Publication Type
Journal Article
Version
publishedVersion
Publication Date
9-2024
Abstract
We introduce an efficient variational hybrid quantum-classical algorithm designed for solving Caputo time-fractional partial differential equations. Our method employs an iterable cost function incorporating a linear combination of overlap history states. The proposed algorithm is not only efficient in terms of time complexity but also has lower memory costs compared to classical methods. Our results indicate that solution fidelity is insensitive to the fractional index and that gradient evaluation costs scale economically with the number of time steps. As a proof of concept, we apply our algorithm to solve a range of fractional partial differential equations commonly encountered in engineering applications, such as the subdiffusion equation, the nonlinear Burgers' equation, and a coupled diffusive epidemic model. We assess quantum hardware performance under realistic noise conditions, further validating the practical utility of our algorithm.
Discipline
Partial Differential Equations | Theory and Algorithms
Areas of Excellence
Digital transformation
Publication
AVS Quantum Science
Volume
6
Issue
3
First Page
1
Last Page
16
Identifier
10.1116/5.0202971
Publisher
American Institute of Physics
Citation
LEONG, Fong Yew; KOH, Dax Enshan; KONG, Jian Feng; GOH, Siong Thye; KHOO, Jun Yong; EWE, Wei Bin; LI, Hongying; THOMPSON, Jayne; and POLETTI, Dario.
Solving fractional differential equations on a quantum computer: A variational approach. (2024). AVS Quantum Science. 6, (3), 1-16.
Available at: https://ink.library.smu.edu.sg/sis_research/9045
Copyright Owner and License
Authors CC-BY
Creative Commons License
This work is licensed under a Creative Commons Attribution 3.0 License.
Additional URL
https://doi.org/10.1116/5.0202971