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Main Authors: Fu, Rong, Su, Zhongling, Zhong, Han-Sen, Zhao, Xiti, Zhang, Jianyang, Pan, Feng, Zhang, Pan, Zhao, Xianhe, Chen, Ming-Cheng, Lu, Chao-Yang, Pan, Jian-Wei, Pei, Zhiling, Zhang, Xingcheng, Ouyang, Wanli
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2407.00769
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author Fu, Rong
Su, Zhongling
Zhong, Han-Sen
Zhao, Xiti
Zhang, Jianyang
Pan, Feng
Zhang, Pan
Zhao, Xianhe
Chen, Ming-Cheng
Lu, Chao-Yang
Pan, Jian-Wei
Pei, Zhiling
Zhang, Xingcheng
Ouyang, Wanli
author_facet Fu, Rong
Su, Zhongling
Zhong, Han-Sen
Zhao, Xiti
Zhang, Jianyang
Pan, Feng
Zhang, Pan
Zhao, Xianhe
Chen, Ming-Cheng
Lu, Chao-Yang
Pan, Jian-Wei
Pei, Zhiling
Zhang, Xingcheng
Ouyang, Wanli
contents Quantum Computational Superiority boasts rapid computation and high energy efficiency. Despite recent advances in classical algorithms aimed at refuting the milestone claim of Google's sycamore, challenges remain in generating uncorrelated samples of random quantum circuits. In this paper, we present a groundbreaking large-scale system technology that leverages optimization on global, node, and device levels to achieve unprecedented scalability for tensor networks. This enables the handling of large-scale tensor networks with memory capacities reaching tens of terabytes, surpassing memory space constraints on a single node. Our techniques enable accommodating large-scale tensor networks with up to tens of terabytes of memory, reaching up to 2304 GPUs with a peak computing power of 561 PFLOPS half-precision. Notably, we have achieved a time-to-solution of 14.22 seconds with energy consumption of 2.39 kWh which achieved fidelity of 0.002 and our most remarkable result is a time-to-solution of 17.18 seconds, with energy consumption of only 0.29 kWh which achieved a XEB of 0.002 after post-processing, outperforming Google's quantum processor Sycamore in both speed and energy efficiency, which recorded 600 seconds and 4.3 kWh, respectively.
format Preprint
id arxiv_https___arxiv_org_abs_2407_00769
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Achieving Energetic Superiority Through System-Level Quantum Circuit Simulation
Fu, Rong
Su, Zhongling
Zhong, Han-Sen
Zhao, Xiti
Zhang, Jianyang
Pan, Feng
Zhang, Pan
Zhao, Xianhe
Chen, Ming-Cheng
Lu, Chao-Yang
Pan, Jian-Wei
Pei, Zhiling
Zhang, Xingcheng
Ouyang, Wanli
Quantum Physics
Distributed, Parallel, and Cluster Computing
Quantum Computational Superiority boasts rapid computation and high energy efficiency. Despite recent advances in classical algorithms aimed at refuting the milestone claim of Google's sycamore, challenges remain in generating uncorrelated samples of random quantum circuits. In this paper, we present a groundbreaking large-scale system technology that leverages optimization on global, node, and device levels to achieve unprecedented scalability for tensor networks. This enables the handling of large-scale tensor networks with memory capacities reaching tens of terabytes, surpassing memory space constraints on a single node. Our techniques enable accommodating large-scale tensor networks with up to tens of terabytes of memory, reaching up to 2304 GPUs with a peak computing power of 561 PFLOPS half-precision. Notably, we have achieved a time-to-solution of 14.22 seconds with energy consumption of 2.39 kWh which achieved fidelity of 0.002 and our most remarkable result is a time-to-solution of 17.18 seconds, with energy consumption of only 0.29 kWh which achieved a XEB of 0.002 after post-processing, outperforming Google's quantum processor Sycamore in both speed and energy efficiency, which recorded 600 seconds and 4.3 kWh, respectively.
title Achieving Energetic Superiority Through System-Level Quantum Circuit Simulation
topic Quantum Physics
Distributed, Parallel, and Cluster Computing
url https://arxiv.org/abs/2407.00769