56F8036 Data Sheet Preliminary Technical Data 56F8000 16-bit Digital Signal Controllers MC56F8036 Rev. 3 01/2007 freescale.com Document Revision History Version History Description of Change Rev. 0 Initial public release. Rev. 1 • In Table 10-4, added an entry for flash data retention with less than 100 program/erase cycles (minimum 20 years). • In Table 10-6, changed the device clock speed in STOP mode from 8MHz to 4MHz. • In Table 10-12, changed the typical relaxation oscillator output frequency in Standby mode from 400kHz to 200kHz. • Changed input propagation delay values in Table 10-21 as follows: Old values: 1 μs typical, 2 μs maximum New values: 35 ns typical, 45 ns maximum Rev. 2 In Table 10-20, changed the maximum ADC internal clock frequency from 8MHz to 5.33MHz. Rev. 3 Added the following note to the description of the TMS signal in Table 2-3: Note: Always tie the TMS pin to VDD through a 2.2K resistor. Please see http://www.freescale.com for the most current Data Sheet revision. 56F8036 Data Sheet, Rev. 3 2 Freescale Semiconductor Preliminary 56F8036 General Description • Up to 32 MIPS at 32MHz core frequency • One Queued Serial Peripheral Interface (QSPI) • DSP and MCU functionality in a unified, C-efficient architecture • Freescale’s scalable controller area network (MSCAN) 2.0 A/B Module • 64KB (32K x 16) Program Flash • One 16-bit Quad Timer clocked at up to 96MHz • 8KB (4K x 16) Unified Data/Program RAM • One Inter-Integrated Circuit (I2C) port • One 6-channel PWM module clocked at up to 96MHz • Computer Operating Properly (COP)/Watchdog • Two independent 5-channel 12-bit high-speed Analog-to-Digital Converters (ADCs) • On-Chip Relaxation Oscillator • Integrated Power-On Reset (POR) and Low-Voltage Interrupt (LVI) module • Two internal 12-bit Digital-to-Analog Converters (DACs) • Two Analog Comparators • JTAG/Enhanced On-Chip Emulation (OnCE™) for unobtrusive, real-time debugging • Three Programmable Interval Timers (PITs) • Up to 39 GPIO lines • One Queued Serial Communication Interface (QSCI) with LIN slave functionality • 48-pin LQFP Package RESET or GPIOA 4 JTAG/EOnCE Port or GPIOD PWM or TMRA or CMP or GPIOA 11 VSS 2 3 Digital Reg VDDA VSSA Analog Reg Low-Voltage Supervisor 16-Bit 56800E Core Data ALU 16 x 16 + 36 -> 36-Bit MAC Three 16-bit Input Registers Four 36-bit Accumulators Bit Manipulation Unit PAB PDB CDBR CDBW DAC 5 VDD 2 Address Generation Unit Program Controller and Hardware Looping Unit 5 VCAP AD0 Memory ADC or CMP or GPIOC R/W Control Program Memory 32K x 16 Flash AD1 Unified Data / Program RAM 4K x 16 Programmable Interval Timer I2C or CAN or CMP or GPIOB 4 XDB2 XAB1 XAB2 System Bus Control PAB PDB CDBR CDBW IPBus Bridge (IPBB) QSPI or PWM or I2C or TMRA or GPIOB 4 QSCI or PWM or I2C or TMRA or GPIOB COP/ Watchdog Interrupt Controller System Integration Module P O R O Clock S Generator* C XTAL, CLKIN, or GPIOD EXTAL or GPIOD *Includes On-Chip Relaxation Oscillator 3 56F8036 Block Diagram 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 3 56F8036 Data Sheet Table of Contents Part 1: Overview . . . . . . . . . . . . . . . . . . . . . . . 5 1.1. 1.2. 1.3. 1.4. 1.5. 1.6. 56F8036 Features . . . . . . . . . . . . . . . . . . . . . 5 56F8036 Description . . . . . . . . . . . . . . . . . . . 7 Award-Winning Developme . nt Environment 8 Architecture Block Diagram 8 Product Documentation . . . . . . . . . . . . . . . 16 Data Sheet Conventions. . . . . . . . . . . . . . . 16 Part 2: Signal/Connection Descriptions . . 17 2.1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 17 2.2. 56F8036 Signal Pins . . . . . . . . . . . . . . . . . 21 Part 3: OCCS . . . . . . . . . . . . . . . . . . . . . . . . . 33 3.1. 3.2. 3.3. 3.4. 3.5. 3.6. 3.7. Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 Operating Modes . . . . . . . . . . . . . . . . . . . . 33 Internal Clock Source . . . . . . . . . . . . . . . . . 34 Crystal Oscillator . . . . . . . . . . . . . . . . . . . . . 34 Ceramic Resonator . . . . . . . . . . . . . . . . . . . 35 External Clock Input - Crystal Oscillator Option. . . . . . . . . . . . . . 35 3.8. Alternate External Clock Input . . . . . . . . . . . 36 Part 4: Memory Maps . . . . . . . . . . . . . . . . . 36 4.1. 4.2. 4.3. 4.4. 4.5. 4.6. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 36 Interrupt Vector Table . . . . . . . . . . . . . . . . . 37 Program Map . . . . . . . . . . . . . . . . . . . . . . . . 39 Data Map . . . . . . . . . . . . . . . . . . . . . . . . . . 40 EOnCE Memory Map . . . . . . . . . . . . . . . . . 41 Peripheral Memory-Mapped Registers . . . . 42 Part 5: Interrupt Controller (ITCN) . . . . . . . 56 5.1. 5.2. 5.3. 5.4. 5.5. 5.6. 5.7. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 56 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . 56 Functional Description . . . . . . . . . . . . . . . . . 56 Block Diagram . . . . . . . . . . . . . . . . . . . . . . 58 Operating Modes . . . . . . . . . . . . . . . . . . . . . 59 Register Descriptions . . . . . . . . . . . . . . . . . 59 Resets . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78 Part 6: System Integration Module (SIM) . . 79 6.1. 6.2. 6.3. 6.4. 6.5. 6.6. 6.7. 6.8. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 79 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . 79 Register Descriptions . . . . . . . . . . . . . . . . . 81 Clock Generation Overview . . . . . . . . . . . . 107 Power-Saving Modes . . . . . . . . . . . . . . . . 108 Resets . . . . . . . . . . . . . . . . . . . . . . . . . . . 109 Clocks . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110 Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . 112 Part 8: General Purpose Input/Output (GPIO) . . . . . . . . . . . . 114 8.1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 114 8.2. Configuration . . . . . . . . . . . . . . . . . . . . . . . 114 8.3. Reset Values . . . . . . . . . . . . . . . . . . . . . . . 117 Part 9: Joint Test Action Group (JTAG) . . 122 9.1. 56F8036 Informatio . . . . . . . . . . . . . . . . .n 122 Part 10: Specifications . . . . . . . . . . . . . . . .122 10.1. General Characteristics . . . . . . . . . . . . . . 122 10.2. DC Electrical Characteristics . . . . . . . . . . 126 10.3. AC Electrical Characteristics . . . . . . . . . . 129 10.4. Flash Memory Characteristics . . . . . . . . . 129 10.5. External Clock Operation Timing . . . . . . . 130 10.6. Phase Locked Loop Timing . . . . . . . . . . . 131 10.7. Relaxation Oscillator Timing. . . . . . . . . . . 131 10.8. Reset, Stop, Wait, Mode Select, and Interrupt Timing . . . . . . . . . . . . . . 133 10.9. Serial Peripheral Interface (SPI) Timing . 134 10.10. Quad Timer Timing. . . . . . . . . . . . . . . . . 137 10.11. Serial Communication Interface (SCI) Timing. . . . . . . . . . . . . . . . . 138 10.12. Freescale’s Scalable Controller Area Network (MSCAN) Timing . . 139 10.13. Inter-Integrated Circuit Interface (I2C) Timing . . . . . . . . . . . . . . . . 139 10.14. JTAG Timing. . . . . . . . . . . . . . . . . . . . . . 141 10.15. Analog-to-Digital Converter (ADC) Parameters . . . . . . . . . . . . 142 10.16. Equivalent Circuit for ADC Inputs . . . . . . 143 10.17. Comparator (CMP) Parameters . . . . . . . 143 10.18. Digital-to-Analog Converter (DAC) Parameters . . . . . . . . . . . 144 10.19. Power Consumption . . . . . . . . . . . . . . . 145 Part 11: Packaging . . . . . . . . . . . . . . . . . . .147 11.1. 56F8036 Package and Pin-Out Information . . . . . . . . . . . 147 Part 12: Design Considerations . . . . . . . . 150 12.1. Thermal Design Considerations . . . . . . . . 150 12.2. Electrical Design Considerations . . . . . . . 151 Part 13: Ordering Information . . . . . . . . . . 152 Part 14: Appendix. . . . . . . . . . . . . . . . . . . . 153 Part 7: Security Features . . . . . . . . . . . . . 112 7.1. Operation with Security Enabled . . . . . . . 112 7.2. Flash Access Lock and Unlock Mechanisms . . . . . . . . . . 113 56F8036 Data Sheet, Rev. 3 4 Freescale Semiconductor Preliminary 56F8036 Features Part 1 Overview 1.1 56F8036 Features 1.1.1 • • • • • • • • • • • • • • 1.1.2 • • • Digital Signal Controller Core Efficient 16-bit 56800E family Digital Signal Controller (DSC) engine with dual Harvard architecture As many as 32 Million Instructions Per Second (MIPS) at 32MHz core frequency Single-cycle 16 × 16-bit parallel Multiplier-Accumulator (MAC) Four 36-bit accumulators, including extension bits 32-bit arithmetic and logic multi-bit shifter Parallel instruction set with unique DSP addressing modes Hardware DO and REP loops Three internal address buses Four internal data buses Instruction set supports both DSP and controller functions Controller-style addressing modes and instructions for compact code Efficient C compiler and local variable support Software subroutine and interrupt stack with depth limited only by memory JTAG/Enhanced On-Chip Emulation (OnCE) for unobtrusive, processor speed-independent, real-time debugging Memory Dual Harvard architecture permits as many as three simultaneous accesses to program and data memory Flash security and protection that prevent unauthorized users from gaining access to the internal Flash On-chip memory — 64KB of Program Flash — 8KB of Unified Data/Program RAM • 1.1.3 • EEPROM emulation capability using Flash Peripheral Circuits for 56F8036 One multi-function six-output Pulse Width Modulator (PWM) module — Up to 96MHz PWM operating clock — 15 bits of resolution — Center-aligned and edge-aligned PWM signal mode — Four programmable fault inputs with programmable digital filter — Double-buffered PWM registers — Each complementary PWM signal pair allows selection of a PWM supply source from: – PWM generator 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 5 – External GPIO – Internal timers – Analog comparator outputs – ADC conversion result which compares with values of ADC high- and low-limit registers to set PWM output • Two independent 12-bit Analog-to-Digital Converters (ADCs) — 2 x 5 channel inputs — Supports both simultaneous and sequential conversions — ADC conversions can be synchronized by both PWM and timer modules — Sampling rate up to 2.67MSPS — 16-word result buffer registers • Two internal 12-bit Digital-to-Analog Converters (DACs) — 2 microsecond settling time when output swing from rail to rail — Automatic waveform generation generates square, triangle and sawtooth waveforms with programmable period, update rate, and range • One 16-bit multi-purpose Quad Timer module (TMR) — Up to 96MHz operating clock — Eight independent 16-bit counter/timers with cascading capability — Each timer has capture and compare capability — Up to 12 operating modes • One Queued Serial Communication Interface (QSCI) with LIN Slave functionality — Full-duplex or single-wire operation — Two receiver wake-up methods: – Idle line – Address mark — Four-bytes-deep FIFOs are available on both transmitter and receiver • One Queued Serial Peripheral Interfaces (QSPI) — Full-duplex operation — Master and slave modes — Four-words-deep FIFOs available on both transmitter and receiver — Programmable Length Transactions (2 to 16 bits) • One Inter-Integrated Circuit (I2C) port — Operates up to 400kbps — Supports both master and slave operation — Supports both 10-bit address mode and broadcasting mode • One Freescale scalable controller area network (MSCAN) module 56F8036 Data Sheet, Rev. 3 6 Freescale Semiconductor Preliminary 56F8036 Description — Fully compliant with CAN protocol - Version 2.0 A/B — Supports standard and extended data frames — Supports data rate up to 1Mbps — Five receive buffers and three transmit buffers • • Three 16-bit Programmable Interval Timers (PITs) Two analog Comparators (CMPs) — Selectable input source includes external pins, DACs — Programmable output polarity — Output can drive Timer input, PWM fault input, PWM source, external pin output and trigger ADCs — Output falling and rising edge detection able to generate interrupts • • • • • Computer Operating Properly (COP)/Watchdog timer capable of selecting different clock sources Up to 39 General-Purpose I/O (GPIO) pins with 5V tolerance Integrated Power-On Reset (POR) and Low-Voltage Interrupt (LVI) module Phase Lock Loop (PLL) provides a high-speed clock to the core and peripherals Clock sources: — On-chip relaxation oscillator — External clock: crystal oscillator, ceramic resonator and external clock source • 1.1.4 • • • • • JTAG/EOnCE debug programming interface for real-time debugging Energy Information Fabricated in high-density CMOS with 5V tolerance On-chip regulators for digital and analog circuitry to lower cost and reduce noise Wait and Stop modes available ADC smart power management Each peripheral can be individually disabled to save power 1.2 56F8036 Description The 56F8036 is a member of the 56800E core-based family of Digital Signal Controllers (DSCs). It combines, on a single chip, the processing power of a DSP and the functionality of a microcontroller with a flexible set of peripherals to create an extremely cost-effective solution. Because of its low cost, configuration flexibility, and compact program code, the 56F8036 is well-suited for many applications. The 56F8036 includes many peripherals that are especially useful for industrial control, motion control, home appliances, general purpose inverters, smart sensors, fire and security systems, switched-mode power supply, power management, and medical monitoring applications. The 56800E core is based on a dual Harvard-style architecture consisting of three execution units operating in parallel, allowing as many as six operations per instruction cycle. The MCU-style programming model and optimized instruction set allow straightforward generation of efficient, compact DSP and control code. The instruction set is also highly efficient for C compilers to enable rapid 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 7 development of optimized control applications. The 56F8036 supports program execution from internal memories. Two data operands can be accessed from the on-chip data RAM per instruction cycle. The 56F8036 also offers up to 39 General Purpose Input/Output (GPIO) lines, depending on peripheral configuration. The 56F8036 Digital Signal Controller includes 64KB of Program Flash and 8KB of Unified Data/Program RAM. Program Flash memory can be independently bulk erased or erased in pages. Program Flash page erase size is 512 Bytes (256 Words). A full set of programmable peripherals—PWM, ADCs, QSCI, QSPI, I2C, PITs, Quad Timers, DACs, and analog comparators—supports various applications. Each peripheral can be independently shut down to save power. Any pin in these peripherals can also be used as General Purpose Input/Outputs (GPIOs). 1.3 Award-Winning Development Environment Processor ExpertTM (PE) provides a Rapid Application Design (RAD) tool that combines easy-to-use component-based software application creation with an expert knowledge system. The CodeWarrior Integrated Development Environment is a sophisticated tool for code navigation, compiling, and debugging. A complete set of evaluation modules (EVMs), demonstration board kit and development system cards will support concurrent engineering. Together, PE, CodeWarrior and EVMs create a complete, scalable tools solution for easy, fast, and efficient development. 1.4 Architecture Block Diagram The 56F8036’s architecture is shown in Figures 1-1, 1-2, 1-3, 1-4, 1-5, 1-6, and 1-7. Figure 1-1 illustrates how the 56800E system buses communicate with internal memories and the IPBus Bridge and the internal connections between each unit of the 56800E core. Figure 1-2 shows the peripherals and control blocks connected to the IPBus Bridge. Figures 1-3, 1-4, 1-5, 1-6 and 1-7 detail how the device’s I/O pins are muxed. Please see Part 2, Signal/Connection Descriptions, for information about which signals are multiplexed with those of other peripherals. 1.4.1 PWM, TMR and ADC Connections Figure 1-3 shows the over- and under-voltage connections from the ADC to the PWM and the connections to the PWM from the TMR and GPIO. These signals can control the complementary PWM outputs in a similar manner to the over- and under-voltage control signals. See the 56F802X and 56F803XPeripheral Reference Manual for additional information. The PWM_reload_sync output can be connected to Timer A’s (TMRA) Channel 3 input; TMRA’s Channels 2 and 3 outputs are connected to the ADC sync inputs. TMRA Channel 3 output is connected to SYNC0 and TMRA Channel 2 is connected to SYNC1. SYNC0 is the master ADC sync input that is used to trigger ADCA and ADCB in sequence and parallel mode. SYNC1 is used to trigger ADCB in parallel independent mode. These are controlled by bits in the SIM Control Register; see Section 6.3.1. 56F8036 Data Sheet, Rev. 3 8 Freescale Semiconductor Preliminary Architecture Block Diagram DSP56800E Core Program Control Unit PC LA LA2 HWS0 HWS1 FIRA OMR SR LC LC2 FISR Address Generation Unit (AGU) Instruction Decoder Interrupt Unit ALU1 ALU2 R0 R1 R2 R3 R4 R5 N M01 N3 Looping Unit Program Memory SP XAB1 XAB2 PAB PDB Data / Program RAM CDBW CDBR XDB2 A2 B2 C2 D2 BitManipulation Unit Enhanced OnCE™ JTAG TAP Y A1 B1 C1 D1 Y1 Y0 X0 MAC and ALU A0 B0 C0 D0 IPBUS Interface Data Arithmetic Logic Unit (ALU) Multi-Bit Shifter Figure 1-1 56800E Core Block Diagram 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 9 To/From IPBus Bridge OCCS (ROSC / PLL / OSC) Interrupt Controller Low-Voltage Interrupt GPIO A POR & LVI GPIO B System POR GPIO C SIM GPIO D RESET (Muxed with GPIOA7) COP Reset COP IPBus (Continues on Figure 1-3) Figure 1-2 Peripheral Subsystem 56F8036 Data Sheet, Rev. 3 10 Freescale Semiconductor Preliminary Architecture Block Diagram To/From IPBus Bridge IPBus INTC SYNC PIT0 MSTR_CNT_EN 3 MSTR_CNT_EN DAC SYNC on Figure 1-5 SYNC PIT1 MSTR_CNT_EN SYNC PIT2 2 3 Sync0, Sync1 Over/Under Limits SYNC0, SYNC1 on Figure 1-7 LIMIT on Figure 1-6 ANA0 ANA0 on Figure 1-5 GPIOC2 ANA2 (VREFHA) GPIOC3 ANA3 (VREFLA) GPIOC8 ANA4 GPIOC1 ANA1 ADC ANB0 ANB0 on Figure 1-5 ANB2 (VREFHA) ANB3 (VREFLB) ANB4 ANB1 GPIOC6 GPIOC7 GPIOC12 GPIOC5 Figure 1-3 56F8036 I/O Pin-Out Muxing (Part 1/5) 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 11 To/From IPBus Bridge QSCI0 RXD0, TXD0 2 GPIOB6 - 7 TA2, TA3 on Figure 1-7 MISO0, MOSI0 QSPI0 SCLK0, SS0 2 2 2 I2C SCL, SDA GPIOB2 - 3 GPIOB0 - 1 2 2 2 GPIOB8 - 9 MSCAN CANTX, CANRX 2 IPBus Figure 1-4 56F8036 I/O Pin-Out Muxing (Part 2/5) 56F8036 Data Sheet, Rev. 3 12 Freescale Semiconductor Preliminary Architecture Block Diagram To/From IPBus Bridge FAULT1 on Figure 1-6 TA2 on Figure 1-7 CMP_IN1 CMP_IN3 GPIOA8 CMPAI1 GPIOC0 CMPAI3 CMPA CMP_OUT CMP_IN2 Export Import CMPAO on Figure 1-6, Figure 1-7 GPIOA10 CMPAI2 ANA0 on Figure 1-3 GPIOB10 DAC0 2 3 TA0o, TA1o on Figure 1-7 DAC SYNC on Figure 1-3 RELOAD on Figure 1-6 DAC1 GPIOB11 ANB0 on Figure 1-3 Import Export CMP_IN2 CMP_OUT GPIOA11 CMPBI2 CMPBO on Figure 1-6, Figure 1-7 CMPB CMP_IN3 CMP_IN1 GPIOC4 CMPBI3 CMPBI1 TA3 on Figure 1-7 GPIOA9 FAULT2 on Figure 1-6 IPBus Figure 1-5 56F8036 I/O Pin-Out Muxing (Part 3/5) 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 13 To/From IPBus Bridge TA0 on Figure 1-7 GPIOA6 2 TA2 - 3 on Figure 1-7 GPIOA0 - 3 4 PWM0 - 3 FAULT0 GPIOA4 - 5 2 PWMA4 - 5 1 2 PWM FAULT1 FAULT1 on Figure 1-5 FAULT2 RELOAD PSRC0 - 1 1 FAULT3 FAULT2 on Figure 1-5 TA1 on Figure 1-7 RELOAD on Figure 1-7, Figure 1-5 IPBus GPIOB5 CMPAO on Figure 1-5 CMPBO on Figure 1-5 3 2 3 3 GPIOB2 - 3 on Figure 1-4 LIMIT on Figure 1-3 TA0o, TA2o, TA3 o on Figure 1-3 Figure 1-6 56F8036 I/O Pin-Out Muxing (Part 4/5) 56F8036 Data Sheet, Rev. 3 14 Freescale Semiconductor Preliminary Architecture Block Diagram To/From IPBus Bridge TA0o on Figure 1-6 (PWM) TA0 on Figure 1-6 (GPIOA6) T0o T0i T1o T1i TA1 on Figure 1-6 (GPIOB5) CMPAO on Figure 1-6 (CMPA) SYNC1 on Figure 1-3 (ADC) TMRA TA2o on Figure 1-6 (PWM) TA2 on Figure 1-6 (GPIOA4) T2o TA2 on Figure 1-5 (GPIOA8) T2i TA2 on Figure 1-4 (GPIOB2) CMPBO on Figure 1-6 (CMPB) SYNC0 on Figure 1-3 (ADC) TA3o on Figure 1-6 (PWM) TA2 on Figure 1-6 (GPIOA5) T3o TA3 on Figure 1-5 (GPIOA9) T3i TA2 on Figure 1-4 (GPIOB3) RELOAD on Figure 1-6 (PWM) IPBus Figure 1-7 56F8036 I/O Pin-Out Muxing (Part 5/5) 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 15 1.5 Product Documentation The documents listed in Table 1-1 are required for a complete description and proper design with the 56F8036. Documentation is available from local Freescale distributors, Freescale Semiconductor sales offices, Freescale Literature Distribution Centers, or online at: http://www.freescale.com Table 1-1 56F8036 Chip Documentation Topic Description Order Number DSP56800E Reference Manual Detailed description of the 56800E family architecture, 16-bit Digital Signal Controller core processor, and the instruction set DSP56800ERM 56F802X and 56F803XPeripheral Reference Manual Detailed description of peripherals of the 56F802x and 56F803x family of devices MC56F80xxRM 56F802x and 56F803x Serial Bootloader User Guide Detailed description of the Serial Bootloader in the 56F801x family of devices 56F801xBLUG 56F8036 Technical Data Sheet Electrical and timing specifications, pin descriptions, and package descriptions (this document) MC56F8036 56F8036 Errata Details any chip issues that might be present MC56F8036E 1.6 Data Sheet Conventions This data sheet uses the following conventions: OVERBAR This is used to indicate a signal that is active when pulled low. For example, the RESET pin is active when low. “asserted” A high true (active high) signal is high or a low true (active low) signal is low. “deasserted” A high true (active high) signal is low or a low true (active low) signal is high. Examples: Signal/Symbol Logic State Signal State Voltage1 PIN True Asserted VIL/VOL PIN False Deasserted VIH/VOH PIN True Asserted VIH/VOH PIN False Deasserted VIL/VOL 1. Values for VIL, VOL, VIH, and VOH are defined by individual product specifications. 56F8036 Data Sheet, Rev. 3 16 Freescale Semiconductor Preliminary Introduction Part 2 Signal/Connection Descriptions 2.1 Introduction The input and output signals of the 56F8036 are organized into functional groups, as detailed in Table 2-1. Table 2-2 summarizes all device pins. In Table 2-2, each table row describes the signal or signals present on a pin, sorted by pin number. Table 2-1 Functional Group Pin Allocations Functional Group Number of Pins Power Inputs (VDD, VDDA) 3 Ground (VSS, VSSA) 4 Supply Capacitors 2 Reset1 1 Pulse Width Modulator (PWM) Ports1 12 Queued Serial Peripheral Interface (QSPI) Ports1 4 Timer Module A (TMRA) Ports1 4 Analog-to-Digital Converter (ADC) Ports1 10 Queued Serial Communications Interface 0 (QSCI0) Ports1 2 MSCAN Ports1 2 Inter-Integrated Circuit Interface (I2C) Ports1 2 Oscillator Signals1 2 JTAG/Enhanced On-Chip Emulation (EOnCE)1 4 1. Pins may be shared with other peripherals; see Table 2-2. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 17 In Table 2-2, peripheral pins in bold identify reset state. Table 2-2 56F8036 Pins Peripherals: Pin # Pin Name Signal Name GPIO I2C QSCI RXD0 1 GPIOB6 GPIOB6, RXD0, SDA, CLKIN B6 SDA 2 GPIOB1 GPIOB1, SS0, SDA B1 SDA SCL QSPI ADC PWM Quad Timer Comp MSCAN Power & Ground JTAG Misc CLKIN SS0 3 GPIOB7 GPIOB7, TXD0, SCL B7 4 GPIOB5 GPIOB5, TA1, FAULT3, CLKIN B5 TXD0 FAULT3 TA1 5 GPIOA9 GPIOA9, FAULT2, TA3, CMPBI1 A9 FAULT2 TA3 6 GPIOA11 GPIOA11, CMPBI2 A11 7 GPIOC12 GPIOC12, ANB4 C12 ANB4 8 GPIOC4 GPIOC4, ANB0, CMPBI3 C4 ANB0 9 GPIOC5 GPIOC5, ANB1 C5 ANB1 10 GPIOC6 GPIOC6, ANB2, VREFHB C6 ANB2 VREFHB 11 GPIOC7 GPIOC7, ANB3, VREFLB C7 ANB3 VREFLB 12 VDDA VDDA VDDA 13 VSSA VSSA VSSA 14 GPIOC3 GPIOC3, ANA3, VREFLA C3 ANA3 VREFLA 15 GPIOC2 GPIOC2, ANA2, VREFHA C2 ANA2 VREFHA 16 GPIOC1 GPIOC1, ANA1 C1 ANA1 17 GPIOC0 GPIOC0, ANA0, CMPAI3 C0 ANA0 18 GPIOC8 GPIOC8, ANA4 C8 ANA4 19 VSS VSS VSS 20 VCAP VCAP VCAP CLKIN CMPBI1 CMPBI2 CMPBI3 CMPAI3 21 TCK TCK, GPIOD2 D2 22 GPIOB10 GPIOB10, CMPAO, B10 TCK 23 RESET RESET, GPIOA7 A7 24 GPIOB3 GPIOB3, MOSI0, TA3, PSRC1 B3 MOSI0 PSRC1 TA3 25 GPIOB2 GPIOB2, MISO0, TA2, PSRC0 B2 MISO0 PSRC0 TA2 26 GPIOA6 GPIOA6, FAULT0, TA0 A6 FAULT0 TA0 27 GPIOA10 GPIOA10, CMPAI2 A10 CMPAO RESET CMPAI2 56F8036 Data Sheet, Rev. 3 18 Freescale Semiconductor Preliminary Introduction Table 2-2 56F8036 Pins (Continued) Peripherals: Pin # Pin Name 28 GPIOA8 GPIOA8, FAULT1, TA2, CMPAI1 29 GPIOA5 GPIOA5, PWM5, TA3, FAULT2 30 VSS VSS VSS 31 VDD VDD VDD 32 GPIOB0 GPIOB0, SCLK0, SCL B0 33 GPIOA4 GPIOA4, PWM4, TA2, FAULT1 A4 34 GPIOB9 GPIOB9, SDA, CANRX B9 Signal Name PWM Quad Timer Comp A8 FAULT1 TA2 CMPAI1 A5 PWM5 FAULT2 TA3 GPIO I2C SCL QSCI QSPI ADC MSCAN Power & Ground JTAG Misc SCLK0 PWM4 FAULT1 TA2 SDA CANRX 35 GPIOA2 GPIOA2, PWM2 A2 PWM2 36 GPIOA3 GPIOA3, PWM3 A3 PWM3 37 VCAP VCAP VCAP 38 VDD VDD VDD 39 VSS VSS VSS 40 GPIOD5 GPIOD5, XTAL, CLKIN D5 XTAL CLKIN 41 GPIOD4 GPIOD4, EXTAL D4 EXTAL 42 GPIOB8 GPIOB8, SCL, CANTX B8 43 GPIOA1 GPIOA1, PWM1 A1 PWM1 44 GPIOA0 GPIOA0, PWM0 A0 PWM0 45 TDI TDI, GPIOD0 D0 46 GPIOB11 GPIOB11, CMPBO B11 47 TMS TMS, GPIOD3 D3 TMS 48 TDO TDO, GPIOD1 D1 TDO SCL CANTX TD1 CMPBO 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 19 VDD Power Ground Power Ground Other Supply Ports VSS VDDA VSSA VCAP GPIOD4 (EXTAL) OSC Port or GPIO GPIOD5 (XTAL, CLKIN) RESET or GPIOA RESET (GPIOA7) GPIOB0 (SCLK0, SCL) QSPI or I2C or PWM or TMRA or GPIOB GPIOB1 (SS0, SDA) GPIOB2 (MISO0, TA2, PSRC0) GPIOB3 (MOSI0, TA3, PSRC1) 4 2 3 1 1 1 1 56F8036 2 1 1 1 1 1 1 1 GPIOB5 (TA1, FAULT3, CLKIN) 1 1 1 1 1 GPIOB7 (TXD0, SCL) 1 1 1 1 1 TCK (GPIOD2) TMS (GPIOD3) GPIOA8 (FAULT1, TA2, CMPAI1) GPIOA9 (FAULT2, TA3, CMPBI1) PWM or TMRA or CMP or QSPI or GPIOA GPIOA10 (CMPAI2) GPIOA11 (CMPBI2) GPIOB10 (CMPAO) CAN or CMP or GPIOB GPIOB11 (CMPBO) GPIOB8 (SCL, CANTX) GPIOB9 (SDA, CANRX) 1 1 JTAG/ EOnCE or GPIOD GPIOA6 (FAULT0, TA0) 1 1 TDO (GPIOD1) GPIOA5 (PWM5, TA3, FAULT2) 1 GPIOB6 (RXD0, SDA, CLKIN) TDI (GPIOD0) GPIOA4 (PWM4, TA2, FAULT1) 1 1 QSCI or PWM or I2C or TMRA or TMRB or QSPI or GPIOB GPIOA0-3 (PWM0-3) 1 1 1 1 1 1 1 1 1 GPIOC0 (ANA0 & CMPAI3) GPIOC1 (ANA1) GPIOC2 (ANA2, VREFHA) GPIOC3 (ANA3, VREFLA) GPIOC8 (ANA4) GPIOC4 (ANB0 & CMPBI3) ADC or CMP or QSCI1 or GPIOC GPIOC5 (ANB1) GPIOC6 (ANB2, VREFHB) GPIOC7 (ANB3, VREFLB) GPIOC12 (ANB4) Figure 2-1 56F8036 Signals Identified by Functional Group 56F8036 Data Sheet, Rev. 3 20 Freescale Semiconductor Preliminary 56F8036 Signal Pins 2.2 56F8036 Signal Pins After reset, each pin is configured for its primary function (listed first). Any alternate functionality must be programmed. Table 2-3 56F8036 Signal and Package Information for the 48-Pin LQFP Signal Name LQFP Pin No. Type State During Reset Signal Description VDD 31 Supply Supply I/O Power — This pin supplies 3.3V power to the chip I/O interface. VDD 38 VSS 19 Supply Supply VSS — These pins provide ground for chip logic and I/O drivers. VSS 30 VSS 39 VDDA 12 Supply Supply ADC Power — This pin supplies 3.3V power to the ADC modules. It must be connected to a clean analog power supply. VSSA 13 Supply Supply ADC Analog Ground — This pin supplies an analog ground to the ADC modules. VCAP 20 Supply Supply VCAP 37 VCAP — Connect this pin to a 4.7μF or greater bypass capacitor in order to bypass the core voltage regulator, required for proper chip operation. See Section 10.2.1. RESET 23 Input Input, internal pull-up enabled Reset — This input is a direct hardware reset on the processor. When RESET is asserted low, the chip is initialized and placed in the reset state. A Schmitt trigger input is used for noise immunity. The internal reset signal will be deasserted synchronous with the internal clocks after a fixed number of internal clocks. (GPIOA7) Input/Open Drain Output Port A GPIO — This GPIO pin can be individually programmed as an input or open drain output pin. Note that RESET functionality is disabled in this mode and the chip can only be reset via POR, COP reset, or software reset. After reset, the default state is RESET. Return to Table 2-2 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 21 Table 2-3 56F8036 Signal and Package Information for the 48-Pin LQFP (Continued) Signal Name LQFP Pin No. GPIOA0 44 (PWM0) Type Input/ Output State During Reset Input, internal pull-up enabled Output Signal Description Port A GPIO — This GPIO pin can be individually programmed as an input or output pin. PWM0 — This is one of the six PWM output pins. After reset, the default state is GPIOA0. GPIOA1 43 (PWM1) Input/ Output Input, internal pull-up enabled Output Port A GPIO — This GPIO pin can be individually programmed as an input or output pin. PWM1 — This is one of the six PWM output pins. After reset, the default state is GPIOA1. GPIOA2 35 Input/ Output Input, internal pull-up enabled Output (PWM2) Port A GPIO — This GPIO pin can be individually programmed as an input or output pin. PWM2 — This is one of the six PWM output pins. After reset, the default state is GPIOA2. GPIOA3 36 (PWM3) Input/ Output Output Input, internal pull-up enabled Port A GPIO — This GPIO pin can be individually programmed as an input or output pin. PWM3 — This is one of the six PWM output pins. After reset, the default state is GPIOA3. Return to Table 2-2 56F8036 Data Sheet, Rev. 3 22 Freescale Semiconductor Preliminary 56F8036 Signal Pins Table 2-3 56F8036 Signal and Package Information for the 48-Pin LQFP (Continued) Signal Name LQFP Pin No. GPIOA4 33 Type Input/ Output State During Reset Input, internal pull-up enabled Signal Description Port A GPIO — This GPIO pin can be individually programmed as an input or output pin. (PWM4) Output PWM4 — This is one of the six PWM output pins. (TA21) Input/ Output TA2 — Timer A, Channel 2 (FAULT12) Input Fault1 — This fault input pin is used for disabling selected PWM outputs in cases where fault conditions originate off-chip. After reset, the default state is GPIOA4. The peripheral functionality is controlled via the SIM. See Section 6.3.16. 1The 2 TA2 signal is also brought out on the GPIOA8-9 and GPIOB2-3 pins. The Fault1 signal is also brought out on the GPIOA8-9 and GPIOB10 pins. GPIOA5 29 Input/ Output Input, internal pull-up enabled Port A GPIO — This GPIO pin can be individually programmed as an input or output pin. (PWM5) Output PWM5 — This is one of the six PWM output pins. (TA33) Input/ Output TA3 — Timer A, Channel 3 (FAULT24) Input Fault2 — This fault input pin is used for disabling selected PWM outputs in cases where fault conditions originate off-chip. After reset, the default state is GPIOA5. The peripheral functionality is controlled via the SIM. See Section 6.3.16. 