Conventional field-programmable gate arrays are typically overprovisioned with routing resources to ensure that they meet routeability targets, which results in increased routing static and dynamic power. In this paper, we… Click to show full abstract
Conventional field-programmable gate arrays are typically overprovisioned with routing resources to ensure that they meet routeability targets, which results in increased routing static and dynamic power. In this paper, we leverage the excess routing conductors to reduce dynamic and static power. To reduce dynamic power, we propose to ensure that used routing conductors are adjacent to unused routing conductors, which are left floating to reduce the effective capacitance seen by active nets. To reduce static power, we observe that leakage in routing multiplexers is dominated by specific paths; if the routing conductors, which connect to the input pins on these paths, are unused and left floating, the leakage of the multiplexer may be significantly reduced. To ensure that unused conductors are allowed to float requires the use of tristate routing buffers, and thus we propose two low-cost tristate buffer topologies with different power and area-overhead tradeoffs. We also introduce CAD techniques to optimize the overall energy dissipation in the routing network using the proposed techniques. Results show that interconnect dynamic power reductions of up to 25%, interconnect static power reductions of up to 81%, and overall interconnect energy reductions ranging between 14.9%–42.7% are expected, with a critical path degradation of <1.8% and area-overhead of 2.6%–4.8%.
               
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