Massively Parallel Approximate Simulation of Hard Quantum Circuits

2020 57th ACM/IEEE Design Automation Conference (DAC) Pub Date : 2020-07-01 DOI:10.1109/DAC18072.2020.9218591
I. Markov, Aneeqa Fatima, S. Isakov, S. Boixo
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引用次数: 8

Abstract

As quantum computers grow more capable, simulating them on conventional hardware becomes more challenging yet more attractive since this helps in design and verification. Some quantum algorithms and circuits are amenable to surprisingly efficient simulation, and this makes hard-to-simulate computations particularly valuable. For such circuits, we develop accurate massively-parallel simulation with dramatic speedups over earlier methods on 42- and 45-qubit circuits. We propose two ways to trade circuit fidelity for computational speedups, so as to match the error rate of any quantum computer. Using Google Cloud, we simulate approximate sampling from the output of a circuit with 7 × 8 qubits and depth 42 with fidelity 0.5% at an estimated cost of $35K.
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硬量子电路的大规模并行近似模拟
随着量子计算机变得越来越强大,在传统硬件上模拟它们变得更具挑战性,但也更具吸引力,因为这有助于设计和验证。一些量子算法和电路适用于令人惊讶的高效模拟,这使得难以模拟的计算特别有价值。对于这种电路,我们在42和45量子位电路上开发了精确的大规模并行模拟,其速度比先前的方法要快得多。我们提出了两种以电路保真度换取计算速度的方法,以匹配任何量子计算机的错误率。使用Google Cloud,我们模拟了7 × 8量子位和深度42的电路输出的近似采样,保真度为0.5%,估计成本为3.5万美元。
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2020 57th ACM/IEEE Design Automation Conference (DAC)
2020 57th ACM/IEEE Design Automation Conference (DAC)
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