Differentiable Quantum Computing for Large-Scale Linear Control
Abstract
As industrial models and designs grow increasingly complex, the demand for optimal control of large-scale dynamical systems has significantly increased. However, traditional methods for optimal control incur significant overhead as problem dimensions grow. In this paper, we introduce an end-to-end quantum algorithm for linear-quadratic control with provable speedups. Our algorithm, based on a policy gradient method, incorporates a novel quantum subroutine for solving the matrix Lyapunov equation. Specifically, we build a quantum-assisted differentiable simulator for efficient gradient estimation that is more accurate and robust than classical methods relying on stochastic approximation. Compared to the classical approaches, our method achieves a super-quadratic speedup. To the best of our knowledge, this is the first end-to-end quantum application to linear control problems with provable quantum advantage.
Cite
Text
Clayton et al. "Differentiable Quantum Computing for Large-Scale Linear Control." Neural Information Processing Systems, 2024. doi:10.52202/079017-1173Markdown
[Clayton et al. "Differentiable Quantum Computing for Large-Scale Linear Control." Neural Information Processing Systems, 2024.](https://mlanthology.org/neurips/2024/clayton2024neurips-differentiable/) doi:10.52202/079017-1173BibTeX
@inproceedings{clayton2024neurips-differentiable,
title = {{Differentiable Quantum Computing for Large-Scale Linear Control}},
author = {Clayton, Connor and Leng, Jiaqi and Yang, Gengzhi and Qiao, Yi-Ling and Lin, Ming C. and Wu, Xiaodi},
booktitle = {Neural Information Processing Systems},
year = {2024},
doi = {10.52202/079017-1173},
url = {https://mlanthology.org/neurips/2024/clayton2024neurips-differentiable/}
}