0.45 2.00 2.40 0.30 0.40 0.80 BSC ––– 0.25 0.13 0.23 0.65 0.95 12.00 REF 5_ 10_ 0.13 0.17 0.40 BSC 0_ 7_ 0.13 0.30 16.95 17.45 0.13 ––– 0_ ––– 16.95 17.45 0.35 0.45 1.6 REF INCHES MIN MAX 0.547 0.555 0.547 0.555 0.085 0.096 0.012 0.018 0.079 0.094 0.012 0.016 0.031 BSC ––– 0.010 0.005 0.009 0.026 0.037 0.472 REF 5_ 10_ 0.005 0.007 0.016 BSC 0_ 7_ 0.005 0.012 0.667 0.687 0.005 ––– 0_ ––– 0.667 0.687 0.014 0.018 0.063 REF Data Sheet 293 Data Sheet 294 MC68HC08AS32A — Rev. 1.1 Freescale Semiconductor How to Reach Us: Home Page: www.freescale.com E-mail: [email protected] USA/Europe or Locations Not Listed: Freescale Semiconductor Technical Information Center, CH370 1300 N. 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