3 The TA3 signal is also brought out on the GPIOA8-9 and GPIOB2-3 pins. 4The Fault2 signal is also brought out on the GPIOA8-9 and GPIOB10 pins. Return to Table 2-2 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 23 Table 2-3 56F8036 Signal and Package Information for the 48-Pin LQFP (Continued) Signal Name LQFP Pin No. GPIOA6 26 (FAULT0) Type Input/ Output State During Reset Input, internal pull-up enabled Input Signal Description Port A GPIO — This GPIO pin can be individually programmed as an input or output pin. Fault0 — This fault input pin is used for disabling selected PWM outputs in cases where fault conditions originate off-chip. (TA0) TA0 — Timer A, Channel 0. After reset, the default state is GPIOA6. The peripheral functionality is controlled via the SIM. See Section 6.3.16. GPIOA8 28 Input/ Output (FAULT1) Input (TA2) Input/ Output (CMPAI1) Input Input, internal pull-up enabled Port A GPIO — This GPIO pin can be individually programmed as an input or output pin. Fault1 — This fault input pin is used for disabling selected PWM outputs in cases where fault conditions originate off-chip. TA2 — Timer A, Channel 2. Comparator A, Input 1 — This is an analog input to Comparator A. After reset, the default state is GPIOA8. The peripheral functionality is controlled via the SIM. See Section 6.3.16. GPIOA9 5 Input/ Output (FAULT2) Input (TA3) Input/ Output (CMPBI1) Input Input, internal pull-up enabled Port A GPIO — This GPIO pin can be individually programmed as an input or output pin. Fault2 — This fault input pin is used for disabling selected PWM outputs in cases where fault conditions originate off-chip. TA2 — Timer A, Channel 3. Comparator B, Input 1 — This is an analog input to Comparator B. After reset, the default state is GPIOA9. The peripheral functionality is controlled via the SIM. See Section 6.3.16. Return to Table 2-2 56F8036 Data Sheet, Rev. 3 24 Freescale Semiconductor Preliminary 56F8036 Signal Pins Table 2-3 56F8036 Signal and Package Information for the 48-Pin LQFP (Continued) Signal Name LQFP Pin No. GPIOA10 27 (CMPAI2) Type Input/ Output Input State During Reset Input, internal pull-up enabled Signal Description Port A GPIO — This GPIO pin can be individually programmed as an input or output pin. Comparator A, Input 2 — This is an analog input to Comparator A. After reset, the default state is GPIOA10. The peripheral functionality is controlled via the SIM. See Section 6.3.16. GPIOA11 6 (CMPBI2) Input/ Output Input Input, internal pull-up enabled Port A GPIO — This GPIO pin can be individually programmed as an input or output pin. Comparator B, Input 2 — This is an analog input to Comparator B. After reset, the default state is GPIOA11. The peripheral functionality is controlled via the SIM. See Section 6.3.16. GPIOB0 32 Input/ Output Input, internal pull-up enabled Port B GPIO — This GPIO pin can be individually programmed as an input or output pin. (SCLK0) Input/ Output QSPI0 Serial Clock — In the master mode, this pin serves as an output, clocking slaved listeners. In slave mode, this pin serves as the data clock input. A Schmitt trigger input is used for noise immunity. (SCL5) Input/ Output Serial Clock — This pin serves as the I2C serial clock. After reset, the default state is GPIOB0. The peripheral functionality is controlled via the SIM. See Section 6.3.16. 5The SCL signal is also brought out on the GPIOB7 pin. GPIOB1 2 Input/ Output (SS0) Input/ Output (SDA6) Input Input, internal pull-up enabled Port B GPIO — This GPIO pin can be individually programmed as an input or output pin. QSPI0 Slave Select — SS is used in slave mode to indicate to the QSPI0 module that the current transfer is to be received. Serial Data — This pin serves as the I2C serial data line. After reset, the default state is GPIOB1. The peripheral functionality is controlled via the SIM. See Section 6.3.16. 6The SDA signal is also brought out on the GPIOB6 pin. Return to Table 2-2 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 25 Table 2-3 56F8036 Signal and Package Information for the 48-Pin LQFP (Continued) Signal Name LQFP Pin No. GPIOB2 25 Type Input/ Output State During Reset Input, internal pull-up enabled Signal Description Port B GPIO — This GPIO pin can be individually programmed as an input or output pin. (MISO0) Input/ Output QSPI0 Master In/Slave Out — This serial data pin is an input to a master device and an output from a slave device. The MISO line of a slave device is placed in the high-impedance state if the slave device is not selected. The slave device places data on the MISO line a half-cycle before the clock edge the master device uses to latch the data. (TA27) Input/ Output TA2 — Timer A, Channel 2 (PSRC0) Input PSRC0 — External PWM signal source input for the complementary PWM4/PWM5 pair. After reset, the default state is GPIOB2. The peripheral functionality is controlled via the SIM. See Section 6.3.16. 7 The TA2 signal is also brought out on the GPIOA4 and GPIOA8 pins. GPIOB3 24 Input/ Output Input, internal pull-up enabled Port B GPIO — This GPIO pin can be individually programmed as an input or output pin. (MOSI0) Input/ Output QSPI0 Master Out/Slave In— This serial data pin is an output from a master device and an input to a slave device. The master device places data on the MOSI line a half-cycle before the clock edge the slave device uses to latch the data. (TA38) Input/ Output TA3 — Timer A, Channel 3 (PSRC1) Input PSRC1 — External PWM signal source input for the complementary PWM2/PWM3 pair. After reset, the default state is GPIOB3. The peripheral functionality is controlled via the SIM. See Section 6.3.16. 8 The TA3 signal is also brought out on the GPIOA5 and GPIOA9 pins. Return to Table 2-2 56F8036 Data Sheet, Rev. 3 26 Freescale Semiconductor Preliminary 56F8036 Signal Pins Table 2-3 56F8036 Signal and Package Information for the 48-Pin LQFP (Continued) Signal Name LQFP Pin No. GPIOB5 4 Type Input/ Output State During Reset Input, internal pull-up enabled Signal Description Port B GPIO — This GPIO pin can be individually programmed as an input or output pin. (TA1) Input/ Output (FAULT3) Input FAULT3 — This fault input pin is used for disabling selected PWM outputs in cases where fault conditions originate off-chip. (CLKIN) Input External Clock Input— This pin serves as an external clock input. TA1 — Timer A, Channel 1 After reset, the default state is GPIOB5. The peripheral functionality is controlled via the SIM. See Section 6.3.16. GPIOB6 1 Input/ Output (RXD0) Input (SDA9) Input/ Output (CLKIN) Input Input, internal pull-up enabled Port B GPIO — This GPIO pin can be individually programmed as an input or output pin. Receive Data 0 — QSCI0 receive data input. Serial Data — This pin serves as the I2C serial data line. External Clock Input — This pin serves as an external clock input. After reset, the default state is GPIOB6. The peripheral functionality is controlled via the SIM (See Section 6.3.16) and the CLKMODE bit of the OCCS Oscillator Control Register. 9 The SDA signal is also brought out on the GPIOB1 pin. GPIOB7 3 Input/ Output Input, internal pull-up enabled Port B GPIO — This GPIO pin can be individually programmed as an input or output pin. (TXD0) Input/ Output Transmit Data 0 — QSCI0 transmit data output or transmit / receive in single wire operation. (SCL10) Input/ Output Serial Clock — This pin serves as the I2C serial clock. After reset, the default state is GPIOB7. The peripheral functionality is controlled via the SIM. See Section 6.3.16. 10 The SCL signal is also brought out on the GPIOB0 pin. Return to Table 2-2 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 27 Table 2-3 56F8036 Signal and Package Information for the 48-Pin LQFP (Continued) Signal Name LQFP Pin No. GPIOB8 42 Type Input/ Output (SCL11) Input/ Output (CANTX12) Open Drain Output State During Reset Input, internal pull-up enabled Signal Description Port B GPIO — This GPIO pin can be individually programmed as an input or output pin. Serial Clock 1 — This pin serves as the I2C serial clock. CAN Transmit Data — This is the SCAN interface output. After reset, the default state is GPIOB8. The peripheral functionality is controlled via the SIM. See Section 6.3.16. 11 The SCL signal is also brought out on the GPIOB0 and GPIOB7 pins. 12 The CANTX signal is also brought out on the GPIOB12 pin. GPIOB9 34 Input/ Output (SDA13) Input/ Output (CANRX14) Input Input, internal pull-up enabled Port B GPIO — This GPIO pin can be individually programmed as an input or output pin. Serial Data 1 — This pin serves as the I2C serial data line. CAN Receive Data — This is the MSCAN interface input. After reset, the default state is GPIOB9. The peripheral functionality is controlled via the SIM. See Section 6.3.16. 13 The SDA signal is also brought out on the GPIOB1 and GPIOB6 pins. 14 The CANRX signal is also brought out on the GPIOB13 pin. GPIOB10 22 (CMPAO) Input/ Output Output Input, internal pull-up enabled Port B GPIO — This GPIO pin can be individually programmed as an input or output pin. Comparator A Output— This is the output of comparator A. After reset, the default state is GPIOB10. The peripheral functionality is controlled via the SIM. See Section 6.3.16. GPIOB11 46 (CMPBO) Input/ Output Output Input, internal pull-up enabled Port B GPIO — This GPIO pin can be individually programmed as an input or output pin. Comparator B Output— This is the output of comparator B. After reset, the default state is GPIOB11. The peripheral functionality is controlled via the SIM. See Section 6.3.16. Return to Table 2-2 56F8036 Data Sheet, Rev. 3 28 Freescale Semiconductor Preliminary 56F8036 Signal Pins Table 2-3 56F8036 Signal and Package Information for the 48-Pin LQFP (Continued) Signal Name LQFP Pin No. GPIOC0 17 (ANA0 & CMPAI3) Type Input/ Output State During Reset Input Analog Input Signal Description Port C GPIO — This GPIO pin can be individually programmed as an input or output pin. ANA0 — Analog input to ADC A, Channel 0. Comparator A, Input 3 — This is an analog input to Comparator A. When used as an analog input, the signal goes to both the ANA0 and CMPAI3. After reset, the default state is GPIOC0. GPIOC1 16 (ANA1) Input/ Output Input Analog Input Port C GPIO — This GPIO pin can be individually programmed as an input or output pin. ANA1 — Analog input to ADC A, Channel 1. After reset, the default state is GPIOC1. GPIOC2 15 Input/ Output Input Port C GPIO — This GPIO pin can be individually programmed as an input or output pin. (ANA2) Analog Input ANA2 — Analog input to ADC A, Channel 2. (VREFHA) Analog Input VREFHA — Analog reference voltage high (ADC A). After reset, the default state is GPIOC2. GPIOC3 14 Input/ Output Input Port C GPIO — This GPIO pin can be individually programmed as an input or output pin. (ANA3) Analog Input ANA3 — Analog input to ADC A, Channel 3. (VREFLA) Analog Input VREFLA — Analog reference voltage low (ADC A). After reset, the default state is GPIOC3. Return to Table 2-2 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 29 Table 2-3 56F8036 Signal and Package Information for the 48-Pin LQFP (Continued) Signal Name LQFP Pin No. GPIOC4 8 (ANB0 & CMPBI3) Type Input/ Output State During Reset Input Analog Input Signal Description Port C GPIO — This GPIO pin can be individually programmed as an input or output pin. ANB0 — Analog input to ADC B, Channel 0. Comparator B, Input 3 — This is an analog input to Comparator B. When used an analog input, the signal goes to both the ANB0 and CMPBI3. After reset, the default state is GPIOC4. GPIOC5 9 (ANB1) Input/ Output Input Port C GPIO — This GPIO pin can be individually programmed as an input or output pin. ANB1 — Analog input to ADC B, Channel 1. Analog Input After reset, the default state is GPIOC5. GPIOC6 10 Input/ Output (ANB2) Analog Input (VREFHB) Input Input Port C GPIO — This GPIO pin can be individually programmed as an input or output pin. ANB2 — Analog input to ADC B, Channel 2. VREFHB — Analog reference voltage high (ADC B). After reset, the default state is GPIOC6. GPIOC7 11 Input/ Output (ANB3) Analog Input (VREFLB) Input Input Port C GPIO — This GPIO pin can be individually programmed as an input or output pin. ANB3 — Analog input to ADC B, Channel 3. VREFLB — Analog reference voltage low (ADC B). After reset, the default state is GPIOC7. GPIOC8 18 (ANA4) Input/ Output Analog Input Input Port C GPIO — This GPIO pin can be individually programmed as an input or output pin. ANA4 — Analog input to ADC A, Channel 4. After reset, the default state is GPIOC8. Return to Table 2-2 56F8036 Data Sheet, Rev. 3 30 Freescale Semiconductor Preliminary 56F8036 Signal Pins Table 2-3 56F8036 Signal and Package Information for the 48-Pin LQFP (Continued) Signal Name LQFP Pin No. GPIOC12 7 (ANB4) Type Input/ Output State During Reset Input Analog Input Signal Description Port C GPIO — This GPIO pin can be individually programmed as an input or output pin. ANB4 — Analog input to ADC B, Channel 4. After reset, the default state is GPIOC12. GPIOD4 41 (EXTAL) Input/ Output Input Analog Input Port D GPIO — This GPIO pin can be individually programmed as an input or output pin. External Crystal Oscillator Input — This input can be connected to an 8MHz external crystal. Tie this pin low if XTAL is being driven by an external clock source. After reset, the default state is GPIOD4. GPIOD5 40 Input/ Output (XTAL) Analog Input/ Output (CLKIN) Input Input Port D GPIO — This GPIO pin can be individually programmed as an input or output pin. External Crystal Oscillator Output — This output connects the internal crystal oscillator output to an external crystal. External Clock Input — This pin serves as an external clock input. After reset, the default state is GPIOD5. TDI 45 (GPIOD0) Input Input, internal pull-up enabled Input/ Output Test Data Input — This input pin provides a serial input data stream to the JTAG/EOnCE port. It is sampled on the rising edge of TCK and has an on-chip pull-up resistor. Port D GPIO — This GPIO pin can be individually programmed as an input or output pin. After reset, the default state is TDI. TDO 48 (GPIOD1) Output Input/ Output Output tri-stated, internal pull-up enabled Test Data Output — This tri-stateable output pin provides a serial output data stream from the JTAG/EOnCE port. It is driven in the shift-IR and shift-DR controller states, and changes on the falling edge of TCK. Port D GPIO — This GPIO pin can be individually programmed as an input or output pin. After reset, the default state is TDO. Return to Table 2-2 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 31 Table 2-3 56F8036 Signal and Package Information for the 48-Pin LQFP (Continued) Signal Name LQFP Pin No. Type TCK 21 Input (GPIOD2) State During Reset Input, internal pull-up enabled Input/ Output Signal Description Test Clock Input — This input pin provides a gated clock to synchronize the test logic and shift serial data to the JTAG/EOnCE port. The pin is connected internally to a pull-up resistor. A Schmitt trigger input is used for noise immunity. Port D GPIO — This GPIO pin can be individually programmed as an input or output pin. After reset, the default state is TCK. TMS 47 (GPIOD3) Input Input/ Output Input, internal pull-up enabled Test Mode Select Input — This input pin is used to sequence the JTAG TAP controller’s state machine. It is sampled on the rising edge of TCK and has an on-chip pull-up resistor. Port D GPIO — This GPIO pin can be individually programmed as an input or output pin. After reset, the default state is TMS. Note: Always tie the TMS pin to VDD through a 2.2K resistor. Return to Table 2-2 56F8036 Data Sheet, Rev. 3 32 Freescale Semiconductor Preliminary Overview Part 3 OCCS 3.1 Overview The On-Chip Clock Synthesis (OCCS) module allows designers using an internal relaxation oscillator, an external crystal, or an external clock to run 56F8000 family devices at user-selectable frequencies up to 32MHz. For details, see the OCCS chapter in the 56F802X and 56F803XPeripheral Reference Manual. 3.2 Features The OCCS module interfaces to the oscillator and PLL and offers these features: • • • • • • • • • Internal relaxation oscillator Ability to power down the internal relaxation oscillator or crystal oscillator Ability to put the internal relaxation oscillator into Standby mode 3-bit postscaler provides control for the PLL output Ability to power down the PLL Provides a 2X system clock which operates at twice the system clock to the System Integration Module (SIM) Provides a 3X system clock which operates at three times the system clock to PWM and Timer modules Safety shutdown feature is available if the PLL reference clock is lost Can be driven from an external clock source The clock generation module provides the programming interface for the PLL, internal relaxation oscillator, and crystal oscillator. 3.3 Operating Modes In 56F8000 family devices, an internal oscillator, an external crystal, or an external clock source can be used to provide a reference clock to the SIM. The 2X system clock source output from the OCCS can be described by one of the following equations: 2X system frequency = oscillator frequency 2X system frequency = (oscillator frequency x 8) / (postscaler) where: postscaler = 1, 2, 4, 8, 16, or 32 The SIM is responsible for further dividing these frequencies by two, which will insure a 50% duty cycle in the system clock output. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 33 The 56F8000 family devices’ on-chip clock synthesis module has the following registers: • • • • • Control Register (OCCS_CTRL) Divide-by Register (OCCS_DIVBY) Status Register (OCCS_STAT) Shutdown Register (OCCS_SHUTDN) Oscillator Control Register (OCCS_OCTRL) For more information on these registers, please refer to the 56F802X and 56F803XPeripheral Reference Manual. 3.4 Internal Clock Source An internal relaxation oscillator can supply the reference frequency when an external frequency source or crystal is not used. It is optimized for accuracy and programmability while providing several power-saving configurations which accommodate different operating conditions. The internal relaxation oscillator has very little temperature and voltage variability. To optimize power, the architecture supports a standby state and a power-down state. During a boot or reset sequence, the relaxation oscillator is enabled by default (the PRECS bit in the PLLCR word is set to 0). Application code can then also switch to the external clock source and power down the internal oscillator, if desired. If a changeover between internal and external clock sources is required at power-on, the user must ensure that the clock source is not switched until the desired external clock source is enabled and stable. To compensate for variances in the device manufacturing process, the accuracy of the relaxation oscillator can be incrementally adjusted to within + 0.078% of 8MHz by trimming an internal capacitor. Bits 0-9 of the OSCTL (oscillator control) register allow the user to set in an additional offset (trim) to this preset value to increase or decrease capacitance. Each unit added or subtracted changes the output frequency by about 0.078% of 8MHz, allowing incremental adjustment until the desired frequency accuracy is achieved. The center frequency of the internal oscillator is calibrated at the factory to 8MHz and the TRIM value is stored in the Flash information block and loaded to the FMOPT1 register at reset. When using the relaxation oscillator, the boot code should read the FMOPT1 register and set this value as OSCTL TRIM. For further information, see the 56F802X and 56F803XPeripheral Reference Manual. 3.5 Crystal Oscillator The internal crystal oscillator circuit is designed to interface with a parallel-resonant crystal resonator in a frequency range of 4-8MHz, specified for the external crystal. Figure 3-1 shows a typical crystal oscillator circuit. Follow the crystal supplier’s recommendations when selecting a crystal, since crystal parameters determine the component values required to provide maximum stability and reliable start-up. The load capacitance values used in the oscillator circuit design should include all stray layout capacitances. The crystal and associated components should be mounted as near as possible to the EXTAL and XTAL pins to minimize output distortion and start-up stabilization time. 56F8036 Data Sheet, Rev. 3 34 Freescale Semiconductor Preliminary Ceramic Resonator Crystal Frequency = 4 - 8MHz (optimized for 8MHz) EXTAL XTAL Rz EXTAL XTAL Rz Sample External Crystal Parameters: Rz = 750 KΩ Note: If the operating temperature range is limited to below 85oC (105oC junction), then Rz = 10 Meg Ω CL1 CL2 Figure 3-1 External Crystal Oscillator Circuit 3.6 Ceramic Resonator The internal crystal oscillator circuit is also designed to interface with a ceramic resonator in the frequency range of 4-8MHz. Figure 3-2 shows the typical 2 and 3 terminal ceramic resonators and their circuits. Follow the resonator supplier’s recommendations when selecting a resonator, since their parameters determine the component values required to provide maximum stability and reliable start up. The load capacitance values used in the resonator circuit design should include all stray layout capacitances. The resonator and associated components should be mounted as close as possible to the EXTAL and XTAL pins to minimize output distortion and start-up stabilization time. Resonator Frequency = 4 - 8MHz (optimized for 8MHz) 3 Terminal 2 Terminal EXTAL XTAL Rz CL1 CL2 EXTAL XTAL Rz C1 Sample External Ceramic Resonator Parameters: Rz = 750 KΩ C2 Figure 3-2 External Ceramic Resonator Circuit 3.7 External Clock Input - Crystal Oscillator Option The recommended method of connecting an external clock is illustrated in Figure 3-3. The external clock source is connected to XTAL and the EXTAL pin is grounded. The external clock input must be generated using a relatively low impedance driver. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 35 56F8036 CLKMODE = 1 XTAL EXTAL External Clock GND or GPIO Figure 3-3 Connecting an External Clock Signal using XTAL 3.8 Alternate External Clock Input The recommended method of connecting an external clock is illustrated in Figure 3-3. The external clock source is connected to GPIO6/RXD (primary) or GPIOB5/TA1/FAULT3/XTAL/EXTAL (secondary). The user has the option of using GPIO6/RXD/CLKIN or GPIOB5/TA1/FAULT3/CLKIN as external clock input. 56F8036 GPIO External Clock Figure 3-4 Connecting an External Clock Signal using GPIO Part 4 Memory Maps 4.1 Introduction The 56F8036 device is a 16-bit motor-control chip based on the 56800E core. It uses a Harvard-style architecture with two independent memory spaces for Data and Program. On-chip RAM is shared by both spaces and Flash memory is used only in Program space. This section provides memory maps for: • • Program Address Space, including the Interrupt Vector Table Data Address Space, including the EOnCE Memory and Peripheral Memory Maps On-chip memory sizes for the device are summarized in Table 4-1. Flash memories’ restrictions are identified in the “Use Restrictions” column of Table 4-1. 56F8036 Data Sheet, Rev. 3 36 Freescale Semiconductor Preliminary Interrupt Vector Table Table 4-1 Chip Memory Configurations On-Chip Memory 56F8036 Use Restrictions Program Flash (PFLASH) 32k x 16 or 64KB Erase / Program via Flash interface unit and word writes to CDBW Unified RAM (RAM) 4k x 16 or 8KB Usable by both the Program and Data memory spaces 4.2 Interrupt Vector Table Table 4-2 provides the 56F8036’s reset and interrupt priority structure, including on-chip peripherals. The table is organized with higher-priority vectors at the top and lower-priority interrupts lower in the table. As indicated, the priority of an interrupt can be assigned to different levels, allowing some control over interrupt priorities. All level 3 interrupts will be serviced before level 2, and so on. For a selected priority level, the lowest vector number has the highest priority. The location of the vector table is determined by the Vector Base Address (VBA). Please see Section 5.6.8 for the reset value of the VBA. By default, VBA = 0, and the reset address and COP reset address will correspond to vector 0 and 1 of the interrupt vector table. In these instances, the first two locations in the vector table must contain branch or JMP instructions. All other entries must contain JSR instructions. Table 4-2 Interrupt Vector Table Contents1 Peripheral Vector Number Priority Level Vector Base Address + Interrupt Function core P:$00 Reserved for Reset Overlay2 core P:$02 Reserved for COP Reset Overlay P:$04 Illegal Instruction core 2 3 core 3 3 P:$06 SW Interrupt 3 core 4 3 P:$08 HW Stack Overflow core 5 3 P:$0A Misaligned Long Word Access core 6 1-3 P:$0C EOnCE Step Counter core 7 1-3 P:$0E EOnCE Breakpoint Unit core 8 1-3 P:$10 EOnCE Trace Buffer core 9 1-3 P:$12 EOnCE Transmit Register Empty core 10 1-3 P:$14 EOnCE Receive Register Full core 11 2 P:$16 SW Interrupt 2 core 12 1 P:$18 SW Interrupt 1 core 13 0 P:$1A SW Interrupt 0 14 Reserved 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 37 Table 4-2 Interrupt Vector Table Contents1 (Continued) Peripheral Vector Number Priority Level Vector Base Address + Interrupt Function LVI 15 1-3 P:$1E Low-Voltage Detector (Power Sense) PLL 16 1-3 P:$20 Phase-Locked Loop FM 17 0-2 P:$22 FM Access Error Interrupt FM 18 0-2 P:$24 FM Command Complete FM 19 0-2 P:$26 FM Command, Data, and Address Buffers Empty MSCAN 20 0-2 P:$28 MSCAN Error MSCAN 21 0-2 P:$2a MSCAN Receive MSCAN 22 0-2 P:$2C MSCAN Transmit MSCAN 23 0-2 P:$2E MSCAN Wake-Up GPIOD 24 0-2 P:$30 GPIOD GPIOC 25 0-2 P:$32 GPIOC GPIOB 26 0-2 P:$34 GPIOB GPIOA 27 0-2 P:$36 GPIOA QSPI0 28 0-2 P:$38 QSPI0 Receiver Full QSPI0 29 0-2 P:$3A QSPI0 Transmitter Empty 30 - 31 Reserved QSCI0 32 0-2 P:$40 QSCI0 Transmitter Empty QSCI0 33 0-2 P:$42 QSCI0 Transmitter Idle QSCI0 34 0-2 P:$44 QSCI0 Receiver Error QSCI0 35 0-2 P:$46 QSCI0 Receiver Full 36 - 39 Reserved I2C 40 0-2 P:$50 I2C Error I2C 41 0-2 P:$52 I2C General I2C 42 0-2 P:$54 I2C Receive I2C 43 0-2 P:$56 I2C Transmit I2C 44 0-2 P:$58 I2C Status TMRA 45 0-2 P:$5A Timer A, Channel 0 TMRA 46 0-2 P:$5C Timer A, Channel 1 TMRA 47 0-2 P:$5E Timer A, Channel 2 48 0-2 P:$60 Timer A, Channel 3 TMRA 49 - 52 Reserved CMPA 53 0-2 P:$6A Comparator A CMPB 54 0-2 P:$6C Comparator B PIT0 55 0-2 P:$6E Interval Timer 0 PIT1 56 0-2 P:$70 Interval Timer 1 PIT2 57 0-2 P:$72 Interval Timer 2 ADC 58 0-2 P:$74 ADC A Conversion Complete ADC 59 0-2 P:$76 ADC B Conversion Complete 56F8036 Data Sheet, Rev. 3 38 Freescale Semiconductor Preliminary Program Map Table 4-2 Interrupt Vector Table Contents1 (Continued) Peripheral Vector Number Priority Level Vector Base Address + Interrupt Function ADC 60 0-2 P:$78 ADC Zero Crossing or Limit Error PWM 61 0-2 P:$7A Reload PWM PWM 62 0-2 P:$7C PWM Fault SWILP 63 -1 P:$7E SW Interrupt Low Priority 1. Two words are allocated for each entry in the vector table. This does not allow the full address range to be referenced from the vector table, providing only 19 bits of address. 2. If the VBA is set to $0000, the first two locations of the vector table will overlay the chip reset addresses since the reset address would match the base of this vector table. 4.3 Program Map The Program Memory map is shown in Table 4-3. Table 4-3 Program Memory Map1 at Reset Begin/End Address Memory Allocation P: $1F FFFF P: $00 8800 RESERVED P: $00 87FF P: $00 8000 On-Chip RAM2 8KB P: $00 7FFF P: $00 0000 Internal Program Flash 64KB Cop Reset Address = $00 0002 Boot Location = $00 0000 1. All addresses are 16-bit Word addresses. 2. This RAM is shared with Data space starting at address X: $00 0000; see Figure 4-1. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 39 4.4 Data Map Table 4-4 Data Memory Map1 Begin/End Address Memory Allocation X:$FF FFFF X:$FF FF00 EOnCE 256 locations allocated X:$FF FEFF X:$01 0000 RESERVED X:$00 FFFF X:$00 F000 On-Chip Peripherals 4096 locations allocated X:$00 EFFF X:$00 8800 RESERVED X:$00 87FF X:$00 8000 RESERVED X:$00 7FFF X:$00 0800 RESERVED X:$00 07FF X:$00 0000 On-Chip Data RAM 8KB2 1. All addresses are 16-bit Word addresses. 