Sub-clock power-gating technique for minimising leakage power during active mode

Mistry, Jatin N.; Al-Hashimi, Bashir M.; Flynn, David; Hill, Stephen

doi:10.1109/date.2011.5763026

Cited by 13 publications

(13 citation statements)

References 8 publications

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“…For experimental comparisons, three modes of operation were implemented in the Cortex-M0: the proposed SCPG with symmetric virtual rail clamping, no power gating enforced using the nOverride signal in Fig. 4, and SCPG with complete shut down [19] achieved by disabling the Ret & nRet transistors shown in Fig. 4.…”

Section: Methodsmentioning

confidence: 99%

“…14. Measured V V dd charge-up and evaluation time in sub-clock power gating with shut down power gating [19] combinational logic is brought out of shut down and reevaluates which opposes the recharging of V V dd [12]. This droop subsequently slows the combinational re-evaluation, exacerbating the length of T eval to 4µs as shown.…”

Section: A Test Chip Validationmentioning

confidence: 99%

“…13. Measured V V dd and V Vss behaviour in sub-clock power gating with shut down power gating [19] VV ss VV dd T pgstart + T eval = 4µs…”

Section: Experimental Validationmentioning

confidence: 99%

“…Table I showed that the wake-up energy associated with shut down power gating was higher than the proposed symmetric virtual rail clamping circuit through ring oscillator simulations. To compare sub-clock power gating with shut down power gating [19] and the proposed symmetric virtual rail clamping, both techniques have been compared across a range of clock frequencies. Fig.…”

Section: B Applicationsmentioning

confidence: 99%

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Active Mode Subclock Power Gating

Mistry

Myers

Al-Hashimi

et al. 2014

IEEE Trans. VLSI Syst.

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Abstract-This paper presents a technique, called sub-clock power gating, for reducing leakage power during the active mode in low performance, energy constrained applications. The proposed technique achieves power reduction through two mechanisms: 1) power gating the combinational logic within the clock period (sub-clock) and 2) reducing the virtual supply to less than V th rather than shutting down completely as is the case in conventional power gating. To achieve this reduced voltage, a pair of NMOS and PMOS transistors are used at the head and foot of the power gated logic for symmetric virtual rail clamping of the power and ground supplies. The sub-clock power gating technique has been validated by incorporating it with an ARM Cortex-M0 microprocessor which was fabricated in a 65nm process. Two sets of experiments are done: the first experimentally validates the functionality of the proposed technique in the fabricated test chip and the second investigates the utility of the proposed technique in example applications. Measured results from the fabricated chip show 27% power saving during the active mode for an example wireless sensor node application when compared to the same microprocessor without sub-clock power gating.

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Section: Methodsmentioning

confidence: 99%

Section: A Test Chip Validationmentioning

confidence: 99%

“…13. Measured V V dd and V Vss behaviour in sub-clock power gating with shut down power gating [19] VV ss VV dd T pgstart + T eval = 4µs…”

Section: Experimental Validationmentioning

confidence: 99%

Section: B Applicationsmentioning

confidence: 99%

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Active Mode Subclock Power Gating

Mistry

Myers

Al-Hashimi

et al. 2014

IEEE Trans. VLSI Syst.

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“…However, the proposed sub-block AMPG can be very useful in frequency scaling applications [5]. For example, an ARM Cortex-M0 chip targeted for very low power applications is known to consume 0.9 mW with a supply voltage of 0.6 V using a 90 nm technology library, but a typical power budget can be between tens and hundreds of μWs [6].…”

Section: Introductionmentioning

confidence: 99%

Carry select adder with sub-block power gating for reducing active-mode leakage in sub-32-nm VLSIs

Jung

Lee

et al. 2011

IEICE Electron. Express

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Abstract:In this paper, we propose the sub-block Active-Mode Power Gating (AMPG) scheme to reduce the active-mode leakage and apply it to the 32-bit Carry Select Adder (CSA), where the sub-blocks are activated and deactivated according to the idleness during the active time. By doing so, we can reduce the active-mode energy by 21% at the cycle time of 10 ns for the 22-nm node compared to the conventional AMPG. The critical path delay is degraded as little as 1% in the sub-block AMPG. For a given power budget as small as 100 μW, the new sub-block AMPG with 32-nm node can run faster by 47% than the conventional AMPG. Keywords: low-leakage, power gating, sleep transistor, active-mode power gating, run-time power gating Classification: Integrated circuits References

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Power Gating and State Retention Applied to SOC Standby Power Management

Flynn

2013

Frequency References, Power Management for SoC, and Smart Wireless Interfaces

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Sub-clock power-gating technique for minimising leakage power during active mode

Cited by 13 publications

References 8 publications

Active Mode Subclock Power Gating

Active Mode Subclock Power Gating

Carry select adder with sub-block power gating for reducing active-mode leakage in sub-32-nm VLSIs

Power Gating and State Retention Applied to SOC Standby Power Management

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