We develop a qubit routing algorithm with polynomial classical run time for the Quantum Approximate Optimization Algorithm (QAOA). The algorithm follows a two step process. First, it obtains a near-optimal solution, based on Vizing's theorem for the edge coloring problem, consisting of subsets of the interaction gates that can be executed in parallel on a fully parallelized all-to-all connected QPU. Second, it proceeds with greedy application of SWAP gates based on their net effect on the distance of remaining interaction gates on a specific hardware connectivity graph. Our algorithm strikes a balance between optimizing for both the circuit depth and total SWAP gate count. We show that it improves upon existing state-of-the-art routing algorithms for QAOA circuits defined on k-regular as well as Erd\"os-Renyi problem graphs of sizes up to N≤400.
@article{arxiv.2312.15982,
title = {Improved Qubit Routing for QAOA Circuits},
author = {Ayse Kotil and Fedor Simkovic and Martin Leib},
journal= {arXiv preprint arXiv:2312.15982},
year = {2023}
}