A Survey of Quantum Computing for Finance

Herman, Dylan; Googin, Cody; Liu, Xiaoyuan; Galda, Alexey; Safro, Ilya; Sun, Yan; Pistoia, Marco; Alexeev, Yuri

doi:10.48550/arxiv.2201.02773

Cited by 48 publications

(48 citation statements)

References 269 publications

(417 reference statements)

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“…As the technology is scaled up, it will ultimately enable powerful quantum algorithms capable of both polynomial and exponential speedups over their classical counterparts. However, many of these algorithms require efficient state preparation procedures to achieve their speedup, as is the case in: option pricing [6][7][8], machine learning [9][10][11], matrix inversion [12], quantum chemistry [13,14], and quantum Monte Carlo based algorithms [15,16]. As such, it remains a crucial open question: can we efficiently prepare quantum states given a set of prespecified amplitudes?…”

Section: Introductionmentioning

confidence: 99%

Preparing Arbitrary Continuous Functions in Quantum Registers With Logarithmic Complexity

Rattew¹,

Koczor²

2022

Preprint

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Quantum computers will be able solve important problems with significant polynomial and exponential speedups over their classical counterparts, for instance in option pricing in finance, and in real-space molecular chemistry simulations. However, key applications can only achieve their potential speedup if their inputs are prepared efficiently. We effectively solve the important problem of efficiently preparing quantum states following arbitrary continuous (as well as more general) functions with complexity logarithmic in the desired resolution, and with rigorous error bounds. This is enabled by the development of a fundamental subroutine based off of the simulation of rank-1 projectors. Combined with diverse techniques from quantum information processing, this subroutine enables us to present a broad set of tools for solving practical tasks, such as state preparation, numerical integration of Lipschitz continuous functions, and superior sampling from probability density functions. As a result, our work has significant implications in a wide range of applications, for instance in financial forecasting, and in quantum simulation.

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Section: Introductionmentioning

confidence: 99%

Preparing Arbitrary Continuous Functions in Quantum Registers With Logarithmic Complexity

Rattew¹,

Koczor²

2022

Preprint

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“…Although only achieving a quadratic speedup over a classical brute-force search, Grover's algorithm makes no assumption on the function other than the number of the solutions (later relaxed by Brassard et al (2002)), and therefore has a wide range of potential applications (Ambainis, 2004;Sun et al, 2014;Zhong et al, 2021). In recent years, quantum algorithms have been developed for various domains including finance (Hong et al, 2014;Herman et al, 2022), chemistry (Cao et al, 2019), optimization (Durr and Hoyer, 1996;Kochenberger et al, 2014;Wang et al, 2016;Hu and Wang, 2020), machine learning (Ramezani et al, 2020), and high-dimensional statistics (Zhong et al, 2021), among others.…”

Section: Introductionmentioning

confidence: 99%

Adaptive Algorithm for Quantum Amplitude Estimation

Zhao¹,

Wang²,

Xu³

et al. 2022

Preprint

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Quantum amplitude estimation is a key sub-routine of a number of quantum algorithms with various applications. We propose an adaptive algorithm for interval estimation of amplitudes. The quantum part of the algorithm is based only on Grover's algorithm. The key ingredient is the introduction of an adjustment factor, which adjusts the amplitude of good states such that the amplitude after the adjustment, and the original amplitude, can be estimated without ambiguity in the subsequent step. We show with numerical studies that the proposed algorithm uses a similar number of quantum queries to achieve the same level of precision ǫ compared to state-of-the-art algorithms, but the classical part, i.e., the non-quantum part, has substantially lower computational complexity. We rigorously prove that the number of oracle queries achieves O(1/ǫ), i.e., a quadratic speedup over classical Monte Carlo sampling, and the computational complexity of the classical part achieves O(log(1/ǫ)), both up to a double-logarithmic factor.

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“…Thus, hybrid optimization algorithms are used whenever the objective function can be evaluated more efficiently on a quantum computer than on a classical one. This is the case for applications to quantum chemistry [6][7][8], quantum control [9][10][11], quantum simulation [12,13], entanglement detection [14][15][16], state estimation [17][18][19][20][21], quantum machine learning [22][23][24][25][26], error correction [27], graph theory [28][29][30], differential equations [31][32][33], and finances [34].…”

Section: Introductionmentioning

confidence: 99%

Stochastic optimization algorithms for quantum applications

Gidi¹,

Candia²,

Muñoz-Moller³

et al. 2022

Preprint

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Hybrid classical quantum optimization methods have become an important tool for efficiently solving problems in the current generation of NISQ computers. These methods use an optimization algorithm that is executed in a classical computer, which is fed with values of the objective function that are obtained in a quantum computer. Therefore, a proper choice of optimization algorithm is essential to achieve good performance. Here, we review the use of first-order, second-order, and quantum natural gradient stochastic optimization methods, which are defined in the field of real numbers, and propose new stochastic algorithms defined in the field of complex numbers. The performance of the methods is evaluated by means of their application to variational quantum eigensolver, quantum control of quantum states, and quantum state estimation. In general, complex number optimization algorithms perform better and second-order algorithms provide a large improvement over first-order methods in the case of variational quantum eigensolver.

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A Survey of Quantum Computing for Finance

Cited by 48 publications

References 269 publications

Preparing Arbitrary Continuous Functions in Quantum Registers With Logarithmic Complexity

Preparing Arbitrary Continuous Functions in Quantum Registers With Logarithmic Complexity

Adaptive Algorithm for Quantum Amplitude Estimation

Stochastic optimization algorithms for quantum applications

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