Systematic Mapping and Critical Evaluation of Quantum and Quantum-Inspired Optimization Algorithms in the Context of Large-Scale Operations Research Applications
DOI:
https://doi.org/10.62802/rpn04402Keywords:
quantum optimization, quantum-inspired algorithms, operations research, systematic mapping, hybrid quantum–classical methods, scalability, computational complexity, decision scienceAbstract
The growing intersection of quantum computing and operations research (OR) has opened new avenues for solving high-dimensional optimization problems that remain computationally intractable under classical paradigms. This study presents a systematic mapping and critical evaluation of both quantum and quantum-inspired optimization algorithms, with a particular focus on their scalability, convergence efficiency, and applicability to large-scale operations research challenges. Through a structured review of contemporary literature and empirical implementations, the research categorizes existing algorithms into key families—such as quantum annealing, variational quantum algorithms (VQAs), and hybrid quantum–classical frameworks—while identifying trends in algorithmic performance across industrial logistics, network design, and resource allocation models. The systematic mapping process was conducted collaboratively, emphasizing transparent data collection, inclusion–exclusion criteria, and reproducible methodology following evidence-based review standards. Critical evaluation highlighted the need for unified performance metrics, improved hybridization strategies, and enhanced interpretability in quantum-inspired heuristics. The research also provided valuable insight into refining methodological rigor, including bibliometric analysis, coding frameworks, and academic presentation of findings. Ultimately, this work contributes to the ongoing dialogue between quantum computation and operations research, demonstrating how quantum-enhanced optimization can accelerate decision-making processes in complex, data-intensive environments.
References
Acquaye, A. (2025). Operational research for sustainability: a synthesis of methods, applications and challenges. Journal of the Operational Research Society, 1-35.
Athanasopoulou, K., Michalopoulou, V. I., Scorilas, A., & Adamopoulos, P. G. (2025). Integrating Artificial Intelligence in Next-Generation Sequencing: Advances, Challenges, and Future Directions. Current Issues in Molecular Biology, 47(6), 470.
Bala, I., Ahuja, K., & Mijwil, M. M. (2025). Quantum Machine Learning for Industry 4.0. Quantum Computing and Artificial Intelligence: The Industry Use Cases, 415-433.
Iovane, G. (2025). Quantum-Inspired Algorithms and Perspectives for Optimization. Electronics, 14(14), 2839.
Markoska, R., & Markoski, A. (2025). Quantum vs Classical Computing: Technologies in Tandem. International Journal of Recent Research in Mathematics Computer Science and Information Technology, 11(2).
Sharma, M., & Lau, H. C. (2025). Adaptive Graph Shrinking for Quantum Optimization of Constrained Combinatorial Problems. arXiv preprint arXiv:2506.14250.
Siddi Moreau, G., Pisani, L., Profir, M., Podda, C., Leoni, L., & Cao, G. (2025). Quantum Artificial Intelligence Scalability in the NISQ Era: Pathways to Quantum Utility. Advanced Quantum Technologies, 8(10), 2400716.
Ur Rehman, J., Ulum, M. S., Shaffar, A. W., Hakim, A. A., Abdullah, Z., Al-Hraishawi, H., ... & Shin, H. (2025). Evolutionary Algorithms and Quantum Computing: Recent Advances, Opportunities, and Challenges. IEEE Access.
Volpe, D., Orlandi, G., & Turvani, G. (2025). Improving the solving of optimization problems: A comprehensive review of quantum approaches. Quantum Reports, 7(1), 3.
