Quantum Algorithms Using Infeasible Solution Constraints for Collision-Avoidance Route Planning

Quantum Algorithms Using Infeasible Solution Constraints for Collision-Avoidance Route Planning

Route planning of consumer electronics supply chains, especially collision-avoidance, is a frequently encountered problem in artificial intelligence applications. This paper explores variational quantum algorithms that efficiently utilizes qubits to address this problem, adapting to the current limi...

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Veröffentlicht in:IEEE transactions on consumer electronics 2024-10, p.1-1
Hauptverfasser: Li, Qiting, Huang, Zhaolong, Jiang, Weiwei, Tang, Zikang, Song, Meimei
Format: Artikel
Sprache:eng
Schlagworte:
Binary Vectors Identity
Collision-Avoidance
Computers
Consumer electronics
Costs
Optimization
Planning
Quantum algorithm
Quantum computing
Qubit
Routing
Variational Quantum Algorithm
Vectors
Vehicle Routing Problem
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Zusammenfassung:Route planning of consumer electronics supply chains, especially collision-avoidance, is a frequently encountered problem in artificial intelligence applications. This paper explores variational quantum algorithms that efficiently utilizes qubits to address this problem, adapting to the current limits on quantum computing resources. Firstly, by establishing a mathematically sufficient and necessary condition as a criterion of binary vectors identity, we have constructed infeasible solution constraint about infeasible solution constrains. Next, a route planning model is developed in this paper, which integrates the vehicle routing problem with the collision-avoidance problem. Then, our infeasible solution constraints are employed in a joint optimization algorithm for solving this model, specifically for reducing the number of qubits used during sub-loop elimination and for addressing collision scenarios. Moreover, in order to further reduce the demand for qubits, enabling the computation of larger-scale problems with a limited number of qubits, our algorithm is subsequently enhanced into a stepwise optimization algorithm at an acceptable cost. Finally, the effectiveness of the proposed method, model and algorithms are all validated through quantum simulation computations.
ISSN:0098-3063
1558-4127
DOI:10.1109/TCE.2024.3476156