Quantum Circuit Design using a Progressive Widening Enhanced Monte Carlo Tree Search
This work addresses the problem of automated quantum circuit design for researchers in quantum computing, offering incremental improvements in efficiency and robustness.
The paper tackles the challenge of designing quantum circuits for Variational Quantum Algorithms by proposing a gradient-free Monte Carlo Tree Search technique, which reduces quantum circuit evaluations by 10-100 times and achieves up to three times fewer CNOT gates compared to previous methods.
The performance of Variational Quantum Algorithms (VQAs) strongly depends on the choice of the parameterized quantum circuit to optimize. One of the biggest challenges in VQAs is designing quantum circuits tailored to the particular problem. This article proposes a gradient-free Monte Carlo Tree Search (MCTS) technique to automate the process of quantum circuit design. Our proposed technique introduces a novel formulation of the action space based on a sampling scheme and a progressive widening technique to explore the space dynamically. When testing our MCTS approach on the domain of random quantum circuits, MCTS approximates unstructured circuits under different values of stabilizer Rényi entropy. It turns out that MCTS manages to approximate the benchmark quantum states independently from their degree of nonstabilizerness. Next, our technique exhibits robustness across various application domains, including quantum chemistry and systems of linear equations. Compared to previous MCTS research, our technique reduces the number of quantum circuit evaluations by a factor of 10 up to 100 while achieving equal or better results. In addition, the resulting quantum circuits exhibit up to three times fewer CNOT gates, which is important for implementation on noisy quantum hardware.