Quantum computational advantage using photons

Zhong, Han-Sen; Wang, Hui; Deng, Yu-Hao; Chen, Ming-Cheng; Peng, Li-Chao; Luo, Yi-Han; Qin, Jian; Wu, Dajun; Ding, Xing; Hu, Yi; Hu, Peng; Xiao-yan, Yang; Zhang, Weijun; Li, Hao; Li, Yuxuan; Jiang, Xiao; Gan, Lin; Yang, Guangwen; You, Lixing; Wang, Zhen; Li, Li; Liu, Nai-Le; Lu, Chao‐Yang; Pan, Jian-Wei

doi:10.1126/science.abe8770

Cited by 1,819 publications

(952 citation statements)

References 69 publications

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“…Note here that the power ω j is also normalized to be consistent with SOC ∈ [0, 1]. Lastly (7) guarantees that a bus can only be charged continuously, and not intermittently, at most once during each charging window. Hence, the original EV-bus charging problem Eqs 2-7 is an integer programming problem with inequality constraints.…”

Section: Ev-bus Charging Scheduling Problem 21 Problem Definitionmentioning

confidence: 99%

“…In the previous Section 2.3, we have shown that some penalty functions can contain higher-order terms that can not be written into the QUBO objective function, cf. quadratic constraint (7) and the corresponding penalty (11).…”

Section: Limitations Of the Quadratic Penalty Modelmentioning

confidence: 99%

“…Yet, controlling and manufacturing a quantum computer remains an unsolved challenge, although past decades have witnessed multiple breakthroughs. Despite the recently achieved significant milestones for quantum computing, with quantum supremacy tests being performed (Google's superconducting quantum computer Sycamore [6], photonic quantum computer JiuZhang [7]), it is still a fundamental research question to determine which problems and applications should be solved more efficiently by using quantum computing in place of classical computers; and to what extent. Given the current technological advancement, quantum annealing-a metaheuristic optimization algorithmachieves promising experimental performances in finding near-optimal solutions for some NP-hard optimization problems [8][9][10][11].…”

Section: Introductionmentioning

confidence: 99%

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Applying the Hubbard-Stratonovich Transformation to Solve Scheduling Problems Under Inequality Constraints With Quantum Annealing

Nabil²

2021

Front. Phys.

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Quantum annealing is a global optimization algorithm that uses the quantum tunneling effect to speed-up the search for an optimal solution. Its current hardware implementation relies on D-Wave’s Quantum Processing Units, which are limited in terms of number of qubits and architecture while being restricted to solving quadratic unconstrained binary optimization (QUBO) problems. Consequently, previous applications of quantum annealing to real-life use cases have focused on problems that are either native QUBO or close to native QUBO. By contrast, in this paper we propose to tackle inequality constraints and non-quadratic terms. We demonstrate how to handle them with a realistic use case-a bus charging scheduling problem. First, we reformulate the original integer programming problem into a QUBO with the penalty method and directly solve it on a D-Wave machine. In a second approach, we dualize the problem by performing the Hubbard-Stratonovich transformation. The dual problem is solved indirectly by combining quantum annealing and adaptive classical gradient-descent optimizer. Whereas the penalty method is severely limited by the connectivity of the realistic device, we show experimentally that the indirect approach is able to solve problems of a larger size, offering thus a better scaling. Hence, the implementation of the Hubbard-Stratonovich transformation carried out in this paper on a scheduling use case suggests that this approach could be investigated further and applied to a variety of real-life integer programming problems under multiple constraints to lower the cost of mapping to QUBO, a key step towards the near-term practical application of quantum computing.

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Section: Ev-bus Charging Scheduling Problem 21 Problem Definitionmentioning

confidence: 99%

Section: Limitations Of the Quadratic Penalty Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Applying the Hubbard-Stratonovich Transformation to Solve Scheduling Problems Under Inequality Constraints With Quantum Annealing

Nabil²

2021

Front. Phys.