2. This RAM is mapped into Program space starting at P: $00 8000; see Figure 4-1. Program Data EOnCE Reserved Reserved RAM Reserved Peripherals Dual Port RAM Reserved Flash RAM Figure 4-1 Dual Port RAM 56F8036 Data Sheet, Rev. 3 40 Freescale Semiconductor Preliminary EOnCE Memory Map 4.5 EOnCE Memory Map Figure 4-5 lists all EOnCE registers necessary to access or control the EOnCE. Table 4-5 EOnCE Memory Map Address Register Acronym Register Name X:$FF FFFF OTX1 / ORX1 Transmit Register Upper Word Receive Register Upper Word X:$FF FFFE OTX / ORX (32 bits) Transmit Register Receive Register X:$FF FFFD OTXRXSR Transmit and Receive Status and Control Register X:$FF FFFC OCLSR Core Lock / Unlock Status Register X:$FF FFFB - X:$FF FFA1 X:$FF FFA0 Reserved OCR Control Register X:$FF FF9F Instruction Step Counter X:$FF FF9E OSCNTR (24 bits) Instruction Step Counter X:$FF FF9D OSR Status Register X:$FF FF9C OBASE Peripheral Base Address Register X:$FF FF9B OTBCR Trace Buffer Control Register X:$FF FF9A OTBPR Trace Buffer Pointer Register X:$FF FF99 Trace Buffer Register Stages X:$FF FF98 OTB (21 - 24 bits/stage) Trace Buffer Register Stages X:$FF FF97 X:$FF FF96 Breakpoint Unit Control Register OBCR (24 bits) X:$FF FF95 X:$FF FF94 Breakpoint Unit Address Register 1 OBAR1 (24 bits) X:$FF FF93 X:$FF FF92 OBAR2 (32 bits) Breakpoint Unit Address Register 2 Breakpoint Unit Mask Register 2 OBMSK (32 bits) X:$FF FF8F X:$FF FF8E Breakpoint Unit Address Register 1 Breakpoint Unit Address Register 2 X:$FF FF91 X:$FF FF90 Breakpoint Unit Control Register Breakpoint Unit Mask Register 2 Reserved OBCNTR EOnCE Breakpoint Unit Counter X:$FF FF8D Reserved X:$FF FF8C Reserved X:$FF FF8B Reserved X:$FF FF8A X:$FF FF89 - X:$FF FF00 OESCR External Signal Control Register Reserved 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 41 4.6 Peripheral Memory-Mapped Registers On-chip peripheral registers are part of the data memory map on the 56800E series. These locations may be accessed with the same addressing modes used for ordinary Data memory, except all peripheral registers should be read or written using word accesses only. Table 4-6 summarizes base addresses for the set of peripherals on the 56F8036 device. Peripherals are listed in order of the base address. The following tables list all of the peripheral registers required to control or access the peripherals. Table 4-6 Data Memory Peripheral Base Address Map Summary Peripheral Prefix Base Address Table Number X:$00 F000 4-7 Timer A TMRA ADC ADC X:$00 F080 4-8 PWM PWM X:$00 F0C0 4-9 ITCN ITCN X:$00 F0E0 4-10 SIM SIM X:$00 F100 4-11 COP COP X:$00 F120 4-12 CLK, PLL, OSC OCCS X:$00 F130 4-13 Power Supervisor PS X:$00 F140 4-14 GPIO Port A GPIOA X:$00 F150 4-15 GPIO Port B GPIOB X:$00 F160 4-16 GPIO Port C GPIOC X:$00 F170 4-17 GPIO Port D GPIOD X:$00 F180 4-18 PIT 0 PIT0 X:$00 F190 4-19 PIT 1 PIT1 X:$00 F1A0 4-20 PIT 2 PIT2 X:$00 F1B0 4-21 DAC 0 DAC0 X:$00 F1C0 4-22 DAC 1 DAC1 X:$00 F1D0 4-23 Comparator A CMPA X:$00 F1E0 4-24 Comparator B CMPB X:$00 F1F0 4-25 QSCI 0 SCI0 X:$00 F200 4-26 QSPI 0 SPI0 X:$00 F220 4-27 2C I2C X:$00 F280 4-28 FM FM X:$00 F400 4-29 MSCAN CAN X:$00 F800 4-30 I 56F8036 Data Sheet, Rev. 3 42 Freescale Semiconductor Preliminary Peripheral Memory-Mapped Registers Table 4-7 Quad Timer A Registers Address Map (TMRA_BASE = $00 F000) Register Acronym Address Offset Register Description TMRA0_COMP1 $0 Compare Register 1 TMRA0_COMP2 $1 Compare Register 2 TMRA0_CAPT $2 Capture Register TMRA0_LOAD $3 Load Register TMRA0_HOLD $4 Hold Register TMRA0_CNTR $5 Counter Register TMRA0_CTRL $6 Control Register TMRA0_SCTRL $7 Status and Control Register TMRA0_CMPLD1 $8 Comparator Load Register 1 TMRA0_CMPLD2 $9 Comparator Load Register 2 TMRA0_CSCTRL $A Comparator Status and Control Register TMRA0_FILT $B Input Filter Register Reserved TMRA0_ENBL $F Timer Channel Enable Register TMRA1_COMP1 $10 Compare Register 1 TMRA1_COMP2 $11 Compare Register 2 TMRA1_CAPT $12 Capture Register TMRA1_LOAD $13 Load Register TMRA1_HOLD $14 Hold Register TMRA1_CNTR $15 Counter Register TMRA1_CTRL $16 Control Register TMRA1_SCTRL $17 Status and Control Register TMRA1_CMPLD1 $18 Comparator Load Register 1 TMRA1_CMPLD2 $19 Comparator Load Register 2 TMRA1_CSCTRL $1A Comparator Status and Control Register TMRA1_FILT $1B Input Filter Register Reserved TMRA2_COMP1 $20 Compare Register 1 TMRA2_COMP2 $21 Compare Register 2 TMRA2_CAPT $22 Capture Register TMRA2_LOAD $23 Load Register TMRA2_HOLD $24 Hold Register TMRA2_CNTR $25 Counter Register TMRA2_CTRL $26 Control Register TMRA2_SCTRL $27 Status and Control Register 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 43 Table 4-7 Quad Timer A Registers Address Map (Continued) (TMRA_BASE = $00 F000) Register Acronym Address Offset Register Description TMRA2_CMPLD1 $28 Comparator Load Register 1 TMRA2_CMPLD2 $29 Comparator Load Register 2 TMRA2_CSCTRL $2A Comparator Status and Control Register TMRA2_FILT $2B Input Filter Register Reserved TMRA3_COMP1 $30 Compare Register 1 TMRA3_COMP2 $31 Compare Register 2 TMRA3_CAPT $32 Capture Register TMRA3_LOAD $33 Load Register TMRA3_HOLD $34 Hold Register TMRA3_CNTR $35 Counter Register TMRA3_CTRL $36 Control Register TMRA3_SCTRL $37 Status and Control Register TMRA3_CMPLD1 $38 Comparator Load Register 1 TMRA3_CMPLD2 $39 Comparator Load Register 2 TMRA3_CSCTRL $3A Comparator Status and Control Register TMRA3_FILT $3B Input Filter Register Reserved Table 4-8 Analog-to-Digital Converter Registers Address Map (ADC_BASE = $00 F080) Register Acronym Address Offset Register Description ADC_CTRL1 $0 Control Register 1 ADC_CTRL2 $1 Control Register 2 ADC_ZXCTRL $2 Zero Crossing Control Register ADC_CLIST 1 $3 Channel List Register 1 ADC_CLIST 2 $4 Channel List Register 2 ADC_CLIST 3 $5 Channel List Register 3 ADC_CLIST 4 $6 Channel List Register 4 ADC_SDIS $7 Sample Disable Register ADC_STAT $8 Status Register ADC_RDY $9 Conversion Ready Register ADC_LIMSTAT $A Limit Status Register ADC_ZXSTAT $B Zero Crossing Status Register ADC_RSLT0 $C Result Register 0 ADC_RSLT1 $D Result Register 1 56F8036 Data Sheet, Rev. 3 44 Freescale Semiconductor Preliminary Peripheral Memory-Mapped Registers Table 4-8 Analog-to-Digital Converter Registers Address Map (Continued) (ADC_BASE = $00 F080) Register Acronym Address Offset Register Description ADC_RSLT2 $E Result Register 2 ADC_RSLT3 $F Result Register 3 ADC_RSLT4 $10 Result Register 4 ADC_RSLT5 $11 Result Register 5 ADC_RSLT6 $12 Result Register 6 ADC_RSLT7 $13 Result Register 7 ADC_RSLT8 $14 Result Register 8 ADC_RSLT9 $15 Result Register 9 ADC_RSLT10 $16 Result Register 10 ADC_RSLT11 $17 Result Register 11 ADC_RSLT12 $18 Result Register 12 ADC_RSLT13 $19 Result Register 13 ADC_RSLT14 $1A Result Register 14 ADC_RSLT15 $1B Result Register 15 ADC_LOLIM0 $1C Low Limit Register 0 ADC_LOLIM1 $1D Low Limit Register 1 ADC_LOLIM2 $1E Low Limit Register 2 ADC_LOLIM3 $1F Low Limit Register 3 ADC_LOLIM4 $20 Low Limit Register 4 ADC_LOLIM5 $21 Low Limit Register 5 ADC_LOLIM6 $22 Low Limit Register 6 ADC_LOLIM7 $23 Low Limit Register 7 ADC_HILIM0 $24 High Limit Register 0 ADC_HILIM1 $25 High Limit Register 1 ADC_HILIM2 $26 High Limit Register 2 ADC_HILIM3 $27 High Limit Register 3 ADC_HILIM4 $28 High Limit Register 4 ADC_HILIM5 $29 High Limit Register 5 ADC_HILIM6 $2A High Limit Register 6 ADC_HILIM7 $2B High Limit Register 7 ADC_OFFST0 $2C Offset Register 0 ADC_OFFST1 $2D Offset Register 1 ADC_OFFST2 $2E Offset Register 2 ADC_OFFST3 $2F Offset Register 3 ADC_OFFST4 $30 Offset Register 4 ADC_OFFST5 $31 Offset Register 5 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 45 Table 4-8 Analog-to-Digital Converter Registers Address Map (Continued) (ADC_BASE = $00 F080) Register Acronym Address Offset Register Description ADC_OFFST6 $32 Offset Register 6 ADC_OFFST7 $33 Offset Register 7 ADC_PWR $34 Power Control Register ADC_CAL $35 Calibration Register Reserved Table 4-9 Pulse Width Modulator Registers Address Map (PWM_BASE = $00 F0C0) Register Acronym Address Offset Register Description PWM_CTRL $0 Control Register PWM_FCTRL $1 Fault Control Register PWM_FLTACK $2 Fault Status Acknowledge Register PWM_OUT $3 Output Control Register PWM_CNTR $4 Counter Register PWM_CMOD $5 Counter Modulo Register PWM_VAL0 $6 Value Register 0 PWM_VAL1 $7 Value Register 1 PWM_VAL2 $8 Value Register 2 PWM_VAL3 $9 Value Register 3 PWM_VAL4 $A Value Register 4 PWM_VAL5 $B Value Register 5 PWM_DTIM0 $C Dead Time Register 0 PWM_DTIM1 $D Dead Time Register 1 PWM_DMAP1 $E Disable Mapping Register 1 PWM_DMAP2 $F Disable Mapping Register 2 PWM_CNFG $10 Configure Register PWM_CCTRL $11 Channel Control Register PWM_PORT $12 Port Register PWM_ICCTRL $13 Internal Correction Control Register PWM_SCTRL $14 Source Control Register PWM_SYNC $15 Synchronization Window Register PWM_FFILT0 $16 Fault0 Filter Register PWM_FFILT1 $17 Fault1 Filter Register PWM_FFILT2 $18 Fault2 Filter Register PWM_FFILT3 $19 Fault3 Filter Register 56F8036 Data Sheet, Rev. 3 46 Freescale Semiconductor Preliminary Peripheral Memory-Mapped Registers Table 4-10 Interrupt Control Registers Address Map (ITCN_BASE = $00 F0E0) Register Acronym Address Offset Register Description ITCN_IPR0 $0 Interrupt Priority Register 0 ITCN_IPR1 $1 Interrupt Priority Register 1 ITCN_IPR2 $2 Interrupt Priority Register 2 ITCN_IPR3 $3 Interrupt Priority Register 3 ITCN_IPR4 $4 Interrupt Priority Register 4 ITCN_IPR5 $5 Interrupt Priority Register 5 ITCN_IPR6 $6 Interrupt Priority Register 6 ITCN_VBA $7 Vector Base Address Register ITCN_FIM0 $8 Fast Interrupt Match 0 Register ITCN_FIVAL0 $9 Fast Interrupt Vector Address Low 0 Register ITCN_FIVAH0 $A Fast Interrupt Vector Address High 0 Register ITCN_FIM1 $B Fast Interrupt Match 1 Register ITCN_FIVAL1 $C Fast Interrupt Vector Address Low 1 Register ITCN_FIVAH1 $D Fast Interrupt Vector Address High 1 Register ITCN_IRQP0 $E IRQ Pending Register 0 ITCN_IRQP1 $F IRQ Pending Register 1 ITCN_IRQP2 $10 IRQ Pending Register 2 ITCN_IRQP3 $11 IRQ Pending Register 3 Reserved ITCN_ICTRL $16 Interrupt Control Register Reserved Table 4-11 SIM Registers Address Map (SIM_BASE = $00 F100) Register Acronym SIM_CTRL Address Offset $0 Register Description Control Register SIM_RSTAT $1 Reset Status Register SIM_SWC0 $2 Software Control Register 0 SIM_SWC1 $3 Software Control Register 1 SIM_SWC2 $4 Software Control Register 2 SIM_SWC3 $5 Software Control Register 3 SIM_MSHID $6 Most Significant Half JTAG ID SIM_LSHID $7 Least Significant Half JTAG ID SIM_PWR $8 Power Control Register 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 47 Table 4-11 SIM Registers Address Map (Continued) (SIM_BASE = $00 F100) Register Acronym Address Offset Register Description Reserved SIM_CLKOUT $A Clock Out Select Register SIM_PCR $B Peripheral Clock Rate Register SIM_PCE0 $C Peripheral Clock Enable Register 0 SIM_PCE1 $D Peripheral Clock Enable Register 1 SIM_SD0 $E Peripheral STOP Disable Register 0 SIM_SD1 $F Peripheral STOP Disable Register 1 SIM_IOSAHI $10 I/O Short Address Location High Register SIM_IOSALO $11 I/O Short Address Location Low Register SIM_PROT $12 Protection Register SIM_GPSA0 $13 GPIO Peripheral Select Register 0 for GPIOA SIM_GPSA1 $14 GPIO Peripheral Select Register 1 for GPIOA SIM_GPSB0 $15 GPIO Peripheral Select Register 0 for GPIOB SIM_GPSB1 $16 GPIO Peripheral Select Register 1 for GPIOB SIM_GPSCD $17 GPIO Peripheral Select Register for GPIOC and GPIOD SIM_IPS0 $18 Internal Peripheral Source Select Register 0 for PWM SIM_IPS1 $19 Internal Peripheral Source Select Register 1 for DACs SIM_IPS2 $1A Internal Peripheral Source Select Register 2 for TMRA Reserved Table 4-12 Computer Operating Properly Registers Address Map (COP_BASE = $00 F120) Register Acronym COP_CTRL Address Offset $0 Register Description Control Register COP_TOUT $1 Time-Out Register COP_CNTR $2 Counter Register Table 4-13 Clock Generation Module Registers Address Map (OCCS_BASE = $00 F130) Register Acronym Address Offset Register Description OCCS_CTRL $0 Control Register OCCS_DIVBY $1 Divide-By Register OCCS_STAT $2 Status Register Reserved OCCS_OCTRL $5 Oscillator Control Register OCCS_CLKCHK $6 Clock Check Register OCCS_PROT $7 Protection Register 56F8036 Data Sheet, Rev. 3 48 Freescale Semiconductor Preliminary Peripheral Memory-Mapped Registers Table 4-14 Power Supervisor Registers Address Map (PS_BASE = $00 F140) Register Acronym Address Offset Register Description PS_CTRL $0 Control Register PS_STAT $1 Status Register Reserved Table 4-15 GPIOA Registers Address Map (GPIOA_BASE = $00 F150) Register Acronym Address Offset Register Description GPIOA_PUPEN $0 Pull-up Enable Register GPIOA_DATA $1 Data Register GPIOA_DDIR $2 Data Direction Register GPIOA_PEREN $3 Peripheral Enable Register GPIOA_IASSRT $4 Interrupt Assert Register GPIOA_IEN $5 Interrupt Enable Register GPIOA_IEPOL $6 Interrupt Edge Polarity Register GPIOA_IPEND $7 Interrupt Pending Register GPIOA_IEDGE $8 Interrupt Edge-Sensitive Register GPIOA_PPOUTM $9 Push-Pull Output Mode Control Register GPIOA_RDATA $A Raw Data Input Register GPIOA_DRIVE $B Output Drive Strength Control Register Table 4-16 GPIOB Registers Address Map (GPIOB_BASE = $00 F160) Register Acronym Address Offset Register Description GPIOB_PUPEN $0 Pull-up Enable Register GPIOB_DATA $1 Data Register GPIOB_DDIR $2 Data Direction Register GPIOB_PEREN $3 Peripheral Enable Register GPIOB_IASSRT $4 Interrupt Assert Register GPIOB_IEN $5 Interrupt Enable Register GPIOB_IEPOL $6 Interrupt Edge Polarity Register GPIOB_IPEND $7 Interrupt Pending Register GPIOB_IEDGE $8 Interrupt Edge-Sensitive Register GPIOB_PPOUTM $9 Push-Pull Output Mode Control Register GPIOB_RDATA $A Raw Data Input Register GPIOB_DRIVE $B Output Drive Strength Control Register 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 49 Table 4-17 GPIOC Registers Address Map (GPIOC_BASE = $00 F170) Register Acronym Address Offset Register Description GPIOC_PUPEN $0 Pull-up Enable Register GPIOC_DATA $1 Data Register GPIOC_DDIR $2 Data Direction Register GPIOC_PEREN $3 Peripheral Enable Register GPIOC_IASSRT $4 Interrupt Assert Register GPIOC_IEN $5 Interrupt Enable Register GPIOC_IEPOL $6 Interrupt Edge Polarity Register GPIOC_IPEND $7 Interrupt Pending Register GPIOC_IEDGE $8 Interrupt Edge-Sensitive Register GPIOC_PPOUTM $9 Push-Pull Output Mode Control Register GPIOC_RDATA $A Raw Data Input Register GPIOC_DRIVE $B Output Drive Strength Control Register Table 4-18 GPIOD Registers Address Map (GPIOD_BASE = $00 F180) Register Acronym Address Offset Register Description GPIOD_PUPEN $0 Pull-up Enable Register GPIOD_DATA $1 Data Register GPIOD_DDIR $2 Data Direction Register GPIOD_PEREN $3 Peripheral Enable Register GPIOD_IASSRT $4 Interrupt Assert Register GPIOD_IEN $5 Interrupt Enable Register GPIOD_IEPOL $6 Interrupt Edge Polarity Register GPIOD_IPEND $7 Interrupt Pending Register GPIOD_IEDGE $8 Interrupt Edge-Sensitive Register GPIOD_PPOUTM $9 Push-Pull Output Mode Control Register GPIOD_RDATA $A Raw Data Input Register GPIOD_DRIVE $B Output Drive Strength Control Register Table 4-19 Programmable Interval Timer 0 Registers Address Map (PIT0_BASE = $00 F190) Register Acronym Address Offset Register Description PIT0_CTRL $0 Control Register PIT0_MOD $1 Modulo Register PIT0_CNTR $2 Counter Register 56F8036 Data Sheet, Rev. 3 50 Freescale Semiconductor Preliminary Peripheral Memory-Mapped Registers Table 4-20 Programmable Interval Timer 1 Registers Address Map (PIT1_BASE = $00 F1A0) Register Acronym Address Offset Register Description PIT1_CTRL $0 Control Register PIT1_MOD $1 Modulo Register PIT1_CNTR $2 Counter Register Table 4-21 Programmable Interval Timer 2 Registers Address Map (PIT2_BASE = $00 F1B0) Register Acronym Address Offset Register Description PIT2_CTRL $0 Control Register PIT2_MOD $1 Modulo Register PIT2_CNTR $2 Counter Register Table 4-22 Digital-to-Analog Converter 0 Registers Address Map (DAC0_BASE = $00 F1C0) Register Acronym Address Offset Register Description DAC0_CTRL $0 Control Register DAC0_DATA $1 Data Register DAC0_STEP $2 Step Register DAC0_MINVAL $3 Minimum Value Register DAC0_MAXVAL $4 Maximum Value Register Table 4-23 Digital-to-Analog Converter 0 Registers Address Map (DAC1_BASE = $00 F1D0) Register Acronym Address Offset Register Description DAC1_CTRL $0 Control Register DAC1_DATA $1 Data Register DAC1_STEP $2 Step Register DAC1_MINVAL $3 Minimum Value Register DAC1_MAXVAL $4 Maximum Value Register 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 51 Table 4-24 Comparator A Registers Address Map (CMPA_BASE = $00 F1E0) Register Acronym Address Offset Register Description CMPA_CTRL $0 Control Register CMPA_STAT $1 Status Register CMPA_FILT $2 Filter Register Table 4-25 Comparator B Registers Address Map (CMPB_BASE = $00 F1F0) Register Acronym Address Offset Register Description CMPB_CTRL $0 Control Register CMPB_STAT $1 Status Register CMPB_FILT $2 Filter Register Table 4-26 Queued Serial Communication Interface 0 Registers Address Map (QSCI0_BASE = $00 F200) Register Acronym Address Offset Register Description QSCI0_RATE $0 Baud Rate Register QSCI0_CTRL1 $1 Control Register 1 QSCI0_CTRL2 $2 Control Register 2 QSCI0_STAT $3 Status Register QSCI0_DATA $4 Data Register Table 4-27 Queued Serial Peripheral Interface 0 Registers Address Map (QSPI0_BASE = $00 F220) Register Acronym Address Offset Register Description QSPI0_SCTRL $0 Status and Control Register QSPI0_DSCTRL $1 Data Size and Control Register QSPI0_DRCV $2 Data Receive Register QSPI0_DXMIT $3 Data Transmit Register QSPI0_FIFO $4 FIFO Control Register QSPI0_DELAY $5 Delay Register 56F8036 Data Sheet, Rev. 3 52 Freescale Semiconductor Preliminary Peripheral Memory-Mapped Registers Table 4-28 I2C Registers Address Map (I2C_BASE = $00 F280) Register Acronym Address Offset Register Description I2C_CTRL $0 Control Register I2C_TAR $2 Target Address Register I2C_SAR $4 Slave Address Register I2C_DATA $8 RX/TX Data Buffer and Command Register I2C_SSHCNT $A Standard Speed Clock SCL High Count Register I2C_SSLCNT $C Standard Speed Clock SCL Low Count Register I2C_FSHCNT $E Fast Speed Clock SCL High Count Register I2C_FSLCNT $10 Fast Speed Clock SCL Low Count Register I2C_ISTAT $16 Interrupt Status Register I2C_IMASK $18 Interrupt Mask Register I2C_RISTAT $1A Raw Interrupt Status Register I2C_RXFT $1C Receive FIFO Threshold Register I2C_TXFT $1E Transmit FIFO Threshold Register I2C_CLRINT $20 Clear Combined and Individual Interrupts Register I2C_CLRRXUND $22 Clear RX_UNDER Interrupt Register I2C_CLRRXOVR $24 Clear RX_OVER Interrupt Register I2C_CLRTXOVR $26 Clear TX_OVER Interrupt Register I2C_CLRRDREQ $28 Clear RD_REQ Interrupt Register I2C_CLRTXABRT $2A Clear TX_ABRT Interrupt Register I2C_CLRRXDONE $2C Clear RX_DONE Interrupt Register I2C_CLRACT $2E Clear Activity Interrupt Register I2C_CLRSTPDET $30 Clear STOP_DET Interrupt Register I2C_CLRSTDET $32 Clear START_DET Interrupt Register I2C_CLRGC $34 Clear GEN_CALL Interrupt Register I2C_ENBL $36 Enable Register I2C_STAT $38 Status Register I2C_TXFLR $3A Transmit FIFO Level Register I2C_RXFLR $3C Receive FIFO Level Register I2C_TXABRTSRC $40 Transmit Abort Status Register 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 53 Table 4-29 Flash Module Registers Address Map (FM_BASE = $00 F400) Register Acronym Address Offset Register Description FM_CLKDIV $0 Clock Divider Register FM_CNFG $1 Configuration Register $2 Reserved FM_SECHI $3 Security High Half Register FM_SECLO $4 Security Low Half Register $5 - $9 FM_PROT $10 Reserved Protection Register $11 - $12 Reserved FM_USTAT $13 User Status Register FM_CMD $14 Command Register $15 - $17 FM_DATA $18 Data Buffer Register $19 - $A FM_IFROPT_1 FM_TSTSIG Reserved Reserved $1B Information Option Register 1 $1C Reserved $1D Test Array Signature Register Table 4-30 MSCAN Registers Address Map (MSCAN_BASE = $00 F800) Register Acronym Address Offset Register Description MSCAN_CTRL0 $00 Control Register 0 MSCAN_CTRL1 $01 Control Register 1 MSCAN_BTR0 $02 Bus Timing Register 0 MSCAN_BTR1 $03 Bus Timing Register 1 MSCAN_RFLG $04 Receiver Flag Register MSCAN_RIER $05 Receiver Interrupt Enable Register MSCAN_TFLG $06 Transmitter Flag Register MSCAN_TIER $07 Transmitter Interrupt Enable Register MSCAN_TARQ $08 Transmitter Message Abort Request Register MSCAN_TAAK $09 Transmitter Message Abort Acknowledge Register MSCAN_TBSEL $0A Transmitter Buffer Selection Register MSCAN_IDAC $0B Identifier Acceptance Control Register Reserved MSCAN_MISC $0D Miscellaneous Register MSCAN_RXERR $0E Receive Error Register 56F8036 Data Sheet, Rev. 3 54 Freescale Semiconductor Preliminary Peripheral Memory-Mapped Registers Table 4-30 MSCAN Registers Address Map (Continued) (MSCAN_BASE = $00 F800) Register Acronym Address Offset Register Description MSCAN_TXERR $0F Transmit Error Register MSCAN_IDAR0 $10 Identifier Acceptance Register 0 MSCAN_IDAR1 $11 Identifier Acceptance Register 1 MSCAN_IDAR2 $12 Identifier Acceptance Register 2 MSCAN_IDAR3 $13 Identifier Acceptance Register 3 MSCAN_IDMR0 $14 Identifier Mask Register 0 MSCAN_IDMR1 $15 Identifier Mask Register 1 MSCAN_IDMR2 $16 Identifier Mask Register 2 MSCAN_IDMR3 $17 Identifier Mask Register 3 MSCAN_IDAR4 $18 Identifier Acceptance Register 4 MSCAN_IDAR5 $19 Identifier Acceptance Register 5 MSCAN_IDAR6 $1A Identifier Acceptance Register 6 MSCAN_IDAR7 $1B Identifier Acceptance Register 7 MSCAN_IDMR4 $1C Identifier Mask Register 4 MSCAN_IDMR5 $1D Identifier Mask Register 5 MSCAN_IDMR6 $1E Identifier Mask Register 6 MSCAN_IDMR7 $1F Identifier Mask Register 7 MSCAN_RXFG0 $20 Foreground Receive Buffer 0 MSCAN_RXFG1 $21 Foreground Receive Buffer 1 MSCAN_RXFG2 $22 Foreground Receive Buffer 2 MSCAN_RXFG3 $23 Foreground Receive Buffer 3 MSCAN_RXFG4 $24 Foreground Receive Buffer 4 MSCAN_RXFG5 $25 Foreground Receive Buffer 5 MSCAN_RXFG6 $26 Foreground Receive Buffer 6 MSCAN_RXFG7 $27 Foreground Receive Buffer 7 MSCAN_RXFG8 $28 Foreground Receive Buffer 8 MSCAN_RXFG9 $29 Foreground Receive Buffer 9 MSCAN_RXFG10 $2A Foreground Receive Buffer 10 MSCAN_RXFG11 $2B Foreground Receive Buffer 11 MSCAN_RXFG12 $2C Foreground Receive Buffer 12 MSCAN_RXFG13 $2D Foreground Receive Buffer 13 MSCAN_RXFG14 $2E Foreground Receive Buffer 14 MSCAN_RXFG15 $2F Foreground Receive Buffer 15 MSCAN_TXFG0 $30 Foreground Transmit Buffer 0 MSCAN_TXFG1 $31 Foreground Transmit Buffer 1 MSCAN_TXFG2 $32 Foreground Transmit Buffer 2 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 55 Table 4-30 MSCAN Registers Address Map (Continued) (MSCAN_BASE = $00 F800) Register Acronym Address Offset Register Description MSCAN_TXFG3 $33 Foreground Transmit Buffer 3 MSCAN_TXFG4 $34 Foreground Transmit Buffer 4 MSCAN_TXFG5 $35 Foreground Transmit Buffer 5 MSCAN_TXFG6 $36 Foreground Transmit Buffer 6 MSCAN_TXFG7 $37 Foreground Transmit Buffer 7 MSCAN_TXFG8 $38 Foreground Transmit Buffer 8 MSCAN_TXFG9 $39 Foreground Transmit Buffer 9 MSCAN_TXFG10 $3A Foreground Transmit Buffer 10 MSCAN_TXFG11 $3B Foreground Transmit Buffer 11 MSCAN_TXFG12 $3C Foreground Transmit Buffer 12 MSCAN_TXFG13 $3D Foreground Transmit Buffer 13 MSCAN_TXFG14 $3E Foreground Transmit Buffer 14 MSCAN_TXFG15 $3F Foreground Transmit Buffer 15 Reserved Part 5 Interrupt Controller (ITCN) 5.1 Introduction The Interrupt Controller (ITCN) module arbitrates between various interrupt requests (IRQs), signals to the 56800E core when an interrupt of sufficient priority exists, and to what address to jump in order to service this interrupt. 5.2 Features The ITCN module design includes these distinctive features: • • • • Programmable priority levels for each IRQ Two programmable Fast Interrupts Notification to SIM module to restart clocks out of Wait and Stop modes Ability to drive initial address on the address bus after reset For further information, see Table 4-2, Interrupt Vector Table Contents. 5.3 Functional Description The Interrupt Controller is a slave on the IPBus. It contains registers that allow each of the 64 interrupt sources to be set to one of four priority levels (excluding certain interrupts that are of fixed priority). Next, all of the interrupt requests of a given level are priority encoded to determine the lowest numerical value of the active interrupt requests for that level. Within a given priority level, number 0 is the highest priority and number 63 is the lowest. 56F8036 Data Sheet, Rev. 3 56 Freescale Semiconductor Preliminary Functional Description 5.3.1 Normal Interrupt Handling Once the INTC has determined that an interrupt is to be serviced and which interrupt has the highest priority, an interrupt vector address is generated. Normal interrupt handling concatenates the Vector Base Address (VBA) and the vector number to determine the vector address, generating an offset into the vector table for each interrupt. 5.3.2 Interrupt Nesting Interrupt exceptions may be nested to allow an IRQ of higher priority than the current exception to be serviced. The 56800E core controls the masking of interrupt priority levels it will accept by setting the I0 and I1 bits in its status register. Table 5-1 Interrupt Mask Bit Definition SR[9] (I1) SR[8] (I0) Exceptions Permitted Exceptions Masked 0 0 Priorities 0, 1, 2, 3 None 0 1 Priorities 1, 2, 3 Priority 0 1 0 Priorities 2, 3 Priorities 0, 1 1 1 Priority 3 Priorities 0, 1, 2 The IPIC bits of the ICTRL register reflect the state of the priority level being presented to the 56800E core. Table 5-2 Interrupt Priority Encoding 5.3.3 IPIC_VALUE[1:0] Current Interrupt Priority Level Required Nested Exception Priority 00 No interrupt or SWILP Priorities 0, 1, 2, 3 01 Priority 0 Priorities 1, 2, 3 10 Priority 1 Priorities 2, 3 11 Priority 2 or 3 Priority 3 Fast Interrupt Handling Fast interrupts are described in the DSP56800E Reference Manual. The interrupt controller recognizes Fast Interrupts before the core does. A Fast Interrupt is defined (to the ITCN) by: 1. Setting the priority of the interrupt as level 2, with the appropriate field in the IPR registers 2. Setting the FIMn register to the appropriate vector number 3. Setting the FIVALn and FIVAHn registers with the address of the code for the Fast Interrupt 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 57 When an interrupt occurs, its vector number is compared with the FIM0 and FIM1 register values. If a match occurs, and it is a level 2 interrupt, the ITCN handles it as a Fast Interrupt. The ITCN takes the vector address from the appropriate FIVALn and FIVAHn registers, instead of generating an address that is an offset from the VBA. The core then fetches the instruction from the indicated vector address and if it is not a JSR, the core starts its Fast Interrupt handling. 5.4 Block Diagram Priority Level INT1 2 -> 4 Decode any0 Level 0 64 -> 6 Priority Encoder 6 INT VAB CONTROL any3 Level 3 Priority Level INT64 IPIC IACK SR[9:8] 64 -> 6 Priority Encoder 6 PIC_EN 2 -> 4 Decode Figure 5-1 Interrupt Controller Block Diagram 56F8036 Data Sheet, Rev. 3 58 Freescale Semiconductor Preliminary Operating Modes 5.5 Operating Modes The ITCN module design contains two major modes of operation: • • Functional Mode The ITCN is in this mode by default. Wait and Stop Modes During Wait and Stop modes, the system clocks and the 56800E core are turned off. The ITCN will signal a pending IRQ to the System Integration Module (SIM) to restart the clocks and service the IRQ. An IRQ can only wake up the core if the IRQ is enabled prior to entering the Wait or Stop mode. 5.6 Register Descriptions A register address is the sum of a base address and an address offset. The base address is defined at the system level and the address offset is defined at the module level. Table 5-3 ITCN Register Summary (ITCN_BASE = $00 F060) Register Acronym Base Address + Register Name Section Location IPR0 $0 Interrupt Priority Register 0 5.6.1 IPR1 $1 Interrupt Priority Register 1 5.6.2 IPR2 $2 Interrupt Priority Register 2 5.6.3 IPR3 $3 Interrupt Priority Register 3 5.6.4 IPR4 $4 Interrupt Priority Register 4 5.6.5 IPR5 $5 Interrupt Priority Register 5 5.6.6 IPR6 $6 Interrupt Priority Register 6 5.6.7 VBA $7 Vector Base Address Register 5.6.8 FIM0 $8 Fast Interrupt Match 0 Register 5.6.9 FIVAL0 $9 Fast Interrupt 0 Vector Address Low Register 5.6.10 FIVAH0 $A Fast Interrupt 0 Vector Address High 0 Register 5.6.11 FIM1 $B Fast Interrupt Match 1 Register 5.6.12 FIVAL1 $C Fast Interrupt 1 Vector Address Low Register 5.6.13 FIVAH1 $D Fast Interrupt 1 Vector Address High Register 5.6.14 IRQP0 $E IRQ Pending Register 0 5.6.15 IRQP1 $F IRQ Pending Register 1 5.6.16 IRQP2 $10 IRQ Pending Register 2 5.6.17 IRQP3 $11 IRQ Pending Register 3 5.6.18 Reserved ICTRL $16 Interrupt Control Register 5.6.19 Reserved 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 59 Add. Offset Register Name $0 IPR0 $1 IPR1 $2 IPR2 $3 IPR3 $4 IPR4 $5 IPR5 $6 IPR6 $7 VBA $8 FIM0 $9 FIVAL0 $A FIVAH0 $B FIM1 $C FIVAL1 $D FIVAH1 $E IRQP0 $F IRQP1 $10 IRQP2 $11 IRQP3 15 R W R W R W R W R W R W R 14 13 12 PLL IPL LVI IPL GPIOD IPL MSCAN_WK UP IPL QSCI0_XMIT IPL I2C_ERR IPL 11 10 0 0 MSCAN_TX IPL 0 0 0 0 0 0 0 0 9 6 5 4 0 STPCNT IPL MSCAN_RX IPL MSCAN_ERR IPL FM_CBE IPL FM_CC IPL FM_ERR IPL QSPI0_XMIT IPL QSPI0_RCV IPL GPIOA IPL GPIOB IPL GPIOC IPL QSCI0_RCV IPL QSCI0_RERR IPL QSCI0_TIDL IPL I2C_TX IPL I2C_RX IPL I2C_GEN IPL 0 0 TMRA_1 IPL TMRA_0 IPL PIT1 IPL PIT0 IPL COMPB IPL COMPA IPL 0 0 0 PWM_F IPL PWM_RL IPL 0 0 0 0 0 0 I2C_STAT IPL 0 0 ADC_ZC IPL 0 0 0 ADCB_CC IPL 0 ADCA_CC IPL 0 0 PIT2 IPL VECTOR_BASE_ADDRESS 0 0 0 R 0 0 0 0 0 FAST INTERRUPT 0 FAST INTERRUPT 0 VECTOR ADDRESS LOW 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 FAST INTERRUPT 0 VECTOR ADDRESS HIGH W FAST INTERRUPT 1 W R FAST INTERRUPT 1 VECTOR ADDRESS LOW W R 1 BKPT_U IPL TMRA_2 IPL W R 2 TRBUF IPL W R 3 TX_REG IPL TMRA_3 IPL 0 7 RX_REG IPL W R 8 0 0 0 0 0 0 0 0 0 0 0 FAST INTERRUPT 1 VECTOR ADDRESS HIGH W R 1 PENDING[16:2] W R PENDING[32:17] W R PENDING[48:33] W R PENDING[63:49] W Reserved $16 ICTRL R INT IPIC VAB W INT_ DIS 1 1 1 0 0 Reserved = Reserved Figure 5-2 ITCN Register Map Summary 56F8036 Data Sheet, Rev. 3 60 Freescale Semiconductor Preliminary Register Descriptions 5.6.1 Interrupt Priority Register 0 (IPR0) Base + $0 Read 15 14 13 PLL IPL Write RESET 0 0 12 11 10 0 0 0 0 LVI IPL 0 0 9 8 RX_REG IPL 0 0 7 6 TX_REG IPL 0 0 5 4 TRBUF IPL 0 0 3 2 BKPT_U IPL 0 0 1 0 STPCNT IPL 0 0 Figure 5-3 Interrupt Priority Register 0 (IPR0) 5.6.1.1 PLL Loss of Reference or Change in Lock Status Interrupt Priority Level (PLL IPL)—Bits 15–14 This field is used to set the interrupt priority levels for the PLL Loss of Reference or Change in Lock Status IRQ. This IRQ is limited to priorities 1 through 3. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 1 10 = IRQ is priority level 2 11 = IRQ is priority level 3 5.6.1.2 Low Voltage Detector Interrupt Priority Level (LVI IPL)—Bits 13–12 This field is used to set the interrupt priority levels for the Low Voltage Detector IRQ. This IRQ is limited to priorities 1 through 3 and is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 1 10 = IRQ is priority level 2 11 = IRQ is priority level 3 5.6.1.3 Reserved—Bits 11–10 This bit field is reserved. Each bit must be set to 0. 5.6.1.4 EOnCE Receive Register Full Interrupt Priority Level (RX_REG IPL)— Bits 9–8 This field is used to set the interrupt priority level for the EOnCE Receive Register Full IRQ. This IRQ is limited to priorities 1 through 3. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 1 10 = IRQ is priority level 2 11 = IRQ is priority level 3 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 61 5.6.1.5 EOnCE Transmit Register Empty Interrupt Priority Level (TX_REG IPL)— Bits 7–6 This field is used to set the interrupt priority level for the EOnCE Transmit Register Empty IRQ. This IRQ is limited to priorities 1 through 3. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 1 10 = IRQ is priority level 2 11 = IRQ is priority level 3 5.6.1.6 EOnCE Trace Buffer Interrupt Priority Level (TRBUF IPL)— Bits 5–4 This field is used to set the interrupt priority level for the EOnCE Trace Buffer IRQ. This IRQ is limited to priorities 1 through 3. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 1 10 = IRQ is priority level 2 11 = IRQ is priority level 3 5.6.1.7 EOnCE Breakpoint Unit Interrupt Priority Level (BKPT_U IPL)— Bits 3–2 This field is used to set the interrupt priority level for the EOnCE Breakpoint Unit IRQ. This IRQ is limited to priorities 1 through 3. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 1 10 = IRQ is priority level 2 11 = IRQ is priority level 3 5.6.1.8 EOnCE Step Counter Interrupt Priority Level (STPCNT IPL)— Bits 1–0 This field is used to set the interrupt priority level for the EOnCE Step Counter IRQ. This IRQ is limited to priorities 1 through 3. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 1 10 = IRQ is priority level 2 11 = IRQ is priority level 3 56F8036 Data Sheet, Rev. 3 62 Freescale Semiconductor Preliminary Register Descriptions 5.6.2 Interrupt Priority Register 1 (IPR1) Base + $1 Read 15 14 GPIOD IPL Write RESET 0 0 13 12 MSCAN_WK UP IPL 0 0 11 10 MSCAN_TX IPL 0 0 9 8 MSCAN_RX IPL 0 0 7 6 MSCAN_ERR IPL 0 0 5 4 FM_CBE IPL 0 0 3 2 FM_CC IPL 0 0 1 0 FM_ERR IPL 0 0 Figure 5-4 Interrupt Priority Register 1 (IPR1) 5.6.2.1 GPIOD Interrupt Priority Level (GPIOD IPL)—Bits 15–14 This field is used to set the interrupt priority level for the GPIOD IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.2.2 MSCAN Wake Up Interrupt Priority Level (MSCAN_WKUP IPL)—Bits 13–12 This field is used to set the interrupt priority level for the MSCAN Wake Up IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.2.3 MSCAN Transmit Interrupt Priority Level (MSCAN_TX IPL)—Bits 11–10 This field is used to set the interrupt priority level for the MSCAN Transmit IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 63 5.6.2.4 MSCAN Receive Interrupt Priority Level (MSCAN_RX IPL)—Bits 9–8 This field is used to set the interrupt priority level for MSCAN Receive IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.2.5 MSCAN Error Interrupt Priority Level (MSCAN_ERR IPL)—Bits 7–6 This field is used to set the interrupt priority level for the MSCAN Error IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.2.6 FM Command, Data, Address Buffers Empty Interrupt Priority Level (FM_CBE IPL)—Bits 5–4 This field is used to set the interrupt priority level for the FM Command, Data Address Buffers Empty IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.2.7 FM Command Complete Interrupt Priority Level (FM_CC IPL)—Bits 3–2 This field is used to set the interrupt priority level for the FM Command Complete IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.2.8 FM Error Interrupt Priority Level (FM_ERR IPL)—Bits 1–0 This field is used to set the interrupt priority level for the FM Error IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 56F8036 Data Sheet, Rev. 3 64 Freescale Semiconductor Preliminary Register Descriptions 5.6.3 Interrupt Priority Register 2 (IPR2) Base + $2 Read 15 14 QSCI0_XMIT IPL Write RESET 0 0 13 12 11 10 0 0 0 0 0 0 0 0 9 8 QSPI0_XMIT IPL 0 0 7 6 QSPI0_RCV IPL 0 0 5 4 GPIOA IPL 0 0 3 2 GPIOB IPL 0 0 1 0 GPIOC IPL 0 0 Figure 5-5 Interrupt Priority Register 2 (IPR2) 5.6.3.1 QSCI 0 Transmitter Empty Interrupt Priority Level (QSCI0_XMIT IPL)— Bits 15–14 This field is used to set the interrupt priority level for the QSCI0 Transmitter Empty IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.3.2 Reserved—Bits 13–10 This bit field is reserved. Each bit must be set to 0. 