The use of power switches in modern system chips (SOCs) is inevitable as they allow for efficient on-chip static power management. Leakage is today one of the main hurdles in low-power applications. Power switches enable power gating functionality, i.e., one or more parts of the SOC can be powered-off during standby mode leading in this way to savings in the overall SOC's power consumption. In this paper, we present a circuit and a method to test power switches. The proposed method allows testing of on/off functionality. In case of segmented power switches individual failing segments can be identified as well by using the proposed test strategy. The method requires only a small number of test patterns that are easy to generate. Furthermore, the proposed method is very scalable with the number of power switches and has a very small area-overhead.
In this paper we examine the expectations and limitations of design technologies such as adaptive voltage scaling (AVS) and adaptive body biasing (ABB) in a modern deep sub-micron process. To serve this purpose, a set of ring oscillators was fabricated in a 90nm triple-well CMOS technology. The analysis hereby presented is based on two ring oscillators running at 822MHz and 93MHz, respectively. Measurement results indicate that it is possible to reach 13.8x power savings by 3.4x frequency downscaling using AVS, ±11% power and ±8% frequency tuning at nominal conditions using ABB only, 22x power savings with 5x frequency downscaling by combining AVS and ABB, as well as 22x leakage reduction.
Abstract-Worst-case design uses extreme process corner conditions which rarely occur. This limits maximum speed specifications and costs additional power due to area over-dimensioning during synthesis. We present a new design synthesis strategy for digital CMOS circuits that makes use of forward body biasing. Our approach renders consistently a better performance-per-area ratio by constraining circuit over-dimensioning without sacrificing circuit performance. An in-depth analysis of the body-bias-driven design theory is provided. It is complemented by an algorithm that enables fast reconstruction of the area-clock period tradeoff curve of the design. We validated these new concepts through industrial processor designs in 90-nm low-power CMOS. For standard-th implementations, we observed performance-per-area improvements up to 40%, area and leakage reductions up to 30%, and dynamic power savings of up to 10% without performance penalties as a benefit from our proposed body-bias-driven design strategy. The benefits are larger for high-th implementations. In this case, we observed performance-per-area improvements up to 90%, area and leakage reductions up to 40%, and dynamic power savings of up to 25% without performance penalties.
We present an on-chip, fully-digital, power-supply control system. The scheme consists of two independent control loops that regulate power supply variations due to semiconductor process spread, temperature, and chip's workload. Smart power-switches working as linear voltage regulators are used to adjust the local power supply. The smart power-switch allows us to keep the global power network unchanged. It offers an integrated standby mode and has a fast dynamic response, i.e. low transition times between voltage steps at the cost of the reduced power conversion efficiency when compared to complex DC-DC converters.
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The upscaling of biphasic photochemical reactions is challenging because of the inherent constraints of liquid-gas mixing and light penetration. Using semi-permeable coaxial flow chemistry within a modular photoreactor, the photooxidation...
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