Reducing quantum annealing biases for solving the graph partitioning problem

TL;DR

This paper presents a two-step bias mitigation method for quantum annealers to improve solutions for the NP-hard graph partitioning problem, addressing calibration and implementation biases.

Contribution

It introduces a bias correction approach for quantum annealing, specifically applied to the graph partitioning problem, enhancing solution accuracy by mitigating implementation biases.

Findings

Bias correction improves solution quality.

Iterative bias mitigation effectively reduces implementation biases.

Enhanced accuracy in quantum annealing solutions for graph partitioning.

Abstract

Quantum annealers offer an efficient way to compute high quality solutions of NP-hard problems when expressed in a QUBO (quadratic unconstrained binary optimization) or an Ising form. This is done by mapping a problem onto the physical qubits and couplers of the quantum chip, from which a solution is read after a process called quantum annealing. However, this process is subject to multiple sources of biases, including poor calibration, leakage between adjacent qubits, control biases, etc., which might negatively influence the quality of the annealing results. In this work, we aim at mitigating the effect of such biases for solving constrained optimization problems, by offering a two-step method, and apply it to Graph Partitioning. In the first step, we measure and reduce any biases that result from implementing the constraints of the problem. In the second, we add the objective function to the resulting bias-corrected implementation of the constraints, and send the problem to the quantum annealer. We apply this concept to Graph Partitioning, an important NP-hard problem, which asks to find a partition of the vertices of a graph that is balanced (the constraint) and minimizes the cut size (the objective). We first quantify the bias of the implementation of the constraint on the quantum annealer, that is, we require, in an unbiased implementation, that any two vertices have the same likelihood of being assigned to the same or to different parts of the partition. We then propose an iterative method to correct any such biases. We demonstrate that, after adding the objective, solving the resulting bias-corrected Ising problem on the quantum annealer results in a higher solution accuracy.