Energy efficient computation with self-adaptive single-ended body bias

S. Jayapal; J. Stuijt; J. Huisken; Y. Manoli

Energy efficient computation with self-adaptive single-ended body bias

S. Jayapal, J. Stuijt, J. Huisken, Y. Manoli

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

Abstract

Energy efficient computation becomes increasingly important for battery driven ubiquitous computing applications. To extend the battery life time while still meeting the performance demands, the designers face critical challenges in choosing the appropriate circuit topologies and low-power design techniques in order to optimally balance the power and performance trade-offs. In this paper, we evaluate various form of single-ended body bias configuration and experimented the fine-grained self-adaptive circuit optimization technique such as pull-up body bias and pull-down body bias to combine the monotonic precharge-evaluate logic circuits and application of body bias based on the evaluation and idle modes within logic stages. This technique improves the evaluation delay by 19% and 16% with 15% and 10% lower energy consumption for the non-clocked and clocked 16-bit CLA adder respectively.

Original language	English
Title of host publication	SOC Conference (SOCC), 2010 IEEE International
Pages	326-329
Number of pages	4
Publication status	Published - 2010
Externally published	Yes

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title = "Energy efficient computation with self-adaptive single-ended body bias",

abstract = "Energy efficient computation becomes increasingly important for battery driven ubiquitous computing applications. To extend the battery life time while still meeting the performance demands, the designers face critical challenges in choosing the appropriate circuit topologies and low-power design techniques in order to optimally balance the power and performance trade-offs. In this paper, we evaluate various form of single-ended body bias configuration and experimented the fine-grained self-adaptive circuit optimization technique such as pull-up body bias and pull-down body bias to combine the monotonic precharge-evaluate logic circuits and application of body bias based on the evaluation and idle modes within logic stages. This technique improves the evaluation delay by 19% and 16% with 15% and 10% lower energy consumption for the non-clocked and clocked 16-bit CLA adder respectively.",

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author = "S. Jayapal and J. Stuijt and J. Huisken and Y. Manoli",

year = "2010",

language = "English",

isbn = "Pending",

pages = "326--329",

booktitle = "SOC Conference (SOCC), 2010 IEEE International",

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T1 - Energy efficient computation with self-adaptive single-ended body bias

AU - Jayapal, S.

AU - Stuijt, J.

AU - Huisken, J.

AU - Manoli, Y.

PY - 2010

Y1 - 2010

N2 - Energy efficient computation becomes increasingly important for battery driven ubiquitous computing applications. To extend the battery life time while still meeting the performance demands, the designers face critical challenges in choosing the appropriate circuit topologies and low-power design techniques in order to optimally balance the power and performance trade-offs. In this paper, we evaluate various form of single-ended body bias configuration and experimented the fine-grained self-adaptive circuit optimization technique such as pull-up body bias and pull-down body bias to combine the monotonic precharge-evaluate logic circuits and application of body bias based on the evaluation and idle modes within logic stages. This technique improves the evaluation delay by 19% and 16% with 15% and 10% lower energy consumption for the non-clocked and clocked 16-bit CLA adder respectively.

AB - Energy efficient computation becomes increasingly important for battery driven ubiquitous computing applications. To extend the battery life time while still meeting the performance demands, the designers face critical challenges in choosing the appropriate circuit topologies and low-power design techniques in order to optimally balance the power and performance trade-offs. In this paper, we evaluate various form of single-ended body bias configuration and experimented the fine-grained self-adaptive circuit optimization technique such as pull-up body bias and pull-down body bias to combine the monotonic precharge-evaluate logic circuits and application of body bias based on the evaluation and idle modes within logic stages. This technique improves the evaluation delay by 19% and 16% with 15% and 10% lower energy consumption for the non-clocked and clocked 16-bit CLA adder respectively.

KW - battery driven ubiquitous computing, battery driven ubiquitous computing, battery life time, battery life time, circuit topologies, circuit topologies, energy conservation, energy conservation, energy efficient computation, energy efficient computation, f

M3 - Conference contribution

SN - Pending

SP - 326

EP - 329

BT - SOC Conference (SOCC), 2010 IEEE International

ER -

Energy efficient computation with self-adaptive single-ended body bias

Abstract

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