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ECE 551 - Digital System Design & Synthesis Lecture 2 - Pragmatic Design Issues Overview Miscellaneous problems that arise in design and their solutions Classification of Issues o o o o o 9/6/2001 Three-State and Other Hi-Z States Sequential Circuit Basics Asynchronous Circuits Clock Design Electrical Issues ECE 551 Fall 2001 1 Three-State and Other Hi-Z States Three-state conflicts Floating three-state nets and inputs Pull-ups and Pull-downs Bus keepers 9/6/2001 ECE 551 Fall 2001 2 Three-State Conflicts What are they and what are their effects? o Static – Chip damage or static power consumption o Dynamic – Dynamic or static power consumption 9/6/2001 1 D0 1 E0 0 D1 1 E1 E0 1 E1 1 1 E0 0 E1 01 OUT ECE 551 Fall 2001 3 Three-State Conflicts (continued) How can conflicts be avoided? o Static – Decoded enable signals o Dynamic – Delay control 1 0 9/6/2001 1 E0 0 E1 01 D0 E0 1 E0 0 E1 1 OUT D1 E1 ECE 551 Fall 2001 4 Floating Inputs and ThreeState Nets Floating input values on gates can cause: o static power dissipation o high-frequency switching that induces power supply noise Floating input values arise from: o Gate inputs, e. g., for example on exterior of IC, that are not connected o Lines driven by 3-state buffer or gate outputs, all of which are in the Hi-Z state. 9/6/2001 ECE 551 Fall 2001 5 Floating Inputs and ThreeState Nets (continued) How can floating inputs and nets be avoided? o Use a pull-up or pull-down resistor or transistor with a fixed gate voltage value. Advantage – simple Disadvantages – static power dissipation and loading of node o On internal lines, particularly buses, use a bus keeper (weak buffer) 9/6/2001 ECE 551 Fall 2001 6 Sequential Circuit Basics Non-D flip-flops System initialization process Mixed-edge clocking Multi-phase clocks Multiple 9/6/2001 clocks ECE 551 Fall 2001 7 Non-D flip-flops D Flip-Flops o Unique characteristic – the typical master-slave DFF is also functionally an edge-triggered DFF. Non- D Flip-Flops (JK, T, etc.) o In the cell libraries, these flip-flop may be full-custom designs or may simply consist of a DFF with added logic. o If it is just a DFF with added logic, you might as well design for a DFF to give the logic optimization software more flexibility. 9/6/2001 ECE 551 Fall 2001 8 System Initialization Process Flip-flop initialization o Occurs at power-up or at reset o Which of the following flip-flops need to be initialized immediately on power-up or reset: Sequencing circuit in the control unit? Register file in the datapath? No Program counter? Yes Yes o How are the other flip-flops initialized? 9/6/2001 ECE 551 Fall 2001 9 System Initialization Process (continued) Flip-flop initialization o How are flip-flops initialized? By using direct set and direct reset inputs on the flip-flops (typically need only one or the other) Suppose that a FF is to be initialized to 1 and there are only library cells with with direct reset. What can you do? D Q D Q C R CLK 9/6/2001 ECE 551 Fall 2001 RESET 10 Mixed-Edge Clocking Clocking on both: o Positive and negative edges, or o Positive and negative pulses In some cases may be useful to: o Obtain two event triggers per clock cycle o Deal with certain nasty timing problems such as hold time difficulties Confusing and more difficult to handle when using tools Quantizes time and adds FF delay time much as pipelining does, so can reduce speed unless throughput is the issue as with pipelining 9/6/2001 ECE 551 Fall 2001 11 Multi-Phase Clocks Uses L F1 F2 C L F1 Latches C Latches o As primary clocking approach using latches o As means to solve special timing problems F2 CL - Combinational Logic 9/6/2001 ECE 551 Fall 2001 12 Multiple Clocks Typical in sophisticated circuit Example - Microprocessor o 133 MHz External o 1 GHz Internal Potential for synchronization problems between clocking domains 9/6/2001 ECE 551 Fall 2001 13