5.6.3.3 QSPI 0 Transmitter Empty Interrupt Priority Level (QSPI0_XMIT IPL)— Bits 9–8 This field is used to set the interrupt priority level for the QSPI0 Transmitter Empty IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.3.4 QSPI 0 Receiver Full Interrupt Priority Level (QSPI0_RCV IPL)—Bits 7–6 This field is used to set the interrupt priority level for the QSPI0 Receiver Full IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 65 5.6.3.5 GPIOA Interrupt Priority Level (GPIOA IPL)—Bits 5–4 This field is used to set the interrupt priority level for the GPIOA IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.3.6 GPIOB Interrupt Priority Level (GPIOB IPL)—Bits 3–2 This field is used to set the interrupt priority level for the GPIOB IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.3.7 GPIOC Interrupt Priority Level (GPIOC IPL)—Bits 1–0 This field is used to set the interrupt priority level for the GPIOC IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.4 Interrupt Priority Register 3 (IPR3) Base + $3 Read 15 14 I2C_ERR IPL Write RESET 0 0 13 12 11 10 9 8 7 6 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 5 4 QSCI0_RCV IPL 0 0 3 2 QSCI0_RERR IPL 0 0 1 0 QSCI0_TIDL IPL 0 0 Figure 5-6 Interrupt Priority Register 3 (IPR3) 5.6.4.1 I2C Error Interrupt Priority Level (I2C_ERR IPL)—Bits 15–14 This field is used to set the interrupt priority level for the I2C Error IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 56F8036 Data Sheet, Rev. 3 66 Freescale Semiconductor Preliminary Register Descriptions 5.6.4.2 Reserved—Bits 13–6 This bit field is reserved. Each bit must be set to 0. 5.6.4.3 QSCI 0 Receiver Full Interrupt Priority Level (QSCI0_RCV IPL)—Bits 5–4 This field is used to set the interrupt priority level for the QSCI0 Receiver Full IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.4.4 QSCI 0 Receiver Error Interrupt Priority Level (QSCI0_RERR IPL)— Bits 3–2 This field is used to set the interrupt priority level for the QSCI0 Receiver Error IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.4.5 QSCI 0 Transmitter Idle Interrupt Priority Level (QSCI0_TIDL IPL)— Bits 1–0 This field is used to set the interrupt priority level for the QSCI0 Transmitter Idle IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.5 Interrupt Priority Register 4 (IPR4) Base + $4 Read Write RESET 15 14 TMRA_3 IPL 0 0 13 12 TMRA_2 IPL 0 0 11 10 TMRA_1 IPL 0 0 9 8 TMRA_0 IPL 0 0 7 6 I2C_STAT IPL 0 0 5 4 I2C_TX IPL 0 0 3 2 I2C_RX IPL 0 0 1 0 I2C_GEN IPL 0 0 Figure 5-7 Interrupt Priority Register 4 (IPR4) 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 67 5.6.5.1 Timer A, Channel 3 Interrupt Priority Level (TMRA_3 IPL)— Bits 15–14 This field is used to set the interrupt priority level for the Timer A, Channel 3 IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.5.2 Timer A, Channel 2 Interrupt Priority Level (TMRA_2 IPL)— Bits 13–12 This field is used to set the interrupt priority level for the Timer A, Channel 2 IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.5.3 Timer A, Channel 1 Interrupt Priority Level (TMRA_1 IPL)— Bits 11–10 This field is used to set the interrupt priority level for the Timer A, Channel 1 IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.5.4 Timer A, Channel 0 Interrupt Priority Level (TMRA_0 IPL)— Bits 9–8 This field is used to set the interrupt priority level for the Timer A, Channel 0 IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 56F8036 Data Sheet, Rev. 3 68 Freescale Semiconductor Preliminary Register Descriptions I2C Status Interrupt Priority Level (I2C_STAT IPL)—Bits 7–6 5.6.5.5 This field is used to set the interrupt priority level for the I2C Status IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 I2C Transmit Interrupt Priority Level (I2C_TX IPL)—Bits 5–4 5.6.5.6 This field is used to set the interrupt priority level for the I2C Transmit IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 I2C Receive Interrupt Priority Level (I2C_RX IPL)— Bits 3–2 5.6.5.7 This field is used to set the interrupt priority level for the I2C Receiver IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 I2C General Call Interrupt Priority Level (I2C_GEN IPL)—Bits 1–0 5.6.5.8 This field is used to set the interrupt priority level for the I2C General Call IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.6 Interrupt Priority Register 5 (IPR5) Base + $5 Read Write RESET 15 14 13 12 PIT1 IPL PIT0 IPL 0 0 0 0 11 10 COMPB IPL 0 0 9 8 COMPA IPL 0 0 7 6 5 4 3 2 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Figure 5-8 Interrupt Priority Register 5 (IPR6) 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 69 5.6.6.1 Programmable Interval Timer 1 Interrupt Priority Level (PIT1 IPL)— Bits 15–14 This field is used to set the interrupt priority level for the Programmable Interval Timer 1 IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.6.2 Programmable Interval Timer 0 Interrupt Priority Level (PIT0 IPL)— Bits 13–12 This field is used to set the interrupt priority level for the Programmable Interval Timer 0 IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.6.3 Comparator B Interrupt Priority Level (COMPB IPL)— Bits 11–10 This field is used to set the interrupt priority level for the Comparator B IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.6.4 Comparator A Interrupt Priority Level (COMPA IPL)— Bits 9–8 This field is used to set the interrupt priority level for the Comparator IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.6.5 Reserved—Bits 7–0 This bit field is reserved. Each bit must be set to 0. 56F8036 Data Sheet, Rev. 3 70 Freescale Semiconductor Preliminary Register Descriptions 5.6.7 Interrupt Priority Register 6 (IPR6) Base + $6 15 14 13 12 Read 0 0 0 0 0 0 0 0 Write RESET 11 10 PWM_F IPL 0 9 8 PWM_RL IPL 0 0 0 7 6 ADC_ZC IPL 0 0 5 4 ADCB_CC IPL 0 0 3 2 ADCA_CC IPL 0 0 1 0 PIT2 IPL 0 0 Figure 5-9 Interrupt Priority Register 6 (IPR6) 5.6.7.1 Reserved—Bits 15–12 This bit field is reserved. Each bit must be set to 0. 5.6.7.2 PWM Fault Interrupt Priority Level (PWM_F IPL)—Bits 11–10 This field is used to set the interrupt priority level for the PWM Fault Interrupt IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.7.3 Reload PWM Interrupt Priority Level (PWM_RL IPL)—Bits 9–8 This field is used to set the interrupt priority level for the Reload PWM Interrupt IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.7.4 ADC Zero Crossing Interrupt Priority Level (ADC_ZC IPL)—Bits 7–6 This field is used to set the interrupt priority level for the ADC Zero Crossing IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 71 5.6.7.5 ADC B Conversion Complete Interrupt Priority Level (ADCB_CC IPL)—Bits 5–4 This field is used to set the interrupt priority level for the ADC B Conversion Complete IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.7.6 ADC A Conversion Complete Interrupt Priority Level (ADCA_CC IPL)—Bits 3–2 This field is used to set the interrupt priority level for the ADC A Conversion Complete IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.7.7 Programmable Interval Timer 2 Interrupt Priority Level (PIT2 IPL)—Bits 1–0 This field is used to set the interrupt priority level for the Programmable Interval Timer 2 IRQ. This IRQ is limited to priorities 0 through 2. It is disabled by default. • • • • 00 = IRQ disabled (default) 01 = IRQ is priority level 0 10 = IRQ is priority level 1 11 = IRQ is priority level 2 5.6.8 Vector Base Address Register (VBA) Base + $7 15 14 Read 0 0 0 0 13 12 11 10 9 7 6 5 4 3 2 1 0 01 0 0 0 0 VECTOR_BASE_ADDRESS Write RESET 8 0 0 0 0 0 0 0 0 0 1. The 56F8036 resets to a value of 0 x 0000. This corresponds to reset addresses of 0 x 000000. Figure 5-10 Vector Base Address Register (VBA) 5.6.8.1 Reserved—Bits 15–14 This bit field is reserved. Each bit must be set to 0. 56F8036 Data Sheet, Rev. 3 72 Freescale Semiconductor Preliminary Register Descriptions 5.6.8.2 Vector Address Bus (VAB) Bits 13–0 The value in this register is used as the upper 14 bits of the interrupt vector VAB[20:0]. The lower 7 bits are determined based on the highest priority interrupt and are then appended onto VBA before presenting the full VAB to the Core. 5.6.9 Fast Interrupt Match 0 Register (FIM0) Base + $8 15 14 13 12 11 10 9 8 7 6 Read 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 5 4 2 1 0 0 0 FAST INTERRUPT 0 Write RESET 3 0 0 0 0 Figure 5-11 Fast Interrupt Match 0 Register (FIM0) 5.6.9.1 Reserved—Bits 15–6 This bit field is reserved. Each bit must be set to 0. 5.6.9.2 Fast Interrupt 0 Vector Number (FAST INTERRUPT 0)—Bits 5–0 These values determine which IRQ will be Fast Interrupt 0. Fast Interrupts vector directly to a service routine based on values in the Fast Interrupt Vector Address registers without having to go to a jump table first. IRQs used as Fast Interrupts must be set to priority level 2. Unexpected results will occur if a Fast Interrupt vector is set to any other priority. A Fast Interrupt automatically becomes the highest-priority level 2 interrupt regardless of its location in the interrupt table prior to being declared as Fast Interrupt. Fast Interrupt 0 has priority over Fast Interrupt 1. To determine the vector number of each IRQ, refer to the vector table. 5.6.10 Fast Interrupt 0 Vector Address Low Register (FIVAL0) Base + $9 15 14 13 12 11 Read 10 9 8 7 6 5 4 3 2 1 0 0 0 0 0 0 FAST INTERRUPT 0 VECTOR ADDRESS LOW Write RESET 0 0 0 0 0 0 0 0 0 0 0 Figure 5-12 Fast Interrupt 0 Vector Address Low Register (FIVAL0) 5.6.10.1 Fast Interrupt 0 Vector Address Low (FIVAL0)—Bits 15–0 The lower 16 bits of the vector address used for Fast Interrupt 0. This register is combined with FIVAH0 to form the 21-bit vector address for Fast Interrupt 0 defined in the FIM0 register. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 73 5.6.11 Fast Interrupt 0 Vector Address High Register (FIVAH0) Base + $A 15 14 13 12 11 10 9 8 7 6 5 Read 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 4 2 1 0 FAST INTERRUPT 0 VECTOR ADDRESS HIGH Write RESET 3 0 0 0 0 0 Figure 5-13 Fast Interrupt 0 Vector Address High Register (FIVAH0) 5.6.11.1 Reserved—Bits 15–5 This bit field is reserved. Each bit must be set to 0. 5.6.11.2 Fast Interrupt 0 Vector Address High (FIVAH0)—Bits 4–0 The upper five bits of the vector address used for Fast Interrupt 0. This register is combined with FIVAL0 to form the 21-bit vector address for Fast Interrupt 0 defined in the FIM0 register. 5.6.12 Fast Interrupt 1 Match Register (FIM1) Base + $B 15 14 13 12 11 10 9 8 7 6 Read 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 5 4 2 1 0 0 0 FAST INTERRUPT 1 Write RESET 3 0 0 0 0 Figure 5-14 Fast Interrupt 1 Match Register (FIM1) 5.6.12.1 Reserved—Bits 15–6 This bit field is reserved. Each bit must be set to 0. 5.6.12.2 Fast Interrupt 1 Vector Number (FAST INTERRUPT 1)—Bits 5–0 These values determine which IRQ will be Fast Interrupt 1. Fast Interrupts vector directly to a service routine based on values in the Fast Interrupt Vector Address registers without having to go to a jump table first. IRQs used as Fast Interrupts must be set to priority level 2. Unexpected results will occur if a Fast Interrupt vector is set to any other priority. A Fast Interrupt automatically becomes the highest priority level 2 interrupt, regardless of its location in the interrupt table prior to being declared as Fast Interrupt. Fast Interrupt 0 has priority over Fast Interrupt 1. To determine the vector number of each IRQ, refer to the vector table. 5.6.13 Fast Interrupt 1 Vector Address Low Register (FIVAL1) Base + $C 15 14 13 12 11 Read 9 8 7 6 5 4 3 2 1 0 0 0 0 0 0 FAST INTERRUPT 1 VECTOR ADDRESS LOW Write RESET 10 0 0 0 0 0 0 0 0 0 0 0 Figure 5-15 Fast Interrupt 1 Vector Address Low Register (FIVAL1) 56F8036 Data Sheet, Rev. 3 74 Freescale Semiconductor Preliminary Register Descriptions 5.6.13.1 Fast Interrupt 1 Vector Address Low (FIVAL1)—Bits 15–0 The lower 16 bits of the vector address used for Fast Interrupt 1. This register is combined with FIVAH1 to form the 21-bit vector address for Fast Interrupt 1 defined in the FIM1 register. 5.6.14 Fast Interrupt 1 Vector Address High (FIVAH1) Base + $D 15 14 13 12 11 10 9 8 7 6 5 Read 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 4 Write RESET 3 2 1 0 FAST INTERRUPT 1 VECTOR ADDRESS HIGH 0 0 0 0 0 Figure 5-16 Fast Interrupt 1 Vector Address High Register (FIVAH1) 5.6.14.1 Reserved—Bits 15–5 This bit field is reserved. Each bit must be set to 0. 5.6.14.2 Fast Interrupt 1 Vector Address High (FIVAH1)—Bits 4–0 The upper five bits of the vector address used for Fast Interrupt 1. This register is combined with FIVAL1 to form the 21-bit vector address for Fast Interrupt 1 defined in the FIM1 register. 5.6.15 IRQ Pending Register 0 (IRQP0) Base + $E 15 14 13 12 11 10 Read 9 8 7 6 5 4 3 2 1 PENDING[16:2] 0 1 Write RESET 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 Figure 5-17 IRQ Pending Register 0 (IRQP0) 5.6.15.1 IRQ Pending (PENDING)—Bits 16–2 These register bit values represent the pending IRQs for interrupt vector numbers 2 through 16. Ascending IRQ numbers correspond to ascending bit locations. • • 0 = IRQ pending for this vector number 1 = No IRQ pending for this vector number 5.6.15.2 Reserved—Bit 0 This bit field is reserved. It must be set to 0. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 75 5.6.16 IRQ Pending Register 1 (IRQP1) Base + $F 15 14 13 12 11 10 9 Read 8 7 6 5 4 3 2 1 0 1 1 1 1 1 1 1 PENDING[32:17] Write RESET 1 1 1 1 1 1 1 1 1 Figure 5-18 IRQ Pending Register 1 (IRQP1) 5.6.16.1 IRQ Pending (PENDING)—Bits 32–17 These register bit values represent the pending IRQs for interrupt vector numbers 17 through 32. Ascending IRQ numbers correspond to ascending bit locations. • • 0 = IRQ pending for this vector number 1 = No IRQ pending for this vector number 5.6.17 IRQ Pending Register 2 (IRQP2) Base + $10 15 14 13 12 11 10 9 Read 8 7 6 5 4 3 2 1 0 1 1 1 1 1 1 1 PENDING[48:33] Write RESET 1 1 1 1 1 1 1 1 1 Figure 5-19 IRQ Pending Register 2 (IRQP2) 5.6.17.1 IRQ Pending (PENDING)—Bits 48–33 These register bit values represent the pending IRQs for interrupt vector numbers 33 through 48. Ascending IRQ numbers correspond to ascending bit locations. • • 0 = IRQ pending for this vector number 1 = No IRQ pending for this vector number 5.6.18 IRQ Pending Register 3 (IRQP3) Base + $11 15 14 13 12 11 10 9 Read 8 7 6 5 4 3 2 1 0 1 1 1 1 1 1 1 PENDING[63:49] Write RESET 1 1 1 1 1 1 1 1 1 Figure 5-20 IRQ Pending Register 3 (IRQP3) 5.6.18.1 IRQ Pending (PENDING)—Bits 63–49 These register bit values represent the pending IRQs for interrupt vector numbers 49 through 63. Ascending IRQ numbers correspond to ascending bit locations. • • 0 = IRQ pending for this vector number 1 = No IRQ pending for this vector number 56F8036 Data Sheet, Rev. 3 76 Freescale Semiconductor Preliminary Register Descriptions 5.6.19 Interrupt Control Register (ICTRL) $Base + $16 15 Read INT 14 13 12 11 10 IPIC 9 8 7 6 VAB Write RESET 0 0 0 0 0 0 0 0 0 0 5 4 3 2 1 0 INT_ DIS 1 1 1 0 0 0 1 1 1 0 0 Figure 5-21 Interrupt Control Register (ICTRL) 5.6.19.1 Interrupt (INT)—Bit 15 This read-only bit reflects the state of the interrupt to the 56800E core. • • 0 = No interrupt is being sent to the 56800E core 1 = An interrupt is being sent to the 56800E core 5.6.19.2 Interrupt Priority Level (IPIC)—Bits 14–13 These read-only bits reflect the state of the new interrupt priority level bits being presented to the 56800E core. These bits indicate the priority level needed for a new IRQ to interrupt the current interrupt being sent to the 56800E core. This field is only updated when the 56800E core jumps to a new interrupt service routine. Note: • • • • Nested interrupts may cause this field to be updated before the original interrupt service routine can read it. 00 = Required nested exception priority levels are 0, 1, 2, or 3 01 = Required nested exception priority levels are 1, 2, or 3 10 = Required nested exception priority levels are 2 or 3 11 = Required nested exception priority level is 3 Table 5-4 Interrupt Priority Encoding 5.6.19.3 IPIC_VALUE[1:0] Current Interrupt Priority Level Required Nested Exception Priority 00 No interrupt or SWILP Priorities 0, 1, 2, 3 01 Priority 0 Priorities 1, 2, 3 10 Priority 1 Priorities 2, 3 11 Priority 2 or 3 Priority 3 Vector Number - Vector Address Bus (VAB)—Bits 12–6 This read-only field shows bits [7:1] of the Vector Address Bus used at the time the last IRQ was taken. In the case of a Fast Interrupt, it shows the lower address bits of the jump address. This field is only updated when the 56800E core jumps to a new interrupt service routine. Note: Nested interrupts may cause this field to be updated before the original interrupt service routine can read it. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 77 5.6.19.4 Interrupt Disable (INT_DIS)—Bit 5 This bit allows all interrupts to be disabled. • • 0 = Normal operation (default) 1 = All interrupts disabled 5.6.19.5 Reserved—Bits 4-2 This bit field is reserved. Each bit must be set to 1. 5.6.19.6 Reserved—Bits 1–0 This bit field is reserved. Each bit must be set to 0. 5.7 Resets 5.7.1 General Table 5-5 Reset Summary Reset Priority Core Reset 5.7.2 5.7.2.1 Source Characteristics RST Core reset from the SIM Description of Reset Operation Reset Handshake Timing The ITCN provides the 56800E core with a reset vector address on the VAB pins whenever RESET is asserted from the SIM. The reset vector will be presented until the second rising clock edge after RESET is released. The general timing is shown in Figure 5-22. RES CLK VAB RESET_VECTOR_ADR PAB READ_ADR Figure 5-22 Reset Interface 56F8036 Data Sheet, Rev. 3 78 Freescale Semiconductor Preliminary Introduction 5.7.3 ITCN After Reset After reset, all of the ITCN registers are in their default states. This means all interrupts are disabled, except the core IRQs with fixed priorities: • • • • • • • • Illegal Instruction SW Interrupt 3 HW Stack Overflow Misaligned Long Word Access SW Interrupt 2 SW Interrupt 1 SW Interrupt 0 SW Interrupt LP These interrupts are enabled at their fixed priority levels. Part 6 System Integration Module (SIM) 6.1 Introduction The SIM module is a system catchall for the glue logic that ties together the system-on-chip. It controls distribution of resets and clocks and provides a number of control features. The System Integration Module’s functions are discussed in more detail in the following sections. 6.2 Features The SIM has the following features: • • • • • • • • • • • Chip reset sequencing Core and peripheral clock control and distribution Stop/Wait mode control System status control Registers containing the JTAG ID of the chip Controls for programmable peripheral and GPIO connections Peripheral clocks for TMR and PWM with a high-speed (3X) option Power-saving clock gating for peripherals Three power modes (Run, Wait, Stop) to control power utilization — Stop mode shuts down the 56800E core, system clock, and peripheral clock — Wait mode shuts down the 56800E core and unnecessary system clock operation — Run mode supports full device operation Controls the enable/disable functions of the 56800E core WAIT and STOP instructions with write protection capability Controls the enable/disable functions of Large Regulator Standby mode with write protection capability 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 79 • • • • • • • • Permits selected peripherals to run in Stop mode to generate Stop recovery interrupts Controls for programmable peripheral and GPIO connections Software chip reset I/O short address base location control Peripheral protection control to provide runaway code protection for safety-critical applications Controls output of internal clock sources to I/O pins Four general-purpose software control registers are reset only at power-on Peripherals Stop mode clocking control 56F8036 Data Sheet, Rev. 3 80 Freescale Semiconductor Preliminary Register Descriptions 6.3 Register Descriptions A write to an address without an associated register is an NOP. A read from an address without an associated register returns unknown data. Table 6-1 SIM Registers (SIM_BASE = $00 F100) Register Acronym Base Address + Register Name Section Location CTRL $0 Control Register 6.3.1 RSTAT $1 Reset Status Register 6.3.2 SWC0 $2 Software Control Register 0 6.3.3 SWC1 $3 Software Control Register 1 6.3.3 SWC2 $4 Software Control Register 2 6.3.3 SWC3 $5 Software Control Register 3 6.3.3 MSHID $6 Most Significant Half of JTAG ID 6.3.4 LSHID $7 Least Significant Half of JTAG ID 6.3.5 PWR $8 Power Control Register 6.3.6 Reserved CLKOUT $A CLKO Select Register 6.3.7 PCR $B Peripheral Clock Rate Register 6.3.8 PCE0 $C Peripheral Clock Enable Register 0 6.3.9 PCE1 $D Peripheral Clock Enable Register 0 6.3.10 SD0 $E Stop Disable Register 0 6.3.11 SD1 $F Stop Disable Register 1 6.3.12 IOSAHI $10 I/O Short Address Location High Register 6.3.13 IOSALO $11 I/O Short Address Location Low Register 6.3.14 PROT $12 Protection Register 6.3.15 GPSA0 $13 GPIO Peripheral Select Register 0 for GPIOA 6.3.16 GPSA1 $14 GPIO Peripheral Select Register 1 for GPIOA 6.3.17 GPSB0 $15 GPIO Peripheral Select Register 0 for GPIOB 6.3.18 GPSB1 $16 GPIO Peripheral Select Register 1 for GPIOB 6.3.19 GPSCD $17 GPIO Peripheral Select Register for GPIOC and GPIOD 6.3.20 IPS0 $18 Internal Peripheral Source Select Register 0 for PWM 6.3.21 IPSS1 $19 Internal Peripheral Source Select Register 1 for DACs 6.3.22 IPSS2 $1A Internal Peripheral Source Select Register 2 for Quad Timer A 6.3.23 Reserved 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 81 Add. Offset Address Acronym $0 SIM_ CTRL $1 SIM_ RSTAT $2 SIM_SWC0 $3 SIM_SWC1 $4 SIM_SWC2 $5 SIM_SWC3 $6 SIM_MSHID $7 SIM_LSHID $8 SIM_PWR R 15 14 13 12 11 10 9 8 7 6 5 4 0 0 0 0 0 0 0 0 0 0 ONCE EBL0 SW RST 0 0 0 0 0 0 0 0 0 SWR W R 3 2 1 STOP_ DISABLE COP_ COP_ EXTR TOR LOR 0 WAIT_ DISABLE POR 0 0 W R Software Control Data 0 W R Software Control Data 1 W R Software Control Data 2 W R Software Control Data 3 W R 0 0 0 0 0 0 0 1 1 1 1 1 0 0 1 0 1 0 0 0 0 0 0 0 0 0 0 1 1 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 TMRA_ PWM_C CR R I2C_ CR 0 0 0 0 0 0 0 0 CMPA DAC1 DAC0 PIT2 PIT1 PIT0 W R W R LRSTDBY W Reserved $A SIM_ CLKOUT $B SIM_PCR $C SIM_PCE0 $D SIM_PCE1 $E SIM_SD0 $F SIM_SD1 $10 SIM_IOSAHI $11 SIM_IOSALO $12 SIM_PROT $13 SIM_GPSA0 $14 SIM_GPSA1 $15 SIM_GPSB0 $16 SIM_GPSB1 $17 SIM_GPSCD $18 SIM_IPS0 $19 SIM_IPS1 $1A SIM_IPS2 R W R 0 W R W R CMPB 0 W R W R CMPB_ CMPA_ DAC1_ DAC0_ SD SD SD SD 0 PIT2_ SD 0 0 W R PIT1_S PIT0_ D SD 0 0 0 ADC PWM3 PWM2 PWM1 PWM0 0 0 0 0 0 0 0 I2C 0 0 QSCI0 0 0 0 0 0 0 0 0 0 ADC_ SD 0 0 0 I2C_ SD 0 0 0 0 0 0 0 0 0 0 0 0 QSPI0 TA2 TA1 TA0 QSCI0 _SD 0 QSPI0 _SD 0 PWM_ SD 0 0 TA3_ SD TA2_ SD TA1_ SD TA0_ SD 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 ISAL[23:22] ISAL[21:6] W R 0 0 0 0 0 0 0 0 GPS_ A6 0 0 0 0 0 0 0 PCEP W R W R GPS_A5 0 GPS_A4 0 0 0 0 0 0 0 W R 0 W R GPS_B6 GPS_B5 GPS_B3 GPS_B2 0 GPS_A9 GPS_A8 0 GPS_ B1 0 GPS_ B0 0 0 0 0 0 0 0 0 GPS_ B9 0 GPS_ B8 0 GPS_ B7 0 0 0 GPS_ D5 0 0 0 0 0 0 0 0 0 0 0 0 0 0 IPS0_ FAULT2 0 IPS0_ FAULT1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 IPS2_ TA3 0 0 0 IPS2_ TA2 0 IPS0_PSRC2 IPS0_PSRC1 IPS1_DSYNC1 W R 0 0 W R 0 0 W R GIPSP 0 W R PWM TA3 W R 0 W 0 0 IPS2_ TA1 IPS0_PSRC0 0 0 IPS1_DSYNC0 0 0 0 Reserved 0 = Read as 0 1 = Read as 1 = Reserved Figure 6-1 SIM Register Map Summary 56F8036 Data Sheet, Rev. 3 82 Freescale Semiconductor Preliminary Register Descriptions 6.3.1 SIM Control Register (SIM_CTRL) Base + $0 15 14 13 12 11 10 9 8 7 6 5 4 Read 0 0 0 0 0 0 0 0 0 0 ONCE EBL SW RST 0 0 0 0 0 0 0 0 0 0 0 0 Write RESET 3 2 1 0 STOP_ DISABLE WAIT_ DISABLE 0 0 0 0 Figure 6-2 SIM Control Register (SIM_CTRL) 6.3.1.1 Reserved—Bits 15–6 This bit field is reserved. Each bit must be set to 0. 6.3.1.2 • • 0 = OnCE clock to 56800E core enabled when core TAP is enabled 1 = OnCE clock to 56800E core is always enabled Note: Using default state “0” is recommended. 6.3.1.3 • • • • 6.3.2 Stop Disable (STOP_DISABLE)—Bits 3–2 00 = Stop mode will be entered when the 56800E core executes a STOP instruction 01 = The 56800E STOP instruction will not cause entry into Stop mode 10 = Stop mode will be entered when the 56800E core executes a STOP instruction and the STOP_DISABLE field is write-protected until the next reset 11 = The 56800E STOP instruction will not cause entry into Stop mode and the STOP_DISABLE field is write-protected until the next reset 6.3.1.5 • • • Software Reset (SWRST)—Bit 4 Writing 1 to this field will cause the device to reset Read is 0 6.3.1.4 • • • OnCE Enable (ONCEEBL)—Bit 5 Wait Disable (WAIT_DISABLE)—Bits 1–0 00 = Wait mode will be entered when the 56800E core executes a WAIT instruction 01 = The 56800E WAIT instruction will not cause entry into Wait mode 10 = Wait mode will be entered when the 56800E core executes a WAIT instruction and the WAIT_DISABLE field is write-protected until the next reset 11 = The 56800E WAIT instruction will not cause entry into Wait mode and the WAIT_DISABLE field is write-protected until the next reset SIM Reset Status Register (SIM_RSTAT) This read-only register is updated upon any system reset and indicates the cause of the most recent reset. It indicates whether the COP reset vector or regular reset vector (including Power-On Reset, External Reset, Software Reset) in the vector table is used. This register is asynchronously reset during Power-On Reset and subsequently is synchronously updated based on the precedence level of reset inputs. Only the 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 83 most recent reset source will be indicated if multiple resets occur. If multiple reset sources assert simultaneously, the highest-precedence source will be indicated. The precedence from highest to lowest is Power-On Reset, External Reset, COP Loss of Reference Reset, COP Time-Out Reset, and Software Reset. Power-On Reset is always set during a Power-On Reset; however, Power-On Reset will be cleared and External Reset will be set if the external reset pin is asserted or remains asserted after the Power-On Reset has deasserted. Base + $1 Read 15 14 13 12 11 10 9 8 7 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 6 5 COP_ SWR TOR 4 3 2 1 0 COP_ LOR EXTR POR 0 0 0 0 1 0 0 Write RESET 0 0 Figure 6-3 SIM Reset Status Register (SIM_RSTAT) 6.3.2.1 Reserved—Bits 15–7 This bit field is reserved. Each bit must be set to 0. 6.3.2.2 Software Reset (SWR)—Bit 6 When set, this bit indicates that the previous system reset occurred as a result of a software reset (written 1 to SWRST bit in the SIM_CTRL register). 6.3.2.3 COP Time-Out Reset (COP_TOR)—Bit 5 When set, this bit indicates that the previous system reset was caused by the Computer Operating Properly (COP) module signaling a COP time-out reset. If COP_TOR is set as code starts executing, the COP reset vector in the vector table will be used. Otherwise, the normal reset vector is used. 6.3.2.4 COP Loss of Reference Reset (COP_LOR)—Bit 4 When set, this bit indicates that the previous system reset was caused by the Computer Operating Properly (COP) module signaling a loss of COP reference clock reset. If COP_LOR is set as code starts executing, the COP reset vector in the vector table will be used. Otherwise, the normal reset vector is used. 6.3.2.5 External Reset (EXTR)—Bit 3 When set, this bit indicates that the previous system reset was caused by an external reset. 6.3.2.6 Power-On Reset (POR)—Bit 2 This bit is set during a Power-On Reset. 6.3.2.7 Reserved—Bits 1–0 This bit field is reserved. Each bit must be set to 0. 56F8036 Data Sheet, Rev. 3 84 Freescale Semiconductor Preliminary Register Descriptions 6.3.3 SIM Software Control Registers (SIM_SWC0, SIM_SWC1, SIM_SWC2, and SIM_SWC3) These registers are general-purpose registers. They are reset only at power-on, so they can monitor software execution flow. Base + $2 15 14 13 12 11 10 Read 9 8 7 6 5 4 3 2 1 0 0 0 0 0 0 0 Software Control Data 0 - 3 Write RESET 0 0 0 0 0 0 0 0 0 0 Figure 6-4 SIM Software Control Register 0 (SIM_SWC0 - 3) 6.3.3.1 Software Control Register 0 - 3 (FIELD)—Bits 15–0 This register is reset only by the Power-On Reset (POR). It is intended for use by a software developer to contain data that will be unaffected by the other reset sources (external reset, software reset, and COP reset). 6.3.4 Most Significant Half of JTAG ID (SIM_MSHID) This read-only register displays the most significant half of the JTAG ID for the chip. This register reads $01F2. Base + $6 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Read 0 0 0 0 0 0 0 1 1 1 1 1 0 0 1 0 0 0 0 0 0 0 0 1 1 1 1 1 0 0 1 0 Write RESET Figure 6-5 Most Significant Half of JTAG ID (SIM_MSHID) 6.3.5 Least Significant Half of JTAG ID (SIM_LSHID) This read-only register displays the least significant half of the JTAG ID for the chip. This register reads $801D. Base + $7 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Read 1 0 0 0 0 0 0 0 0 0 0 1 1 1 0 1 1 0 0 0 0 0 0 0 0 0 0 1 1 1 0 1 Write RESET Figure 6-6 Least Significant Half of JTAG ID (SIM_LSHID) 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 85 6.3.6 SIM Power Control Register (SIM_PWR) This register controls the Standby mode of the large on-chip regulator. The large on-chip regulator derives the core digital logic power supply from the IO power supply. At a system bus frequency of 200kHz, the large regulator may be put in a reduced-power standby mode without interfering with device operation to reduce device power consumption. Refer to the overview of power-down modes and the overview of clock generation for more information on the use of large regulator standby. Base + $8 15 14 13 12 11 10 9 8 7 6 5 4 3 2 Read 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 LRSTDBY Write RESET 0 0 0 Figure 6-7 SIM Power Control Register (SIM_PWR) 6.3.6.1 Reserved—Bits 15–2 6.3.6.2 Large Regulator Standby Mode[1:0] (LRSTDBY)—Bits 1–0 This bit field is reserved. Each bit must be set to 0. • • • • 00 = Large regulator is in Normal mode 01 = Large regulator is in Standby (reduced-power) mode 10 = Large regulator is in Normal mode and the LRSTDBY field is write-protected until the next reset 11 = Large regulator is in Standby mode and the LRSTDBY field is write-protected until the next reset 6.3.7 Clock Output Select Register (SIM_CLKOUT) The Clock Output Select register can be used to multiplex out selected clock sources generated inside the clock generation and SIM modules onto the muxed clock output pins. All functionality is for test purposes only. Glitches may be produced when the clock is enabled or switched. The delay from the clock source to the output is unspecified. The observability of the clock output signals at output pads is subject to the frequency limitations of the associated IO cell. GPIOA[3:0] can function as GPIO, PWM, or as clock output pins. If GPIOA[3:0] are programmed to operate as peripheral outputs, then the choice is between PWM and clock outputs. The default state is for the peripheral function of GPIOA[3:0] to be programmed as PWM (selected by bits [9:6] of the Clock Output Select register). See Figure 6-8 for details. Base + $A 15 14 13 12 11 10 Read 0 0 0 0 0 0 0 0 0 0 0 0 Write RESET 9 8 PWM3 PWM2 0 0 7 6 PWM1 PWM0 0 0 5 4 3 2 1 0 1 0 0 0 0 0 1 0 0 0 0 0 Figure 6-8 CLKO Select Register (SIM_CLKOUT) 56F8036 Data Sheet, Rev. 3 86 Freescale Semiconductor Preliminary Register Descriptions 6.3.7.1 Reserved—Bits 15–10 This bit field is reserved. Each bit must be set to 0. 