Angione, Claudio; Occhipinti, Annalisa; Stracquadanio, Giovanni; Nicosia, Giuseppe Bose-Einstein condensation in satisfiability problems. (English) Zbl 1292.68109 Eur. J. Oper. Res. 227, No. 1, 44-54 (2013). Summary: This paper is concerned with the complex behavior arising in satisfiability problems. We present a new statistical physics-based characterization of the satisfiability problem. Specifically, we design an algorithm that is able to produce graphs starting from a \(k\)-SAT instance, in order to analyze them and show whether a Bose-Einstein condensation occurs. We observe that, analogously to complex networks, the networks of \(k\)-SAT instances follow Bose statistics and can undergo Bose-Einstein condensation. In particular, \(k\)-SAT instances move from a fit-get-rich network to a winner-takes-all network as the ratio of clauses to variables decreases, and the phase transition of \(k\)-SAT approximates the critical temperature for the Bose–Einstein condensation. Finally, we employ the fitness-based classification to enhance SAT solvers (e.g., ChainSAT) and obtain the consistently highest performing SAT solver for CNF formulas, and therefore a new class of efficient hardware and software verification tools. Cited in 1 Document MSC: 68Q87 Probability in computer science (algorithm analysis, random structures, phase transitions, etc.) 82B10 Quantum equilibrium statistical mechanics (general) 68Q25 Analysis of algorithms and problem complexity 68T20 Problem solving in the context of artificial intelligence (heuristics, search strategies, etc.) Keywords:\(k\)-SAT; complex networks; Bose-Einstein condensation; phase transition; performance Software:ManySAT; ChainSAT; Chaff PDFBibTeX XMLCite \textit{C. Angione} et al., Eur. J. Oper. Res. 227, No. 1, 44--54 (2013; Zbl 1292.68109) Full Text: DOI arXiv