Mathematics and Computers in Simulation
An efficient algorithm for library-based cell-type selection in high-performance low-power designs
Proceedings of the International Conference on Computer-Aided Design
Sensitivity-guided metaheuristics for accurate discrete gate sizing
Proceedings of the International Conference on Computer-Aided Design
Architecturally homogeneous power-performance heterogeneous multicore systems
IEEE Transactions on Very Large Scale Integration (VLSI) Systems
High-performance gate sizing with a signoff timer
Proceedings of the International Conference on Computer-Aided Design
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A general sequential circuit consists of a number of combinational stages that lie between latches. For the circuit to meet a given clocking specification, it is necessary for each combinational stage to satisfy a certain delay requirement. Roughly speaking, increasing the sizes of some transistors in a stage reduces the delay, with the penalty of increased area. The problem of transistor sizing is to minimize the area of a combinational stage, subject to its delay being less than a given specification. Although this problem has been recognized as a convex programming problem, most existing approaches do not take full advantage of this fact, and often give nonoptimal results. An efficient convex optimization algorithm has been used here. This algorithm is guaranteed to find the exact solution to the convex programming problem. We have also improved upon existing methods for computing the circuit delay as an Elmore time constant, to achieve higher accuracy, CMOS circuit examples, including a combinational circuit with 832 transistors are presented to demonstrate the efficacy of the new algorithm