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Chapter 2 (Contd.)

Chapter 2 (Contd.). 8088 Processor. Address Lines Data Lines Control Lines Power/GND Lines Clock (33% Duty cycle) Reset Pin held high for min. of 4 clk cycles Executes instruction at FFFF0 H Disables interrupts. Instruction Execution (MOV A, X). Execute Instruction Issue Address of X.

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Chapter 2 (Contd.)

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  1. Chapter 2 (Contd.)

  2. 8088 Processor • Address Lines • Data Lines • Control Lines • Power/GND Lines • Clock (33% Duty cycle) • Reset • Pin held high for min. of 4 clk cycles • Executes instruction at FFFF0 H • Disables interrupts

  3. Instruction Execution (MOV A, X) Execute Instruction Issue Address of X Fetch Instruction Issue Address of MOV A, X 8088 RAM MOV A, X Address Bus Code Control Bus Data Bus 3 Decode Instruction Decoding MOV A, X Data

  4. Address & Data Bus • Address Bus Size • Size of Memory accessible by Processor • 20 bit = 1 MByte • 8088 A0 - A19 Address Lines • Data Bus Size • Chunk of Data accessible • 8088 D0 – D7 Data Lines • 8086 D0 – D15 Data Lines • 8088 Address and Data Bus Multiplexed

  5. Multipurpose/General Purpose Registers • AX Accumulator 16-bit register • AH and AL 8-bit Registers AX • Used for Arithmetic & logical operations • Used specifically for multiplication, division and adjustment instructions • Holds offset address of a location in memory • BX Base Index 16-bit register • BH and BL 8-bit Registers • Used for Arithmetic and Data operations • Holds offset address of a location in memory

  6. Multipurpose/General Purpose Registers • CX Count 16-bit register • CH and CL 8-bit Registers • Used for Arithmetic and data operations • Holds count value for various instructions • Counts the number of characters in string operations

  7. Multipurpose/General Purpose Registers • DX Data 16-bit register • DH and DL 8-bit Registers • Used for Arithmetic and Data Operations • Holds the high 16-bits of the product in multiplication operations • Holds remainder for 16-bit division • Holds I/O addresses

  8. Base Registers • Base Pointer BP 16-bit Register • Points to a memory location • Holds an offset or displacement from Stack Segment (SS) Register • Used by subroutines to locate variables passed on stack by calling program • BX Base Index 16-bit register • BH and BL 8-bit Registers • Used for Arithmetic and Data operations • Holds offset address of a location in memory

  9. Index Registers • Destination Index DI 16-bit Register • Addresses string destination for string instructions • Holds an offset or displacement from ES register • Source Index SI 16-bit Register • Addresses string source for string instructions • Holds an offset or displacement from DS register

  10. Stack Pointer Registers • Stack Pointer SP 16-bit Register • Addresses Stack memory • Holds an offset or displacement from SS Register • Contents are combined with contents of SS Register to give address of top of stack

  11. Special Registers • Instruction Pointer IP 16-bit Register • Points to the next instruction in the Code Segment • Contents are combined with contents of Code Segment (CS) Register to give address of next instruction to be fetched • Flag 16-bit Register • Contents of this register are neither data nor address • Individual bits in this register indicate different status information • Individual bits are set (1) or cleared (0) as a result of an operation by the microprocessor

  12. Special Registers • Bit 0: Carry Flag • Set to indicate occurrence of Carry • Bit 2: Parity Flag • Set to indicate even Parity • Bit 4: Auxiliary Flag • Set to indicate occurrence of Aux. carry • Bit 6: Zero Flag • Set to indicate Zero result

  13. Special Registers • Bit 7: Sign Flag • Set to indicate a negative number • Bit 8: Trap Flag • Set to enable Debug mode • Bit 9: Interrupt Flag • Set to indicate interrupt enabled • Bit 10: Direction Flag • Set to 1 automatically decrements DI & SI • Set to 0 automatically increments DI & SI

  14. Special Registers • Bit 11: Overflow Flag • Set to indicate an overflow

  15. Chapter 3 • 8086 microprocessor • Internal registers • Making of Memory address • Number conversion

  16. Instruction Execution (MOV A, X) Execute Instruction Issue Address of X Fetch Instruction Issue Address of MOV A, X 8088 RAM MOV A, X Address Bus Code Control Bus Data Bus 3 Decode Instruction Decoding MOV A, X Data

  17. Address & Data Bus • Address Bus Size • Size of Memory accessible by Processor • 20 bit = 1 MByte • 8088 A0 - A19 Address Lines • Data Bus Size • Chunk of Data accessible • 8088 D0 – D7 Data Lines • 8086 D0 – D15 Data Lines • 8088 Address and Data Bus Multiplexed

  18. 8088 Processor • Address Lines • Data Lines • Control Lines • Power/GND Lines • Clock (33% Duty cycle) • Reset • Pin held high for min. of 4 clk cycles • Executes instruction at FFFF0 H • Disables interrupts

  19. Lecture 02 DC Characteristics • Input Characteristics • Input current and voltage requirements • Logic 0 0.8 Vmax ±10 Amax • Logic 1 2 Vmin ±10 Amax • Inputs gate connections of MOSFETs • Leakage currents

  20. Lecture 02 DC Characteristics • Output Characteristics • Output current and voltage requirements • Logic 0 0.45 Vmax 2.0 mAmax • Logic 1 2.4 Vmin -400 Amax • Reduced noise immunity 350 mV • Avoid long connections • Avoid too many loads • Max. 10 loads without Buffering

