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MC68HC11 System Overview

MC68HC11 System Overview. MC68HC11 System Overview. System block diagram (A8 version). 68HC11: major features. HCMOS Technology (low power / high speed) On-chip RAM, ROM, EEPROM Basic core functions of MC6801 --improved instruction set functionality

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MC68HC11 System Overview

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  1. MC68HC11System Overview

  2. MC68HC11System Overview System block diagram (A8 version)

  3. 68HC11: major features • HCMOS Technology (low power / high speed) • On-chip RAM, ROM, EEPROM • Basic core functions of MC6801 --improved instruction set functionality • 2 operating modes and 2 test modes • On-chip counter / timer • On-chip analog-to-digital conversion • On-chip parallel and serial ports • Improved interrupt capabilities than earlier products • supports 21 interrupt vectors • Some fault detection capability for major errors • (power, illegal instruction, hung processor)

  4. 68HC11: major features • Available in at least 25 different versions – Different pin counts and packaging – Different amounts/types of memory » RAM size (192 to 1.25K bytes) » ROM size (4K to 32K bytes) » EEPROM (512 to 2K bytes) » ROM, EPROM, or EEPROM program memory Memory maps vary from version to version! – Different I/O capabilities (number of timers, chip selects, DMA channels, A/D types, etc.) CONTD

  5. 68HC11: major features • Our textbook generally discusses the 68HC11A8 version, but we use the 68HC11E9 in the lab – A8: 256 bytes RAM 8 KB ROM 512 bytes EEPROM – E9: 512 bytes RAM 12 KB ROM 512 bytes EEPROM

  6. 68HC11: major features

  7. Pin assignments • Basic support pins • – Vdd, Vss: power (+5V) and ground • – Xtal, Extal: crystal connection for internal oscillator • – E: "enable" clock output signal (input freq ÷ 4) • – Reset*: external reset; system failure indicator • – IRQ*, XIRQ*: interrupt request lines • – MODA, MODB: specifies operating mode CONTD

  8. Pin assignments Port functions (in addition to parallel I/O) – Port A: timer functions – Port B: strobed outputs, expanded mode address (high byte) – Port C: parallel I/O, expanded mode address (low byte) and data – Port D: general serial I/O pins, handshake lines for expanded mode – Port E: A/D conversion

  9. Modes of operation • The chip has • 2 “operating” modes and • 2 “test” modes • Mode determination: • – On reset or power up, the mode is selected by values on pins MODA and MODB • » Jumpers J3 and J4 on EVBU trainer kit • – During operation, mode can be changed in some cases by writing to the HPRIO register

  10. 2 “operating” modes • Single chip (MODA=0, MODB=1) • – No external address and data bus functions • » CPU can only access on-chip memory • – Ports B and C are general purpose parallel I/O • – All software needed to control MCU must be in internal memory • – On reset, execution begins at address $E000 • » Located in ROM • » For EVBU version, checks jumper J2, may jump to $B600 (EEPROM) CONTD

  11. 2 “operating” modes • Expanded multiplexed (MODA=MODB=1) – External memory and peripheral devices can be accessed by time-multiplexed address-data bus – Port B used for high byte of address (output) – Port C provides low byte of address (output) and 8- bit data (bi-directional) – External address latch is required – Execution begins at address $E000 » Just as in single-chip mode, jumper J2 can be used to have the program jump to address $B600

  12. 2 “test” modes • Special bootstrap (MODA=MODB=0) • – On power up or reset, the program in the bootstrap ROM is executed • – CPU waits for a 256-byte program segment to be downloaded through the serial link and stored starting at address $0000 • – Execution then begins at address $0000 • – Permits wide variety of programs to be downloaded CONTD

  13. 2 “test” modes • Special test (MODA=1, MODB=0) – Primarily a testing mode for the manufacturer – Overrides some automatic protection mechanisms -- risky!

