Energy-Efficient Low-Latency 600 MHz FIR With High-Overdrive Charge-Recovery Logic
IEEE Transactions on Very Large Scale Integration (VLSI) Systems(2012)
摘要
This paper presents a 14-tap 8-bit finite impulse response (FIR) test-chip that has been designed using a novel charge-recovery logic family, called Enhanced Boost Logic (EBL), to achieve high-speed and low-power operation. Compared to previous charge-recovery circuitry, EBL achieves increased gate overdrive, resulting in low latency overhead over static CMOS design. The EBL-based FIR has been designed with only 1.5 cycles of additional latency over its static CMOS counterpart, while consuming 21% less energy per cycle, based on post-layout simulations of the two designs. The test-chip has been fabricated in a 0.13 μ m CMOS process with a fully-integrated 3 nH inductor. Correct function has been validated in the 365-600 MHz range. At its resonant frequency of 466 MHz, the test-chip dissipates 39.1 mW with a 93.6 nW/MHz/Tap/InBit/CoeffBit figure of merit, recovering 45% of the energy supplied to it every cycle.
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关键词
CMOS logic circuits,FIR filters,logic circuits,logic design,low-power electronics,EBL-based FIR,FIR test-chip,additional latency,charge-recovery circuitry,charge-recovery logic family,energy-efficient low-latency,enhanced boost logic,figure of merit,finite impulse response test-chip,frequency 365 MHz to 600 MHz,frequency 466 MHz,frequency 600 MHz,fully-integrated inductor,gate overdrive,high-overdrive charge-recovery logic,high-speed operation,low-power operation,post-layout simulations,power 39.1 mW,resonant frequency,static CMOS counterpart,static CMOS design,Digital signal processing (DSP),low-power VLSI
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