Mario Lok, Ku He, Murari Mani, C. Caramanis, M. Orshansky
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Design of power-optimal buffers tunable to process variability
In many digital designs, multi-stage tapered buffers are needed to drive large capacitive loads. These buffers contribute a significant percentage of overall power. In this paper, we propose two novel tunable buffer designs that enable power reduction in the presence of process variation. A strategy to derive the optimal buffer size and tuning rule in post-silicon phase is developed. By comparing several tunable buffer circuit topologies, we also demonstrate the tradeoffs in tunable buffer topology selection as a function of switching activity, timing requirements, and the magnitude of process variation. Using a combination of HSPICE simulations and our optimization algorithm, we show that up to 30% average power reduction can be achieved with the proposed buffer structures.
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