Hiran Tennakoon scite author profile

─ In this paper, we present Forge, an optimal algorithm for gate sizing using the Elmore delay model. The algorithm utilizes Lagrangian relaxation with a fast gradient-based pre-processing step that provides an effective set of initial Lagrange multipliers. Compared to the previous Lagrangian-based approach, Forge is considerably faster and does not have the inefficiencies due to difficult-to-determine initial conditions and constant factors. We compared the two algorithms on 30 benchmark designs, on a Sun UltraSparc-60 workstation. On average Forge is 200 times faster than the previously published algorithm. We then improved Forge by incorporating a slew-rate-based convex delay model, which handles distinct rise and fall gate delays. We show that Forge is 15 times faster, on average , than the AMPS transistor-sizing tool from Synopsys, while achieving the same delay targets and using similar total transistor area.

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Power reduction via near-optimal library-based cell-size selection

Rahman

Tennakoon

Sechen

2011

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Power efficient standard cell library design

Afonso

Rahman

Tennakoon

et al. 2009

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Nonconvex Gate Delay Modeling and Delay Optimization

Tennakoon

Sechen

2008

IEEE Trans. Comput.-Aided Des. Integr. Circuits Syst.

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Hiran Tennakoon

Gate sizing using Lagrangian relaxation combined with a fast gradient-based pre-processing step

Gate sizing using Lagrangian relaxation combined with a fast gradient-based pre-processing step

Power reduction via near-optimal library-based cell-size selection

Power efficient standard cell library design

Nonconvex Gate Delay Modeling and Delay Optimization

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