NISQ computing: where are we and where do we go?

Jonathan Wei Zhong Lau, Kian Hwee Lim, Harshank Shrotriya, Leong Chuan Kwek
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Abstract

In this short review article, we aim to provide physicists not working within the quantum computing community a hopefully easy-to-read introduction to the state of the art in the field, with minimal mathematics involved. In particular, we focus on what is termed the Noisy Intermediate Scale Quantum era of quantum computing. We describe how this is increasingly seen to be a distinct phase in the development of quantum computers, heralding an era where we have quantum computers that are capable of doing certain quantum computations in a limited fashion, and subject to certain constraints and noise. We further discuss the prominent algorithms that are believed to hold the most potential for this era, and also describe the competing physical platforms on which to build a quantum computer that have seen the most success so far. We then talk about the applications that are most feasible in the near-term, and finish off with a short discussion on the state of the field. We hope that as non-experts read this article, it will give context to the recent developments in quantum computers that have garnered much popular press, and help the community understand how to place such developments in the timeline of quantum computing.

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NISQ 计算:我们在哪里?
在这篇简短的综述文章中,我们旨在为不在量子计算领域工作的物理学家提供一个希望简单易读的介绍,让他们了解该领域的最新进展,并尽量少涉及数学知识。我们尤其关注量子计算的所谓 "噪声中间量级量子时代"。我们描述了量子计算机发展的一个独特阶段是如何被越来越多的人所认识的,它预示着一个量子计算机时代的到来,在这个时代,我们的量子计算机能够以有限的方式进行某些量子计算,并受到某些限制和噪声的影响。我们将进一步讨论据信在这一时代最具潜力的著名算法,并介绍迄今为止最成功的用于构建量子计算机的竞争性物理平台。然后,我们讨论了近期内最可行的应用,最后对该领域的现状进行了简短的讨论。我们希望非专业人士在阅读这篇文章时,能够了解量子计算机近期发展的来龙去脉,这些发展已在大众媒体上引起广泛关注,并帮助社会各界了解如何将这些发展置于量子计算的时间轴上。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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8.20
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