A Characterization of Quantum Generative Models-Reference-Cited by-同舟云学术

A Characterization of Quantum Generative Models

Published:2024-06-17 Issue:2 Volume:5 Page:1-34
ISSN:2643-6809
Container-title:ACM Transactions on Quantum Computing
language:en
Short-container-title:ACM Trans. Quantum Comput.

Author:

Riofrio Carlos A.¹²^ORCID,Mitevski Oliver³²^ORCID,Jones Caitlin⁴²^ORCID,Krellner Florian⁵²^ORCID,Vuckovic Aleksandar⁶⁷²^ORCID,Doetsch Joseph⁸²^ORCID,Klepsch Johannes¹²^ORCID,Ehmer Thomas⁷²^ORCID,Luckow Andre¹²^ORCID

Affiliation:

1. BMW Group, Munchen, Germany

2. QUTAC, Quantum Technology and Application Consortium, Munich Germany

3. Munich Re Group, Munchen, Germany

4. BASF Digital Solutions, Ludwigshafen Germany

5. SAP SE, Walldorf, Germany

6. Faculty of Physics, TU Darmstadt, Darmstadt, Germany

7. Healthcare R&D Digital Innovation, Merck KGaA, Darmstadt, Germany

8. Lufthansa Industry Solutions, Norderstedt Germany

Abstract

Quantum generative modeling is a growing area of interest for industry-relevant applications. This work systematically compares a broad range of techniques to guide quantum computing practitioners when deciding which models and methods to use in their applications. We compare fundamentally different architectural ansatzes of parametric quantum circuits: (1) A continuous architecture, which produces continuous-valued data samples, and (2) a discrete architecture, which samples on a discrete grid. We also compare the performance of different data transformations: the min-max and the probability integral transforms. We use two popular training methods: (1) quantum circuit Born machines (QCBM), and (2) quantum generative adversarial networks (QGAN). We study their performance and tradeoffs as the number of model parameters increases, with a baseline comparison of similarly trained classical neural networks. The study is performed on six low-dimensional synthetic and two real financial data sets. Our two key findings are that: (1) For all data sets, our quantum models require similar or fewer parameters than their classical counterparts. In the extreme case, the quantum models require two orders of magnitude less parameters. (2) We empirically find that a variant of the discrete architecture, which learns the copula of the probability distribution, outperforms all other methods.

Publisher

Association for Computing Machinery (ACM)

Link

https://dl.acm.org/doi/pdf/10.1145/3655027

Reference70 articles.

1. 2022. Yahoo Finance API. Retrieved from https://finance.yahoo.com/.

2. The computational complexity of linear optics

3. Classical versus quantum models in machine learning: insights from a finance application

4. Noise Robustness and Experimental Demonstration of a Quantum Generative Adversarial Network for Continuous Distributions

5. The Probability Integral Transform and Related Results

Cited by 2 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Benchmarking Quantum Generative Learning: A Study on Scalability and Noise Resilience using QUARK;KI - Künstliche Intelligenz;2024-08-19

2. On the sample complexity of quantum Boltzmann machine learning;Communications Physics;2024-08-14