  21. Lecture 02 Bus Buffering & Latching • Bus should be buffered for large systems • Multiplexed Address & Data Buses should be De-multiplexed • Why De-multiplexed Buses? • Address on the Address Bus has to remain constant throughout a read and write cycle • Read and Write Cycle? • 8088/8086 read/write operation is completed in a minimum period of 4 clocks

  22. Lecture 02 Bus De-Multiplexing • During T1 clock of Read/write cycle • 8088 issues address AD0 to AD7 & A8 to A19 • 8088 activates ALE signal (Address Latch Enable)

  23. Lecture 02 373 Latch

  24. Lecture 03 Bus Buffering • Address Lines A0 – A19 have to be buffered • A0 – A7 & A16 – A19 have been buffered by 373 • Logic 0 sinks 32 mA • Logic 1 sources 5.2 mA • A8 – A15 have to be buffered • 74LS244 Octal Buffer used for Buffering

  25. De-multiplexed Bus GND OE* 8088 373 A16 – A19 LE A8 – A15 A0 – A7 LE OE* 373 Latch ALE GND AD0 – AD7 D0 – D7

  26. Lecture 03 Clock Circuitry • Clock Generator 8284 • Clock Signals • Reset Synchronization • READY Synchronization • TTL-level peripheral clock

  27. Lecture 04 Clock Generator 8284

  28. Lecture 04 Processor RESET • RESET pin needs to remain high for min. of 4 clocks and must not go low for at least 50 s

  29. Lecture 04 Bus Timing • Memory & I/O is slow • Rate of data transfer depends on access time of Memory & I/O • Processor Read/Write cycles have to be extended to allow transfer from slow devices • Basic Bus Operation • Address, Data and Control Buses are involved in reading and writing of data • Address, Data and Control Bus operations are carried out in a sequence

  30. Lecture 04 Bus Timing • 8086/8088 use the Memory/IO in periods called Bus Cycles • Each Bus Cycle equals 4 system clocking periods (T states) • Pentium has 2 T state Bus cycle • At 5 MHz, one Bus cycle is completed at 0.8 sec or 800 nsec • Processor can read/write at a max. rate of 1.25 million times a sec.

  31. Lecture 04 Bus Timing • With internal queue processor can execute 2.5 million instructions per sec. [MIPS] in bursts • Pentium operates at much higher rates due to higher clock rates, shorter Bus cycle and internal queuing

  32. Lecture 04 Bus Timing T1 Clock • Address of the Memory/IO is issued via the Address/Data Multiplexed Bus • Following Signals are also issued • ALE Address Latch Enable signal • DT/R* Data Transmit/Receive signal • IO/M* IO/Memory signal

  33. Lecture 04 Bus Timing T2 & T3 Clocks • RD* or WR* Read or Write Signal is issued • Incase of Write the Data to be written also appears on the Data Bus • DEN* Data Bus Enable signal is issued • READY signal is sampled at the end of T2 • If READY is low T3 becomes a Wait State TW • READY is again sampled in the middle of Wait State • If the Bus Cycle is Read Cycle, Data Bus is sampled at the end of T3

  34. Lecture 04 Bus Timings T4 Clock • All Bus signals are deactivated in preparation for the next Bus Cycle • During a Read Cycle the processor continues to sample the Data Bus during T4 cycle • During a Write Cycle the trailing edge of the Write signal transfers the data to Memory or IO

  35. Minimum Vs. Maximum Mode • 8088/8086 has two Modes of operation • Minimum Mode • Maximum Mode • Minimum Mode • Operation similar to 8085 (8 bit processor) • MN/MX* pin connected to +5 V • 8-bit peripherals can be used with 8088/8086

  36. Minimum Vs. Maximum Mode • Maximum Mode • Enhanced Operation used whenever a coprocessor is used with 8088/8086 • MN/MX* pin connected to GND • 8288 Bus Controller required to generate extra signals

  37. Summary

  38. Memory Interface • Memory Pin Connections • Address Pins • Data Pins • Control Pins • Selection Pins

  39. Memory Interface • Address Pins • Number of locations in memory determine the number of Address Pins • 4 K = 12 lines • 1 M = 20 lines

  40. Memory Interface • Data Pins • Width of memory determines the number of Data Pins • 8 bit width = 8 lines • 1 bit width = 1 line

  41. Memory Interface • ROM Control Pins • OE* or G* allows data to flow out • RAM Control Pins • WE* allows data to be written • OE*allows data to be read • Can have a single R/W* pin

  42. Memory Interface • Selection Pins • CE* or CS* allows the RAM/ROM chip to be selected • Sometimes there are more than one CS* signal

  43. ROM • Read Only ROM • Permanently stores program/data • Does not allow write (read Only)

  44. 2764 (8 KB) EPROM

  45. Address Decoding • Processors have very large address space • Pentium 4 has a 64 GB memory space • Entire memory space is not used • Processor memory space is used for specific purpose • Operating System • Program Code • Data • Interrupt Vector Table

  46. Address Decoding • RAM, ROM and I/O devices are mapped in the processor memory space • More memory can be added in the vacant memory space

  47. Memory Mapping • Least significant lines of the processor address bus always connected to the address lines of the Memory chip (A0 – A18) • Most significant line(s) of the processor address bus always used for mapping memory chip in the address space and connected to the chip select (A19) • First 512 KB Ram chip selected when A19 = 0 • Second 512 KB Ram chip selected when A19 = 1

  48. Memory Mapping

  49. Memory Mapping • 256 KB RAM chip (A0 – A17) • Four 256 KB RAM chips should be connected to completely map the 1 MB processor memory space • Address Lines A18 & A19 used for chip selection

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