Towards Deeply Scaled 3D MPSoCs with Integrated Flow Cell Array Technology

Najibi, Halima; Levisse, Alexandre; Zapater, Marina; Aly, Mohamed M. Sabry; Atienza, David

doi:10.1145/3386263.3406923

Cited by 2 publications

(5 citation statements)

References 19 publications

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“…High channel temperatures increase the electrochemical reaction rate, effectively transforming heat into available power for high-performance 3D MPSoCs. As shown in [5] and [11], FCA-generated current can recover up to 20% voltage drop when augmenting an existing PDN. Alternatively, FCAs can also be employed to reduce the density of power delivery components (e.g., power TSVs) for a traditional PDN while abiding by a given voltage drop constraint.…”

Section: Background On 3d Mpsoc Thermal and Power Managementmentioning

confidence: 91%

“…As fan-based cooling struggles to maintain 3D MPSoC temperatures at acceptable levels, a high-performance direct liquid cooling solution using a cold plate has been proposed [10]. Nonetheless, such an approach requires large cold plate dimensions, low coolant temperatures, and costly materials to extract the high amount of heat generated by 3D MPSoCs [11]. Similar to FCA technology, inter-tier liquid cooling employs micro-channels etched in the silicon substrate of 3D MPSoC dies, through which a liquid is pumped, which absorbs the generated heat [12].…”

Section: Background On 3d Mpsoc Thermal and Power Managementmentioning

confidence: 99%

“…The transistors are typically sized to achieve 10nA/µm leakage per gate width for low and medium performance, and 20nA/µm leakage per gate width for high performance [35], at the reference temperature of 25°C. Then, this value increases exponentially with temperature [11]. Hence, the total leakage power of the GPU die for a temperature t GP U is calculated as follows:…”

Section: B Temperature and Voltage-aware 3d Mpsoc Frequency Optimizat...mentioning

confidence: 99%

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Thermal and Voltage-Aware Performance Management of 3-D MPSoCs With Flow Cell Arrays and Integrated SC Converters

Najibi¹,

Levisse²,

Ansaloni³

et al. 2023

IEEE Trans. Comput.-Aided Des. Integr. Circuits Syst.

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Flow cell arrays (FCAs) concurrently provide efficient on-chip liquid cooling and electrochemical power generation. This technology is especially promising for threedimensional multi-processor systems-on-chip (3D MPSoCs) realized in deeply scaled technologies, which present very challenging power and thermal requirements. Indeed, FCAs effectively improve power delivery network (PDN) performance, particularly if switched capacitor (SC) converters are employed to decouple the flow cells and the systems-on-chip voltages, allowing each to operate at their optimal point. Nonetheless, the design of FCAbased solutions entails non-obvious considerations and trade-offs, stemming from their dual role in governing both the thermal and power delivery characteristics of 3D MPSoCs. Showcasing them in this paper, we explore multiple FCA design configurations and demonstrate that this technology can decrease the temperature of a heterogeneous 3D MPSoC by 78°C, and its total power consumption by 46%, compared to a high-performance cold-plate based liquid cooling solution. At the same time, FCAs enable up to 90% voltage drop recovery across dies, using SC converters occupying a small fraction of the chip area. Such outcomes provide an opportunity to boost 3D MPSoC computing performance by increasing the operating frequency of dies. Leveraging these results, we introduce a novel temperature and voltage-aware model predictive control (MPC) strategy that optimizes power efficiency during run-time. We achieve application-wide speedups of up to 16% on various machine learning (ML), data mining, and other high-performance benchmarks while keeping the 3D MPSoC temperature below 83°C and voltage drops below 5%.

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Section: Background On 3d Mpsoc Thermal and Power Managementmentioning

confidence: 91%

Section: Background On 3d Mpsoc Thermal and Power Managementmentioning

confidence: 99%

Section: B Temperature and Voltage-aware 3d Mpsoc Frequency Optimizat...mentioning

confidence: 99%

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Thermal and Voltage-Aware Performance Management of 3-D MPSoCs With Flow Cell Arrays and Integrated SC Converters

Najibi¹,

Levisse²,

Ansaloni³

et al. 2023

IEEE Trans. Comput.-Aided Des. Integr. Circuits Syst.

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“…The FCAs are connected to the 3D MPSoC power grid through DC-DC voltage regulators, ensuring that they operate at their optimal voltage (enabling the maximal power generation) regardless of transient load changes in the chip [12]. As shown in [13] and [12], FCAs can reduce temperature by 50°C compared to traditional fan-based cooling, and recover up to 20% of voltage drop in the 3D PDNs. Consequently, FCAs provide an opportunity to increase the load of dies while mitigating the performance losses related to voltage drop and temperature.…”

Section: D Mpsocs Thermal and Power Management With Flow Cell Arraysmentioning

confidence: 99%

“…The temperature map 𝑇 of each die is evaluated using 3D-ICE [15] when the power consumption profiles of the 3D MP-SoC computing dies correspond to the previously calculated power maps. (iii) The leakage map 𝑃 𝑙𝑒𝑎𝑘 is estimated for each computing die according to its thermal map 𝑇 , using the temperature and transistor leakage relationship that characterizes the specific CMOS technology [13]. Hence, the total power map is calculated as: 𝑃 𝑡𝑜𝑡𝑎𝑙 = 𝑃 𝑑𝑦𝑛 + 𝑃 𝑙𝑒𝑎𝑘 .…”

Section: Performance Management Of 3d Mpsocs With Fcasmentioning

confidence: 99%

Thermal and Power-Aware Run-time Performance Management of 3D MPSoCs with Integrated Flow Cell Arrays

Najibi

Levisse

Ansaloni

et al. 2022

Proceedings of the Great Lakes Symposium on VLSI 2022

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Flow Cell Arrays (FCA) technology employs microchannels filled with an electrolytic fluid to concurrently provide cooling and power generation to integrated circuits (ICs). This solution is particularly appealing for Three-Dimensional Multi-Processor Systems-on-Chip (3D MPSoCs) realized in deeply scaled technologies, as their extreme power densities result in significant thermal and voltage supply challenges. FCAs provide them with extra power to boost performance. However, the dual effects of FCAs (cooling and power supply) have conflicting trends leading to a complex interplay between temperature, voltage stability, and performance. In this paper, we explore this trade-off by introducing a novel methodology that controls the operating frequency of computing components and the electrolytic coolant flow rate at run-time. Our strategy enables tangible performance gains while abiding by timing, voltage drop, and temperature constraints. We showcase its benefits by targeting a 4-layer 3D MPSoC, achieving up to 24% increase in the operating frequencies and resulting in application speedups of up to 17%, while reducing the costs related to FCA liquid pumping energy. CCS CONCEPTS• Hardware → 3D integrated circuits; Power networks; Temperature control.

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Towards Deeply Scaled 3D MPSoCs with Integrated Flow Cell Array Technology

Cited by 2 publications

References 19 publications

Thermal and Voltage-Aware Performance Management of 3-D MPSoCs With Flow Cell Arrays and Integrated SC Converters

Thermal and Voltage-Aware Performance Management of 3-D MPSoCs With Flow Cell Arrays and Integrated SC Converters

Thermal and Power-Aware Run-time Performance Management of 3D MPSoCs with Integrated Flow Cell Arrays

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