August 7, 2024
Conference Paper

Red-QAOA: Efficient Variational Optimization through Circuit Reduction

Abstract

The Quantum Approximate Optimization Algorithm (QAOA) provides a quantum solution for combinatorial optimization problems. However, the optimal parameter searching process of QAOA is greatly affected by noise, leading to non-optimal solutions. This paper introduces a novel approach to optimize QAOA by exploiting the energy landscape concentration of similar instances via graph reduction, thus addressing the effect of noise. We formalize the notion of similar instances in QAOA and develop a Simulated Annealing-based graph reduction algorithm, called Red-QAOA, to identify the most similar subgraph for efficient parameter optimization. Red-QAOA outperforms state-of-the-art Graph Neural Network (GNN) based graph pooling techniques in performance and demonstrates effectiveness on a diverse set of real-world optimization problems encompassing 3200 graphs. Red-QAOA reduced the node counts and edge counts by 28% and 37%, respectively, while maintaining a low mean square error of 2%. These enable the identification of an optimal parameter set that is closer to the ideal true optimal solution in the presence of noise. By substantially streamlining the search for QAOA parameters, our approach sets the stage for the practical application of quantum algorithms in solving complex optimization problems.

Published: August 7, 2024

Citation

Wang M., B. Fang, A. Li, and P. Nair. 2024. Red-QAOA: Efficient Variational Optimization through Circuit Reduction. In ACM International Conference on Architectural Support for Programming Languages and Operating Systems (ASPLOS 2024), April 27-May 1, 2024, La Jolla, CA, 2, 990-998. New York, New York:Association for Computing Machinery. PNNL-SA-192496. doi:10.1145/3620665.3640363