Logic and Computer Design Fundamentals. Chapter 6 Selected Design Topics. Part 1 The Design Space

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Logic and Computer Design Fundamentals Chapter 6 Selected Design Topics Part 1 The Design Space Charles Kime & Thomas Kaminski 2008 Pearson Education, Inc. (Hyperlinks are active in View Show mode) Overview Part 1 The Design Space Integrated Circuits Levels of Integration CMOS Circuit Technology CMOS Transistor Models Circuits of Switches Fully Complementary CMOS Circuits Technology Parameters Part 2 Propagation Delay and Timing Part 3 Asynchronous Interactions Part 4 - Programmable Implementation Technologies Chapter 6 - Part 1 2 1

Integrated Circuits Integrated circuit (informally, a chip ) is a semiconductor crystal (most often silicon) containing the electronic components for the digital gates and storage elements which are interconnected on the chip. Terminology - Levels of chip integration SSI (small-scale integrated) - fewer than 10 gates MSI (medium-scale integrated) - 10 to 100 gates LSI (large-scale integrated) - 100 to thousands of gates VLSI (very large-scale integrated) - thousands to 100s of millions of gates Chapter 6 - Part 1 3 MOS Transistor 0Volts 0Volts G (Gate) V Volts DD S (Source) D (Drain) n-channel Transistor: OFF - no D-to-S Cur rent Channel length Location of conducting layer Substrate Chapter 6 - Part 1 4 2

MOS Transistor 0Volts S (Source) V DD Volts G (Gate) V DD Volts D (Drain) n-channel Transistor: ON - D-to-S Current Channel length Location of conducting layer Substrate Chapter 6 - Part 1 5 Switch Models for MOS Transistors n-channel Normally Open (NO) Switch Contact G X D S Symbol X: Switch Model: p-channel Normally Closed (NC) Switch Contact S X: X Simplifed Switch Model G X D Symbol X: Switch Model X: X Simplified Switch Model Chapter 6 - Part 1 6 3

Circuits of Switch Models Series X: X XANDY Y: Y Parallel Series X: X Y: Y X OR Y Parallel Chapter 6 - Part 1 7 Fully-Complementary CMOS Circuit Circuit structure for fully-complementary logic 1 +V CMOS gate F using p-type transistors (NC switches) F X 1 X 2 X n F using n-type transistors (NO switches) logic 0 General Structure Chapter 6 - Part 1 8 4

CMOS Circuit Design Example Find a CMOS gate with the following function: F = X Z + Y Z = (X + Y)Z Beginning with F0, and using F F0 Circuit: F = X Y + Z The switch model circuit in terms of NO switches: X: X Y: Y Z: Z Chapter 6 - Part 1 9 CMOS Circuit Design Example The switch model circuit for F1 in terms of NC contacts is the dual of the switch model circuit for F0: X: X Y: Y Z: Z The function for this circuit is: F1 Circuit: F = (X + Y) Z which is the correct F. Chapter 6 - Part 1 10 5

CMOS Circuit Design Example Replacing the switch models with CMOS transistors; note input Z must be used. X Z Y From F 1 +V F From F 0 Chapter 6 - Part 1 11 Technology Parameters Specific gate implementation technologies are characterized by the following parameters: Fan-in the number of inputs available on a gate Fan-out the number of standard loads driven by a gate output Logic Levels the signal value ranges for 1 and 0 on the inputs and 1 and 0 on the outputs (see Figure 1-1) Noise Margin the maximum external noise voltage superimposed on a normal input value that will not cause an undesirable change in the circuit output Cost for a gate - a measure of the contribution by the gate to the cost of the integrated circuit Propagation Delay The time required for a change in the value of a signal to propagate from an input to an output Power Dissipation the amount of power drawn from the power supply and consumed by the gate Chapter 6 - Part 1 12 6

Fan-out Fan-out can be defined in terms of a standard load Example: 1 standard load equals the load contributed by the input of 1 inverter. Transition time -the time required for the gate output to change from H to L, t HL, or from L to H, t LH The maximum fan-out that can be driven by a gate is the number of standard loads the gate can drive without exceeding its specified maximum transition time Chapter 6 - Part 1 13 Cost In an integrated circuit: The cost of a gate is proportional to the chip area occupied by the gate The gate area is roughly proportional to the number and size of the transistors and the amount of wiring connecting them Ignoring the wiring area, the gate area is roughly proportional to the gate input count So gate input count is a rough measure of gate cost If the actual chip layout area occupied by the gate is known, it is a far more accurate measure Chapter 6 - Part 1 14 7

Terms of Use All (or portions) of this material 2008 by Pearson Education, Inc. Permission is given to incorporate this material or adaptations thereof into classroom presentations and handouts to instructors in courses adopting the latest edition of Logic and Computer Design Fundamentals as the course textbook. These materials or adaptations thereof are not to be sold or otherwise offered for consideration. This Terms of Use slide or page is to be included within the original materials or any adaptations thereof. Chapter 6 - Part 1 15 8

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