6.3.7.2 • • PWM3—Bit 9 0 = Peripheral output function of GPIOA[3] is defined to be PWM3 1 = Peripheral output function of GPIOA[3] is defined to be the Relaxation Oscillator Clock 6.3.7.3 • • PWM2—Bit 8 0 = Peripheral output function of GPIOA[2] is defined to be PWM2 1 = Peripheral output function of GPIOA[2] is defined to be the system clock 6.3.7.4 • • PWM1—Bit 7 0 = Peripheral output function of GPIOA[1] is defined to be PWM1 1 = Peripheral output function of GPIOA[1] is defined to be 2X system clock 6.3.7.5 • • PWM0—Bit 6 0 = Peripheral output function of GPIOA[0] is defined to be PWM0 1 = Peripheral output function of GPIOA[0] is defined to be 3X system clock 6.3.7.6 Reserved—Bit 5 This bit field is reserved for factory test. It must be set to 1. 6.3.7.7 Reserved—Bits 4–0 This bit field is reserved for factory test. Each bit must be set to 0. 6.3.8 Peripheral Clock Rate Register (SIM_PCR) By default, all peripherals are clocked at the system clock rate, which has a maximum of 32MHz. Selected peripherals clocks have the option to be clocked at 3X system clock rate, which has a maximum of 96MHz, if the PLL output clock is selected as the system clock. If PLL is disabled, the 3X system clock will not be available. This register is used to enable high-speed clocking for those peripherals that support it. Note: Operation is unpredictable if peripheral clocks are reconfigured at runtime, so peripherals should be disabled before a peripheral clock is reconfigured. Base + $B 15 Read 0 14 Write RESET 13 TMRA_ PWM_ CR CR 0 0 12 11 10 9 8 7 6 5 4 3 2 1 0 I2C_ CR 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Figure 6-9 Peripheral Clock Rate Register (SIM_PCR) 6.3.8.1 Reserved—Bit 15 This bit field is reserved. It must be set to 0. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 87 6.3.8.2 Quad Timer A Clock Rate (TMRA_CR)—Bit 14 This bit selects the clock speed for the Quad Timer A module. • • 0 = Quad Timer A clock rate equals the system clock rate, to a maximum 32MHz (default) 1 = Quad Timer A clock rate equals 3X system clock rate, to a maximum 96MHz 6.3.8.3 Pulse Width Modulator Clock Rate (PWM_CR)—Bit 13 This bit selects the clock speed for the PWM module. • • 0 = PWM module clock rate equals the system clock rate, to a maximum 32MHz (default) 1 = PWM module clock rate equals 3X system clock rate, to a maximum 96MHz 6.3.8.4 Inter-Integrated Circuit Run Clock Rate (I2C_CR)—Bit 12 This bit selects the clock speed for the I2C run clock. • 0 = I2C module run clock rate equals the system clock rate, to a maximum 32MHz (default) • 1 = I2C module run clock rate equals 3X system clock rate, to a maximum 96MHz 6.3.8.5 Reserved—Bits 11–0 This bit field is reserved. Each bit must be set to 0. 6.3.9 Peripheral Clock Enable Register 0 (SIM_PCE0) The Peripheral Clock Enable register enables or disables clocks to the peripherals as a power savings feature. Significant power savings are achieved by enabling only the peripheral clocks that are in use. When a peripheral’s clock is disabled, that peripheral is in Stop mode. Accesses made to a module that has its clock disabled will have no effect. The corresponding peripheral should itself be disabled while its clock is shut off. IPBus writes are not possible. Setting the PCE bit does not guarantee that the peripheral’s clock is running. Enabled peripheral clocks will still become disabled in Stop mode, unless the peripheral’s Stop Disable control in the SDn register is set to 1. Note: The MSCAN module supports extended power management capabilities, including Sleep, Stop-in-Wait, and Disable modes. MSCAN clocks are selected by MSCAN control registers. Refer to the 56F802X and 56F803XPeripheral Reference Manual for details. Base + $C Read Write RESET 15 14 13 12 CMPB CMPA DAC1 DAC0 0 0 0 0 11 0 0 10 ADC 0 9 8 7 0 0 0 0 0 0 6 I2C 0 5 0 0 4 QSCI0 0 3 0 2 QSPI0 0 0 1 0 0 0 PWM 0 Figure 6-10 Peripheral Clock Enable Register 0 (SIM_PCE0) 6.3.9.1 • • Comparator B Clock Enable (CMPB)—Bit 15 0 = The clock is not provided to the Comparator B module (the Comparator B module is disabled) 1 = The clock is enabled to the Comparator B module 56F8036 Data Sheet, Rev. 3 88 Freescale Semiconductor Preliminary Register Descriptions 6.3.9.2 • • 0 = The clock is not provided to the Comparator A module (the Comparator A module is disabled) 1 = The clock is enabled to the Comparator A module 6.3.9.3 • • Digital-to-Analog Clock Enable 1 (DAC1)—Bit 13 0 = The clock is not provided to the DAC1 module (the DAC1 module is disabled) 1 = The clock is enabled to the DAC1 module 6.3.9.4 • • Comparator A Clock Enable (CMPA)—Bit 14 Digital-to-Analog Clock Enable 0 (DAC0)—Bit 12 0 = The clock is not provided to the DAC0 module (the DAC0 module is disabled) 1 = The clock is enabled to the DAC0 module 6.3.9.5 Reserved—Bit 11 This bit field is reserved. It must be set to 0. 6.3.9.6 • • Analog-to-Digital Converter Clock Enable (ADC)—Bit 10 0 = The clock is not provided to the ADC module (the ADC module is disabled) 1 = The clock is enabled to the ADC module 6.3.9.7 Reserved—Bits 9–7 This bit field is reserved. It must be set to 0. 6.3.9.8 Inter-Integrated Circuit IPBus Clock Enable (I2C)—Bit 6 • 0 = The clock is not provided to the I2C module (the I2C module is disabled) • 1 = The clock is enabled to the I2C module 6.3.9.9 Reserved—Bit 5 This bit field is reserved. It must be set to 0. 6.3.9.10 • • QSCI 0 Clock Enable (QSCI0)—Bit 4 0 = The clock is not provided to the QSCI0 module (the QSCI0 module is disabled) 1 = The clock is enabled to the QSCI0 module 6.3.9.11 Reserved—Bit 3 This bit field is reserved. It must be set to 0. 6.3.9.12 • • QSPI 0 Clock Enable (QSPI0)—Bit 2 0 = The clock is not provided to the QSPI0 module (the QSPI0 module is disabled) 1 = The clock is enabled to the QSPI0 module 6.3.9.13 Reserved—Bit 1 This bit field is reserved. It must be set to 0. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 89 6.3.9.14 • • PWM Clock Enable (PWM)—Bit 0 0 = The clock is not provided to the PWM module (the PWM module is disabled) 1 = The clock is enabled to the PWM module 6.3.10 Peripheral Clock Enable Register 1 (SIM_PCE1) See Section 6.3.9 for general information about Peripheral Clock Enable registers. Base + $D 15 Read 0 Write RESET 0 14 13 12 PIT2 PIT1 PIT0 0 0 0 11 10 9 8 7 6 5 4 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 3 2 1 0 TA3 TA2 TA1 TA0 0 0 0 0 Figure 6-11 Peripheral Clock Enable Register 1 (SIM_PCE1) 6.3.10.1 Reserved—Bit 15 This bit field is reserved. It must be set to 0. 6.3.10.2 • • 0 = The clock is not provided to the PIT2 module (the PIT2 module is disabled) 1 = The clock is enabled to the PIT2 module 6.3.10.3 • • Programmable Interval Timer 1 Clock Enable (PIT1)—Bit 13 0 = The clock is not provided to the PIT1 module (the PIT1 module is disabled) 1 = The clock is enabled to the PIT1 module 6.3.10.4 • • Programmable Interval Timer 2 Clock Enable (PIT2)—Bit 14 Programmable Interval Timer 0 Clock Enable (PIT0)—Bit 12 0 = The clock is not provided to the PIT0 module (the PIT0 module is disabled) 1 = The clock is enabled to the PIT0 module 6.3.10.5 Reserved—Bits 11–4 This bit field is reserved. Each bit must be set to 0. 6.3.10.6 • • 0 = The clock is not provided to the Timer A3 module (the Timer A3 module is disabled) 1 = The clock is enabled to the Timer A3 module 6.3.10.7 • • Quad Timer A, Channel 2 Clock Enable (TA2)—Bit 2 0 = The clock is not provided to the Timer A2 module (the Timer A2 module is disabled) 1 = The clock is enabled to the Timer A2 module 6.3.10.8 • • Quad Timer A, Channel 3 Clock Enable (TA3)—Bit 3 Quad Timer A, Channel 1 Clock Enable (TA1)—Bit 1 0 = The clock is not provided to the Timer A1 module (the Timer A1 module is disabled) 1 = The clock is enabled to the Timer A1 module 56F8036 Data Sheet, Rev. 3 90 Freescale Semiconductor Preliminary Register Descriptions 6.3.10.9 • • Quad Timer A, Channel 0 Clock Enable (TA0)—Bit 0 0 = The clock is not provided to the Timer A0 module (the Timer A0 module is disabled) 1 = The clock is enabled to the Timer A0 module 6.3.11 Stop Disable Register 0 (SD0) By default, peripheral clocks are disabled during Stop mode in order to maximize power savings. This register will allow an individual peripheral to operate in Stop mode. Since asserting an interrupt causes the system to return to Run mode, this feature is provided so that selected peripherals can be left operating in Stop mode for the purpose of generating a wake-up interrupt. For power-conscious applications, it is recommended that only a minimum set of peripherals be configured to remain operational during Stop mode. Peripherals should be put in a non-operating (disabled) configuration prior to entering Stop mode unless their corresponding Stop Disable control is set to 1. Refer to the 56F802X and 56F803XPeripheral Reference Manual for further details. Reads and writes cannot be made to a module that has its clock disabled. Note: The MSCAN module supports extended power management capabilities including Sleep, Stop-in-Wait, and Disable modes. MSCAN clocks are selected by MSCAN control registers. For details, refer to the 56F802X and 56F803XPeripheral Reference Manual. Base + $E Read Write RESET 15 14 13 12 CMPB_ CMPA_ DAC1_ DAC0_ SD SD SD SD 0 0 0 0 11 10 9 8 7 6 5 4 3 2 1 0 0 ADC_ SD 0 0 0 I2C_ SD 0 QSCI0_ SD 0 QSPI0_ SD 0 PWM_ SD 0 0 0 0 0 0 0 0 0 0 0 0 Figure 6-12 Stop Disable Register 0 (SD0) 6.3.11.1 • • 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE0 register 6.3.11.2 • • Comparator A Clock Stop Disable (CMPA_SD)—Bit 14 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE0 register 6.3.11.3 • • Comparator B Clock Stop Disable (CMPB_SD)—Bit 15 Digital-to-Analog Converter 1 Clock Stop Disable (DAC1_SD)—Bit 13 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE0 register 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 91 6.3.11.4 • • Digital-to-Analog Converter 0 Clock Stop Disable (DAC0_SD)—Bit 12 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE0 register 6.3.11.5 Reserved—Bit 11 This bit field is reserved. It must be set to 0. 6.3.11.6 • • Analog-to-Digital Converter Clock Stop Disable (ADC_SD)—Bit 10 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE0 register 6.3.11.7 Reserved—Bits 9–7 This bit field is reserved. It must be set to 0. 6.3.11.8 • • Inter-Integrated Circuit Clock Stop Disable (I2C_SD)—Bit 6 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE0 register 6.3.11.9 Reserved—Bit 5 This bit field is reserved. It must be set to 0. 6.3.11.10 QSCI0 Clock Stop Disable (QSCI0_SD)—Bit 4 • • 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE0 register 6.3.11.11 Reserved—Bit 3 This bit field is reserved. It must be set to 0. 6.3.11.12 QSPI0 Clock Stop Disable (QSPI0_SD)—Bit 2 Each bit controls clocks to the indicated peripheral. • • 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE0 register 6.3.11.13 Reserved—Bit 1 This bit field is reserved. It must be set to 0. 56F8036 Data Sheet, Rev. 3 92 Freescale Semiconductor Preliminary Register Descriptions 6.3.11.14 PWM Clock Stop Disable (PWM_SD)—Bit 0 • • 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE0 register 6.3.12 Stop Disable Register 1 (SD1) See Section 6.3.11 for general information about Stop Disable Registers. Base + $F 15 Read 0 PIT2_ SD 0 0 Write RESET 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 PIT1_ SD PIT0_ SD 0 0 0 0 0 0 0 0 TA3_ SD TA2_ SD TA1_ SD TA0_ SD 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Figure 6-13 Stop Disable Register 1 (SD1) 6.3.12.1 Reserved—Bit 15 This bit field is reserved. It must be set to 0. 6.3.12.2 • • 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE1 register 6.3.12.3 • • Programmable Interval Timer 1 Clock Stop Disable (PIT1_SD)—Bit 13 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE1 register 6.3.12.4 • • Programmable Interval Timer 2 Clock Stop Disable (PIT2_SD)—Bit 14 Programmable Interval Timer 0 Clock Stop Disable (PIT0_SD)—Bit 12 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE1 register 6.3.12.5 Reserved—Bits 11–4 This bit field is reserved. Each bit must be set to 0. 6.3.12.6 • • Quad Timer A, Channel 3 Clock Stop Disable (TA3_SD)—Bit 3 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE1 register 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 93 6.3.12.7 • • 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE1 register 6.3.12.8 • • Quad Timer A, Channel 1 Clock Stop Disable (TA1_SD)—Bit 1 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE1 register 6.3.12.9 • • Quad Timer A, Channel 2 Clock Stop Disable (TA2_SD)—Bit 2 Quad Timer A, Channel 0 Clock Stop Disable (TA0_SD)—Bit 0 0 = The clock is disabled during Stop mode 1 = The clock is enabled during Stop mode if the clock to this peripheral is enabled in the SIM_PCE1 register 6.3.13 I/O Short Address Location Register High (SIM_IOSAHI) In I/O short address mode, the instruction specifies only 6 LSBs of the effective address; the upper 18 bits are “hard coded” to a specific area of memory. This scheme allows efficient access to a 64-location area in peripheral space with single word instruction. Short address location registers specify the upper 18 bits of I/O address, which are “hard coded”. These registers allow access to peripherals using I/O short address mode, regardless of the physical location of the peripheral, as shown in Figure 6-14. “Hard Coded” Address Portion Instruction Portion 6 Bits from I/O Short Address Mode Instruction 16 Bits from SIM_IOSALO Register 2 bits from SIM_IOSAHI Register Full 24-Bit for Short I/O Address Figure 6-14 I/O Short Address Determination With this register set, software can set the SIM_IOSAHI and SIM_IOSALO registers to point to its peripheral registers and then use the I/O short addressing mode to access them. Note: The default value of this register set points to the EOnCE registers. Note: The pipeline delay between setting this register set and using short I/O addressing with the new value is five instruction cycles. 56F8036 Data Sheet, Rev. 3 94 Freescale Semiconductor Preliminary Register Descriptions Base + $10 15 14 13 12 11 10 9 8 7 6 5 4 3 2 Read 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Write RESET 1 0 ISAL[23:22] 1 1 Figure 6-15 I/O Short Address Location High Register (SIM_IOSAHI) 6.3.13.1 Reserved—Bits 15—2 This bit field is reserved. Each bit must be set to 0. 6.3.13.2 Input/Output Short Address Location (ISAL[23:22])—Bits 1–0 This field represents the upper two address bits of the “hard coded” I/O short address. 6.3.14 I/O Short Address Location Register Low (SIM_IOSALO) See Section 6.3.13 for general information about I/O short address location registers. Base + $11 15 14 13 12 11 10 9 Read 8 7 6 5 4 3 2 1 0 1 1 1 1 1 1 1 ISAL[21:6] Write RESET 1 1 1 1 1 1 1 1 1 Figure 6-16 I/O Short Address Location Low Register (SIM_IOSALO) 6.3.14.1 Input/Output Short Address Location (ISAL[21:6])—Bits 15–0 This field represents the lower 16 address bits of the “hard coded” I/O short address. 6.3.15 Protection Register (SIM_PROT) This register provides write protection of selected control fields for safety-critical applications. The primary purpose is to prevent unsafe conditions due to the unintentional modification of these fields between the onset of a code runaway and a reset by the COP watchdog. The GPIO and Internal Peripheral Select Protection (GIPSP) field protects the contents of registers in the SIM and GPIO modules that control inter-peripheral signal muxing and GPIO configuration. The Peripheral Clock Enable Protection (PCEP) field protects the SIM registers’ contents, which contain peripheral clock controls. Some peripherals provide additional safety features. Refer to the 56F802X and 56F803XPeripheral Reference Manual for details. Flexibility is provided so that write protection control values may themselves be optionally locked (write-protected). Protection controls in this register have two bit values which determine the setting of the control and whether the value is locked. While a protection control remains unlocked, protection can be disabled and re-enabled by software. Once a protection control is locked, its value can only be altered by a chip reset, which restores its default non-locked value. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 95 Base + $12 15 14 13 12 11 10 9 8 7 6 5 4 Read 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 3 1 PCEP Write RESET 2 0 0 GIPSP 0 0 0 Figure 6-17 Protection Register (SIM_PROT) 6.3.15.1 Reserved—Bits 15–4 This bit field is reserved. Each bit must be set to 0. 6.3.15.2 Peripheral Clock Enable Protection (PCEP)—Bits 3–2 These bits enable write protection of all fields in the PCEn, SDn, and PCR registers in the SIM module. • • • • 00 = Write protection off (default) 01 = Write protection on 10 = Write protection off and locked until chip reset 11 = Write protection on and locked until chip reset 6.3.15.3 GPIO and Internal Peripheral Select Protection (GIPSP)—Bits 1–0 These bits enable write protection of GPSn and IPSn registers in the SIM module and write protect all GPIOx_PEREN, GPIOx_PPOUTM and GPIOx_DRIVE registers in GPIO modules. • • • • 00 = Write protection off (default) 01 = Write protection on 10 = Write protection off and locked until chip reset 11 = Write protection on and locked until chip reset Note: The PWM fields in the CLKOUT register are also write protected by GIPSP. They are reserved for in-house test only. 6.3.16 SIM GPIO Peripheral Select Register 0 for GPIOA (SIM_GPSA0) Most I/O pins have an associated GPIO function. In addition to the GPIO function, I/O can be configured to be one of several peripheral functions. The GPIOx_PEREN register within the GPIO module controls the selection between peripheral or GPIO control of the I/O pins. The GPIO function is selected when the GPIOx_PEREN bit for the I/O is 0. When the GPIOx_PEREN bit of the GPIO is 1, the fields in the GPSn registers select which peripheral function has control of the I/O. Figure 6-18 illustrates the output path to an I/O pin when an I/O has two peripheral functions. Similar muxing is required on peripheral function inputs to receive input from the properly selected I/O pin. 56F8036 Data Sheet, Rev. 3 96 Freescale Semiconductor Preliminary Register Descriptions GPIOA6_PEREN Register SIM_GPSA0 Register PWM FAULT0 0 Timer A0 1 GPIOA6 0 GPIOA6 pin 1 Figure 6-18 Overall Control of Signal Source Using SIM_GPSnn Control In some cases, the user can choose peripheral function between several I/O, each of which have the option to be programmed to control a specific peripheral function. If the user wishes to use that function, only one of these I/O must be configured to control that peripheral function. If more than one I/O is configured to control the peripheral function, the peripheral output signal will fan out to each I/O, but the peripheral input signal will be the logical OR and AND of all the I/O signals. Complete lists of I/O muxings are provided in Table 2-3. The GPSn setting can be altered during normal operation, but a delay must be inserted between the time when one function is disabled and another function is enabled. Note: After reset, all I/O pins are GPIO, except the JTAG pins and the RESET pin. Base + $13 15 14 13 Read 0 0 0 0 0 0 Write RESET 12 GPS_A6 0 11 10 9 8 GPS_A5 GPS_A4 0 0 0 0 7 6 5 4 3 2 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Figure 6-19 GPIO Peripheral Select Register 0 for GPIOA (SIM_GPSA0) 6.3.16.1 Reserved—Bits 15–13 This bit field is reserved. Each bit must be set to 0. 6.3.16.2 Configure GPIOA6 (GPS_A6)—Bit 12 This field selects the alternate function for GPIOA6. • • 0 = FAULT0 - PWM FAULT0 Input (default) 1 = TA0 - Timer A0 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 97 6.3.16.3 Configure GPIOA5 (GPS_A5)—Bits 11–10 This field selects the alternate function for GPIOA5. • • • • 00 = PWM5 - PWM5 (default) 01 = FAULT2 - PWM FAULT2 Input 10 = TA3 - Timer A3 11 = Reserved 6.3.16.4 Configure GPIOA4 (GPS_A4)—Bits 9–8 This field selects the alternate function for GPIOA4. • • • • 00 = PWM4 - PWM4 (default) 01 = FAULT1 - PWM FAULT1 Input 10 = TA2 - Timer A2 11 = Reserved 6.3.16.5 Reserved—Bits 7–0 This bit field is reserved. Each bit must be set to 0. 6.3.17 SIM GPIO Peripheral Select Register 1 for GPIOA (SIM_GPSA1) See Section 6.3.16 for general information about GPIO Peripheral Select Registers. Base + $14 15 14 13 12 11 10 9 8 7 6 5 4 Read 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Write RESET 3 2 1 0 GPS_A9 GPS_A8 0 0 0 0 Figure 6-20 GPIO Peripheral Select Register 1 for GPIOA (SIM_GPSA1) 6.3.17.1 Reserved—Bits 15–4 This bit field is reserved. Each bit must be set to 0. 6.3.17.2 Configure GPIOA9 (GPS_A9)—Bits 3–2 This field selects the alternate function for GPIOA9. • • • • 00 = FAULT2 - PWM FAULT2 Input (default) 01 = TA3 - Timer A3 10 = CMPBI1 - Comparator B Input 1 11 = Reserved 56F8036 Data Sheet, Rev. 3 98 Freescale Semiconductor Preliminary Register Descriptions 6.3.17.3 Configure GPIOA8 (GPS_A8)—Bits 1–0 This field selects the alternate function for GPIOA8. • • • • 00 = FAULT1 - PWM FAULT1 Input (default) 01 = TA2 - Timer A2 10 = CMPAI1 - Comparator A Input 1 11 = Reserved 6.3.18 SIM GPIO Peripheral Select Register 0 for GPIOB (SIM_GPSB0) See Section 6.3.16 for general information about GPIO Peripheral Select Registers. Base + $15 15 Read 0 Write RESET 0 14 13 12 11 GPS_B6 GPS_B5 0 0 0 0 10 9 8 0 0 0 0 0 0 7 6 5 4 GPS_B3 GPS_B2 0 0 0 0 3 2 1 0 0 GPS_ B1 0 GPS_ B0 0 0 0 0 Figure 6-21 GPIO Peripheral Select Register 0 for GPIOB (SIM_GPSB0) 6.3.18.1 Reserved—Bit 15 This bit field is reserved. It must be set to 0. 6.3.18.2 Configure GPIOB6 (GPS_B6)—Bits 14–13 This field selects the alternate function for GPIOB6. • • • • 00 = RXD0 - QSCI0 Receive Data (default) 01 = SDA - I2C Serial 10 = CLKIN - External Clock Input 11 = Reserved 6.3.18.3 Configure GPIOB5 (GPS_B5)—Bits 12–11 This field selects the alternate function for GPIOB5. • • • • 00 = TA1 - Timer A1 (default) 01 = FAULT3 - PWM FAULT3 Input 10 = CLKIN - External Clock Input 11 = Reserved 6.3.18.4 Reserved—Bits 10–8 This bit field is reserved. Each bit must be set to 0. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 99 6.3.18.5 Configure GPIOB3 (GPS_B3)—Bits 7–6 This field selects the alternate function for GPIOB3. • • • • 00 = MOSI0 - QSPI0 Master Out/Slave In (default) 01 = TA3 - Timer A3 10 = PSRC1 - PWM2 / PWM3 Pair External Source 11 = Reserved 6.3.18.6 Configure GPIOB2 (GPS_B2)—Bits 5–4 This field selects the alternate function for GPIOB2. • • • • 00 = MISO0 QSPI0 Master In/Slave Out (default) 01 = TA2 - Timer A2 10 = PSRC0 - PWM0 / PWM1 Pair External Source 11 = Reserved 6.3.18.7 Reserved—Bit 3 This bit field is reserved. It must be set to 0. 6.3.18.8 Configure GPIOB1 (GPS_B1)—Bit 2 This field selects the alternate function for GPIOB1. • • 0 = SS0 - QSPI0 Slave Select (default) 1 = SDA - I2C Serial Data 6.3.18.9 Reserved—Bit 1 This bit field is reserved. It must be set to 0. 6.3.18.10 Configure GPIOB0 (GPS_B0)—Bits 0 This field selects the alternate function for GPIOB0. • 0 = SCLK0 - QSPI0 Serial Clock (default) • 1 = SCL - I2C Serial Clock 6.3.19 SIM GPIO Peripheral Select Register 1 for GPIOB (SIM_GPSB1) See Section 6.3.16 for general information about GPIO Peripheral Select Registers. Base + $16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Read 0 0 0 0 0 0 0 0 0 0 0 GPS_ B9 0 GPS_ B8 0 GPS_ B7 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Write RESET Figure 6-22 GPIO Peripheral Select Register 1 for GPIOB (SIM_GPSB1) 56F8036 Data Sheet, Rev. 3 100 Freescale Semiconductor Preliminary Register Descriptions 6.3.19.1 Reserved—Bits 15–5 This bit field is reserved. Each bit must be set to 0. 6.3.19.2 Configure GPIOB9 (GPS_B9)—Bit 4 This field selects the alternate function for GPIOB9. • • 0 = SDA - I2C Serial Data (default) 1 = CANRX - MSCAN Receive Data 6.3.19.3 Reserved—Bit 3 This bit field is reserved. It must be set to 0. 6.3.19.4 Configure GPIOB8 (GPS_B8)—Bit 2 This field selects the alternate function for GPIOB8. • • 0 = SCL - I2C Serial Clock (default) 1 = CANTX - MSCAN Transmit Data 6.3.19.5 Reserved—Bit 1 This bit field is reserved. It must be set to 0. 6.3.19.6 Configure GPIOB7 (GPS_B7)—Bit 0 This field selects the alternate function for GPIOB7. • • 0 = TXD0 - QSCI0 Transmit Data (default) 1 = SCL - I2C Serial Clock 6.3.20 SIM GPIO Peripheral Select Register for GPIOC and GPIOD (SIM_GPSCD) See Section 6.3.16 for general information about GPIO Peripheral Select Registers. Base + $17 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Read 0 0 0 GPS_ D5 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Write RESET Figure 6-23 GPIO Peripheral Select Register for GPIOC and GPIOD (SIM_GPSCD) 6.3.20.1 Reserved—Bits 15–13 This bit field is reserved. Each bit must be set to 0. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 101 6.3.20.2 Configure GPIOD5 (GPS_D5)—Bit 12 This field selects the alternate function for GPIOD5. • • 0 = XTAL - External Crystal Oscillator Output (default) 1 = CLKIN - External Clock Input 6.3.20.3 Reserved—Bits 11–0 This bit field is reserved. Each bit must be set to 0. 6.3.21 Internal Peripheral Source Select Register 0 for Pulse Width Modulator (SIM_IPS0) The internal integration of peripherals provides input signal source selection for peripherals where an input signal to a peripheral can be fed from one of several sources. These registers are organized by peripheral type and provide a selection list for every peripheral input signal that has more than one alternative source to indicate which source is selected. If one of the alternative sources is GPIO, the setting in these registers must be made consistently with the settings in the GPSn and GPIOx_PEREN registers. Specifically, when an IPSn field is configured to select an I/O pin as the source, then GPSn register settings must configure only one I/O pin to feed this peripheral input function. Also, the GPIOx_PEREN bit for that I/O pin must be set to 1 to enable peripheral control of the I/O. GPIOA5_PEREN Register SIM_GPSA0 Register SIM_IPS0 Register GPIOA5 PWM5 0 PWM FAULT2 GPIOA5 pin 00 01 Timer A3 0 1 10 1 Comparator A Output (Internal) Figure 6-24 Overall Control of Signal Source using SIM_IPSn Control IPSn settings should not be altered while an affected peripheral is in an enabled (operational) configuration. See the 56F802X and 56F803XPeripheral Reference Manual for details. 56F8036 Data Sheet, Rev. 3 102 Freescale Semiconductor Preliminary Register Descriptions Base + $18 15 14 13 12 11 10 9 Read 0 0 IPS0_ FAULT2 0 IPS0_ FAULT1 0 0 0 0 0 0 0 0 0 Write RESET 8 7 6 5 IPS0_PSRC2 0 0 4 3 2 IPS0_PSRC1 0 0 0 1 0 IPS0_PSRC0 0 0 0 0 Figure 6-25 Internal Peripheral Source Select Register for PWM (SIM_IPS0) 6.3.21.1 Reserved—Bits 15–14 This bit field is reserved. Each bit must be set to 0. 6.3.21.2 Select Input Peripheral Source for FAULT2 (IPS0_FAULT2)—Bit 13 This field selects the alternate input peripheral source signal to feed PWM input FAULT2. • • 0 = I/O Pin (External) - Use PWM FAULT2 Input Pin (default) 1 = CMPBO (Internal) - Use Comparator B Output 6.3.21.3 Reserved—Bit 12 This bit field is reserved. It must be set to 0. 6.3.21.4 Select Input Peripheral Source for FAULT1 (IPS0_FAULT1)—Bit 11 This field selects the alternate input peripheral source signal to feed PWM input FAULT1. • • 0 = I/O pin (External) - Use PWM FAULT2 Input Pin (default) 1 = CMPAO (Internal) - Use Comparator A Output 6.3.21.5 Reserved—Bits 10–9 This bit field is reserved. Each bit must be set to 0. 6.3.21.6 Select Input Peripheral Source for PWM4/PWM5 Pair Source (IPS0_PSRC2)—Bits 8–6 This field selects the alternate input peripheral source signal to feed PWM input PSRC2 as the PWM4/PWM5 pair source. • • • 000 = Reserved (default) 001 = TA3 (Internal) - Use Timer A3 output as PWM source 010 = ADC SAMPLE2 (Internal) - Use ADC SAMPLE2 result as PWM source — If the ADC conversion result in SAMPLE2 is greater than the value programmed into the High Limit register HLMT2, then PWM4 is set to 0 and PWM5 is set to 1 — If the ADC conversion result in SAMPLE2 is less than the value programmed into the Low Limit register LLMT2, then PWM4 is set to 1 and PWM5 is set to 0 • • • • 011 = CMPAO (Internal) - Use Comparator A output as PWM source 100 = CMPBO (Internal) - Use Comparator B output as PWM source 11x = Reserved 1x1 = Reserved 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 103 6.3.21.7 Select Input Peripheral Source for PWM2/PWM3 Pair Source (IPS0_PSRC1)—Bits 5–3 This field selects the alternate input peripheral source signal to feed PWM input PSRC1 as the PWM2/PWM3 pair source. • • • 000 = I/O pin (External) - Use a PSRC1 input pin as PWM source (default) 001 = TA2 (Internal) - Use Timer A2 output as PWM source 010 = ADC SAMPLE1 (Internal) - Use ADC SAMPLE1 result as PWM source — If the ADC conversion result in SAMPLE1 is greater than the value programmed into the High Limit register HLMT1, then PWM2 is set to 0 and PWM3 is set to 1 — If the ADC conversion result in SAMPLE1 is less than the value programmed into the Low Limit register LLMT2, then PWM2 is set to 1 and PWM3 is set to 0 • • • • 011 = CMPAO (Internal) - Use Comparator A output as PWM source 100 = CMPBO (Internal) - Use Comparator B output as PWM source 11x = Reserved 1x1 = Reserved 6.3.21.8 Select Input Peripheral Source for PWM0/PWM1 Pair Source (IPS0_PSRC0)—Bits 2–0 This field selects the alternate input peripheral source signal to feed PWM input PSRC0 as the PWM0/PWM1 pair source. • • • 000 = I/O pin (External) - Use a PSRC0 input pin as PWM source (default) 001 = TA0 (Internal) - Use Timer A0 output as PWM source 010 = ADC SAMPLE0 (Internal) - Use ADC SAMPLE0 result as PWM source — If the ADC conversion result in SAMPLE0 is greater than the value programmed into the High Limit register HLMT1, then PWM0 is set to 0 and PWM1 is set to 1 — If the ADC conversion result in SAMPLE0 is less than the value programmed into the Low Limit register LLMT2, then PWM0 is set to 1 and PWM1 is set to 0 • • • • 011 = CMPAO (Internal) - Use Comparator A output as PWM source 100 = CMPBO (Internal) - Use Comparator B output as PWM source 11x = Reserved 1x1 = Reserved 6.3.22 Internal Peripheral Source Select Register 1 for Digital-to-Analog Converters (SIM_IPS1) See Section 6.3.21 for general information about Internal Peripheral Source Select registers. 