Temperature referenced supply voltage and forward-body-bias control (TSFC) architecture for minimum power consumption [ubiquitous computing processors]
G. Ono, M. Miyazaki, Hidetoshi Tanaka, Nono Ohkubo, T. Kawahara
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引用次数: 12
Abstract
A temperature referenced supply voltage and forward-body-bias (FBB) control architecture for ubiquitous computing processors is proposed. The architecture can minimize power consumption at all temperatures by using our discovered FBB self-feedback effect. The effect is that low temperature forces the FBB-controlled LSI to increase its performance. The TSFC reduced power consumption by 28% without any performance degradation compared with the conventional FBB technique. We also found and analyzed the dual parasitic bipolar modes in the FBB system by evaluating a test chip fabricated in 0.13-/spl mu/m CMOS technology. Moreover, the influence of supply and substrate wire resistances in the FBB system was found to be not significant. The TSFC architecture is effective for achieving ubiquitous computing LSIs.
提出了一种基于温度的普适计算处理器电源电压和正向偏置(FBB)控制架构。利用我们发现的FBB自反馈效应,该架构可以在所有温度下最大限度地降低功耗。其结果是,低温迫使fbb控制的LSI提高其性能。与传统的FBB技术相比,TSFC在没有任何性能下降的情况下降低了28%的功耗。我们还通过评估0.13-/spl μ m CMOS工艺制作的测试芯片,发现并分析了FBB系统中的双寄生双极模式。此外,在FBB系统中,电源和衬底导线电阻的影响并不显著。TSFC架构是实现泛在计算lsi的有效方法。
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