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7-7 Register-Cell Design

7-7 Register-Cell Design. A single-bit cell of an iterative combinational circuit connected to a flip-flop that provides the output forms a two-state sequential circuit called a register cell. Example 7-1 Register-cell design

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7-7 Register-Cell Design

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  1. 7-7 Register-Cell Design A single-bit cell of an iterative combinational circuit connected to a flip-flop that provides the output forms a two-state sequential circuit called a register cell. Example 7-1 Register-cell design A register A and is to implement the following register transfers with an input B :

  2. Example 7-1 • Assumption • Only one of AND, EXOR, and OR is equal to 1 • For all AND, EXOR, and OR equal to 0, the content of A remains unchanged

  3. Example 7-1 • One solution • LOAD=AND+EXOR+OR From Table 7-11, we can rewrite the solution as

  4. Example 7-1 • Simplify the equation • Share the control variables to all register cells since they are the same for each cell • Simplification from 2nd solution in the previous slide

  5. Example 7-1 • Simplification from the 1st solution in slide page 3

  6. Example 7-1 • Use the simplification in slide page 4 can save about 40% (for 16 cells) gate cost and hence time delay compared to those by using the simplification in slide page 5. • Why?

  7. Example 7-2 A register A is to implement the following register transfers with an input B : • Assumption: • Only one of SHL, EXOR, and ADD is equal to 1 • For all SHL, EXOR, and ADD equal to 0, the content of A remains unchanged

  8. Example 7-2 • Solution • LOAD=AND+EXOR+OR • Another solution (combine ADD and SHL (share Ci))

  9. Example 7-2 • Simplification (from 2nd solution in previous slide) (Ci=0 for EXOR)

  10. 7-8 Multiplexer and bus-based transfers for multiple register • Dedicated multiplexer • 2n AND gate cost and n OR gate cost per multiplexer • Total of 9n gate cost

  11. Single bus • 3n AND gate cost and n OR gate cost • Total of 4n gate cost

  12. Single bus Note: The 3rd case in the table is possible for dedicated multiplexer architecture

  13. Three-state bus

  14. 7-9 Serial transfer and Microoperations • Information in a system is transferred or manipulated one bit at a time

  15. Serial transfer

  16. Serial Addition

  17. We are now neglecting the following two sections7-10 Two design examples7-11 HDL

  18. 7-13 Microprogrammed Control • A control unit with its binary control values stored as words in memory • Each word in the control memory contains a microinstruction • A microinstruction specifies one or more microoperations for a system • A sequence of microinstructions constitutes a microprogram

  19. Two registers • Control address register (CAR): a register specifies the address of the microinstruction • Control data register (CDR): a register holds the microinstruction currently being executed by the datapath and the control unit

  20. Next-address generator • When a microinstruction is executed, the next-address generator produces the next address • The address of next instruction to be executed may be next one or located somewhere else in the control memory • A function of control word is to determine the address of the next microinstruction to be executed • Sometimes it is called sequencer

  21. Microprogrammed control unit organization

  22. CISC • A simple instruction set computer (SISC) as introduced above can’t fit the complex applications for today’s computer. • A complex instruction set computer (CISC) has emerged (Chap. 11)

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