56F8036 Data Sheet, Rev. 3 104 Freescale Semiconductor Preliminary Register Descriptions Base + $19 15 14 13 12 11 10 9 8 7 Read 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 6 4 0 0 3 0 IPS1_DSYNC1 Write RESET 5 0 0 2 1 0 IPS1_DSYNC0 0 0 0 Figure 6-26 Internal Peripheral Source Select Register for DACs (SIM_IPS1) 6.3.22.1 Reserved—Bits 15–7 This bit field is reserved. Each bit must be set to 0. 6.3.22.2 Select Input Peripheral Source for SYNC Input to DAC 1 (IPS1_DSYNC1)—Bits 6–4 This field selects the alternate input source signal to feed DAC1 SYNC input. • • • • • • • 000 = PIT0 (Internal) - Use Programmable Interval Timer 0 Output as DAC SYNC input (default) 001 = PIT1 (Internal) - Use Programmable Interval Timer 1 Output as DAC SYNC input 010 = PIT2 (Internal) - Use Programmable Interval Timer 2 Output as DAC SYNC input 011 = PWM SYNC (Internal) - Use PWM reload synchronization signal as DAC SYNC input 100 = TA0 (Internal) - Use Timer A0 output as DAC SYNC input 101 = TA1 (Internal) - Use Timer A1 output as DAC SYNC input 11x = Reserved 6.3.22.3 Reserved—Bit 3 This bit field is reserved. Each bit must be set to 0. 6.3.22.4 Select Input Peripheral Source for SYNC Input to DAC 0 (IPS1_DSYNC0)—Bits 2–0 This field selects the alternate input source signal to feed DAC0 SYNC input. • • • • • • • 000 = PIT0 (Internal) - Use Programmable Interval Timer 0 Output as DAC SYNC input (default) 001 = PIT1 (Internal) - Use Programmable Interval Timer 1 Output as DAC SYNC input 010 = PIT2 (Internal) - Use Programmable Interval Timer 2 Output as DAC SYNC input 011 = PWM SYNC (Internal) - Use PWM reload synchronization signal as DAC SYNC input 100 = TA0 (Internal) - Use Timer A0 output as DAC SYNC input 101 = TA1 (Internal) - Use Timer A1 output as DAC SYNC input 11x = Reserved 6.3.23 Internal Peripheral Source Select Register 2 for Quad Timer A (SIM_IPS2) See Section 6.3.21 for general information about Internal Peripheral Source Select registers. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 105 Base + $1A 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Read 0 0 0 IPS2_ TA3 0 0 0 IPS2_ TA2 0 0 0 IPS2_ TA1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Write RESET Figure 6-27 Internal Peripheral Source Select Register for TMRA (SIM_IPS2) 6.3.23.1 Reserved—Bits 15–13 This bit field is reserved. Each bit must be set to 0. 6.3.23.2 Select Input Peripheral Source for TA3 (IPS2_TA3)—Bit 12 This field selects the alternate input peripheral source signal to feed Quad Timer A, input 3. • • 0 = I/O pin (External) - Use Timer A3 input/output pin 1 = PWM SYNC (Internal) - Use PWM reload synchronization signal 6.3.23.3 Reserved—Bits 11–9 This bit field is reserved. Each bit must be set to 0. 6.3.23.4 Select Input Peripheral Source for TA2 (IPS2_TA2)—Bit 8 This field selects the alternate input source signal to feed Quad Timer A, input 2. • • 0 = I/O pin (External) - Use Timer A2 input/output pin 1 = CMPBO (Internal) - Use Comparator B output 6.3.23.5 Reserved—Bits 7–5 This bit field is reserved. Each bit must be set to 0. 6.3.23.6 Select Input Peripheral Source for TA1 (IPS2_TA1)—Bit 4 This field selects the alternate input peripheral source signal to feed Quad Timer A, input 1. • • 0 = I/O pin (External) - Use Timer A1 input/output pin 1 = CMPAO (Internal) - Use Comparator A output 6.3.23.7 Reserved—Bits 3–0 This bit field is reserved. Each bit must be set to 0. For Timer A to detect the PWM SYNC signal, the clock rate of both the PWM module and Timer A module must be identical, at either the system clock rate or 3X system clock rate. 56F8036 Data Sheet, Rev. 3 106 Freescale Semiconductor Preliminary Clock Generation Overview 6.4 Clock Generation Overview The SIM uses the master clock (2X system clock) at a maximum of 64MHz from the OCCS module to produce a system clock at a maximum of 32MHz for the peripheral, core, and memory. It divides the master clock by two and gates it with appropriate power mode and clock gating controls. A 3X system high-speed peripheral clock input from OCCS operates at three times the system clock at a maximum of 96MHz and can be an optional clock for PWM, Timer A, and I2C modules. These clocks are generated by gating the 3X system high-speed peripheral clock with appropriate power mode and clock gating controls. The OCCS configuration controls the operating frequency of the SIM’s master clocks. In the OCCS, either an external clock (CLKIN), a crystal oscillator, or the relaxation oscillator can be selected as the master clock source (MSTR_OSC). An external clock can be operated at any frequency up to 64MHz. The crystal oscillator can be operated only at a maximum of 8MHz. The relaxation oscillator can be operated at full speed (8MHz), standby speed (400kHz using ROSB), or powered down (using ROPD). An 8MHz MSTR_OSC can be multiplied to 196MHz using the PLL and postscaled to provide a variety of high-speed clock rates. Either the postscaled PLL output or MSTR_OSC signal can be selected to produce the master clocks to the SIM. When the PLL is selected, both the 3X system clock and the 2X system clock are enabled. If the PLL is not selected, the 3X system clock is disabled and the master clock is MSTR_OSC. In combination with the OCCS module, the SIM provides power modes (see Section 6.5), clock enables, and clock rate controls to provide flexible control of clocking and power utilization. The clock rate controls enable the high-speed clocking option for the two quad timers (TMRA and TMRB) and PWM, but requires the PLL to be on and selected. Refer to the 56F802X and 56F803XPeripheral Reference Manual for further details. The peripheral clock enable controls can be used to disable an individual peripheral clock when it is not used. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 107 6.5 Power-Saving Modes The 56F8036 operates in one of five Power-Saving modes, as shown in Table 6-2. Table 6-2 Clock Operation in Power-Saving Modes Mode Core Clocks Peripheral Clocks Description Run Core and memory clocks enabled Peripheral clocks enabled Device is fully functional Wait Core and memory clocks disabled Peripheral clocks enabled Core executes WAIT instruction to enter this mode. Typically used for power-conscious applications. Possible recoveries from Wait mode to Run mode are: 1. Any interrupt 2. Executing a Debug mode entry command during the 56800E core JTAG interface 3. Any reset (POR, external, software, COP) Stop Master clock generation in the OCCS remains operational, but the SIM disables the generation of system and peripheral clocks. Core executes STOP instruction to enter this mode. Possible recoveries from Stop mode to Run mode are: 1. Interrupt from any peripheral configured in the CTRL register to operate in Stop mode (TA0-3, QSCI0, PIT0-1, CAN, CMPA-B) 2. Low-voltage interrupt 3. Executing a Debug mode entry command using the 56800E core JTAG interface 4. Any reset (POR, external, software, COP) Standby The OCCS generates the master clock at a reduced frequency (400kHz). The PLL is disabled and the high-speed peripheral option is not available. System and peripheral clocks operate at 200kHz. The user configures the OCCS and SIM to select the relaxation oscillator clock source (PRECS), shut down the PLL (PLLPD), put the relaxation oscillator in Standby mode (ROSB), and put the large regulator in Standby (LRSTDBY). The device is fully operational, but operating at a minimum frequency and power configuration. Recovery requires reversing the sequence used to enter this mode (allowing for PLL lock time). Power-Down Master clock generation in the OCCS is completely shut down. All system and peripheral clocks are disabled. The user configures the OCCS and SIM to enter Standby mode as shown in the previous description, followed by powering down the oscillator (ROPD). The only possible recoveries from this mode are: 1. External Reset 2. Power-On Reset The power-saving modes provide additional power management options by disabling the clock, reconfiguring the voltage regulator clock generation to manage power utilization, as shown in Table 6-2. Run, Wait, and Stop modes provide methods of enabling/disabling the peripheral and/or core clocking as a group. Stop disable controls for an individual peripheral are provided in the SDn registers to override the 56F8036 Data Sheet, Rev. 3 108 Freescale Semiconductor Preliminary Resets default behavior of Stop mode. By asserting a peripheral’s Stop disable bit, the peripheral clock continues to operate in Stop mode. This is useful to generate interrupts which will recover the device from Stop mode to Run mode. Standby mode provides normal operation but at very low speed and power utilization. It is possible to invoke Stop or Wait mode while in Standby mode for even greater levels of power reduction. A 400kHz external clock can optionally be used in Standby mode to produce the required Standby 200kHz system clock rate. Power-down mode, which selects the ROSC clock source but shuts it off, fully disables the device and minimizes its power utilization but is only recoverable via reset. When the PLL is not selected and the system bus is operating at 200kHz or less, the large regulator can be put into its Standby mode (LRSTDBY) to reduce the power utilization of that regulator. All peripherals, except the COP/watchdog timer, run at the system clock frequency or optional 3X system clock for PWM, Timers, and I2C. The COP timer runs at OSC_CLK / 1024. The maximum frequency of operation is 32MHz. 6.6 Resets The SIM supports five sources of reset, as shown in Figure 6-28. The two asynchronous sources are the external reset pin and the Power-On Reset (POR). The three synchronous sources are the software reset (SW reset), which is generated within the SIM itself by writing the SIM_CTRL register in Section 6.3.1, the COP time-out reset (COP_TOR), and the COP loss-of-reference reset (COP_LOR). The reset generation module has three reset detectors, which resolve into four primary resets. These are outlined in Table 6-3. The JTAG circuitry is reset by the Power-On Reset. Table 6-3 Primary System Resets Reset Sources Reset Signal POR External Software COP Comments EXTENDED_POR X CLKGEN_RST X X X X Released 32 OSC_CLK cycles after all reset sources, including EXTENDED_POR, have released PERIP_RST X X X X Releases 32 SYS_CLK cycles after the CLKGEN_RST is released CORE_RST X X X X Releases 32 SYS_CLK cycles after PERIP_RST is released Stretched version of POR released 64 OSC_CLK cycles after POR deasserts Figure 6-28 provides a graphic illustration of the details in Table 6-3. Note that the POR_Delay blocks use the OSC_CLK as their time base, since other system clocks are inactive during this phase of reset. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 109 EXTENDED_POR JTAG POR Power-On Reset (active low) pulse shaper Delay 64 OSC_CLK Clock Memory Subsystem CLKGEN_RST OCCS COMBINED_RST External RESET IN (active low) pulse shaper COP_TOR (active low) SW Reset COP_LOR (active low) PERIP_RST Delay 32 OSC_CLK Clock RESET Delay 32 sys clocks pulse shaper Delay blocks assert immediately and deassert only after the programmed number of clock cycles. Peripherals 56800E Delay 32 sys clocks pulse shaper CORE_RST Figure 6-28 Sources of RESET Functional Diagram (Test modes not included) POR resets are extended 64 OSC_CLK clocks to stabilize the power supply and clock source. All resets are subsequently extended for an additional 32 OSC_CLK clocks and 64 system clocks as the various internal reset controls are released. Given the normal relaxation oscillator rate of 8MHz, the duration of a POR reset from when power comes on to when code is running is 28µS. An external reset generation circuit may also be used. A description of how these resets are used to initialize the clocking system and system modules is included in Section 6.7. 6.7 Clocks The memory, peripheral and core clocks all operate at the same frequency (32MHz maximum) with the exception of the peripheral clocks for quad timers TMRA and TMRB and the PWM, which have the option to operate at 3X system clock. The SIM is responsible for clock distributions. While the SIM generates the ADC peripheral clock in the same way it generates all other peripheral clocks, the ADC standby and conversion clocks are generated by a direct interface between the ADC and the OCCS module. 56F8036 Data Sheet, Rev. 3 110 Freescale Semiconductor Preliminary Clocks The deassertion sequence of internal resets coordinates the device start up, including the clocking system start up. The sequence is described in the following steps: 1. As power is applied, the Relaxation Oscillator starts to operate. When a valid operating voltage is reached, the POR reset will release. 2. The release of POR reset permits operation of the POR reset extender. The POR extender generates an extended POR reset, which is released 64 OSC_CLK cycles after POR reset. This provides an additional time period for the clock source and power to stabilize. 3. A Combined reset consists of the OR of the extended POR reset, the external reset, the COP reset and Software reset. The entire device, except for the POR extender, is held reset as long as Combined reset is asserted. The release of Combined reset permits operation of the CTRL register, the Synchronous reset generator, and the CLKGEN reset extender. 4. The Synchronous reset generator generates a reset to the Software and COP reset logic. The COP and Software reset logic is released three OSC_CLK cycles after Combined reset deasserts. This provides a reasonable minimum duration to the reset for these specialized functions. 5. The CLKGEN reset extender generates the CLKGEN reset used by the clock generation logic. The CLKGEN reset is released 32 OSC_CLK cycles after Combined reset deasserts. This provides a window in which the SIM stabilizes the master clock inputs to the clock generator. 6. The release of CLKGEN reset permits operation of the clock generation logic and the Peripheral reset extender. The Peripheral reset extender generates the Peripheral reset, which is released 32 SYS_CLK cycles after CLKGEN reset. This provides a window in which peripheral and core logic remain clocked, but in reset, so that synchronous resets can be resolved. 7. The release of Peripheral reset permits operation of the peripheral logic and the Core reset extender. The Core reset extender generates the Core reset, which is released 32 SYS_CLK cycles after the Peripheral reset. This provides a window in which critical peripheral start-up functions, such as Flash Security in the Flash memory, can be implemented. 8. The release of Core reset permits execution of code by the 56800E core and marks the end of the system start-up sequence. Figure 6-29 illustrates clock relationships to one another and to the various resets as the device comes out of reset. RST is assumed to be the logical AND of all active-low system resets (for example, POR, external reset, COP and Software reset). In the 56F8036, this signal will be stretched by the SIM for a period of time (up to 96 OSC_CLK clock cycles, depending upon the status of the POR) to create the clock generation reset signal (CLKGEN_RST). The SIM should deassert CLKGEN_RST synchronously with the negative edge of OSC_CLK in order to avoid skew problems. CLKGEN_RST is delayed 32 SYS_CLK cycles to create the peripheral reset signal (PERIP_RST). PERIP_RST is then delayed by 32 SYS_CLK cycles to create CORE_RST. Both PERIP_RST and CORE_RST should be released on the negative edge of SYS_CLK_D as shown. This phased releasing of system resets is necessary to give some peripherals (for example, the Flash interface unit) set-up time prior to the 56800E core becoming active. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 111 Maximum Delay = 64 OSC_CLK cycles for POR reset extension and 32 OSC_CLK cycles for Combined reset extension RST MSTR_OSC Switch on falling OSC_CLK 96 MSTR_OSC cycles CKGEN_RST 2X SYS_CLK SYS_CLK SYS_CLK_D SYS_CLK_DIV2 32 SYS_CLK cycles delay Switch on falling SYS_CLK PERIP_RST Switch on falling SYS_CLK 32 SYS_CLK cycles delay CORE_RST Figure 6-29 Timing Relationships of Reset Signal to Clocks 6.8 Interrupts The SIM generates no interrupts. Part 7 Security Features The 56F8036 offers security features intended to prevent unauthorized users from reading the contents of the Flash Memory (FM) array. The 56F8036’s Flash security consists of several hardware interlocks that prevent unauthorized users from gaining access to the Flash array. Note, however, that part of the security must lie with the user’s code. An extreme example would be user’s code that includes a subroutine to read and transfer the contents of the internal program to QSCI, QSPI or another peripheral, as this code would defeat the purpose of security. At the same time, the user may also wish to put a “backdoor” in his program. As an example, the user downloads a security key through the QSCI, allowing access to a programming routine that updates parameters stored in another section of the Flash. 7.1 Operation with Security Enabled Once the user has programmed the Flash with his application code, the 56F8036 can be secured by programming the security bytes located in the FM configuration field, which are located at the last nine 56F8036 Data Sheet, Rev. 3 112 Freescale Semiconductor Preliminary Flash Access Lock and Unlock Mechanisms words of Program Flash. These non-volatile bytes will keep the device secured through reset and through power-down of the device. Only two bytes within this field are used to enable or disable security. Refer to the Flash Memory chapter in the 56F802X and 56F803XPeripheral Reference Manual for the state of the security bytes and the resulting state of security. When Flash security mode is enabled in accordance with the method described in the Flash Memory module chapter, the 56F8036 will disable the core EOnCE debug capabilities. Normal program execution is otherwise unaffected. 7.2 Flash Access Lock and Unlock Mechanisms The 56F8036 has several operating functional and debug modes. Effective Flash security must address operating mode selection and anticipate modes in which the on-chip Flash can be read without explicit user permission. 7.2.1 Disabling EOnCE Access On-chip Flash can be read by issuing commands across the EOnCE port, which is the debug interface for the 56800E CPU. The TCK, TMS, TDO, and TDI pins comprise a JTAG interface onto which the EOnCE port functionality is mapped. When the 56F8036 boots, the chip-level JTAG TAP (Test Access Port) is active and provides the chip’s boundary scan capability and access to the ID register, but proper implementation of Flash security will block any attempt to access the internal Flash memory via the EOnCE port when security is enabled. 7.2.2 Flash Lockout Recovery Using JTAG If a user inadvertently enables security on the 56F8036, the only lockout recovery mechanism is the complete erasure of the internal Flash contents, including the configuration field, and thus disables security (the protection register is cleared). This does not compromise security, as the entire contents of the user’s secured code stored in Flash are erased before security is disabled on the 56F8036 on the next reset or power-up sequence. To start the lockout recovery sequence, the JTAG public instruction (LOCKOUT_RECOVERY) must first be shifted into the chip-level TAP controller’s instruction register. Once the LOCKOUT_RECOVERY instruction has been shifted into the instruction register, the clock divider value must be shifted into the corresponding 7-bit data register. After the data register has been updated, the user must transition the TAP controller into the RUN-TEST/IDLE state for the lockout sequence to commence. The controller must remain in this state until the erase sequence has completed. Refer to the 56F802X and 56F803XPeripheral Reference Manual for more details, or contact Freescale. Note: Once the lockout recovery sequence has completed, the user must reset both the JTAG TAP controller (by advancing the TAP state machine to the reset state) and the 56F8036 (by asserting external chip reset) to return to normal unsecured operation. 7.2.3 Flash Lockout Recovery using CodeWarrior CodeWarrior can unlock a device using the command sequence described in Section 7.2.2 by selecting the Debug menu, then selecting DSP56800E, followed by Unlock Flash. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 113 Another mechanism is also built into CodeWarrior using the device’s memory configuration file. The command “Unlock_Flash_on_Connect1” in the .cfg file accomplishes the same task as using the Debug menu. 7.2.4 Product Analysis The recommended method of unsecuring a programmed 56F8036 for product analysis of field failures is via the backdoor key access. The customer would need to supply Technical Support with the backdoor key and the protocol to access the backdoor routine in the Flash. Additionally, the KEYEN bit that allows backdoor key access must be set. An alternative method for performing analysis on a secured microcontroller would be to mass-erase and reprogram the Flash with the original code, but modify the security bytes. To insure that a customer does not inadvertently lock himself out of the 56F8036 during programming, it is recommended that the user program the backdoor access key first, the application code second, and the security bytes within the FM configuration field last. Part 8 General Purpose Input/Output (GPIO) 8.1 Introduction This section is intended to supplement the GPIO information found in the 56F802X and 56F803XPeripheral Reference Manual and contains only chip-specific information. This information supersedes the generic information in the 56F802X and 56F803XPeripheral Reference Manual. 8.2 Configuration There are four GPIO ports defined on the 56F8036. The width of each port, the associated peripheral and reset functions are shown in Table 8-1. The specific mapping of GPIO port pins is shown in Table 8-2. Additional details are shown in Tables 2-2 and 2-3. Table 8-1 GPIO Ports Configuration GPIO Port Available Pins in 56F8036 A 12 PWM, Timer, QSPI, Comparator, Reset GPIO, RESET B 11 QSPI, I2C, PWM, Clock, MSCAN, Comparator, Timer GPIO C 10 ADC, Comparator, QSCI GPIO D 6 Clock, Oscillator, DAC, JTAG GPIO, JTAG Peripheral Function Reset Function 56F8036 Data Sheet, Rev. 3 114 Freescale Semiconductor Preliminary Configuration Table 8-2 GPIO External Signals Map GPIO Function Peripheral Function LQFP Package Pin Notes GPIOA0 PWM0 44 Defaults to A0 GPIOA1 PWM1 43 Defaults to A1 GPIOA2 PWM2 35 Defaults to A2 GPIOA3 PWM3 36 Defaults to A3 GPIOA4 PWM4 / TA2 / FAULT1 33 SIM register SIM_GPS is used to select between PWM4, TA2, and FAULT1. Defaults to A4 GPIOA5 PWM5 / TA3 / FAULT2 29 SIM register SIM_GPS is used to select between PWM5, TA3, and FAULT2. Defaults to A5 GPIOA6 FAULT0 / TA0 26 SIM register SIM_GPS is used to select between FAULT0 and TA0. Defaults to A6 GPIOA7 RESET 23 Defaults to RESET GPIOA8 FAULT1 / TA2 / CMPAI1 28 SIM register SIM_GPS is used to select between FAULT1, TA2, and CMPAI1. Defaults to A8 GPIOA9 FAULT2 / TA3 / CMPBI1 5 SIM register SIM_GPS is used to select between FAULT2, TA3, and CMPBI1. Defaults to A9 GPIOA10 CMPAI2 27 Defaults to A10 GPIOA11 CMPBI2 6 Defaults to A11 GPIOB0 SCLK0 / SCL 32 SIM register SIM_GPS is used to select between SCLK and SCL. Defaults to B0 GPIOB1 SS0 / SDA 2 SIM register SIM_GPS is used to select between SS0 and SDA. Defaults to B1 GPIOB2 MISO0 / TA2 / PSRC0 25 SIM register SIM_GPS is used to select between MISO0, TA2, and PSRC0. Defaults to B2 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 115 Table 8-2 GPIO External Signals Map (Continued) GPIO Function Peripheral Function LQFP Package Pin Notes GPIOB3 MOSI0 / TA3 / PSRC1 24 SIM register SIM_GPS is used to select between MOSI0, TA3 and PSRC1. Defaults to B3 GPIOB5 TA1 / FAULT3 / CLKIN 4 SIM register SIM_GPS is used to select between TA1, FAULT3, and CLKIN. CLKIN functionality is enabled using the PLL Control Register within the OCCS block. Defaults to B5 GPIOB6 RXD0 / SDA / CLKIN 1 SIM register SIM_GPS is used to select between RXD0, SDA, and CLKIN. CLKIN functionality is enabled using the PLL Control Register within the OCCS block. Defaults to B6 GPIOB7 TXD0 / SCL 3 SIM register SIM_GPS is used to select between TXD0 and SCL. Defaults to B7 GPIOB8 SCL / CANTX 42 SIM register SIM_GPS is used to select between SCL and CANTX. Defaults to B8 GPIOB9 SDA / CANRX 34 SIM register SIM_GPS is used to select between SDA and CANRX. Defaults to B9 GPIOB10 CMPAO 22 Defaults to B10 GPIOB11 CMPBO 46 Defaults to B11 GPIOC0 ANA0 / CMPAI3 17 SIM register SIM_GPS is used to select between ANA0 and CMPAI3. Defaults to C0 GPIOC1 ANA1 16 Defaults to C1 GPIOC2 ANA2 / VREFHA 15 SIM register SIM_GPS is used to select between ANA2 and VREFHA. Defaults to C2 GPIOC3 ANA3 / VREFLA 14 SIM register SIM_GPS is used to select between ANA3 and VREFLA. Defaults to C3 GPIOC4 ANB0 / CMPBI3 8 SIM register SIM_GPS is used to select between ANB0 and CMPBI3. Defaults to C4 56F8036 Data Sheet, Rev. 3 116 Freescale Semiconductor Preliminary Reset Values Table 8-2 GPIO External Signals Map (Continued) GPIO Function Peripheral Function LQFP Package Pin Notes GPIOC5 ANB1 9 Defaults to C5 GPIOC6 ANB2 / VREFHB 10 SIM register SIM_GPS is used to select between ANB2 and VREFHB. Defaults to C6 GPIOC7 ANB3 / VREFLB 11 SIM register SIM_GPS is used to select between ANB3 and VREFLB. Defaults to C7 GPIOC8 ANA4 18 Defaults to C8 GPIOC12 ANB4 7 Defaults to C12 GPIOD0 TDI 45 Defaults to TDI GPIOD1 TDO 48 Defaults to TDO GPIOD2 TCK 21 Defaults to TCK GPIOD3 TMS 47 Defaults to TMS GPIOD4 EXTAL 41 Defaults to D4 GPIOD5 XTAL / CLKIN 40 SIM register SIM_GPSCD is used to select between XTAL and CLKIN. Defaults to D5 8.3 Reset Values Tables 8-1 and 8-2 detail registers for the 56F8036; Figures 8-1 through 8-4 summarize register maps and reset values. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 117 Add. Offset Register Acronym $0 GPIOA_PUPEN $1 $2 $3 $4 $5 $6 $7 $8 $9 $A $B GPIOA_DATA GPIOA_DDIR GPIOA_PEREN GPIOA_IASSRT GPIOA_IEN GPIOA_IEPOL GPIOA_IPEND GPIOA_IEDGE GPIOA_PPOUTM GPIOA_RDATA GPIOA_DRIVE 15 14 13 12 R W RS 0 0 0 0 0 1 1 1 R W RS .0 .0 .0 .0 0 0 0 0 . 0. .0. . 0. 0 0 0 R . 0. W RS 0 R W RS 0 0 0 0 0 0 0 0 R W RS 0 0 0 0 0 0 0 0 0 0 0 R W RS 0 0 0 0 0 0 0 0 R 0 0 0 0 W RS 0 0 0 0 R 0 0 0 0 W RS 0 0 0 0 R W RS 0 0 0 0 0 0 0 0 R W RS 0 0 0 0 0 1 1 1 R W RS 0 0 0 0 0 X X X R W RS 0 0 0 0 0 0 0 0 R W 0 RS 11 10 9 8 7 6 5 4 3 2 1 0 1 1 1 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 1 1 1 X X X X X 0 0 0 0 0 PU[15:0] 1 1 1 1 1 1 1 D[15:0] 0 0 0 0 0 0 0 DD[15:0] 0 0 0 0 0 0 0 PE[15:0] 0 0 0 0 0 0 0 IA[15:0] 0 0 0 0 0 0 0 IEN[15:0] 0 0 0 0 0 0 0 IEPOL[15:0] 0 0 0 0 0 0 0 IPR[15:0] 0 0 0 0 0 0 0 IES[15:0] 0 0 0 0 0 0 0 OEN[15:0] 1 1 1 1 1 1 1 RAW DATA[15:0] X X X X X X X DRIVE[15:0] 0 0 0 0 0 0 0 Read as 0 Reserved Reset Figure 8-1 GPIOA Register Map Summary 56F8036 Data Sheet, Rev. 3 118 Freescale Semiconductor Preliminary Reset Values Add. Offset Register Acronym $0 GPIOB_PUPEN $1 $2 $3 $4 $5 $6 $7 $8 $9 $A $B GPIOB_DATA GPIOB_DDIR GPIOB_PEREN GPIOB_IASSRT GPIOB_IEN GPIOB_IEPOL GPIOB_IPEND GPIOB_IEDGE GPIOB_PPOUTM GPIOB_RDATA GPIOB_DRIVE 15 14 13 12 R W RS 0 0 0 0 0 0 1 1 R W RS 0 0 0 0 0 0 0 0 R W RS 0 0 0 0 0 0 0 0 R W RS 0 0 0 0 0 0 0 0 R W RS 0 0 0 0 0 0 0 0 R W RS 0 0 0 0 0 0 0 0 R W RS 0 0 0 0 0 0 0 0 R 0 0 0 0 W RS 0 0 0 0 R W RS 0 0 0 0 0 0 0 0 R W RS 0 0 0 0 0 0 1 1 R W RS 0 0 0 0 0 0 X X R W RS 0 0 0 0 0 0 0 0 R W 0 RS 11 10 9 8 7 6 5 4 3 2 1 0 1 1 1 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 1 1 1 X X X X X 0 0 0 0 0 PU[15:0] 1 1 1 1 1 1 1 D[15:0] 0 0 0 0 0 0 0 DD[15:0] 0 0 0 0 0 0 0 PE[15:0] 0 0 0 0 0 0 0 IA[15:0] 0 0 0 0 0 0 0 IEN[15:0] 0 0 0 0 0 0 0 IEPOL[15:0] 0 0 0 0 0 0 0 IPR[15:0] 0 0 0 0 0 0 0 IES[15:0] 0 0 0 0 0 0 0 OEN[15:0] 1 1 1 1 1 1 1 RAW DATA[15:0] X X X X X X X DRIVE[15:0] 0 0 0 0 0 0 0 Read as 0 Reserved Reset Figure 8-2 GPIOB Register Map Summary 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 119 Add. Offset Register Acronym $0 GPIOC_PUPEN $1 $2 $3 $4 $5 $6 $7 $8 $9 $A $B GPIOC_DATA GPIOC_DDIR GPIOC_PEREN GPIOC_IASSRT GPIOC_IEN GPIOC_IEPOL GPIOC_IPEND GPIOC_IEDGE GPIOC_PPOUTM GPIOC_RDATA GPIOC_DRIVE 15 14 13 R W RS 0 0 0 1 1 1 R W RS 0 0 0 0 0 0 R W RS 0 0 0 0 0 0 R W RS 0 0 0 0 0 0 R W RS 0 0 0 0 0 0 R W RS 0 0 0 0 0 0 R W RS 0 0 0 0 0 0 R 0 0 W RS 0 R W RS 11 10 9 8 0 0 0 0 1 1 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 IPR [15:0] 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 R W RS 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 R 0 0 0 RAW DATA [15:0] 0 0 0 0 W RS X X X X X X X X R W RS 0 0 0 0 0 0 0 0 0 0 0 0 0 0 R W 0 RS 12 PU [15:0] 1 D [15:0] 0 DD [15:0] 0 PE [15:0] 0 IA [15:0] 0 IEN [15:0] 0 IEPOL [15:0] IES [15:0] 0 OEN [15:0] DRIVE [15:0] 0 7 6 5 4 3 2 1 0 1 1 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 1 X X X 0 0 0 PU 1 1 1 1 D 0 0 0 0 DD 0 0 0 0 PE 0 0 0 0 IA 0 0 0 0 IEN 0 0 0 0 IEPOL 0 0 0 0 IPR 0 0 0 0 IES 0 0 0 0 OEN 1 1 1 1 1 RAW DATA X X X X X DRIVE 0 0 0 0 0 Read as 0 Reserved Reset Figure 8-3 GPIOC Register Map Summary 56F8036 Data Sheet, Rev. 3 120 Freescale Semiconductor Preliminary Reset Values Add. Offset Register Acronym $0 GPIOD_PUPEN $1 $2 $3 $4 $5 $6 GPIOD_DATA GPIOD_DDIR GPIOD_PEREN GPIOD_IASSRT GPIOD_IEN GPIOD_IEPOL 15 R W RS R W RS R W RS R W RS R W RS R W RS R W RS 14 13 12 11 10 9 8 7 6 5 4 $8 $9 $A $B GPIOD_IPEND GPIOD_IEDGE GPIOD_PPOUTM GPIOD_RDATA GPIOD_DRIVE W RS R W RS R W RS R W RS R W RS R W RS 2 1 0 1 1 0 0 0 0 1 1 0 0 0 0 0 0 0 0 0 0 1 1 PU[15:0] 0 0 0 0 0 0 0 0 1 1 1 1 1 1 D[15:0] 0 0 0 0 0 0 0 0 0 0 0 0 0 0 DD[15:0] 0 0 0 0 0 0 0 0 0 0 0 0 0 0 PE[15:0] 0 0 0 0 0 0 0 0 0 0 0 0 1 1 IA[15:0] 0 0 0 0 0 0 0 0 0 0 0 0 0 0 IEN[15:0] 0 0 0 0 0 0 0 0 0 0 0 0 0 0 IEPOL[15:0] 0 0 0 0 0 0 0 0 0 0 0 0 R $7 3 0 0 IPR[15:0] 0 0 0 0 0 0 0 0 0 0 0 0 0 0 IES[15:0] 0 0 0 0 0 0 0 0 0 0 0 0 0 0 OEN[15:0] 0 0 0 0 0 0 0 0 1 1 1 1 1 1 RAW DATA[15:0] 0 0 0 0 0 0 0 0 X X X X X X X X 0 0 DRIVE[15:0] 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Read as 0 Reserved Reset Figure 8-4 GPIOD Register Map Summary 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 121 Part 9 Joint Test Action Group (JTAG) 9.1 56F8036 Information Please contact your Freescale sales representative or authorized distributor for device/package-specific BSDL information. The TRST pin is not available in this package. The pin is tied to VDD in the package. The JTAG state machine is reset during POR and can also be reset via a soft reset by holding TMS high for five rising edges of TCK, as described in the 56F802X and 56F803XPeripheral Reference Manual. Part 10 Specifications 10.1 General Characteristics The 56F8036 is fabricated in high-density CMOS with 5V-tolerant TTL-compatible digital inputs. The term “5V-tolerant” refers to the capability of an I/O pin, built on a 3.3V-compatible process technology, to withstand a voltage up to 5.5V without damaging the device. Many systems have a mixture of devices designed for 3.3V and 5V power supplies. In such systems, a bus may carry both 3.3V- and 5V-compatible I/O voltage levels (a standard 3.3V I/O is designed to receive a maximum voltage of 3.3V ± 10% during normal operation without causing damage). This 5V-tolerant capability therefore offers the power savings of 3.3V I/O levels, combined with the ability to receive 5V levels without damage. Absolute maximum ratings in Table 10-1 are stress ratings only, and functional operation at the maximum is not guaranteed. Stress beyond these ratings may affect device reliability or cause permanent damage to the device. Unless otherwise stated, all specifications within this chapter apply over the temperature range of -40ºC to 125ºC ambient temperature over the following supply ranges: VSS = VSSA = 0V, VDD = VDDA = 3.0–3.6V, CL < 50pF, fOP = 32MHz CAUTION This device contains protective circuitry to guard against damage due to high static voltage or electrical fields. However, normal precautions are advised to avoid application of any voltages higher than maximum-rated voltages to this high-impedance circuit. Reliability of operation is enhanced if unused inputs are tied to an appropriate voltage level. 