Quantum Computing Techniques for Multi-knapsack Problems

Abhishek Awasthi; Francesco Bär; Joseph Doetsch; Hans Ehm; Marvin Erdmann; Maximilian Hess; Johannes Klepsch; Peter A. Limacher; Andre Luckow; Christoph Niedermeier; Lilly Palackal; Ruben Pfeiffer; Philipp Ross; Hila Safi; Janik Schönmeier-Kromer; Oliver von Sicard; Yannick Wenger; Karen Wintersperger; Sheir Yarkoni

doi:10.1007/978-3-031-37963-5_19

Quantum Computing Techniques for Multi-knapsack Problems

Abhishek Awasthi, Francesco Bär, Joseph Doetsch, Hans Ehm, Marvin Erdmann, Maximilian Hess, Johannes Klepsch, Peter A. Limacher, Andre Luckow, Christoph Niedermeier, Lilly Palackal, Ruben Pfeiffer, Philipp Ross, Hila Safi, Janik Schönmeier-Kromer, Oliver von Sicard, Yannick Wenger, Karen Wintersperger, Sheir Yarkoni

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

11 Scopus citations

Abstract

Optimization problems are ubiquitous in various industrial settings, and multi-knapsack optimization is one recurrent task faced daily by several industries. The advent of quantum computing has opened a new paradigm for computationally intensive tasks, with promises of delivering better and faster solutions for specific classes of problems. This work presents a comprehensive study of quantum computing approaches for multi-knapsack problems, by investigating some of the most prominent and state-of-the-art quantum algorithms using different quantum software and hardware tools. The performance of the quantum approaches is compared for varying hyperparameters. We consider several gate-based quantum algorithms, such as QAOA and VQE, as well as quantum annealing, and present an exhaustive study of the solutions and the estimation of runtimes. Additionally, we analyze the impact of warm-starting QAOA to understand the reasons for the better performance of this approach. We discuss the implications of our results in view of utilizing quantum optimization for industrial applications in the future. In addition to the high demand for better quantum hardware, our results also emphasize the necessity of more and better quantum optimization algorithms, especially for multi-knapsack problems.

Original language	English
Title of host publication	Intelligent Computing - Proceedings of the 2023 Computing Conference
Editors	Kohei Arai
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	264-284
Number of pages	21
ISBN (Print)	9783031379628
DOIs	https://doi.org/10.1007/978-3-031-37963-5_19
State	Published - 2023
Externally published	Yes
Event	Proceedings of the Computing Conference 2023 - London, United Kingdom Duration: 22 Jun 2023 → 23 Jun 2023

Publication series

Name	Lecture Notes in Networks and Systems
Volume	739 LNNS
ISSN (Print)	2367-3370
ISSN (Electronic)	2367-3389

Conference

Conference	Proceedings of the Computing Conference 2023
Country/Territory	United Kingdom
City	London
Period	22/06/23 → 23/06/23

Keywords

Knapsack problem
QAOA
Quantum Annealing
VQE

Access to Document

10.1007/978-3-031-37963-5_19

Cite this

Awasthi, A., Bär, F., Doetsch, J., Ehm, H., Erdmann, M., Hess, M., Klepsch, J., Limacher, P. A., Luckow, A., Niedermeier, C., Palackal, L., Pfeiffer, R., Ross, P., Safi, H., Schönmeier-Kromer, J., von Sicard, O., Wenger, Y., Wintersperger, K., & Yarkoni, S. (2023). Quantum Computing Techniques for Multi-knapsack Problems. In K. Arai (Ed.), Intelligent Computing - Proceedings of the 2023 Computing Conference (pp. 264-284). (Lecture Notes in Networks and Systems; Vol. 739 LNNS). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-3-031-37963-5_19

@inproceedings{c5744ac06a0447598a46b6b9651f1ab7,

title = "Quantum Computing Techniques for Multi-knapsack Problems",

abstract = "Optimization problems are ubiquitous in various industrial settings, and multi-knapsack optimization is one recurrent task faced daily by several industries. The advent of quantum computing has opened a new paradigm for computationally intensive tasks, with promises of delivering better and faster solutions for specific classes of problems. This work presents a comprehensive study of quantum computing approaches for multi-knapsack problems, by investigating some of the most prominent and state-of-the-art quantum algorithms using different quantum software and hardware tools. The performance of the quantum approaches is compared for varying hyperparameters. We consider several gate-based quantum algorithms, such as QAOA and VQE, as well as quantum annealing, and present an exhaustive study of the solutions and the estimation of runtimes. Additionally, we analyze the impact of warm-starting QAOA to understand the reasons for the better performance of this approach. We discuss the implications of our results in view of utilizing quantum optimization for industrial applications in the future. In addition to the high demand for better quantum hardware, our results also emphasize the necessity of more and better quantum optimization algorithms, especially for multi-knapsack problems.",

