Reinforcement Learning Based Quantum Circuit Optimization via ZX-Calculus (2312.11597v3)

Abstract: We propose a novel Reinforcement Learning (RL) method for optimizing quantum circuits using graph-theoretic simplification rules of ZX-diagrams. The agent, trained using the Proximal Policy Optimization (PPO) algorithm, employs Graph Neural Networks to approximate the policy and value functions. We demonstrate the capacity of our approach by comparing it against the best performing ZX-Calculus-based algorithm for the problem in hand. After training on small Clifford+T circuits of 5-qubits and few tenths of gates, the agent consistently improves the state-of-the-art for this type of circuits, for at least up to 80-qubit and 2100 gates, whilst remaining competitive in terms of computational performance. Additionally, we illustrate its versatility by targeting both total and two-qubit gate count reduction, conveying the potential of tailoring its reward function to the specific characteristics of each hardware backend. Our approach is ready to be used as a valuable tool for the implementation of quantum algorithms in the near-term intermediate-scale range (NISQ).