Application of Quantum Computers and Their Unique Properties for Constrained Optimization in Engineering Problems: Welded Beam Design

• Published in: Electronics (Basel) Vol. 14; no. 5; p. 1027
• Main Author: Ewald, Dawid
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.03.2025
• Subjects: Algorithms; Annealing; Bending stresses; Constraints; Cost control; Efficiency; Engineering; Failure; Industrial applications; Linear functions; Load; Manufacturing; Mathematical optimization; Optimization; Production costs; Quantum computers; Quantum computing; Shear stress; Steel beams; Structural analysis; Structural engineering; Variables
• ISSN: 2079-9292; 2079-9292
• DOI: 10.3390/electronics14051027

The welded beam design problem represents a real-world engineering challenge in structural optimization. The objective is to determine the optimal dimensions of a steel beam and weld length to minimize cost while satisfying constraints related to shear stress (τ), bending stress (σ), critical buckling load (Pc), end deflection (δ), and side constraints. The structural analysis of this problem involves the following four design variables: weld height (x1), weld length (x2), beam thickness (x3), and beam width (x4), which are commonly denoted in structural engineering as h,l,t,b respectively. The structural formulation of this problem leads to a nonlinear objective function, which is subject to five nonlinear and two linear inequality constraints. The optimal solution lies on the boundary of the feasible region, with a very small feasible-to-search-space ratio, making it a highly challenging problem for classical optimization algorithms. This paper explores the application of quantum computing to solve the welded beam optimization problem, utilizing the unique properties of quantum computers for constrained optimization in engineering problems. Specifically, we employ the D-Wave quantum computing system, which utilizes quantum annealing and is particularly well-suited for solving constrained optimization problems. The study presents a detailed formulation of the problem in a format compatible with the D-Wave system, ensuring the efficient encoding of constraints and objective functions. Furthermore, we analyze the performance of quantum computing in solving this problem and compare the obtained results with classical optimization methods. The effectiveness of quantum computing is evaluated in terms of computational efficiency, accuracy, and its ability to navigate complex, constrained search spaces. This research highlights the potential of quantum algorithms in tackling real-world engineering optimization problems and discusses the challenges and limitations of current quantum hardware in solving practical industrial application issues.