Ebook: Computer-Aided Design Techniques for Low Power Sequential Logic Circuits
- Tags: Circuits and Systems, Electrical Engineering, Computer-Aided Engineering (CAD CAE) and Design
- Series: The Springer International Series in Engineering and Computer Science 387
- Year: 1997
- Publisher: Springer US
- Edition: 1
- Language: English
- pdf
Rapid increases in chip complexity, increasingly faster clocks, and the proliferation of portable devices have combined to make power dissipation an important design parameter. The power consumption of a digital system determines its heat dissipation as well as battery life. For some systems, power has become the most critical design constraint.
Computer-Aided Design Techniques for Low Power Sequential LogicCircuits presents a methodology for low power design. The authors first present a survey of techniques for estimating the average power dissipation of a logic circuit. At the logic level, power dissipation is directly related to average switching activity. A symbolic simulation method that accurately computes the average switching activity in logic circuits is then described. This method is extended to handle sequential logic circuits by modeling correlation in time and by calculating the probabilities of present state lines.
Computer-Aided Design Techniques for Low Power Sequential LogicCircuits then presents a survey of methods to optimize logic circuits for low power dissipation which target reduced switching activity. A method to retime a sequential logic circuit where registers are repositioned such that the overall glitching in the circuit is minimized is also described. The authors then detail a powerful optimization method that is based on selectively precomputing the output logic values of a circuit one clock cycle before they are required, and using the precomputed value to reduce internal switching activity in the succeeding clock cycle.
Presented next is a survey of methods that reduce switching activity in circuits described at the register-transfer and behavioral levels. Also described is a scheduling algorithm that reduces power dissipation by maximising the inactivity period of the modules in a given circuit.
Computer-Aided Design Techniques for Low Power Sequential LogicCircuits concludes with a summary and directions for future research.
Rapid increases in chip complexity, increasingly faster clocks, and the proliferation of portable devices have combined to make power dissipation an important design parameter. The power consumption of a digital system determines its heat dissipation as well as battery life. For some systems, power has become the most critical design constraint.
Computer-Aided Design Techniques for Low Power Sequential LogicCircuits presents a methodology for low power design. The authors first present a survey of techniques for estimating the average power dissipation of a logic circuit. At the logic level, power dissipation is directly related to average switching activity. A symbolic simulation method that accurately computes the average switching activity in logic circuits is then described. This method is extended to handle sequential logic circuits by modeling correlation in time and by calculating the probabilities of present state lines.
Computer-Aided Design Techniques for Low Power Sequential LogicCircuits then presents a survey of methods to optimize logic circuits for low power dissipation which target reduced switching activity. A method to retime a sequential logic circuit where registers are repositioned such that the overall glitching in the circuit is minimized is also described. The authors then detail a powerful optimization method that is based on selectively precomputing the output logic values of a circuit one clock cycle before they are required, and using the precomputed value to reduce internal switching activity in the succeeding clock cycle.
Presented next is a survey of methods that reduce switching activity in circuits described at the register-transfer and behavioral levels. Also described is a scheduling algorithm that reduces power dissipation by maximising the inactivity period of the modules in a given circuit.
Computer-Aided Design Techniques for Low Power Sequential LogicCircuits concludes with a summary and directions for future research.
Rapid increases in chip complexity, increasingly faster clocks, and the proliferation of portable devices have combined to make power dissipation an important design parameter. The power consumption of a digital system determines its heat dissipation as well as battery life. For some systems, power has become the most critical design constraint.
Computer-Aided Design Techniques for Low Power Sequential LogicCircuits presents a methodology for low power design. The authors first present a survey of techniques for estimating the average power dissipation of a logic circuit. At the logic level, power dissipation is directly related to average switching activity. A symbolic simulation method that accurately computes the average switching activity in logic circuits is then described. This method is extended to handle sequential logic circuits by modeling correlation in time and by calculating the probabilities of present state lines.
Computer-Aided Design Techniques for Low Power Sequential LogicCircuits then presents a survey of methods to optimize logic circuits for low power dissipation which target reduced switching activity. A method to retime a sequential logic circuit where registers are repositioned such that the overall glitching in the circuit is minimized is also described. The authors then detail a powerful optimization method that is based on selectively precomputing the output logic values of a circuit one clock cycle before they are required, and using the precomputed value to reduce internal switching activity in the succeeding clock cycle.
Presented next is a survey of methods that reduce switching activity in circuits described at the register-transfer and behavioral levels. Also described is a scheduling algorithm that reduces power dissipation by maximising the inactivity period of the modules in a given circuit.
Computer-Aided Design Techniques for Low Power Sequential LogicCircuits concludes with a summary and directions for future research.
Content:
Front Matter....Pages i-xvii
Introduction....Pages 1-7
Power Estimation....Pages 9-22
A Power Estimation Method for Combinational Circuits....Pages 23-33
Power Estimation for Sequential Circuits....Pages 35-80
Optimization Techniques for Low Power Circuits....Pages 81-96
Retiming for Low Power....Pages 97-110
Precomputation....Pages 111-150
High-Level Power Estimation and Optimization....Pages 151-171
Conclusion....Pages 173-178
Back Matter....Pages 179-181
Rapid increases in chip complexity, increasingly faster clocks, and the proliferation of portable devices have combined to make power dissipation an important design parameter. The power consumption of a digital system determines its heat dissipation as well as battery life. For some systems, power has become the most critical design constraint.
Computer-Aided Design Techniques for Low Power Sequential LogicCircuits presents a methodology for low power design. The authors first present a survey of techniques for estimating the average power dissipation of a logic circuit. At the logic level, power dissipation is directly related to average switching activity. A symbolic simulation method that accurately computes the average switching activity in logic circuits is then described. This method is extended to handle sequential logic circuits by modeling correlation in time and by calculating the probabilities of present state lines.
Computer-Aided Design Techniques for Low Power Sequential LogicCircuits then presents a survey of methods to optimize logic circuits for low power dissipation which target reduced switching activity. A method to retime a sequential logic circuit where registers are repositioned such that the overall glitching in the circuit is minimized is also described. The authors then detail a powerful optimization method that is based on selectively precomputing the output logic values of a circuit one clock cycle before they are required, and using the precomputed value to reduce internal switching activity in the succeeding clock cycle.
Presented next is a survey of methods that reduce switching activity in circuits described at the register-transfer and behavioral levels. Also described is a scheduling algorithm that reduces power dissipation by maximising the inactivity period of the modules in a given circuit.
Computer-Aided Design Techniques for Low Power Sequential LogicCircuits concludes with a summary and directions for future research.
Content:
Front Matter....Pages i-xvii
Introduction....Pages 1-7
Power Estimation....Pages 9-22
A Power Estimation Method for Combinational Circuits....Pages 23-33
Power Estimation for Sequential Circuits....Pages 35-80
Optimization Techniques for Low Power Circuits....Pages 81-96
Retiming for Low Power....Pages 97-110
Precomputation....Pages 111-150
High-Level Power Estimation and Optimization....Pages 151-171
Conclusion....Pages 173-178
Back Matter....Pages 179-181
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