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引用次数: 7
摘要
研究了正向体偏置(FBB)作为CMOS真单相时钟(TSPC)射频频率除以2电路的片上功耗和运行速度的有效方法。通过在0.18 μ m CMOS中进行广泛的直流和射频仿真,研究了正向体偏置对阈值电压、传播延迟和电流耗散的影响。然后,研究表明,仅在FBB电压为0.2 V时,除以2电路的最大运行速度就提高了22%和21%,而TSPC和扩展TSPC (E-TSPC)型逻辑的电流耗散分别只增加了15%和32%。我们相信,前向体偏置技术有助于实现片上动态可扩展的TSPC分频器,用于低功耗应用。
Investigation of forward body bias effects on TSPC RF frequency dividers in 0.18 μm CMOS
Effects of forward body biasing (FBB) is investigated as an effective mean of on-chip scaling of power consumption and operating speed in CMOS true single phase clock (TSPC) RF frequency divide-by-2 circuits. Through extensive dc and RF simulations in 0.18 mum CMOS, the effects of the forward body bias on the threshold voltage, propagation delay, and current dissipation are examined. Then, it is shown that only with the FBB voltage of 0.2 V, the divide-by-2 circuits achieves 22% and 21% improvements in the maximum operating speed while only at the cost of 15% and 32% more current dissipation for TSPC and extended TSPC (E-TSPC) type logics, respectively. We believe that the forward body biasing technique is instrumental in realizing on-chip on-the-fly scalable TSPC dividers for low power applications.
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