keywords = "Knapsack problem, QAOA, Quantum Annealing, VQE",

author = "Abhishek Awasthi and Francesco B{\"a}r and Joseph Doetsch and Hans Ehm and Marvin Erdmann and Maximilian Hess and Johannes Klepsch and Limacher, \{Peter A.\} and Andre Luckow and Christoph Niedermeier and Lilly Palackal and Ruben Pfeiffer and Philipp Ross and Hila Safi and Janik Sch{\"o}nmeier-Kromer and \{von Sicard\}, Oliver and Yannick Wenger and Karen Wintersperger and Sheir Yarkoni",

note = "Publisher Copyright: {\textcopyright} 2023, The Author(s), under exclusive license to Springer Nature Switzerland AG.; Proceedings of the Computing Conference 2023 ; Conference date: 22-06-2023 Through 23-06-2023",

year = "2023",

doi = "10.1007/978-3-031-37963-5\_19",

language = "English",

isbn = "9783031379628",

series = "Lecture Notes in Networks and Systems",

publisher = "Springer Science and Business Media Deutschland GmbH",

pages = "264--284",

editor = "Kohei Arai",

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address = "Germany",

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Awasthi, A, Bär, F, Doetsch, J, Ehm, H, Erdmann, M, Hess, M, Klepsch, J, Limacher, PA, Luckow, A, Niedermeier, C, Palackal, L, Pfeiffer, R, Ross, P, Safi, H, Schönmeier-Kromer, J, von Sicard, O, Wenger, Y, Wintersperger, K & Yarkoni, S 2023, Quantum Computing Techniques for Multi-knapsack Problems. in K Arai (ed.), Intelligent Computing - Proceedings of the 2023 Computing Conference. Lecture Notes in Networks and Systems, vol. 739 LNNS, Springer Science and Business Media Deutschland GmbH, pp. 264-284, Proceedings of the Computing Conference 2023, London, United Kingdom, 22/06/23. https://doi.org/10.1007/978-3-031-37963-5_19

Quantum Computing Techniques for Multi-knapsack Problems. / Awasthi, Abhishek; Bär, Francesco; Doetsch, Joseph et al.
Intelligent Computing - Proceedings of the 2023 Computing Conference. ed. / Kohei Arai. Springer Science and Business Media Deutschland GmbH, 2023. p. 264-284 (Lecture Notes in Networks and Systems; Vol. 739 LNNS).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Awasthi, Abhishek

AU - Bär, Francesco

AU - Doetsch, Joseph

AU - Ehm, Hans

AU - Erdmann, Marvin

AU - Hess, Maximilian

AU - Klepsch, Johannes

AU - Limacher, Peter A.

AU - Luckow, Andre

AU - Niedermeier, Christoph

AU - Palackal, Lilly

AU - Pfeiffer, Ruben

AU - Ross, Philipp

AU - Safi, Hila

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N2 - Optimization problems are ubiquitous in various industrial settings, and multi-knapsack optimization is one recurrent task faced daily by several industries. The advent of quantum computing has opened a new paradigm for computationally intensive tasks, with promises of delivering better and faster solutions for specific classes of problems. This work presents a comprehensive study of quantum computing approaches for multi-knapsack problems, by investigating some of the most prominent and state-of-the-art quantum algorithms using different quantum software and hardware tools. The performance of the quantum approaches is compared for varying hyperparameters. We consider several gate-based quantum algorithms, such as QAOA and VQE, as well as quantum annealing, and present an exhaustive study of the solutions and the estimation of runtimes. Additionally, we analyze the impact of warm-starting QAOA to understand the reasons for the better performance of this approach. We discuss the implications of our results in view of utilizing quantum optimization for industrial applications in the future. In addition to the high demand for better quantum hardware, our results also emphasize the necessity of more and better quantum optimization algorithms, especially for multi-knapsack problems.

AB - Optimization problems are ubiquitous in various industrial settings, and multi-knapsack optimization is one recurrent task faced daily by several industries. The advent of quantum computing has opened a new paradigm for computationally intensive tasks, with promises of delivering better and faster solutions for specific classes of problems. This work presents a comprehensive study of quantum computing approaches for multi-knapsack problems, by investigating some of the most prominent and state-of-the-art quantum algorithms using different quantum software and hardware tools. The performance of the quantum approaches is compared for varying hyperparameters. We consider several gate-based quantum algorithms, such as QAOA and VQE, as well as quantum annealing, and present an exhaustive study of the solutions and the estimation of runtimes. Additionally, we analyze the impact of warm-starting QAOA to understand the reasons for the better performance of this approach. We discuss the implications of our results in view of utilizing quantum optimization for industrial applications in the future. In addition to the high demand for better quantum hardware, our results also emphasize the necessity of more and better quantum optimization algorithms, especially for multi-knapsack problems.

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KW - Quantum Annealing

KW - VQE

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