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“…The ultimate goal of implementing a fully faulttolerant quantum error correction scheme for quantum algorithms with provable speed-up may still be years away. However, the recent rapid advance in quantum computing hardware has enabled certain Zhenyu Cai: cai.zhenyu.physics@gmail.com computational tasks to be performed that are well beyond classical capabilities [1,2], prompting the question of whether it is possible to perform any practically useful tasks with the noisy intermediate-scale quantum (NISQ) devices that we will soon have.…”

Section: Introductionmentioning

confidence: 99%

Quantum Error Mitigation using Symmetry Expansion

Cai

2021

Quantum

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Even with the recent rapid developments in quantum hardware, noise remains the biggest challenge for the practical applications of any near-term quantum devices. Full quantum error correction cannot be implemented in these devices due to their limited scale. Therefore instead of relying on engineered code symmetry, symmetry verification was developed which uses the inherent symmetry within the physical problem we try to solve. In this article, we develop a general framework named symmetry expansion which provides a wide spectrum of symmetry-based error mitigation schemes beyond symmetry verification, enabling us to achieve different balances between the estimation bias and the sampling cost of the scheme. We show that certain symmetry expansion schemes can achieve a smaller estimation bias than symmetry verification through cancellation between the biases due to the detectable and undetectable noise components. A practical way to search for such a small-bias scheme is introduced. By numerically simulating the Fermi-Hubbard model for energy estimation, the small-bias symmetry expansion we found can achieve an estimation bias 6 to 9 times below what is achievable by symmetry verification when the average number of circuit errors is between 1 to 2. The corresponding sampling cost for random shot noise reduction is just 2 to 6 times higher than symmetry verification. Beyond symmetries inherent to the physical problem, our formalism is also applicable to engineered symmetries. For example, the recent scheme for exponential error suppression using multiple noisy copies of the quantum device is just a special case of symmetry expansion using the permutation symmetry among the copies.

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“…A IBM afirmou em um estudo que o problema proposto pelo Google não demoraria 10 mil anos para ser resolvido em uma máquina comum, mas apenas 2 dias e meio se uma técnica diferente fosse utilizada [11]. Ainda neste contexto, pesquisadores chineses relataram em [12] a criação de um computador quântico fotônico, denominado Jiuzhang, segundo os autores, tal computador leva aproximadamente 3 minutos e meio para realizar uma tarefa específica que levaria, segundo estimativa, em um dos melhores supercomputadores clássicos do mundo, o Sunway TaihuLight, cerca de 2,5 bilhões de anos. Alcançando assim a supremacia quântica.…”

Section: Introductionunclassified

Aplicações da dinâmica de portadores de cargas em semicondutores como sistemas quânticos abertos

Santos¹

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O comportamento dinâmico dos sistemas quânticos abertos desempenha um papel fundamental em muitas aplicações da mecânica quântica. Exemplos de aplicações incluem problemas como a perda de coerência quântica induzida pelo meio, a relaxação em sistemas de muitos corpos, o transporte quântico, a química quântica, a informação quântica, dentre outros. Em estreita analogia com um processo estocástico markoviano clássico, a interação de um sistema quântico aberto com um ambiente ruidosoé muitas vezes modelada, fenomenologicamente, por meio de um superoperador gerador independente do tempo na forma de Lindblad, que descreve tipicamente uma dinâmica de perda irreversível de características quânticas. Aqui, particularmente, estamos interessados em sistemas onde portadores de carga em dispositivos semicondutores estão acoplados a um ambiente térmico ruidoso. Neste contexto, apresentamos nossos estudos de dois problemas: as caraterísticas da conversão fotovoltaica de uma molécula de pontos quânticos acoplada com um reservatório fonônico, sob a ação de radiação térmica, e a formação de estados quânticos de luz em nanocavidades acopladas com pontos quânticos. No segundo problema investigamos a transição quânticoclássico em estados de superposição mesoscópicas do campo no interior da nanocavidade e posteriormente exploramos a ação de uma engenharia de ambiente sobre tais estados.

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Quantum computational advantage using photons

Cited by 1,819 publications

References 69 publications

Applying the Hubbard-Stratonovich Transformation to Solve Scheduling Problems Under Inequality Constraints With Quantum Annealing

Applying the Hubbard-Stratonovich Transformation to Solve Scheduling Problems Under Inequality Constraints With Quantum Annealing

Quantum Error Mitigation using Symmetry Expansion

Aplicações da dinâmica de portadores de cargas em semicondutores como sistemas quânticos abertos

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