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Interface

Interface. 8088 I/F with basic IO, RAM and 8255. Topics. Timing diagram Address Bus, R/W, Data Memory Map I/O Address Decoding CPU is addressable lager than devices. Chip Supports TTL : De-multiplexer, Latch, Buffer. Timing Diagram : Read Cycle. Timing Diagram : Write Cycle.

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Interface

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  1. Interface 8088 I/F with basic IO, RAM and 8255

  2. Topics • Timing diagram • Address Bus, R/W, Data • Memory Map I/O • Address Decoding • CPU is addressable lager than devices. • Chip Supports • TTL : De-multiplexer, Latch, Buffer

  3. Timing Diagram: Read Cycle

  4. Timing Diagram: Write Cycle

  5. BUS Buffering and Latching

  6. Basic Architecture Dr.Jim Plusquellic, University of Maryland, Baltimore County http://www.csee.umbc.edu/~plusquel/310/

  7. Bus Architecture • Address: • If I/O, a value between 0000H and FFFFH is issued. • If memory, it depends on the architecture: • 20 -bits (8086/8088) • 24 -bits (80286/80386SX) • 25 -bits (80386SL/SLC/EX) • 32 -bits (80386DX/80486/Pentium) • 36 -bits (Pentium Pro/II/III)

  8. Bus Architecture • Data: • 8 -bits (8088) • 16 -bits (8086/80286/80386SX/SL/SLC/EX) • 32 -bits (80386DX/80486/Pentium) • 64 -bits (Pentium/Pro/II/III) • Control: • Most systems have at least 4 control bus connections (active low). • MRDC (Memory ReaD Control), MWRC , IORC (I/O Read Control), IOWC

  9. Bus Standards • ISA (Industry Standard Architecture): 8 MHz • 8-bit (8086/8088) • 16-bit (80286-Pentium) • EISA : 8 MHz • 32-bit (older 386 and 486 machines). • PCI (Peripheral Component Interconnect): • 33 MHz 32-bit or 64-bit (Pentiums) • VESA (Video Electronic Standards Association): • 32-bit or 64-bit (Pentiums), Runs at processor speed. • Only disk and video. Competes with the PCI but is not popular.

  10. Bus Standards • USB (Universal Serial Bus): • 12 Mbps / 480 Mbps, Serial connection to microprocessor. • For keyboards, the mouse, modems and sound cards. To reduce system cost through fewer wires. • IEEE 1394 • 400 Mbps, primary target is audio/visual consumer electronic devices • AGP (Advanced Graphics Port): 66MHz • 64-bits for 533MB/sec, Fast parallel connection, video cards. To accommodate the new DVD (Digital Versatile Disk) players.

  11. Memory : Blank Layout

  12. Memory : Blank Layout

  13. Memory : Blank Layout

  14. Basic I/O Architecture

  15. Interrupt Vector: DOS PC

  16. IO Space

  17. Basic I/O Interface : Input

  18. Basic I/O Interface : Output

  19. I/O Port Decoding

  20. MEMORY

  21. Memory Types • Two basic types: • ROM: Read-only memory • RAM: Read-Write memory • Four commonly used memories: • ROM • Flash (EEPROM) • Static RAM (SRAM) • Dynamic RAM (DRAM)

  22. Memory Chips • The data pins are typically bi-directional in read-write memories. • The number of data pins is related to the size of the memory location. For example, an 8-bit wide (byte-wide) memory device has 8 data pins. • Each memory device has at least one chip select (CS) or chip enable (CE) or select (S) pin that enables the memory device. • This enables read and/or write operations. • If more than one are present, then all must be 0 in order to perform a read or write.

  23. SRAM vs. DRAM • SRAMs • SRAMs used for caches have access times as low as 10ns . • DRAMs • SRAMs are limited in size (up to about 128Kb). • DRAMs are available in much larger sizes, e.g., 64M X 1. • DRAMs MUST be refreshed every 2 to 4 ms • Since they store their value on an integrated capacitor that loses charge over time.

  24. Memory Address Decoding

  25. Memory Address Decoding • The processor can usually address a memory space that is much larger than the memory space covered by an individual memory chip. • In order to splice a memory device into the address space of the processor, decoding is necessary. • For example, the 8088 issues 20-bit addresses for a total of 1MB of memory address space.

  26. Ex. Memory Address Decoding • The BIOS on a 2716 EPROM has only 2KB of memory and 11 address pins. • A decoder can be used to decode the additional 9 address pins and allow the EPROM to be placed in any 2KB section of the 1MB address space.

  27. Ex. Memory Address Decoding • To determine the address range that a device is mapped into:

  28. Ex. Memory Address Decoding • This 2KB memory segment maps into the reset location of the 8086/8088 (FFFF0H). • NAND gate decoders are not often used. Rather the 3-to-8 Line Decoder (74LS138) is more common.

  29. 3-to-8 Line Decoder • G2A, G2B, and G1 must be active. • Each output of the decoder can be attached to an 2764 EPROM ( 8K X 8 ).

  30. EPROM 2764 x 8

  31. More on Address Decoding • Yet a third possibility is a PLD (Programmable Logic Device). • PLDs come in three varieties: • PLA (Programmable Logic Array) • PAL (Programmable Array Logic) • GAL (Gated Array Logic) • A PAL example (16L8) is commonly used to decode the memory address, particularly for 32-bit addresses generated by the 80386DX and above.

  32. PLD as address decoder • AMD 16L8 PAL decoder. • It has 10 fixed inputs (Pins 1-9, 11), two fixed outputs (Pins 12 and 19) and 6 pins that can be either (Pins 13-18).

  33. 8088 Memory Interface • The memory systems "sees" the 8088 as a device with: • 20 address connections (A19 to A0). • 8 data bus connections (AD7 to AD0). • 3 control signals, IO/M, RD, and WR. • Interfacing the 8088 with: • 32K of EPROM (at addresses F8000H-FFFFFH). • 512K of SRAM (at addresses 00000H-7FFFFH).

  34. 8088 Memory Interface: EPROM

  35. 8088 Memory Interface: EPROM • The EPROM will also require the generation of a wait state. • The EPROM has an access time of 450ns . • The 74LS138 requires 12ns to decode. • The 8088 runs at 5MHz and only allows 460ns for memory to access data. • A wait state adds 200ns of additional time

  36. 8088 Memory Interface: RAM

  37. 8088 Memory Interface: RAM • The 62256s on the previous slide are actually SRAMs. Access times are on order of 10ns . • Flash memory can also be interfaced to the 8088. However, the write time ( 400ms !) is too slow to be used as RAM.

  38. 8088 I/F with Programmable Peripheral Interface 8255 Part I

  39. PPI : 82C55 • The 82C55 is a popular interfacing component, that can interface any TTL-compatible I/O device to the microprocessor. • It is used to interface to the keyboard and a parallel printer port in PCs (usually as part of an integrated chipset). • Requires insertion of wait states if used with a microprocessor using higher that an 8 MHz clock. • PPI has 24 pins for I/O that are programmable in groups of 12 pins and has three distinct modes of operation. • In the PC, an 82C55 or its equivalent is decoded at I/O ports 60H-63H.

  40. 8255 Block Diagram

  41. Pin layout of 8255

  42. Interfacing 8255 PPI

  43. That’s all

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