56F8036 Data Sheet, Rev. 3 122 Freescale Semiconductor Preliminary General Characteristics Table 10-1 Absolute Maximum Ratings (VSS = 0V, VSSA = 0V) Characteristic Symbol Notes Min Max Unit Supply Voltage Range VDD -0.3 4.0 V Analog Supply Voltage Range VDDA - 0.3 4.0 V ADC High Voltage Reference VREFHx - 0.3 4.0 V Voltage difference VDD to VDDA ΔVDD - 0.3 0.3 V Voltage difference VSS to VSSA ΔVSS - 0.3 0.3 V Digital Input Voltage Range VIN Pin Groups 1, 2 - 0.3 6.0 V Oscillator Voltage Range VOSC Pin Group 4 - 0.4 4.0 V Analog Input Voltage Range VINA Pin Group 3 - 0.3 4.0 V Input clamp current, per pin (VIN < 0)1 VIC — -20.0 mA Output clamp current, per pin (VO < 0)1 VOC — -20.0 mA Output Voltage Range (Normal Push-Pull mode) VOUT Pin Group 1 - 0.3 4.0 V VOUTOD Pin Group 2 - 0.3 6.0 V VDAC Internal - 0.3 4.0 V TA - 40 105 °C TSTG - 55 150 °C Output Voltage Range (Open Drain mode) Output Voltage Range (DAC) Ambient Temperature Industrial Storage Temperature Range (Extended Industrial) 1. Continuous clamp current per pin is -2.0 mA Default Mode Pin Group 1: GPIO, TDI, TDO, TMS, TCK Pin Group 2: RESET, GPIOA7 Pin Group 3: ADC and Comparator Analog Inputs Pin Group 4: XTAL, EXTAL 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 123 10.1.1 ElectroStatic Discharge (ESD) Model Table 10-2 56F8036 ESD Protection Characteristic Min Typ Max Unit ESD for Human Body Model (HBM) 2000 — — V ESD for Machine Model (MM) 200 — — V ESD for Charge Device Model (CDM) 750 — — V Table 10-3 LQFP Package Thermal Characteristics6 Characteristic Comments Symbol Value (LQFP) Unit Notes RθJA 41 °C/W 2 Junction to ambient Natural convection Single layer board (1s) Junction to ambient Natural convection Four layer board (2s2p) RθJMA 34 °C/W 1, 2 Junction to ambient (@200 ft/min) Single layer board (1s) RθJMA 34 °C/W 2 Junction to ambient (@200 ft/min) Four layer board (2s2p) RθJMA 29 °C/W 1, 2 Junction to board RθJB 24 °C/W 4 Junction to case RθJC 8 °C/W 3 ΨJT 2 °C/W 5 Junction to package top Natural Convection 1. Theta-JA determined on 2s2p test boards is frequently lower than would be observed in an application. Determined on 2s2p thermal test board. 2. Junction to ambient thermal resistance, Theta-JA (RθJA), was simulated to be equivalent to the JEDEC specification JESD51-2 in a horizontal configuration in natural convection. Theta-JA was also simulated on a thermal test board with two internal planes (2s2p, where “s” is the number of signal layers and “p” is the number of planes) per JESD51-6 and JESD51-7. The correct name for Theta-JA for forced convection or with the non-single layer boards is Theta-JMA. 3. Junction to case thermal resistance, Theta-JC (RθJC), was simulated to be equivalent to the measured values using the cold plate technique with the cold plate temperature used as the “case” temperature. The basic cold plate measurement technique is described by MIL-STD 883D, Method 1012.1. This is the correct thermal metric to use to calculate thermal performance when the package is being used with a heat sink. 4. Junction to board thermal resistance, Theta-JB (RθJB), is a metric of the thermal resistance from the junction to the printed circuit board determined per JESD51-8. Board temperature is measured on the top surface of the board near the package. 5. Thermal Characterization Parameter, Psi-JT (YJT), is the “resistance” from junction to reference point thermocouple on top center of case as defined in JESD51-2. YJT is a useful value to use to estimate junction temperature in steady state customer environments. 6. Junction temperature is a function of die size, on-chip power dissipation, package thermal resistance, mounting site (board) temperature, ambient temperature, air flow, power dissipation of other components on the board, and board thermal resistance. 7. See Section 12.1 for more details on thermal design considerations. 56F8036 Data Sheet, Rev. 3 124 Freescale Semiconductor Preliminary General Characteristics Table 10-4 Recommended Operating Conditions (VREFL x= 0V, VSSA = 0V, VSS = 0V) Characteristic Min Typ Max Unit VDD, VDDA 3 3.3 3.6 V VREFHx 3.0 VDDA V Voltage difference VDD to VDDA ΔVDD -0.1 0 0.1 V Voltage difference VSS to VSSA ΔVSS -0.1 0 0.1 V 1 0 32 32 MHz Supply voltage ADC Reference Voltage High Device Clock Frequency Using relaxation oscillator Using external clock source Symbol Notes FSYSCLK Input Voltage High (digital inputs) VIH Pin Groups 1, 2 2.0 5.5 V Input Voltage Low (digital inputs) VIL Pin Groups 1, 2 -0.3 0.8 V Oscillator Input Voltage High XTAL not driven by an external clock XTAL driven by an external clock source VIHOSC Pin Group 4 VDDA - 0.8 2.0 VDDA + 0.3 VDDA + 0.3 V Oscillator Input Voltage Low VILOSC Pin Group 4 -0.3 0.8 V Pin Group 1 Pin Group 1 — — -4 -8 mA Pin Groups 1, 2 Pin Groups 1, 2 — — 4 8 mA -40 105 °C Output Source Current High at VOH min.)1 When programmed for low drive strength When programmed for high drive strength IOH Output Source Current Low (at VOL max.)1 When programmed for low drive strength When programmed for high drive strength IOL Ambient Operating Temperature (Extended Industrial) TA Flash Endurance (Program Erase Cycles) NF TA = -40°C to 125°C 10,000 — cycles Flash Data Retention TR TJ <= 85°C avg 15 — years tFLRET TJ <= 85°C avg 20 — years Flash Data Retention with <100 Program/Erase Cycles — 1. Total chip source or sink current cannot exceed 75mA Default Mode Pin Group 1: GPIO, TDI, TDO, TMS, TCK Pin Group 2: RESET, GPIOA7 Pin Group 3: ADC and Comparator Analog Inputs Pin Group 4: XTAL, EXTAL 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 125 10.2 DC Electrical Characteristics Table 10-5 DC Electrical Characteristics At Recommended Operating Conditions Symbol Notes Min Typ Max Unit Test Conditions Output Voltage High VOH Pin Group 1 2.4 — — V IOH = IOHmax Output Voltage Low VOL Pin Groups 1, 2 — — 0.4 V IOL = IOLmax Digital Input Current High (a) pull-up enabled or disabled IIH Pin Groups 1, 2 — 0 +/- 2.5 μA VIN = 2.4V to 5.5V Comparator Input Current High IIHC Pin Group 3 — 0 +/- 2 μA VIN = VDDA IIHOSC Pin Group 3 — 0 +/- 2 μA VIN = VDDA Digital Input Current Low1 pull-up enabled pull-up disabled IIL Pin Groups 1, 2 μA -15 — -30 0 -60 +/- 2.5 VIN = 0V Comparator Input Current Low IILC Pin Group 3 — 0 +/- 2 μA VIN = 0V Oscillator Input Current Low IILOSC Pin Group 3 — 0 +/- 2 μA VIN = 0V DAC Output Voltage Range VDAC Internal Typically VSSA + 40mV — Typically VDDA 40mV V — IOZ Pin Groups 1, 2 — 0 +/- 2.5 μA — VHYS Pin Groups 1, 2 — 0.35 — V — CIN — 10 — pF — COUT — 10 — pF — Characteristic Oscillator Input Current High Output Current 1 High Impedance State Schmitt Trigger Input Hysteresis Input Capacitance Output Capacitance 1. See Figure 10-1 Default Mode Pin Group 1: GPIO, TDI, TDO, TMS, TCK Pin Group 2: RESET, GPIOA7 Pin Group 3: ADC and Comparator Analog Inputs Pin Group 4: XTAL, EXTAL 56F8036 Data Sheet, Rev. 3 126 Freescale Semiconductor Preliminary DC Electrical Characteristics 2.0 0.0 µA - 2.0 - 4.0 - 6.0 - 8.0 - 10.0 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 Volt Figure 10-1 IIN/IOZ vs. VIN (Typical; Pull-Up Disabled) Table 10-6 Current Consumption per Power Supply Pin Typical @ 3.3V, 25°C Mode Conditions Maximum@ 3.6V, 25°C IDD1 IDDA IDD1 IDDA RUN 32MHz Device Clock Relaxation Oscillator on PLL powered on Continuous MAC instructions with fetches from Program Flash All peripheral modules enabled. TMR and PWM using 1X Clock ADC/DAC powered on and clocked Comparator powered on 48mA 18.8mA — — WAIT 32MHz Device Clock Relaxation Oscillator on PLL powered on Processor Core in WAIT state All Peripheral modules enabled. TMR and PWM using 1X Clock ADC/DAC/Comparator powered off 29mA 0μA — — STOP 4MHz Device Clock Relaxation Oscillator on PLL powered off Processor Core in STOP state All peripheral module and core clocks are off ADC/DAC/Comparator powered off 5.4mA 0μA — — 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 127 Table 10-6 Current Consumption per Power Supply Pin (Continued) Typical @ 3.3V, 25°C Mode Conditions Maximum@ 3.6V, 25°C IDD1 IDDA IDD1 IDDA STANDBY > STOP 100kHz Device Clock Relaxation Oscillator in Standby mode PLL powered off Processor Core in STOP state All peripheral module and core clocks are off ADC/DAC/Comparator powered off Voltage regulator in Standby mode 290μA 0μA 390μA 1μA POWERDOWN Device Clock is off Relaxation Oscillator powered off PLL powered off Processor Core in STOP state All peripheral module and core clocks are off ADC /DAC/Comparator powered off Voltage Regulator in Standby mode 190μA 0μA 250μA 1μA 1. No Output Switching All ports configured as inputs All inputs Low No DC Loads Table 10-7 Power-On Reset Low-Voltage Parameters Characteristic Symbol Min Typ Max Unit Low-Voltage Interrupt for 3.3V supply1 VEI3.3 2.58 2.7 — V Low-Voltage Interrupt for 2.5V supply2 VE12.5 — 2.15 — V Low-Voltage Interrupt Recovery Hysteresis VEIH — 50 — mV Power-On Reset3 POR — 1.8 1.9 V 1. When VDD drops below VEI3.3, an interrupt is generated. 2. When VDD drops below VEI32.5, an interrupt is generated. 3. Power-On Reset occurs whenever the internally regulated 2.5V digital supply drops below 1.8V. While power is ramping up, this signal remains active for as long as the internal 2.5V is below 2.15V or the 3.3V 1/O voltage is below 2.7V, no matter how long the ramp-up rate is. The internally regulated voltage is typically 100mV less than VDD during ramp-up until 2.5V is reached, at which time it self-regulates. 10.2.1 Voltage Regulator Specifications The 56F8036 has two on-chip regulators. One supplies the PLL and relaxation oscillator. It has no external pins and therefore has no external characteristics which must be guaranteed (other than proper operation of the device). The second regulator supplies approximately 2.5V to the 56F8036’s core logic. This regulator requires an external 4.4µF, or greater, capacitor for proper operation. Ceramic and tantalum 56F8036 Data Sheet, Rev. 3 128 Freescale Semiconductor Preliminary AC Electrical Characteristics capacitors tend to provide better performance tolerances. The output voltage can be measured directly on the VCAP pin. The specifications for this regulator are shown in Table 10-8. Table 10-8. Regulator Parameters Characteristic Short Circuit Current Short Circuit Tolerance (VCAP shorted to ground) Symbol Min Typical Max Unit ISS — 450 650 mA TRSC — — 30 minutes 10.3 AC Electrical Characteristics Tests are conducted using the input levels specified in Table 10-5. Unless otherwise specified, propagation delays are measured from the 50% to the 50% point, and rise and fall times are measured between the 10% and 90% points, as shown in Figure 10-2. Low VIH Input Signal High 90% 50% 10% Midpoint1 VIL Fall Time Rise Time Note: The midpoint is VIL + (VIH – VIL)/2. Figure 10-2 Input Signal Measurement References Figure 10-3 shows the definitions of the following signal states: • • • Active state, when a bus or signal is driven, and enters a low impedance state Tri-stated, when a bus or signal is placed in a high impedance state Data Valid state, when a signal level has reached VOL or VOH • Data Invalid state, when a signal level is in transition between VOL and VOH Data2 Valid Data1 Valid Data1 Data3 Valid Data2 Data3 Data Tri-stated Data Invalid State Data Active Data Active Figure 10-3 Signal States 10.4 Flash Memory Characteristics 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 129 Table 10-9 Flash Timing Parameters Characteristic Symbol Min Typ Max Unit Program time1 Tprog 20 — 40 μs Erase time 2 Terase 20 — — ms Tme 100 — — ms Mass erase time 1. There is additional overhead which is part of the programming sequence. See the 56F802X and 56F803XPeripheral Reference Manual for details. 2. Specifies page erase time. There are 512 bytes per page in the Program Flash memory. 10.5 External Clock Operation Timing Table 10-10 External Clock Operation Timing Requirements1 Characteristic Symbol Min Typ Max Unit Frequency of operation (external clock driver)2 fosc 4 8 8 MHz Clock Pulse Width3 tPW 6.25 — — ns External Clock Input Rise Time4 trise — — 3 ns External Clock Input Fall Time5 tfall — — 3 ns 1. Parameters listed are guaranteed by design. 2. See Figure 10-4 for details on using the recommended connection of an external clock driver. 3. The chip may not function if the high or low pulse width is smaller than 6.25ns. 4. External clock input rise time is measured from 10% to 90%. 5. External clock input fall time is measured from 90% to 10%. VIH External Clock 90% 50% 10% 90% 50% 10% tPW tPW tfall trise VIL Note: The midpoint is VIL + (VIH – VIL)/2. Figure 10-4 External Clock Timing 56F8036 Data Sheet, Rev. 3 130 Freescale Semiconductor Preliminary Phase Locked Loop Timing 10.6 Phase Locked Loop Timing Table 10-11 PLL Timing Characteristic Symbol Min Typ Max Unit External reference crystal frequency for the PLL1 fosc 4 8 — MHz Internal reference relaxation oscillator frequency for the PLL frosc — 8 — MHz PLL output frequency2 (24 x reference frequency) fop 96 192 — MHz PLL lock time3 tplls — 40 100 µs Accumulated jitter using an 8MHz external crystal as the PLL source4 JA — — 0.37 % tjitterpll — 350 — ps Cycle-to-cycle jitter 1. An externally supplied reference clock should be as free as possible from any phase jitter for the PLL to work correctly. The PLL is optimized for 8MHz input. 2. The core system clock will operate at 1/6 of the PLL output frequency. 3. This is the time required after the PLL is enabled to ensure reliable operation. 4. This is measured on the CLKO signal (programmed as System clock) over 264 System clocks at 32MHz System clock frequency and using an 8MHz oscillator frequency. 10.7 Relaxation Oscillator Timing Table 10-12 Relaxation Oscillator Timing Characteristic Symbol Minimum Relaxation Oscillator output frequency1 Normal Mode Standby Mode fop — Relaxation Oscillator stabilization time2 troscs — 1 3 ms tjitterrosc — 400 — ps Minimum tuning step size — .08 — % Maximum tuning step size — 40 — % Variation over temperature -40°C to 150ºC4 — Variation over temperature 0°C to 105ºC4 — Cycle-to-cycle jitter. This is measured on the CLKO signal (programmed prescaler_clock) over 264 clocks3 Typical Maximum Unit — 8.05 200 MHz kHz +1.0 to -1.5 +3.0 to -3.0 0 to +1 +2.0 to -2.0 % % 1. Output frequency after application of 8MHz trim value, at 125°C. 2. This is the time required from Standby to Normal mode transition. 3. JA is required to meet QSCI requirements. 4. See Figure 10-5 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 131 8.16 8.08 MHz 8 7.92 7.84 -50 -25 0 25 50 75 100 125 150 175 Degrees C (Junction) Figure 10-5 Relaxation Oscillator Temperature Variation (Typical) After Trim at 125°C 56F8036 Data Sheet, Rev. 3 132 Freescale Semiconductor Preliminary Reset, Stop, Wait, Mode Select, and Interrupt Timing 10.8 Reset, Stop, Wait, Mode Select, and Interrupt Timing Note: All address and data buses described here are internal. Table 10-13 Reset, Stop, Wait, Mode Select, and Interrupt Timing1,2 Characteristic Symbol Typical Min Typical Max Unit See Figure Minimum RESET Assertion Duration tRA 4T — ns — Minimum GPIO pin Assertion for Interrupt tIW 2T — ns 10-6 tRDA 96TOSC + 64T 97TOSC + 65T ns — tIF — 6T ns — RESET deassertion to First Address Fetch3 Delay from Interrupt Assertion to Fetch of first instruction (exiting Stop) 1. In the formulas, T = system clock cycle and Tosc = oscillator clock cycle. For an operating frequency of 32MHz, T = 31.25ns. At 8MHz (used during Reset and Stop modes), T = 125ns. 2. Parameters listed are guaranteed by design. 3. During Power-On Reset, it is possible to use the 56F8036 internal reset stretching circuitry to extend this period to 2^21T. GPIO pin (Input) TIW Figure 10-6 GPIO Interrupt Timing (Negative Edge-Sensitive) 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 133 10.9 Serial Peripheral Interface (SPI) Timing Table 10-14 SPI Timing1 Characteristic Symbol Cycle time Master Slave tC Enable lead time Master Slave tELD Enable lag time Master Slave tELG Clock (SCK) high time Master Slave tCH Clock (SCK) low time Master Slave tCL Data set-up time required for inputs Master Slave tDS Data hold time required for inputs Master Slave tDH Access time (time to data active from high-impedance state) Slave tA Disable time (hold time to high-impedance state) Slave tD Data Valid for outputs Master Slave (after enable edge) tDV Data invalid Master Slave tDI Rise time Master Slave tR Fall time Master Slave tF Min Max Unit 125 62.5 — — ns ns — 31 — — ns ns — 125 — — ns ns 50 31 — — ns ns 50 31 — — ns ns 20 0 — — ns ns 0 2 — — ns ns 4.8 15 ns 3.7 15.2 ns — — 4.5 20.4 ns ns 0 0 — — ns ns — — 11.5 10.0 ns ns — — 9.7 9.0 ns ns See Figure 10-7, 10-8, 10-9, 10-10 10-10 10-10 10-7, 10-8, 10-9, 10-10 10-10 10-7, 10-8, 10-9, 10-10 10-7, 10-8, 10-9, 10-10 10-10 10-10 10-7, 10-8, 10-9, 10-10 10-7, 10-8, 10-9, 10-10 10-7, 10-8, 10-9, 10-10 10-7, 10-8, 10-9, 10-10 1. Parameters listed are guaranteed by design. 56F8036 Data Sheet, Rev. 3 134 Freescale Semiconductor Preliminary Serial Peripheral Interface (SPI) Timing SS SS is held High on master (Input) tC tR tF tCL SCLK (CPOL = 0) (Output) tCH tF tR tCL SCLK (CPOL = 1) (Output) tDH tCH tDS MISO (Input) MSB in Bits 14–1 tDI MOSI (Output) LSB in tDI(ref) tDV Master MSB out Bits 14–1 Master LSB out tR tF Figure 10-7 SPI Master Timing (CPHA = 0) SS (Input) SS is held High on master tC tF tR tCL SCLK (CPOL = 0) (Output) tCH tF tCL SCLK (CPOL = 1) (Output) tCH tDS tR MISO (Input) MSB in Bits 14–1 tDI tDV(ref) MOSI (Output) tDH Master MSB out tDV Bits 14– 1 tF LSB in tDI(ref) Master LSB out tR Figure 10-8 SPI Master Timing (CPHA = 1) 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 135 SS (Input) tC tF tCL SCLK (CPOL = 0) (Input) tELG tR tCH tELD tCL SCLK (CPOL = 1) (Input) tCH tA MISO (Output) Slave MSB out tF tR Bits 14–1 tDS Slave LSB out tDV tDI tDH MOSI (Input) MSB in tD Bits 14–1 tDI LSB in Figure 10-9 SPI Slave Timing (CPHA = 0) SS (Input) tF tC tR tCL SCLK (CPOL = 0) (Input) tCH tELG tELD tCL SCLK (CPOL = 1) (Input) tDV tCH tR tA MISO (Output) Slave MSB out Bits 14–1 tDS tDV tDH MOSI (Input) tD tF MSB in Bits 14–1 Slave LSB out tDI LSB in Figure 10-10 SPI Slave Timing (CPHA = 1) 56F8036 Data Sheet, Rev. 3 136 Freescale Semiconductor Preliminary Quad Timer Timing 10.10 Quad Timer Timing Table 10-15 Timer Timing1, 2 Characteristic Symbol Min Max Unit See Figure PIN 2T + 6 — ns 10-11 Timer input high / low period PINHL 1T + 3 — ns 10-11 Timer output period POUT 125 — ns 10-11 POUTHL 50 — ns 10-11 Timer input period Timer output high / low period 1. In the formulas listed, T = the clock cycle. For 32MHz operation, T = 31.25ns. 2. Parameters listed are guaranteed by design. Timer Inputs PIN PINHL PINHL POUT POUTHL POUTHL Timer Outputs Figure 10-11 Timer Timing 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 137 10.11 Serial Communication Interface (SCI) Timing Table 10-16 SCI Timing1 Characteristic Symbol Min Max Unit See Figure BR — (fMAX/16) Mbps — RXD3 Pulse Width RXDPW 0.965/BR 1.04/BR ns 10-12 TXD4 Pulse Width TXDPW 0.965/BR 1.04/BR ns 10-13 Baud Rate2 LIN Slave Mode Deviation of slave node clock from nominal clock rate before synchronization Deviation of slave node clock relative to the master node clock after synchronization FTOL_UNSYNCH -14 14 % — FTOL_SYNCH -2 2 % — TBREAK 13 — Master node bit periods — 11 — Slave node bit periods — Minimum break character length 1. Parameters listed are guaranteed by design. 2. fMAX is the frequency of operation of the system clock in MHz, which is 32MHz for the 56F8036 device. 3. The RXD pin in QSCI0 is named RXD0. 4. The TXD pin in QSCI0 is named TXD0. RXD QSCI Receive data pin (Input) RXDPW Figure 10-12 RXD Pulse Width TXD QSCI Receive data pin (Input) TXDPW Figure 10-13 TXD Pulse Width 56F8036 Data Sheet, Rev. 3 138 Freescale Semiconductor Preliminary Freescale’s Scalable Controller Area Network (MSCAN) Timing 10.12 Freescale’s Scalable Controller Area Network (MSCAN) Timing Table 10-17 MSCAN Timing1 Characteristic Baud rate Bus wake-up detection Symbol Min Max Unit BRCAN — 1 Mbps TWAKEUP TIPBUS — µs 1. Parameters listed are guaranteed by design MSCAN_RX CAN receive data pin (Input) TWAKEUP Figure 10-14 Bus Wake-up Detection 10.13 Inter-Integrated Circuit Interface (I2C) Timing Table 10-18 I2C Timing Characteristic Symbol Standard Mode Fast Mode Unit Minimum Maximum Minimum Maximum fSCL 0 100 0 400 kHz tHD; STA 4.0 — 0.6 — μs LOW period of the SCL clock tLOW 4.7 — 1.3 — μs HIGH period of the SCL clock tHIGH 4.0 — 0.6 — μs Set-up time for a repeated START condition tSU; STA 4.7 — 0.6 — μs Data hold time for I2C bus devices tHD; DAT 01 3.452 01 0.92 μs Data set-up time tSU; DAT 2503 — 1003, 4 — ns SCL Clock Frequency Hold time (repeated) START condition. After this period, the first clock pulse is generated. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 139 Table 10-18 I2C Timing (Continued) Characteristic Symbol Rise time of both SDA and SCL signals Fall time of both SDA and SCL signals Standard Mode Fast Mode Unit Minimum Maximum Minimum Maximum tr — 1000 20 +0.1Cb5 300 ns tf — 300 20 +0.1Cb5 300 ns Set-up time for STOP condition tSU; STO 4.0 — 0.6 — μs Bus free time between STOP and START condition tBUF 4.7 — 1.3 — μs Pulse width of spikes that must be suppressed by the input filter tSP N/A N/A 0 50 ns 1. The master mode I2C deasserts ACK of an address byte simultaneously with the falling edge of SCL. If no slaves acknowledge this address byte, a negative hold time can result, depending on the edge rates of the SDA and SCL lines. 2. The maximum tHD; DAT must be met only if the device does not stretch the LOW period (tLOW) of the SCL signal. 3. Set-up time in slave-transmitter mode is 1 iPBus clock period, if the TX FIFO is empty. 4. A Fast mode I2C bus device can be used in a Standard mode I2C bus system, but the requirement tSU; DAT > = 250ns must then be met. This will automatically be the case if the device does not stretch the LOW period of the SCL signal. If such a device does stretch the LOW period of the SCL signal, it must output the next data bit to the SDA line trmax + tSU; DAT = 1000 + 250 = 1250ns (according to the Standard mode I2C bus specification) before the SCL line is released. 5. Cb = total capacitance of the one bus line in pF SDA tf tLOW tSU; DAT tr tf tHD; STA tSP tr tBUF SCL S tHD; STA tHD; DAT tHIGH tSU; STA SR tSU; STO P S Figure 10-15 Timing Definition for Fast and Standard Mode Devices on the I2C Bus 56F8036 Data Sheet, Rev. 3 140 Freescale Semiconductor Preliminary JTAG Timing 10.14 JTAG Timing Table 10-19 JTAG Timing Characteristic Symbol Min Max Unit See Figure TCK frequency of operation1 fOP DC SYS_CLK/8 MHz 10-16 TCK clock pulse width tPW 50 — ns 10-16 TMS, TDI data set-up time tDS 5 — ns 10-17 TMS, TDI data hold time tDH 5 — ns 10-17 TCK low to TDO data valid tDV — 30 ns 10-17 TCK low to TDO tri-state tTS — 30 ns 10-17 1. TCK frequency of operation must be less than 1/8 the processor rate. 1/fOP tPW tPW VM VM VIH TCK (Input) VIL VM = VIL + (VIH – VIL)/2 Figure 10-16 Test Clock Input Timing Diagram TCK (Input) TDI TMS (Input) tDS tDH Input Data Valid tDV TDO (Output) Output Data Valid tTS TDO (Output) Figure 10-17 Test Access Port Timing Diagram 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 141 10.15 Analog-to-Digital Converter (ADC) Parameters Table 10-20 ADC Parameters1 Parameter Symbol Min Typ Max Unit Resolution RES 12 — 12 Bits ADC internal clock fADIC 0.1 — 5.33 MHz Conversion range RAD VREFL — VREFH V ADC power-up time2 tADPU — 6 13 tAIC cycles3 Recovery from auto standby tREC — 0 1 tAIC cycles3 Conversion time tADC — 6 — tAIC cycles3 Sample time tADS — 1 — tAIC cycles3 Integral non-linearity4 (Full input signal range) INL — +/- 3 +/- 5 LSB5 Differential non-linearity DNL — +/- .6 +/- 1 LSB5 DC Specifications Accuracy Monotonicity GUARANTEED Offset Voltage Internal Ref VOFFSET — +/- 4 +/- 9 mV Offset Voltage External Ref VOFFSET — +/- 6 +/- 12 mV EGAIN — .998 to 1.002 1.01 to .99 — Input voltage (external reference) VADIN VREFL — VREFH V Input voltage (internal reference) VADIN VSSA — VDDA V Input leakage IIA — 0 +/- 2 μA VREFH current IVREFH — 0 — μA Input injection current7, per pin IADI — — 3 mA Input capacitance CADI — See Figure 10-18 — pF Input impedance XIN — See Figure 10-18 — Ohms Signal-to-noise ratio SNR 60 65 dB Total Harmonic Distortion Gain Error (transfer gain) ADC Inputs6 (Pin Group 3) AC Specifications THD 60 64 dB Spurious Free Dynamic Range SFDR 61 66 dB Signal-to-noise plus distortion SINAD 58 62 dB Effective Number Of Bits ENOB — 10.0 Bits 1. All measurements were made at VDD = 3.3V, VREFH = 3.3V, and VREFL = ground 2. Includes power-up of ADC and VREF 3. ADC clock cycles 4. INL measured from VIN = VREFL to VIN = VREFH 5. LSB = Least Significant Bit = 0.806mV 6. Pin groups are detailed following Table 10-1. 7. The current that can be injected or sourced from an unselected ADC signal input without impacting the performance of the ADC. 56F8036 Data Sheet, Rev. 3 142 Freescale Semiconductor Preliminary Equivalent Circuit for ADC Inputs 10.16 Equivalent Circuit for ADC Inputs Figure 10-18 illustrates the ADC input circuit during sample and hold. S1 and S2 are always open/closed at the same time that S3 is closed/open. When S1/S2 are closed and S3 is open, one input of the sample and hold circuit moves to (VREFHx - VREFLx) / 2, while the other charges to the analog input voltage. When the switches are flipped, the charge on C1 and C2 are averaged via S3, with the result that a single-ended analog input is switched to a differential voltage centered about (VREFHx - VREFLx) / 2. The switches switch on every cycle of the ADC clock (open one-half ADC clock, closed one-half ADC clock). Note that there are additional capacitances associated with the analog input pad, routing, etc., but these do not filter into the S/H output voltage, as S1 provides isolation during the charge-sharing phase. One aspect of this circuit is that there is an on-going input current, which is a function of the analog input voltage, VREF, and the ADC clock frequency. 125Ω ESD Resistor 8pF noise damping capacitor 3 Analog Input 4 S1 C1 S/H S3 1 1. 2. 3. 4. 2 (VREFHx - VREFLx ) / 2 C2 S2 C1 = C2 = 1pF Parasitic capacitance due to package, pin-to-pin and pin-to-package base coupling; 1.8pF Parasitic capacitance due to the chip bond pad, ESD protection devices and signal routing; 2.04pF Equivalent resistance for the channel select mux; 100 ohms Sampling capacitor at the sample and hold circuit. Capacitor C1 is normally disconnected from the input and is only connected to it at sampling time; 1.4pF Figure 10-18 Equivalent Circuit for A/D Loading 10.17 Comparator (CMP) Parameters Table 10-21 CMP Parameters Characteristic Conditions/Comments Symbol Min Typ Max Unit Within range of VDDA - .1V to VSSA + .1V VOFFSET — +/- 10 +/- 20 mV Input Propagation Delay tPD — 35 45 ns Power-up time tCPU — TBD TBD Input Offset Voltage1 1. No guaranteed specification within 0.1V of VDDA or VSSA 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 143 10.18 Digital-to-Analog Converter (DAC) Parameters Table 10-22 DAC Parameters Parameter Conditions/Comments Symbol Min Typ Max Unit 12 bits DC Specifications Resolution 12 Conversion time Conversion rate Power-up time Time from release of PWRDWN signal until DACOUT signal is valid TBD — 2 µS TBD — 500.000 conv/sec tDAPU — — 11 µS Accuracy Integral non-linearity1 Range of input digital words: 410 to 3891 ($19A - $F33) 5% to 95% of full range INL — +/- 3 +/- 8.0 LSB2 Differential non-linearity1 Range of input digital words: 410 to 3891 ($19A - $F33) 5% to 95% of full range DNL — +/- .8 <-1 LSB2 Monotonicity > 6 sigma monotonicity, < 3.4 ppm non-monotonicity Offset error1 Range of input digital words: 410 to 3891 ($19A - $F33) 5% to 95% of full range VOFFSET — +/- 25 +/- 40 mV Gain error1 Range of input digital words: 410 to 3891 ($19A - $F33) 5% to 95% of full range EGAIN — +/- .5 +/- 1.5 % Within 40mV of either VREFLX or VREFHX VOUT VREFLX +.04V — VREFHX - .04V V SNR — TBD — dB Spurious free dynamic range SFDR — TBD — dB Effective number of bits ENOB 9 — — bits guaranteed — DAC Output Output voltage range AC Specifications Signal-to-noise ratio 1. No guaranteed specification within 5% of VDDA or VSSA 2. LSB = 0.806mV 56F8036 Data Sheet, Rev. 3 144 Freescale Semiconductor Preliminary Power Consumption 10.19 Power Consumption See Section 10.1 for a list of IDD requirements for the 56F8036. This section provides additional detail which can be used to optimize power consumption for a given application. Power consumption is given by the following equation: Total power = A: internal [static component] +B: internal [state-dependent component] +C: internal [dynamic component] +D: external [dynamic component] +E: external [static component] A, the internal [static component], is comprised of the DC bias currents for the oscillator, leakage currents, PLL, and voltage references. These sources operate independently of processor state or operating frequency. B, the internal [state-dependent component], reflects the supply current required by certain on-chip resources only when those resources are in use. These include RAM, Flash memory and the ADCs. C, the internal [dynamic component], is classic C*V2*F CMOS power dissipation corresponding to the 56800E core and standard cell logic. D, the external [dynamic component], reflects power dissipated on-chip as a result of capacitive loading on the external pins of the chip. This is also commonly described as C*V2*F, although simulations on two of the I/O cell types used on the 56800E reveal that the power-versus-load curve does have a non-zero Y-intercept. Table 10-23 I/O Loading Coefficients at 10MHz Intercept Slope 8mA drive 1.3 0.11mW / pF 4mA drive 1.15mW 0.11mW / pF Power due to capacitive loading on output pins is (first order) a function of the capacitive load and frequency at which the outputs change. Table 10-23 provides coefficients for calculating power dissipated in the I/O cells as a function of capacitive load. In these cases: TotalPower = Σ((Intercept + Slope*Cload)*frequency/10MHz) where: • • • Summation is performed over all output pins with capacitive loads TotalPower is expressed in mW Cload is expressed in pF 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 145 Because of the low duty cycle on most device pins, power dissipation due to capacitive loads was found to be fairly low when averaged over a period of time. E, the external [static component], reflects the effects of placing resistive loads on the outputs of the device. Sum the total of all V2/R or IV to arrive at the resistive load contribution to power. Assume V = 0.5 for the purposes of these rough calculations. For instance, if there is a total of eight PWM outputs driving 10mA into LEDs, then P = 8*.5*.01 = 40mW. In previous discussions, power consumption due to parasitics associated with pure input pins is ignored, as it is assumed to be negligible. 