Fully-functional FPGA prototype with fine-grain programmable body biasing

A fully-functional FPGA prototype chip in which the programmable body bias voltage can be individually applied to elemental circuits such as MUXes, LUT and DFF is fabricated using low-power 90-nm bulk CMOS technology and the area overhead, dynamic current, static current and operational speed are evaluated in silicon. In measurements, 10 ISCAS benchmark circuits are implemented by employing newly developed CAD tools which consist of VT mapper as well as placer and router. Mask layout shows that well-separated margins, programmable body bias circuits, and additional configuration memories occupy 54% of the FPGA tile area. Measurement results show that the fabricated FPGA reduces the static current by 91.4% in average. In addition, evaluations by implementing ring oscillator with various body bias voltage pairs demonstrate the static current reduction from 23.1 uA to 1.0 uA by assigning low threshold voltage and high threshold voltage to MOSFETs on a critical path and the rest of the MOSFETs, respectively while maintaining the same oscillation frequency of 6.6 MHz as the frequency when all MOSFETs are assigned low threshold voltage. Moreover the fine-grain programmable body bias technique accelerates the oscillation frequency of ring oscillator implemented on FPGA by aggressively applying forward body bias voltage, while assignment of HVT to MOSFETs on the non-critical path by applying the reverse body biasing effectively suppresses exponential increase of static current caused by the forward body biasing.