Binary Pufferfish Optimization Algorithm for Combinatorial Problems Article Swipe

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Knapsack problem Discretization Binary number Algorithm Set (abstract data type) Optimization problem Mathematical optimization Particle swarm optimization Mathematics Computer science Combinatorial optimization Position (finance) Optimization algorithm Linear programming Test functions for optimization Evolutionary algorithm Continuous knapsack problem Continuous optimization

Broderick Crawford , Álex Paz , Ricardo Soto , Álvaro Peña Peña Fritz , Gino Astorga , Felipe Cisternas-Caneo , Claudio Patricio Toledo Toledo Mac-lean , Fabián Solís-Piñones , José Lara Lara Arce , Giovanni Giachetti ·

YOU? · · 2025 · Open Access · · DOI: https://doi.org/10.3390/biomimetics11010010 · OA: W7117304035

Metaheuristics are a fundament pillar of Industry 4.0, as they allow for complex optimization problems to be solved by finding good solutions in a reasonable amount of computational time. One category of important problems in modern industry is that of binary problems, where decision variables can take values of zero or one. In this work, we propose a binary version of the Pufferfish optimization algorithm (BPOA), which was originally created to solve continuous problems. The binary mapping follows a two-step technique, first transforming using transfer functions and then discretizing using binarization rules. We study representative pairings of transfer functions and binarization rules, comparing our algorithm with Particle Swarm Optimization, Secretary Bird Optimization Algorithm, and Arithmetic Optimization Algorithm with identical computational budgets. To validate its correct functioning, we solved binary problems present in industry, such as the Set Covering Problem together with its Unicost variant, as well as the Knapsack Problem. The results we achieved with regard to these problems were promising and statistically validated. The tests performed on the executions indicate that many pair differences are not statistically significant when both methods are already close to the optimal level, and significance arises precisely where the descriptive gaps widen, underscoring that transfer–rule pairing is the main performance factor. BPOA is a competitive and flexible framework whose effectiveness is mainly governed by the discretization design.