A Non-Variational Quantum Approach to the Job Shop Scheduling Problem

TL;DR

This paper introduces Iterative-QAOA, a non-variational quantum algorithm that effectively solves large-scale job shop scheduling problems, demonstrating promising results on quantum hardware and simulations.

Contribution

The paper presents a novel non-variational, shallow-depth quantum algorithm with iterative warm-starting for job shop scheduling, suitable for near-term quantum devices.

Findings

Iterative-QAOA converges to optimal and high-quality solutions across tested instances.

The algorithm scales to problems with up to 97 qubits in simulations.

Potential for industrial-scale problem solving on fault-tolerant quantum computers.

Abstract

Quantum heuristics offer a potential advantage for combinatorial optimization but are constrained by near-term hardware limitations. We introduce Iterative-QAOA, a variant of QAOA designed to mitigate these constraints. The algorithm combines a non-variational, shallow-depth circuit approach using fixed-parameter schedules with an iterative warm-starting process. We benchmark the algorithm on Just-in-Time Job Shop Scheduling Problem (JIT-JSSP) instances on IonQ Forte Generation QPUs, representing some of the largest such problems ever executed on quantum hardware. We compare the performance of the algorithm against both the Variational Quantum Imaginary Time Evolution (VarQITE) algorithm and the non-variational Linear Ramp (LR) QAOA algorithm. We find that Iterative-QAOA robustly converges to find optimal solutions as well as high-quality, near-optimal solutions for all problem instances evaluated. We evaluate the algorithm on larger problem instances up to 97 qubits using tensor network simulations. The scaling behavior of the algorithm indicates potential for solving industrial-scale problems on fault-tolerant quantum computers.