Landscapes and their correlation functions
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Publication:1381249
DOI10.1007/BF01165154zbMath1002.92547OpenAlexW3121771796WikidataQ56992112 ScholiaQ56992112MaRDI QIDQ1381249
Publication date: 15 January 2003
Published in: Journal of Mathematical Chemistry (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1007/bf01165154
Related Items (34)
Graph Laplacians, nodal domains, and hyperplane arrangements ⋮ Measuring epistasis in fitness landscapes: the correlation of fitness effects of mutations ⋮ Exact results for amplitude spectra of fitness landscapes ⋮ Rugged and Elementary Landscapes ⋮ Complex networks: from graph theory to biology ⋮ The influence of higher-order epistasis on biological fitness landscape topography ⋮ Universality classes of interaction structures for NK fitness landscapes ⋮ On the Hamming distance in combinatorial optimization problems on hypergraph matchings ⋮ Mutation landscapes ⋮ Metaheuristics for the minimum gap graph partitioning problem ⋮ Quasispecies and recombination ⋮ Application of graph-theoretic approaches to the random landscapes of the three-dimensional assignment problem ⋮ Computing the moments \(k\)-bounded pseudo-Boolean functions over Hamming spheres of arbitrary radius in polynomial time ⋮ Autocorrelation measures for the quadratic assignment problem ⋮ Quantitative measure of nonconvexity for black-box continuous functions ⋮ On the classification of NP-complete problems in terms of their correlation coefficient ⋮ Elementary landscape decomposition of the frequency assignment problem ⋮ The theory of elementary landscapes ⋮ Weakly symmetric graphs, elementary landscapes, and the TSP ⋮ Quantitative analyses of empirical fitness landscapes ⋮ Analysis of adaptive walks on NK fitness landscapes with different interaction schemes ⋮ Random assignment problems ⋮ Fitness landscape analysis for the no-wait flow-shop scheduling problem ⋮ The component model for elementary landscapes and partial neighborhoods ⋮ Coupled map lattices as spatio-temporal fitness functions: Landscape measures and evolutionary optimization ⋮ Neutrality in fitness landscapes. ⋮ Arbitrary elementary landscapes \& AR(1) processes ⋮ The characteristic landscape equation for an AR(2) landscape ⋮ The linear ordering problem: instances, search space analysis and algorithms ⋮ Random walk's correlation function for multi-objective NK landscapes and quadratic assignment problem ⋮ A simple model of co-evolutionary dynamics caused by epistatic selection ⋮ Landscapes on spaces of trees ⋮ Modeling genetic architecture: A multilinear theory of gene interaction ⋮ Fast Fourier transform for fitness landscapes
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