56F8036 Data Sheet, Rev. 3 146 Freescale Semiconductor Preliminary 56F8036 Package and Pin-Out Information Part 11 Packaging 11.1 56F8036 Package and Pin-Out Information VCAP VDD VSS ORIENTATION MARK GPIOB6 / RXD0 / SDA / CLKIN GPIOA3 / PWM3 GPIOB1 / SS0 / SDA GPIOB7 / TXD0 / SCL GPIOD5 / XTAL / CLKIN GPIOD4 / EXTAL GPIOB8 / SCL / CANTX GPIOA1 / PWM1 GPIOA0 / PWM0 TDI / GPIOD0 GPIOB11 / CMPBO TMS / GPIOD3 TDO / GPIOD1 This section contains package and pin-out information for the 56F8036. This device comes in a 48-pin Low-profile Quad Flat Pack (LQFP). Figure 11-1 shows the package outline, Figure 11-2 shows the mechanical parameters and Table 11-1 lists the pin-out. GPIOA2 / PWM2 PIN 37 GPIOB9 / SDA / CANRX PIN 1 GPIOA4 / PWM4 / TA2 / FAULT1 GPIOB5 / TA1 / FAULT3 / CLKIN GPIOB0 / SCLK0 / SCL GPIOA9 / FAULT2 / TA3 / CMPBI1 GPIOA11 / CMPBI2 VDD GPIOC12 / ANB4 VSS GPIOA5 / PWM5 / TA3 / FAULTA2 GPIOC4 / ANB0 & CMPBI3 GPIOA8 / FAULTA1 / TA2 / CMPAI1 GPIOC5 / ANB1 GPIOC6 / ANB2 / VREFHB PIN 25 PIN 13 GPIOC7 / ANB3 / VREFLB GPIOA10 / CMPAI2 GPIOA6 / FAULT0 / TA0 GPIOB2 / MISO0 / TA2 / PSRC0 GPIOB3 / MOSI0 / TA3 / PSRC1 RESET / GPIOA7 GPIOB10 / CMPAO VCAP TCK / GPIOD2 VSS GPIOC8 / ANA4 GPIOC0 / ANA0 & CMPAI3 GPIOC1 / ANA1 GPIOC2 / ANA2 / VREFHB GPIOC3 / ANA3 / VREFLA VSSA VDDA Figure 11-1 Top View, 56F8036 48-Pin LQFP Package 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 147 Table 11-1 56F8036 48-Pin LQFP Package Identification by Pin Number1 Pin # Signal Name Pin # Signal Name Pin # Signal Name Pin # Signal Name 1 GPIOB6 RXD0 / SDA / CLKIN 13 VSSA 25 GPIOB2 MISO0 / TA2 / PSRC0 37 VCAP 2 GPIOB1 SS0 / SDA 14 GPIOC3 ANA3 / VREFLA 26 GPIOA6 FAULT0 / TA0 38 VDD 3 GPIOB7 TXD0 / SCL 15 GPIOC2 ANA2 / VREFHA 27 GPIOA10 CMPAI2 39 VSS 4 GPIOB5 TA1 / FAULT3 / CLKIN 16 GPIOC1 ANA1 28 GPIOA8 FAULT1 / TA2 / CMPAI1 40 GPIOD5 XTAL / CLKIN 5 GPIOA9 FAULT2 / TA3 / CMPBI1 17 GPIOC0 ANA0 & CMPAI3 29 GPIOA5 PWM5 / TA3 / FAULT2 41 GPIOD4 EXTAL 6 GPIOA11 CMPBI2 18 GPIOC8 ANA4 30 VSS 42 GPIOB8 SCL / CANTX 7 GPIOC12 ANB4 19 VSS 31 VDD 43 GPIOA1 PWM1 8 GPIOC4 ANB0 & CMPBI3 20 VCAP 32 GPIOB0 SCLK0 / SCL 44 GPIOA0 PWM0 9 GPIOC5 ANB1 21 TCI GPIOD2 33 GPIOA4 PWM4 / TA2 / FAULT1 45 TDI GPIOD0 10 GPIOC6 ANB2 / VREFHB 22 GPIOB10 CMPAO 34 GPIOB9 SDA / CANRX 46 GPIOB11 CMPBO 11 GPIOC7 ANB3 / VREFLB 23 RESET GPIOA7 35 GPIOA2 PWM2 47 TMS GPIOD3 12 VDDA 24 GPIOB3 MOSI0 / TA3 / PSRC1 36 GPIOA3 PWM3 48 TDO GPIOD1 1. Alternate signals are in italic 56F8036 Data Sheet, Rev. 3 148 Freescale Semiconductor Preliminary 56F8036 Package and Pin-Out Information 4X 0.200 AB T-U Z DETAIL Y A P A1 48 37 1 36 T U B V AE B1 12 25 13 AE V1 24 Z S1 DIM A A1 B B1 C D E F G H J K L M N P R S S1 V V1 W AA T, U, Z S DETAIL Y 4X 0.200 AC T-U Z 0.080 AC G AB AD AC M° BASE METAL TOP & BOTTOM R J 0.250 N MILLIMETERS MIN MAX 7.000 BSC 3.500 BSC 7.000 BSC 3.500 BSC 1.400 1.600 0.170 0.270 1.350 1.450 0.170 0.230 0.500 BSC 0.050 0.150 0.090 0.200 0.500 0.700 0 ° 7° 12 ° REF 0.090 0.160 0.250 BSC 0.150 0.250 9.000 BSC 4.500 BSC 9.000 BSC 4.500 BSC 0.200 REF 1.000 REF C E GAUGE PLANE 9 NOTES: 1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M, 1994. 2. CONTROLLING DIMENSION: MILLIMETER. 3. DATUM PLANE AB 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 T, U, AND Z TO BE DETERMINED AT DATUM PLANE AB. 5. DIMENSIONS S AND V TO BE DETERMINED AT SEATING PLANE AC. 6. DIMENSIONS A AND B DO NOT INCLUDE MOLD PROTRUSION. ALLOWABLE PROTRUSION IS 0.250 PER SIDE. DIMENSIONS A AND B DO INCLUDE MOLD MISMATCH AND ARE DETERMINED AT DATUM PLANE AB. 7. DIMENSION D DOES NOT INCLUDE DAMBAR PROTRUSION. DAMBAR PROTRUSION SHALL NOT CAUSE THE D DIMENSION TO EXCEED 0.350. 8. MINIMUM SOLDER PLATE THICKNESS SHALL BE 0.0076. 9. EXACT SHAPE OF EACH CORNER IS OPTIONAL. F D 0.080 M AC T-U Z SECTION AE-AE H CASE 932-03 ISSUE F W L° K DETAIL AD AA Figure 11-2 56F8036 48-Pin LQFP Mechanical Information Please see www.freescale.com for the most current case outline. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 149 Part 12 Design Considerations 12.1 Thermal Design Considerations An estimation of the chip junction temperature, TJ, can be obtained from the equation: TJ = TA + (RθJΑ x PD) where: TA = Ambient temperature for the package (oC) RθJΑ = Junction-to-ambient thermal resistance (oC/W) PD = Power dissipation in the package (W) The junction-to-ambient thermal resistance is an industry-standard value that provides a quick and easy estimation of thermal performance. Unfortunately, there are two values in common usage: the value determined on a single-layer board and the value obtained on a board with two planes. For packages such as the PBGA, these values can be different by a factor of two. Which value is closer to the application depends on the power dissipated by other components on the board. The value obtained on a single layer board is appropriate for the tightly packed printed circuit board. The value obtained on the board with the internal planes is usually appropriate if the board has low-power dissipation and the components are well separated. When a heat sink is used, the thermal resistance is expressed as the sum of a junction-to-case thermal resistance and a case-to-ambient thermal resistance: RθJA = RθJC + RθCA where: RθJA = RθJC = RθCA = Package junction-to-ambient thermal resistance (°C/W) Package junction-to-case thermal resistance (°C/W) Package case-to-ambient thermal resistance (°C/W) RθJC is device related and cannot be influenced by the user. The user controls the thermal environment to change the case to ambient thermal resistance, RθCA. For instance, the user can change the size of the heat sink, the air flow around the device, the interface material, the mounting arrangement on printed circuit board, or change the thermal dissipation on the printed circuit board surrounding the device. To determine the junction temperature of the device in the application when heat sinks are not used, the Thermal Characterization Parameter (ΨJT) can be used to determine the junction temperature with a measurement of the temperature at the top center of the package case using the following equation: TJ = TT + (ΨJT x PD) where: TT ΨJT PD = Thermocouple temperature on top of package (oC) = Thermal characterization parameter (oC/W) = Power dissipation in package (W) 56F8036 Data Sheet, Rev. 3 150 Freescale Semiconductor Preliminary Electrical Design Considerations The thermal characterization parameter is measured per JESD51-2 specification using a 40-gauge type T thermocouple epoxied to the top center of the package case. The thermocouple should be positioned so that the thermocouple junction rests on the package. A small amount of epoxy is placed over the thermocouple junction and over about 1mm of wire extending from the junction. The thermocouple wire is placed flat against the package case to avoid measurement errors caused by cooling effects of the thermocouple wire. When heat sink is used, the junction temperature is determined from a thermocouple inserted at the interface between the case of the package and the interface material. A clearance slot or hole is normally required in the heat sink. Minimizing the size of the clearance is important to minimize the change in thermal performance caused by removing part of the thermal interface to the heat sink. Because of the experimental difficulties with this technique, many engineers measure the heat sink temperature and then back-calculate the case temperature using a separate measurement of the thermal resistance of the interface. From this case temperature, the junction temperature is determined from the junction-to-case thermal resistance. 12.2 Electrical Design Considerations CAUTION This device contains protective circuitry to guard against damage due to high static voltage or electrical fields. However, normal precautions are advised to avoid application of any voltages higher than maximum-rated voltages to this high-impedance circuit. Reliability of operation is enhanced if unused inputs are tied to an appropriate voltage level. Use the following list of considerations to assure correct operation of the 56F8036: • Provide a low-impedance path from the board power supply to each VDD pin on the 56F8036 and from the board ground to each VSS (GND) pin • The minimum bypass requirement is to place 0.01–0.1µF capacitors positioned as close as possible to the package supply pins. The recommended bypass configuration is to place one bypass capacitor on each of the VDD/VSS pairs, including VDDA/VSSA. Ceramic and tantalum capacitors tend to provide better tolerances. Ensure that capacitor leads and associated printed circuit traces that connect to the chip VDD and VSS (GND) pins are as short as possible Bypass the VDD and VSS with approximately 100µF, plus the number of 0.1µF ceramic capacitors • • • • PCB trace lengths should be minimal for high-frequency signals Consider all device loads as well as parasitic capacitance due to PCB traces when calculating capacitance. This is especially critical in systems with higher capacitive loads that could create higher transient currents in the VDD and VSS circuits. 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 151 • Take special care to minimize noise levels on the VREF, VDDA, and VSSA pins • Using separate power planes for VDD and VDDA and separate ground planes for VSS and VSSA are recommended. Connect the separate analog and digital power and ground planes as close as possible to power supply outputs. If both analog circuit and digital circuit are powered by the same power supply, it is advisable to connect a small inductor or ferrite bead in serial with both VDDA and VSSA traces. • It is highly desirable to physically separate analog components from noisy digital components by ground planes. Do not place an analog trace in parallel with digital traces. It is also desirable to place an analog ground trace around an analog signal trace to isolate it from digital traces. • Because the Flash memory is programmed through the JTAG/EOnCE port, QSPI, QSCI, or I2C, the designer should provide an interface to this port if in-circuit Flash programming is desired If desired, connect an external RC circuit to the RESET pin. The Resistor value should be in the range of 4.7k—10k; the Capacitor value should be in the range of 0.22µf - 4.7µf. Add a 3.3k external pull-up on the TMS pin of the JTAG port to keep EOnce in a restate during normal operation if JTAG converter is not present During reset and after reset but before I/O initialization, all I/O pins are at input state with internal pull-up enable. The typical value of internal pull-up is around 110K. These internal pull-ups can be disabled by software. To eliminate PCB trace impedance effect, each ADC input should have a 33pf-10 ohm RC filter Device GPIOs have only a down (substrate) diode on the GPIO circuit. Devices do not have a positive clamp diode because GPIOs use a floating gate structure to tolerate 5V input. The absolute maximum clamp current is -20mA at Vin less than 0V. The continuous clamp current is -2mA at Vin less than 0V. If positive voltage spikes are a concern, a positive clamp is recommended. • • • • • Part 13 Ordering Information Table 13-1 lists the pertinent information needed to place an order. Consult a Freescale Semiconductor sales office or authorized distributor to determine availability and to order devices. Table 13-1 56F8036 Ordering Information Device Supply Voltage MC56F8036 3.0–3.6 V Package Type Low-Profile Quad Flat Pack (LQFP) Pin Count Frequency (MHz) Ambient Temperature Range Order Number 48 32 -40° to + 105° C MC56F8036VLF* * This package is RoHS compliant. 56F8036 Data Sheet, Rev. 3 152 Freescale Semiconductor Preliminary Electrical Design Considerations Part 14 Appendix Register acronyms are revised from previous device data sheets to provide a cleaner register description. A cross reference to legacy and revised acronyms are provided in the following table. Note: This table comprises all peripherals used in the 56F803x and 56F802x family; some of the peripherals described here may not be present on this device. Table 14-1 Legacy and Revised Acronyms Peripheral Reference Manual Data Sheet Register Name New Acronym Legacy Acronym New Acronym Legacy Acronym Processor Expert Acronym Memory Address Start End Analog-to-Digital Converter (ADC) Module Control 1 Register Control 2 Register CTRL1 ADCR1 ADC_CTRL1 ADC_ADCR1 ADC_ADCR1 0xF080 CTRL2 ADCR2 ADC_CTRL2 ADC_ADCR2 ADC_ADCR2 0xF081 Zero Crossing Control Register ZXCTRL ADZCC ADC_ZXCTRL ADC_ADZCC ADC_ADZCC 0xF082 Channel List 1 Register CLIST1 ADLST1 ADC_CLIST1 ADC_ADLST1 ADC_ADLST1 0xF083 Channel List 2 Register CLIST2 ADLST2 ADC_CLIST2 ADC_ADLST2 ADC_ADLST2 0xF084 Channel List 3 Register CLIST3 ADC_CLIST3 ADC_ADCLST3 ADC_ADCLST3 0xF085 Channel List 4 Register CLIST4 ADC_CLIST4 ADC_ADCLST4 ADC_ADCLST4 0xF086 Sample Disable Register SDIS ADSDIS ADC_SDIS ADC_ADSDIS ADC_ADSDIS 0xF087 Status Register STAT ADSTAT ADC_STAT ADC_ADSTAT ADC_ADSTAT 0xF088 Conversion Ready Register RDY ADC_CNRDY ADC_ADCNRDY ADC_ADCNRDY 0xF089 Limit Status Register LIMSTAT ADLSTAT ADC_LIMSTAT ADC_ADLSTAT ADC_ADLSTAT 0xF08A Zero Crossing Status Register ZXSTAT ADZCSTAT ADC_ZXSTAT ADC_ADZCSTAT ADC_ADZCSTAT 0xF08B Result 0-7 Registers RSLT0-7 ADRSLT0-7 ADC_RSLT0-7 ADC_ADRSLT0-7 ADC_ADRSLT0-7 0xF08C 0XF093 0XF09B Result 8-15 Registers RSLT8-15 ADC_RSLT8-15 ADC_ADRSLT8-15 ADC_ADRSLT8-15 0xF094 Low Limit 0-7 Registers LOLIM0-7 ADLLMT0-7 ADC_LOLIM0-7 ADC_ADLLMT0-7 ADC_ADLLMT0-7 0XF09C 0XF0A3 High Limit 0-7 Registers HILIM0-7 ADHLMT0-7 ADC_HILIM0-7 ADC_ADHLMT0-7 ADC_ADHLMT0-7 0XF0A4 0XF0AB Offset 0-7 Registers OFFST0-7 ADOFS0-7 ADC_OFFST0-7 ADC_ADOFS0-7 ADC_ADOFS0-7 0XF0AC 0XF0B3 Power Control Register PWR ADPOWER ADC_PWR ADC_ADPOWER ADC_ADPOWER 0XF0B4 Calibration Register CAL ADC_CAL ADC_ADCAL ADC_ADCAL 0XF0B5 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 153 Table 14-1 Legacy and Revised Acronyms (Continued) Peripheral Reference Manual Data Sheet Register Name New Acronym Legacy Acronym New Acronym Legacy Acronym Processor Expert Acronym Memory Address Start End Computer Operating Properly (COP) Module Control Register CTRL COPCTL COP_CTRL COPCTL COPCTL 0XF120 Timeout Register TOUT COPTO COP_TOUT COPTO COPTO 0XF121 Counter Register CNTR COPCTR COP_CNTR COPCTR COPCTR 0XF122 56F8036 Data Sheet, Rev. 3 154 Freescale Semiconductor Preliminary Electrical Design Considerations Table 14-1 Legacy and Revised Acronyms (Continued) Peripheral Reference Manual Data Sheet Register Name New Acronym Legacy Acronym New Acronym Legacy Acronym Processor Expert Acronym Memory Address Start End Inter-Integrated Circuit Interface (I2C) Module Control Register CTRL I2C_CTRL I2C_IBCR I2C_IBCR 0xF280 Target Address Register TAR IBCR I2C_TAR I2CTAR I2C_TAR 0xF282 Slave Address Register SAR I2C_SAR I2CSAR I2C_SAR 0xF242 Data Buffer & Command Register DATA I2C_DATA I2C_DATACMD I2C_DATACMD 0xF288 Standard Speed Clock SCL High Count Register SSHCNT I2C_SS_SCL_HCNT I2C_SS_SCLHCNT I2C_SS_SCLHCNT 0xF28A Standard Speed Clock SCL Low Count Register SSLCNT I2C_SS_SCL_LCNT I2C_SS_SCLLCNT I2C_SS_SCLLCNT 0xF28C Fast Speed Clock SCL High Count Register FSHCNT I2C_FS_SCL_HCNT I2C_FS_SCLHCNT I2C_FS_SCLHCNT 0xF28E Fast Speed Clock SCL Low Count Register FSLCNT I2C_FS_SCL_LCNT I2C_FS_SCLLCNT I2C_FS_SCLLCNT 0xF290 Interrupt Status Register ISTAT I2C_INTR_STAT I2C_INTRSTAT I2C_INTRSTAT 0xF296 Interrupt Mask Register IENBL I2C_INTR_MASK I2C_INTRMASK I2C_INTRMASK 0xF298 Raw Interrupt Status Register RISTAT I2C_RAW_INTR_ STAT I2C_RAW_INTRSTAT I2C_RAW_INTRSTAT 0xF29A Receive FIFO Threshold Level Register RXFT I2C_RXTL I2C_RXTL 0xF29C Transmit FIFO Threshold Level Register TXFT I2C_TXTL I2C_TXTL 0xF29E Clear Combined & Individual Interrupts Register CLRINT I2C_CLRINTR I2C_CLRINTR 0xF2A0 Clear Receive Under Interrupt Register CLRRXUND I2C_CLR_RXUNDER I2C_CLR_RXUNDER 0xF2A2 Clear Receive Over Interrupt Register CLRRXOVR I2C_CLROVER I2C_CLROVER 0xF2A4 Clear Transmit Over Register CLRTXOVR I2C_CLR_TXOVER I2C_CLR_TXOVER 0xF2A6 Clear Read Required Interrupt Register CLRRDREQ I2C_CLR_RDREQ I2C_CLR_RDREQ 0xF2A8 Clear Transmit Abort Interrupt Register CLRTXABRT I2C_CLR_TXABRT I2C_CLR_TXABRT 0xF2AA Clear Receive Done Interrupt Register CLRRXDONE I2C_CLR_RXDONE I2C_CLR_RXDONE 0xF2AC 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 155 Table 14-1 Legacy and Revised Acronyms (Continued) Peripheral Reference Manual Data Sheet Register Name New Acronym Clear Activity Interrupt Register Legacy Acronym New Acronym Legacy Acronym Processor Expert Acronym Memory Address Start End CLRACT I2C_CLRACTIVITY I2C_CLRACTIVITY 0xF2AE Clear Stop Detect Interrupt Register CLRSTPDET I2C_CLR_STOPDET I2C_CLR_STOPDET 0xF2B0 Clear Start Detect Interrupt Register CLRSTDET I2C_CLR_STAR_DET I2C_CLR_STAR_DET 0xF2B2 Clear General Call Interrupt Register CLRGC I2C_CLR_GENCALL I2C_CLR_GENCALL 0xF2B4 Enable Register ENBL I2C_ENABLE I2C_ENABLE 0xF2B6 Status Register STAT I2C_STAT I2C_STAT 0xF2B8 Transmit FIFO Level Register TXFLR I2C_TXFLR I2C_TXFLR 0xF2BA Receive FIFO Level Register RXFLR I2C_RXFLR I2C_RXFLR 0xF2BC Transmit Abort Source Register TXABRTSRC I2C_TX_ABRTSRC I2C_TX_ABRTSRC 0xF2C0 Component Parameter 1 Register COMPARM1 I2C_COMPARM1 I2C_COMPARM1 0xF2FA Component Parameter 2 Register COMPARM2 I2C_COMPARM2 I2C_COMPARM2 0xF2FB Component Version 1 Register COMVER1 I2C_COMVER1 I2C_COMVER1 0xF2FC Component Version 2 Register COMVER2 I2C_COMVER2 I2C_COMVER2 0xF2FD Component Type 1 Register COMTYP1 I2C_COMTYP1 I2C_COMTYP1 0xF2FE Component Type 2 Register COMTYP2 I2C_COMTYP2 I2C_COMTYP2 0xF2FF PLLCR 0xF130 On-Clock Chip Synthesis (OCCS) Module Control Register CTRL PLLCR OCCS_CTRL Divide-By Register Status Register DIVBY PLLDB OCCS_DIVBY PLLDB PLLDB 0xF131 STAT PLLSR OCCS_STAT PLLSR PLLSR 0xF132 Oscillator Control Register OCTRL OSCTL OCCS_OCTRL OSCTL OSCTL 0xF135 Clock Check Register CLKCHK OCCS_CLCHK PLLCLCHK OCCS_CLCHK 0xF136 PROT OCCS_PROT PLLPROT OCCS_PROT 0xF137 Protection Register PLLCR Clock Divider Register CLKDIV FMCLKD FM_CLKDIV FMCLKD FMCLKD 0xF400 Configuration Register CNFG FMCR FM_CNFG FMCR FMCR 0xF401 Security High Half Register SECHI FMSECH FM_SECHI FMSECH FMSECH 0xF403 Security Low Half Register SECLO FMSECL FM_SECLO FMSECL FMSECL 0xF404 Protection Register PROT FMPROT FM_PROT FMPROT FMPROT 0xF410 56F8036 Data Sheet, Rev. 3 156 Freescale Semiconductor Preliminary Electrical Design Considerations Table 14-1 Legacy and Revised Acronyms (Continued) Peripheral Reference Manual Data Sheet Register Name User Status Register New Acronym Legacy Acronym New Acronym Legacy Acronym Processor Expert Acronym Memory Address Start End USTAT FMUSTAT FM_USTAT FMUSTAT FMUSTAT 0xF413 Command Register CMD FMCMD FM_CMD FMCMD FMCMD 0xF414 Data Buffer Register DATA FMDATA FM_DATA FMDATA FMDATA 0xF418 Info Optional Data 1 Register OPT1 FMOPT1 FM_OPT1 FMOPT1 FMOPT1 0xF41B Test Array Signature Register TSTSIG FMTST_SIG FM_TSTSIG FMTST_SIG FMTST_SIG 0xF41D General Purpose Input/Output (GPIO) Module x = A (n=0) B (n=1) C (n=2) D (n=3) Pull-Up Enable Register PUPEN PUR GPIOx_PUPEN GPIOx_PUR GPIO_x_PUR 0xF1n0 Data Register DATA DR GPIOx_DATA GPIOx_DR GPIO_x_DR 0xF1n1 Data Direction Register DDIR DDR GPIOx_DDIR GPIOx_DDR GPIO_x_DDR 0xF1n2 Peripheral Enable Register PEREN PER GPIOx_PEREN GPIOx_PER GPIO_x_PER 0xF1n3 Interrupt Assert Register IASSRT IAR GPIOx_IASSRT GPIOx_IAR GPIO_x_IAR 0xF1n4 Interrupt Enable Register IEN IENR GPIOx_IEN GPIOx_IENR GPIO_x_IENR 0xF1n5 Interrupt Polarity Register IPOL IPOLR GPIOx_IPOL GPIOx_IPOLR GPIO_x_IPOLR 0xF1n6 Interrupt Pending Register IPEND IPR GPIOx_IPEND GPIOx_IPR GPIO_x_IPR 0xF1n7 Interrupt Edge-Sensitive Register IEDGE IESR GPIOx_IEDGE GPIOx_IESR GPIO_x_IESR 0xF1n8 Push-Pull Mode Registers PPOUTM PPMODE GPIOx_PPOUTM GPIOx_PPMODE GPIO_x_PPMODE 0xF1n9 Raw Data Input Register RDATA RAWDATA GPIOx_RDATA GPIOx_RAWDATA GPIO_x_RAWDATA 0xF1nA Output Drive Strength Register DRIVE DRIVE GPIOx_DRIVE GPIOx_DRIVE GPIO_x_DRIVE 0xF1nB 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 157 Table 14-1 Legacy and Revised Acronyms (Continued) Peripheral Reference Manual Data Sheet Register Name New Acronym Legacy Acronym New Acronym Legacy Acronym Processor Expert Acronym Memory Address Start End Pulse Width Modulator (PWM) Module Control Register CTRL PMCTL Fault Control Register FCTRL Fault Status/Acknowledge Regis. FLTACK Output Control Register PWM_CTRL PWM_PMCTL PWM_PMCTL 0xF0C0 PMFCTL PWM_FCTRL PWM_PMFCTL PWM_PMFCTL 0xF0C1 PMFSA PWM_FLTACK PWM_PMFSA PWM_PMFSA 0xF0C2 OUT PMOUT PWM_OUT PWM_PMOUT PWM_PMOUT 0xF0C3 Counter Register CNTR PMCNT PWM_CNTR PWM_PMCNT PWM_PMCNT 0xF0C4 Counter Modulo Register CMOD MCM PWM_CMOD PWM_MCM PWM_MCM 0xF0C5 Value 0-5 Registers VAL0-5 PMVAL0-5 PWM_VAL0-5 PWM_PMVAL0-5 PWM_PMVAL0-5 Deadtime 0-1 Registers DTIM0-1 PMDEADTM0-1 PWM_DTIM0-1 PWM_PMDEADTM0-1 PWM_PMDEADTM0-1 0xF0CC 0xF0CD Disable Mapping 1-2 Registers DMAP1-2 PMDISMAP1-2 PWM_DMAP1-2 PWM_PMDISMAP1-2 PWM_PMDISMAP1-2 0xF0C6 0xF0CE 0xF0CB 0xF0CF Configure Register CNFG PMCFG PWM_CNFG PWM_PMCFG PWM_PMCFG 0xF0D0 Channel Control Register CCTRL PMCCR PWM_CCTRL PWM_PMCCR PWM_PMCCR 0xF0D1 Port Register PORT PMPORT PWM_PORT PWM_PMPORT PWM_PMPORT 0xF0D2 Internal Correction Control Register ICCTRL PMICCR PWM_ICCTRL PWM_PMICCR PWM_PMICCR 0xF0D3 Source Control Register SCTRL PMSRC PWM_SCTRL PWM_PMSRC PWM_PMSRC 0xF0D4 Synchronization Window Register SYNC PWM_SYNC PWM_SYNC PWM_SYNC 0xF0D5 FFILT0-3 PWM_FFILT0-3 PWM_FFILT0-3 PWM_FFILT0-3 Fault Filter 0-3 Register 0xF0D6 0xF0D9 Multi-Scalable Controller Area Network (MSCAN) Module Control 0 Register CTRL0 CAN_CTRL0 CANCTRL0 0XF800 Control 1 Register CTRL1 CAN_CTRL1 CANCTRL1 0XF801 Bus Timing 0 Register BTR0 CAN_BTR0 CANBTR0 0XF802 Bus Timing 1 Register BTR1 CAN_BTR1 CANBTR1 0XF803 Receive Flag Register RFLG CAN_RFLG CANRFLG 0XF804 Receiver Interrupt Enable Register RIER CAN_RIER CANRIER 0XF805 Transmitter Flag Register TFLG CAN_TFLG CANTFLG 0XF806 Transmitter Interrupt Enable Register. TIER CAN_TIER CANTIER 0XF807 Transmitter Msg Abort Request Register TARQ CAN_TARQ CANTARQ 0XF808 56F8036 Data Sheet, Rev. 3 158 Freescale Semiconductor Preliminary Electrical Design Considerations Table 14-1 Legacy and Revised Acronyms (Continued) Peripheral Reference Manual Data Sheet Register Name New Acronym Legacy Acronym New Acronym Legacy Acronym Processor Expert Acronym Memory Address Start End Transmitter Message Abort Acknowledge Register TAAK CAN_TAAK CANTAAK 0XF809 Transmitter FIFO Selection Register TBSEL CAN_TBSEL CANTBSEL 0XF80A Identifier Acceptance Control Register IDAC CAN_IDAC CANIDAC 0XF80B Miscellaneous Register MISC CAN_MISC CANMISC 0XF80D Receive Error Register RXERR CAN_RXERR CANRXERR 0XF80E Transmit Error Register TXERR CAN_TXERR CANTXERR 0XF80F Identifier Acceptance 0-3 Registers IDAR0-3 CAN_IDAR0-3 CANIDAR0-3 0xF810 0xF813 Identifier Mask 0-3 Registers IDMR0-3 CAN_IDMR0-3 CANIDMR0-3 0xF814 0xF817 Identifier Acceptance 4-7 Register IDAR4-7 CAN_IDAR4-7 CANIDAR4-7 0xF818 0xF81B Identifier Mask 4-7 Registers IDMR4-7 CAN_IDMR4-7 CANIDMR4-7 0xF81C 0xF81F Foreground Receive FIFO Register RXFG CAN_RXFG CANRXFG 0xF82F 0xF820 Foreground Transmit FIFO Register TXFG CAN_TXFG CANTXFG 0xF830 0xF83F Power Supervisor (PS) Module Control Register CTRL LVICONTROL PS_CTRL LVICONTROL LVICTRL 0xF140 Status Register STAT LVISTATUS PS_STAT LVISTATUS LVISR 0xF141 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 159 Table 14-1 Legacy and Revised Acronyms (Continued) Peripheral Reference Manual Data Sheet Register Name New Acronym Legacy Acronym New Acronym Legacy Acronym Processor Expert Acronym Memory Address Start End Queued Serial Communications Interface (QSCI) Module n = 0, 1 Baud Rate Register RATE QSCI_RATE QSCI_SCIBR 0xF2n0 Control 1 Register CTRL1 QSCI_CTRL1 QSCI_SCICR 0xF2n1 Control 2 Register CTRL2 QSCI_CTRL2 QSCI_SCICR2 0xF2n2 Status Register STAT QSCI_STAT QSCI_SCISR 0xF2n3 Data Register DATA QSCI_DATA QSCI_SCIDR 0xF2n4 Queued Serial Peripheral Interface (QSPI) Module Status and Control Register SCTRL QSPI_SCTRL QSPI_SPSCR 0xF2n0 DSCTRL QSPI_DSCTRL QSPI_SPDSR 0xF2n1 Data Receive Register DRCV QSPI_DRCV QSPI_SPDRR 0xF2n2 Data Transmit Register DXMIT QSPI_DXMIT QSPI_SPDTR 0xF2n3 Data Size and Control Register FIFO Control Register FIFO QSPI_FIFO QSPI_SPFIFO 0xF2n4 Wait Register WAIT QSPI_WAIT QSPI_SPWAIT 0xF2n5 Quad-Timer (TMR) Module n = 0, 1, 2, 3 Compare 1 Register COMP1 TMRCMP1 TMRn_COMP1 TMRn_CMP1 TMRn_CMP1 0xF0n0 Compare 2 Register COMP2 TMRCMP2 TMRn_COMP2 TMRn_CMP2 TMRn_CMP2 0xF0n1 Capture Register CAPT TMRCAP TMRn_CAPT TMRn_CAP TMRn_CAP 0xF0n2 Load Register LOAD TMRLOAD TMRn_LOAD TMRn_LOAD TMRn_LOAD 0xF0n3 Hold Register HOLD TMRHOLD TMRn_HOLD TMRn_HOLD TMRn_HOLD 0xF0n4 Counter Register CNTR TMRCNTR TMRn_CNTR TMRn_CNTR TMRn_CNTR 0xF0n5 Control Register CTRL TMRCTRL TMRn_CTRL TMRn_CTRL TMRn_CTRL 0xF0n6 Status and Control Register SCTRL TMRSCR TMRn_SCTRL TMRn_SCR TMRn_SCR 0xF0n7 Comparator Load 1 Register CMPLD1 TMRCMPLD1 TMRn_CMPLD1 TMRn_CMPLD1 TMRn_CMPLD1 0xF0n8 Comparator Load 2 Register CMPLD2 TMRCMPLD2 TMRn_CMPLD2 TMRn_CMPLD2 TMRn_CMPLD2 0xF0n9 Comparator Status/Control Register CSCTRL TMRCOMSCR TMRn_CSCTRL TMRn_COMSCR TMRn_COMSCR 0xF0nA Input Filter Register FILT TMRn_FILT TMRn_FILT TMRn_FILT 0xF0nB Enable Register ENBL TMRn_ENBL TMRn_ENBL TMRn_ENBL 0xF0nF Voltage Regulator (VREG) Module See SIM section 56F8036 Data Sheet, Rev. 3 160 Freescale Semiconductor Preliminary Electrical Design Considerations Table 14-1 Legacy and Revised Acronyms (Continued) Peripheral Reference Manual Register Name New Acronym Legacy Acronym Memory Address Data Sheet New Acronym Legacy Acronym Processor Expert Acronym Start End Programmable Interval Timer (PIT) Module n = 0, 1, 2 Control Register CTRL PITn_CTRL PITCTRL0-2 PITn_CTRL 0xF1n0 Modulo Register MOD PITn_MOD PITMOD0-2 PITn_MOD 0xF1n1 Counter Register CNTR PITn_CNTR PITCNTR0-2 PITn_CNTR 0xF1n2 Control Register CTRL DACn_CTRL DACCTRL0-2 DACn_CTRL 0xF1n0 Data Register DATA DACn_DATA DACDATA0-2 DACn_DATA 0xF1n1 Step Register STEP DACn_STEP DACSTEP0-2 DACn_STEP 0xF1n2 Minimum Value Register MINVAL DACn_MINVAL DACMINVAL0-2 DACn_MINVAL 0xF1n3 Maximum Value Register MAXVAL DACn_MAXVAL DACMAXVAL0-2 DACn_MAXVAL 0xF1n4 n = 0, 1 Comparator (CMP) Module Ax=EBx=F Control Register CTRL CMP_CTRL CMPx_CTRL CMPx_CTRL 0xF1x0 Status Register STAT CMP_STAT CMPx_STAT CMPx_STAT 0xF1x1 Filter Register FILT CMP_FILT CMPx_FILT CMPx_FILT 0xF1x2 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 161 Table 14-1 Legacy and Revised Acronyms (Continued) Peripheral Reference Manual Data Sheet Register Name New Acronym Legacy Acronym New Acronym Legacy Acronym Processor Expert Acronym Memory Address Start End 0XF060 0XF064 Interrupt Controller (ITCN) Module Interrupt Priority 0-4 Registers N/A N/A ITCN_IPR0-4 ITCN_IPR0-4 INTC_IPR0-4 Vector Base Address Register N/A N/A ITCN_VBA ITCN_VBA INTC_VBA 0XF065 Fast Interrupt Match 0 Register N/A N/A ITCN_FIM0 ITCN_FIM0 INTC_FIM0 0XF066 Fast Interrupt Vector Address Low 0 N/A N/A ITCN_FIVAL0 ITCN_FIVAL0 INTC_FIVAL0 0XF067 Fast Interrupt Vector Address High 0 N/A N/A ITCN_FIVAH0 ITCN_FIVAH0 INTC_FIVAH0 0XF068 Fast Interrupt Match 1 Register N/A N/A ITCN_FIM1 ITCN_FIM1 INTC_FIM1 0xF069 Fast Interrupt Vector Address Low 1 N/A N/A ITCN_FIVAL1 ITCN_FIVAL1 INTC_FIVAL1 0xF06A Fast Interrupt Vector Address High 1 N/A N/A ITCN_FIVAH1 ITCN_FIVAH1 INTC_FIVAH1 0xF06B Interrupt Pending 0 Register N/A N/A ITCN_IRQP0 ITCN_IRQP0 INTC_IRQP0 0xF06C Interrupt Pending 1 Register N/A N/A ITCN_IRQP1 ITCN_IRQP1 INTC_IRQP1 0xF06D Interrupt Pending 2 Register N/A N/A ITCN_IRQP2 ITCN_IRQP2 INTC_IRQP2 0xF06E System Integration Module (SIM) Control Register N/A N/A SIM_CTRL SIM_CONTROL SIM_CONTROL 0xF100 Reset Status Register N/A N/A SIM_RSTAT SIM_RSTSTS SIM_RSTSTS 0xF101 Software Control 0-3 Registers N/A N/A SIM_SWC0-3 SIM_SCR0-3 SIM_SCR0-3 Most Significant Half JTAG ID N/A N/A SIM_MSHID SIM_MSH_ID SIM_MSH_ID 0xF106 Least Significant Half JTAG ID N/A N/A SIM_LSHID SIM_LSH_ID SIM_LSH_ID 0xF107 Power Control Register N/A N/A SIM_PWR SIM_POWER Clock Out Select Register N/A N/A SIM_CLKOUT SIM_CLKOSR SIM_CLKOSR 0xF10A Peripheral Clock Rate Register N/A N/A SIM_PCR SIM_PCR SIM_PCR 0xF10B Peripheral Clock Enable 0-1 Register N/A N/A SIM_PCE0-1 SIM_PCE0-1 SIM_PCE0-1 0xF10C 0xF10D Peripheral Stop Disable 0-1 Register N/A N/A SIM_SD0-1 SIM_SD0-1 SIM_SD0-1 0xF10E 0xF10F 0xF102 0xF105 0xF108 56F8036 Data Sheet, Rev. 3 162 Freescale Semiconductor Preliminary Electrical Design Considerations Table 14-1 Legacy and Revised Acronyms (Continued) Peripheral Reference Manual Data Sheet Register Name Processor Expert Acronym Memory Address New Acronym Legacy Acronym New Acronym Legacy Acronym I/O Short Address Location High Register N/A N/A SIM_ISALH SIM_ISALH SIM_ISALH 0xF110 I/O Short Address Location Low Register N/A N/A SIM_ISALL SIM_ISALL SIM_ISALL 0xF111 Protection Register N/A N/A SIM_PROT SIM_PROT SIM_PROT 0xF112 GPIOA Peripheral Select 0 Register N/A N/A SIM_GPISA0 SIM_GPISA0 SIM_GPISA0 0xF113 GPIOA Peripheral Select 0 Register N/A N/A SIM_GPSA1 SIM_GPSA1 SIM_GPSA1 0xF114 GPIOB Peripheral Select 0 Register N/A N/A SIM_GPSB0 SIM_GPSB0 SIM_GPSB0 0xF115 GPIOB Peripheral Select 1 Register N/A N/A SIM_GPSB1 SIM_GPSB1 SIM_GPSB1 0xF116 GPIO Perip. Select Register for GPIO C & D N/A N/A SIM_GPSCD SIM_GPSCD SIM_GPSCD 0xF117 Internal Peripheral. Select Register for PWM N/A N/A SIM_ISPWM SIM_ISPWM SIM_ISPWM 0xF118 Internal Peripheral Select Register for DAC N/A N/A SIM_IPSDAC SIM_IPSDAC SIM_IPSDAC 0xF119 Internal Peripheral Select Register for TMRA N/A N/A SIM_IPSTMRA SIM_IPSTMRA SIM_IPSTMRA 0xF11A Start End 56F8036 Data Sheet, Rev. 3 Freescale Semiconductor Preliminary 163 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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Freescale™ and the Freescale logo are trademarks of Freescale Semiconductor, Inc. All other product or service names are the property of their respective owners. This product incorporates SuperFlash® technology licensed from SST. © Freescale Semiconductor, Inc. 2006. All rights reserved. MC56F8036 Rev. 3 01/2007