  14. On-chip memory • ROM (12K bytes) • – Factory programmed • – Special bootstrap ROM • RAM (512 bytes) • – Data, stack • – Can be used for downloaded code • – Low-power standby mode • EEPROM (512 bytes) • – Programmed and erased on-chip • – Calibration storage, diagnostic log, critical data logging, security data • – Can also be used for downloaded code CONTD

  15. Off-chip memory • EPROM • – For prototype development • – Windowed and one-time programmable versions

  16. Memory maps • Different versions of the HC11 have different memory maps: type, quantity, and location of memory varies • Be sure to know which version you are using! • – Our text references the generic HC11A8 version • – We use the HC11E9 version in the lab

  17. Working with memory • Usually work with 8-bit data values in HC11 (sometimes 16-bit values) • Addresses are 16 bits • Example:

  18. Working with memory • Often show memory contents as follows: • $110 8E 01 FF BD 60 00 CE 8A C0 31 E2 42 29 90 01 FE • Addr 16 data values • 16-bit data values are stored in consecutive memory locations • – MSB = first location • – LSB = second location • – What is the 16-bit value stored at location $11A?

  19. 68HC11 register set

  20. 68HC11 register set • 68HC11 CPU registers • – Accumulators ACCA and ACCB used for computations • » 8-bit values • » For 16-bit computation, ACCA and ACCB may be combined and accessed as ACCD • – Index registers IX and IY generally used to hold addresses • » 16-bit values • » Used as pointers to memory locations • » Some instructions use them for 16-bit computation, also CONTD

  21. 68HC11 register set – SP and PC » Used by the CPU » Not generally used by the programmer • Programming model – Register-register operations – Register-memory operations – Memory-only operations – Indexed addressing

  22. Condition code register

  23. 5 on-chip I/O ports • Port A (8 bits) • – 1 bidirectional pin, 4 output pins, 3 input pins • – Also used for timer • Port D (6 bits) • – 6 bidirectional pins (controlled by direction register) • – Also used for asynchronous (SCI) and synchronous • serial (SPI) I/O • Port E (8 bits) • – 8 input pins • – Also used for A/D converter CONTD

  24. 5 on-chip I/O ports • Port B (8 bits) – 8 output pins with optional handshaking – Also used as address in expanded mode (replaced by PRU) • Port C (8 bits) – 8 bidirectional pins with optional handshaking and wired-or mode – Also used as data/address in expanded mode (replaced by PRU)

  25. I/O registers • HC11 includes 64 I/O registers • – Each has a specific function • – Some are used for system configuration • – Others are used to interface with the different • I/O subsystems • » Control • » Status • » Data CONTD

  26. I/O registers • These registers are accessed like memory locations – Addresses $1000 to $103F – Programming Reference Guide and textbook both contain list of I/O registers • Eg., you write a value to a specific I/O port by storing a value to the corresponding memory location – The PORTA register is at address $1000 – The instruction STAA $1000 will write the value in ACCA to Port A

  27. Programming model -- summary • Use ACCA and ACCB for most operations and computations • – 8-bit values • Use ACCD and/or IX for 16-bit computations • IX and IY usually used to hold addresses • – Pointers to memory locations • Perform I/O by reading/writing I/O registers • – Memory locations $1000-$103F • There are also several addressing modes -----but that's a topic for another day

  28. MC68HC11 EVBUUniversal Evaluation Board • Kit includes • – MC68HC11 board • – Development software (freeware assembler, PCbug11 monitor, Buffalo monitor) • – Documentation • Compact, low-cost "universal" evaluation board • – MC68HC11E9 or MC68HCX711E9 • » 12K ROM or EPROM CONTD

  29. MC68HC11 EVBUUniversal Evaluation Board • » 512 bytes EEPROM • » 512 bytes RAM – 8 MHz crystal (2 MHz bus clock) – RS232 interface (MC145407) with DB25 connector – Reset switch (MC34064P) – Wire-wrap area • Added for ECPE 4535 at Virginia Tech: – Power supply – Protoboard area – IASM11 assembler and SIM11 simulator

  30. Designing with the MC68HC11 • Understand HC11 capabilities • – Microcontroller resources • – Standard components such as switches and displays • Understand application domain • – Application requirements • – Appropriate algorithms • – Data and signal formats CONTD

  31. Designing with the MC68HC11 • Structure the design – Decompose functions and map to resources – Define interfaces between functions and keep them simple – Specify memory and timing requirements for each function – Understand interactions for timing, interrupts, data, etc.

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