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Autores principales: Griset, Rodolphe, Lavdas, Ioannis, Jarkovsky, Jiri Guth
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2501.07174
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author Griset, Rodolphe
Lavdas, Ioannis
Jarkovsky, Jiri Guth
author_facet Griset, Rodolphe
Lavdas, Ioannis
Jarkovsky, Jiri Guth
contents Quantum search has emerged as one of the most promising fields in quantum computing. State-of-the-art quantum search algorithms enable the search for specific elements in a distribution by monotonically increasing the density of these elements until reaching a high density. This kind of algorithms demonstrate a theoretical quadratic speed-up on the number of queries compared to classical search algorithms in unstructured spaces. Unfortunately, the major part of the existing literature applies quantum search to problems which size grows exponnentialy with the input size without exploiting any specific problem structure, rendering this kind of approach not exploitable in real industrial problems. In contrast, this work proposes exploiting specific constraints of scheduling problems to build an initial superposition of states with size almost quadraticaly increasing as a function of the problem size. This state space reduction, inspired by the quantum walk algorithm, constructs a state superposition corresponding to all paths in a state-graph embedding spacing constraints between jobs. Our numerical results on quantum emulators highlights the potential of state space reduction approach, which could lead to more efficient quantum search processes by focusing on a smaller, more relevant, solution space.
format Preprint
id arxiv_https___arxiv_org_abs_2501_07174
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle State-space reduction techniques exploiting specific constraints for quantum search Application to a specific job scheduling problem
Griset, Rodolphe
Lavdas, Ioannis
Jarkovsky, Jiri Guth
Optimization and Control
Quantum Physics
Quantum search has emerged as one of the most promising fields in quantum computing. State-of-the-art quantum search algorithms enable the search for specific elements in a distribution by monotonically increasing the density of these elements until reaching a high density. This kind of algorithms demonstrate a theoretical quadratic speed-up on the number of queries compared to classical search algorithms in unstructured spaces. Unfortunately, the major part of the existing literature applies quantum search to problems which size grows exponnentialy with the input size without exploiting any specific problem structure, rendering this kind of approach not exploitable in real industrial problems. In contrast, this work proposes exploiting specific constraints of scheduling problems to build an initial superposition of states with size almost quadraticaly increasing as a function of the problem size. This state space reduction, inspired by the quantum walk algorithm, constructs a state superposition corresponding to all paths in a state-graph embedding spacing constraints between jobs. Our numerical results on quantum emulators highlights the potential of state space reduction approach, which could lead to more efficient quantum search processes by focusing on a smaller, more relevant, solution space.
title State-space reduction techniques exploiting specific constraints for quantum search Application to a specific job scheduling problem
topic Optimization and Control
Quantum Physics
url https://arxiv.org/abs/2501.07174