This paper introduces an innovative approach to explore the capabilities of Quantum Annealing (QA) for trajectory optimization in dynamic systems. The proposed method involves transforming trajectory optimization problems into equivalent binary optimization problems using Quadratic Unconstrained Binary Optimization (QUBO) representation. The procedure is general and adaptable, making it applicable to a wide range of optimal control problems that entail the satisfaction of dynamic, boundary, and path constraints. Specifically, the trajectory is discretized and approximated using polynomials. In contrast to the conventional approach of determining the polynomial degree (n) solely based on the number of boundary conditions, a specific factor is introduced in our method to augment the polynomial degree. As a result, the ultimate polynomial degree is calculated as a composite of two components: n = l + ((Formula presented.)), where m denotes the count of boundary conditions and l signifies the number of independent variables. By leveraging inverse dynamics, the control required to follow the approximated trajectory can be determined as a linear function of independent variables l. As a result, the optimization function, which is represented by the integral of the square of the control, can be formulated as a QUBO problem and the QA is employed to find the optimal binary solutions.

Cutting-Edge Trajectory Optimization through Quantum Annealing / Carbone, A.; De Grossi, F.; Spiller, D.. - In: APPLIED SCIENCES. - ISSN 2076-3417. - 13:23(2023). [10.3390/app132312853]

Cutting-Edge Trajectory Optimization through Quantum Annealing

Carbone A.
;
De Grossi F.;Spiller D.
2023

Abstract

This paper introduces an innovative approach to explore the capabilities of Quantum Annealing (QA) for trajectory optimization in dynamic systems. The proposed method involves transforming trajectory optimization problems into equivalent binary optimization problems using Quadratic Unconstrained Binary Optimization (QUBO) representation. The procedure is general and adaptable, making it applicable to a wide range of optimal control problems that entail the satisfaction of dynamic, boundary, and path constraints. Specifically, the trajectory is discretized and approximated using polynomials. In contrast to the conventional approach of determining the polynomial degree (n) solely based on the number of boundary conditions, a specific factor is introduced in our method to augment the polynomial degree. As a result, the ultimate polynomial degree is calculated as a composite of two components: n = l + ((Formula presented.)), where m denotes the count of boundary conditions and l signifies the number of independent variables. By leveraging inverse dynamics, the control required to follow the approximated trajectory can be determined as a linear function of independent variables l. As a result, the optimization function, which is represented by the integral of the square of the control, can be formulated as a QUBO problem and the QA is employed to find the optimal binary solutions.
2023
inverse dynamics; polynomial approximation; quantum annealing; QUBO formulation; trajectory optimization
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Cutting-Edge Trajectory Optimization through Quantum Annealing / Carbone, A.; De Grossi, F.; Spiller, D.. - In: APPLIED SCIENCES. - ISSN 2076-3417. - 13:23(2023). [10.3390/app132312853]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/1726284
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