Applying the Quantum Approximate Optimization Algorithm to the Tail Assignment Problem
Pontus Vikstål,Mattias Grönkvist,Marika Svensson,Marika Svensson,Martin Andersson,Göran Johansson,Giulia Ferrini +6 more
TLDR
This article simulates the Quantum Approximate Optimization Algorithm applied to instances of this problem derived from real world data and finds that repeated runs of the QAOA identify the feasible solution with close to unit probability for all instances.Abstract:
Airlines today are faced with a number of large scale scheduling problems. One such problem is the tail assignment problem, which is the task of assigning individual aircraft to a given set of flights, minimizing the overall cost. Each aircraft is identified by the registration number on its tail fin. In this article, we simulate the Quantum Approximate Optimization Algorithm (QAOA) applied to instances of this problem derived from real world data. The QAOA is a variational hybrid quantum-classical algorithm recently introduced and likely to run on near-term quantum devices. The instances are reduced to fit on quantum devices with 8, 15 and 25 qubits. The reduction procedure leaves only one feasible solution per instance, which allows us to map the tail assignment problem onto the Exact Cover problem. We find that repeated runs of the QAOA identify the feasible solution with close to unit probability for all instances. Furthermore, we observe patterns in the variational parameters such that an interpolation strategy can be employed which significantly simplifies the classical optimization part of the QAOA. Finally, we empirically find a relation between the connectivity of the problem graph and the single-shot success probability of the algorithm.read more
Citations
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Journal ArticleDOI
Scaling quantum approximate optimization on near-term hardware
Phillip C. Lotshaw,Thiên-Lôc Nguyên,Anthony Santana,Alexander McCaskey,Rebekah Herrman,James Ostrowski,George Siopsis,Travis S. Humble +7 more
TL;DR: In this paper , the authors quantify scaling of the expected resource requirements by synthesizing optimized circuits for hardware architectures with varying levels of connectivity, and estimate the number of measurements needed to sample the output of the idealized QAOA circuit with high probability.
Journal ArticleDOI
A study of the performance of classical minimizers in the Quantum Approximate Optimization Algorithm
Mario Fernández-Pendás,Mario Fernández-Pendás,Elías F. Combarro,Elías F. Combarro,Sofia Vallecorsa,José Ranilla,Ignacio F. Rúa +6 more
TL;DR: This work studies the performance of twelve different classical optimizers when used with QAOA to solve the maximum cut problem in graphs and presents results that show that some optimizers can be hundreds of times more efficient than others in some cases.
Journal ArticleDOI
Perceval: A Software Platform for Discrete Variable Photonic Quantum Computing
Nicolas Heurtel,Andreas Fyrillas,Gr'egoire de Gliniasty,Raphael Le Bihan,S'ebastien Malherbe,Marceau Pailhas,Eric Bertasi,Boris Bourdoncle,Pierre-Emmanuel Emeriau,Rawad Mezher,Luka Music,Nadia Belabas,Benoît Valiron,Pascale Senellart,Shane Mansfield,J Senellart +15 more
TL;DR: Perceval as mentioned in this paper is an open-source software platform for simulating and interfacing with discrete-variable photonic quantum computers, which allows photonic circuits to be composed from basic photonic building blocks like photon sources, beam splitters, phase-shifters and detectors.
Journal ArticleDOI
Constraint Preserving Mixers for the Quantum Approximate Optimization Algorithm
TL;DR: This article presents a framework for constructing mixing operators that restrict the evolution to a subspace of the full Hilbert space given by these constraints, and exposes the underlying mathematical structure which reveals more of how mixers work and how one can minimize their cost in terms of the number of CX gates.
Journal ArticleDOI
Applying the quantum approximate optimization algorithm to the minimum vertex cover problem
TL;DR: In this paper , a quantum circuit solution scheme based on the quantum approximate optimization algorithm is presented for the minimum vertex cover problem, which is difficult to obtain the near-optimal solution in the polynomial time range using classical algorithms.
References
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