3D-ICE: A Compact Thermal Model for Early-Stage Design of Liquid-Cooled ICs

Sridhar, Arvind; Vincenzi, Alessandro; Atienza, David; Brunschwiler, Thomas

doi:10.1109/tc.2013.127

Cited by 101 publications

(54 citation statements)

References 29 publications

(53 reference statements)

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“…With the applied flow rate, which is translated to an average flow velocity of 1.4 m/s, the target MPSoC is kept at relatively low temperatures, with 41 o C peak value. It is important to mention however that this flow rate corresponds to a pressure drop of 1.5 bar/cm, which is comparable with the pressure drops used for microchannel liquid cooling in the literature [7].…”

Section: B Heat Dissipation Potential and Impact On Redox Flow Cellsupporting

confidence: 59%

“…7). In this analysis, we use both COMSOL [19] and the compact thermal model 3D-ICE [7] for system-level evaluation. Fig.…”

Section: B Heat Dissipation Potential and Impact On Redox Flow Cellmentioning

confidence: 99%

“…Single-or two-phase cooling of ICs can dynamically adapt to changes in heat dissipations, reduce energy spent on cooling [6] and enable even denser packaging of devices via 3D stacking of ICs with interlayer cooling of such devices [6][7][8]. Recent advances in this cooling technology have delivered promising results and given rise to a new idea: to combine liquid cooling of ICs with on-chip power generation to overcome the drawbacks of the traditional approaches to achieving energy efficiency described above.…”

Section: Introductionmentioning

confidence: 99%

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Integrated microfluidic power generation and cooling for bright silicon MPSoCs

Sabry

Sridhar

Atienza

et al. 2014

Design, Automation &Amp; Test in Europe Conference &Amp; Exhibition (DATE), 2014

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Abstract-The soaring demand for computing power in our digital information age has produced, as an undesirable sideeffect, a surge in power consumption and heat density for Multiprocessors Systems-on-Chip (MPSoCs). The resulting temperature rise results in operating conditions that already preclude operating all the cores at maximum performance levels, in order to prevent system overheating and failures. With more power demands, MPSoCs will face a power delivery wall due to the reliability limitations of the underlying power delivery medium. Thus, state-of-the-art power and cooling delivery solutions are reaching their performance limits and it will no longer be possible to power up simultaneously all the available on-chip cores (situation known as dark silicon). In this paper we investigate a recently proposed disruptive approach to overcome the prevailing worst-case power and cooling provisioning paradigms for MPSoCs. This proposed approach integrates MPSoC with an on-chip microfluidic fuel cell network for joint cooling and power supply (i.e., localized power generation and delivery). By providing alternative means to power delivery integrated with cooling, MPSoCs are expected to gain in I/O connectivity. Based on this disruptive technology, we can envision the removal of the current limits of power delivery and heat dissipation in MPSoC designs, subsequently avoiding dark silicon and enabling a paradigm shift in future energy-proportional computing architecture designs.

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Section: B Heat Dissipation Potential and Impact On Redox Flow Cellsupporting

confidence: 59%

“…7). In this analysis, we use both COMSOL [19] and the compact thermal model 3D-ICE [7] for system-level evaluation. Fig.…”

Section: B Heat Dissipation Potential and Impact On Redox Flow Cellmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Integrated microfluidic power generation and cooling for bright silicon MPSoCs

Sabry

Sridhar

Atienza

et al. 2014

Design, Automation &Amp; Test in Europe Conference &Amp; Exhibition (DATE), 2014

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“…More advances show that 3D-ICE can even reach speed-ups up to 13478x with 10% peak temperature error [54]. Finally, the recent validations against a realistic test bed [55] show that 3D-ICE achieves an average error of 8.5% with respect to experimental thermal measurements of the test bed (cf. Fig.…”

Section: Compact Thermal Modeling For 3d Mpsocsmentioning

confidence: 99%

Temperature-Aware Design and Management for 3D Multi-Core Architectures

Sabry

Atienza

2014

FNT in Electronic Design Automation

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“…Modeling methods for thermal simulation of ICs with microchannels already exist in in the literature [2]. These tools and methods are useful for evaluating designs.…”

Section: Introductionmentioning

confidence: 99%

ICCAD 2015 contest in 3D interlayer cooling optimized network

Sridhar¹,

Sabry²,

Atienza³

2015

2015 IEEE/ACM International Conference on Computer-Aided Design (ICCAD)

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Microchannel liquid cooling has been proposed since the late 2000s as a viable enabler for 3D integration of microprocessors to continue scaling of computing power in the face of increasingly reduced returns from CMOS technology scaling. Thermal and electrical demonstrations of microchannel liquid-cooled heat sinks on the back side of IC dies exist in the literature and the compatibility of its fabrication with the existing CMOS process has been shown. This compatibility also gives rise to the prospect of building of nearly an infinite variety of channel networks with no additional manufacturing cost. This ICCAD 2015 problem aims to identify methods to optimize such microchannel fluid networks, and to evaluate impact of different cooling networks on different computing architectures floorplans.

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3D-ICE: A Compact Thermal Model for Early-Stage Design of Liquid-Cooled ICs

Cited by 101 publications

References 29 publications

Integrated microfluidic power generation and cooling for bright silicon MPSoCs

Integrated microfluidic power generation and cooling for bright silicon MPSoCs

Temperature-Aware Design and Management for 3D Multi-Core Architectures

ICCAD 2015 contest in 3D interlayer cooling optimized network

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