Constrained Quantum Optimization for Extractive Summarization on a Trapped-ion Quantum Computer
Abstract
Realizing the potential of near-term quantum computers to solve industry-relevant constrained-optimization problems is a promising path to quantum advantage. In this work, we consider the extractive summarization constrained-optimization problem and demonstrate the largest-to-date execution of a quantum optimization algorithm that natively preserves constraints on quantum hardware. We report results with the Quantum Alternating Operator Ansatz algorithm with a Hamming-weight-preserving XY mixer (XY-QAOA) on trapped-ion quantum computer. We successfully execute XY-QAOA circuits that restrict the quantum evolution to the in-constraint subspace, using up to 20 qubits and a two-qubit gate depth of up to 159. We demonstrate the necessity of directly encoding the constraints into the quantum circuit by showing the trade-off between the in-constraint probability and the quality of the solution that is implicit if unconstrained quantum optimization methods are used. We show that this trade-off makes choosing good parameters difficult in general. We compare XY-QAOA to the Layer Variational Quantum Eigensolver algorithm, which has a highly expressive constant-depth circuit, and the Quantum Approximate Optimization Algorithm. We discuss the respective trade-offs of the algorithms and implications for their execution on near-term quantum hardware.
Cite
@article{arxiv.2206.06290,
title = {Constrained Quantum Optimization for Extractive Summarization on a Trapped-ion Quantum Computer},
author = {Pradeep Niroula and Ruslan Shaydulin and Romina Yalovetzky and Pierre Minssen and Dylan Herman and Shaohan Hu and Marco Pistoia},
journal= {arXiv preprint arXiv:2206.06290},
year = {2022}
}
Comments
camera-ready version