Quasi-Optimal Recombination Operator

Ambiguities of jet algorithms are reinterpreted as instability wrt small variations of input. Optimal stability occurs for observables possessing property of calorimetric continuity (C-continuity) predetermined by kinematical structure of calorimetric detectors. The so-called C-correlators form a basic class of such observables and fit naturally into QFT framework, allowing systematic theoretical studies. A few rules generate other C-continuous observables. The resulting C-algebra correctly quantifies any feature of multijet structure such as the "number of jets" and mass spectra of "multijet substates." The new observables are physically equivalent to traditional ones but can be computed from final states bypassing jet algorithms which reemerge as a tool of approximate computation of C-observables from data with all ambiguities under analytical control and an optimal recombination criterion minimizing approximation errors.

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Thermodynamical analysis of optimal recombination centers in thyristors

Solid-State Electronics ◽

10.1016/0038-1101(78)90243-5 ◽

1978 ◽

Vol 21 (11-12) ◽

pp. 1571-1576 ◽

Cited By ~ 117

Author(s):

Olof Engström ◽

Anders Alm

Keyword(s):

Recombination Centers ◽

Optimal Recombination

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On Complexity of Optimal Recombination for Binary Representations of Solutions

Evolutionary Computation ◽

10.1162/evco.2008.16.1.127 ◽

2008 ◽

Vol 16 (1) ◽

pp. 127-147 ◽

Cited By ~ 13

Author(s):

Anton V. Eremeev

Keyword(s):

Optimization Problem ◽

Minimum Weight ◽

Packing Problem ◽

Set Covering ◽

Set Packing ◽

Set Partition ◽

Maximum Weight ◽

Linear Programming Problems ◽

Optimal Recombination ◽

Set Packing Problem

We consider the optimization problem of finding the best possible offspring as a result of a recombination operator in an evolutionary algorithm, given two parent solutions. The optimal recombination is studied in the case where a vector of binary variables is used as a solution encoding. By means of efficient reductions of the optimal recombination problems (ORPs) we show the polynomial solvability of the ORPs for the maximum weight set packing problem, the minimum weight set partition problem, and for linear Boolean programming problems with at most two variables per inequality, and some other problems. We also identify several NP-hard cases of optimal recombination: the Boolean linear programming problems with three variables per inequality, the knapsack, the set covering, the p-median, and some other problems.

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On complexity of optimal recombination for flowshop scheduling problems

Journal of Applied and Industrial Mathematics ◽

10.1134/s1990478916020071 ◽

2016 ◽

Vol 10 (2) ◽

pp. 220-231

Author(s):

Yu. V. Kovalenko

Keyword(s):

Scheduling Problems ◽

Flowshop Scheduling ◽

Optimal Recombination

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Dynastic Potential Crossover Operator

Evolutionary Computation ◽

10.1162/evco_a_00305 ◽

2021 ◽

pp. 1-35

Author(s):

Francisco Chicano ◽

Gabriela Ochoa ◽

L. Darrell Whitley ◽

Renato Tinós

Keyword(s):

Polynomial Time ◽

Population Based ◽

Combinatorial Problems ◽

Crossover Operator ◽

Empirical Comparison ◽

Worst Case ◽

Optimal Recombination ◽

Max Sat ◽

Variable Interaction

Abstract An optimal recombination operator for two parent solutions provides the best solution among those that take the value for each variable from one of the parents (gene transmission property). If the solutions are bit strings, the offspring of an optimal recombination operator is optimal in the smallest hyperplane containing the two parent solutions. Exploring this hyperplane is computationally costly, in general, requiring exponential time in the worst case. However, when the variable interaction graph of the objective function is sparse, exploration can be done in polynomial time. In this paper, we present a recombination operator, called Dynastic Potential Crossover (DPX), that runs in polynomial time and behaves like an optimal recombination operator for low-epistasis combinatorial problems. We compare this operator, both theoretically and experimentally, with traditional crossover operators, like uniform crossover and network crossover, and with two recently defined efficient recombination operators: partition crossover and articulation points partition crossover. The empirical comparison uses NKQ Landscapes and MAX-SAT instances. DPX outperforms the other crossover operators in terms of quality of the offspring and provides better results included in a trajectory and a population-based metaheuristic, but it requires more time and memory to compute the offspring.

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