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Difference in gene duplicability may explain the difference in overall structure of protein-protein interaction networks among eukaryotesDiscriminative topological features reveal biological network mechanismsJoint estimation of preferential attachment and node fitness in growing complex networks.Random geometric graphsPercolation on correlated networksWhat can graph theory tell us about word learning and lexical retrieval?Assortative model for social networks.Analysis of feedback loops and robustness in network evolution based on Boolean models.Network archaeology: uncovering ancient networks from present-day interactions.Inferring network mechanisms: the Drosophila melanogaster protein interaction network.The lexical restructuring hypothesis and graph theoretic analyses of networks based on random lexicons.Spatially embedded growing small-world networks.The non-random brain: efficiency, economy, and complex dynamicsAttack robustness and centrality of complex networks.Localized attacks on spatially embedded networks with dependenciesRobustness of oscillatory behavior in correlated networks.Evolution of Cooperation in Social Dilemmas on Complex Networks.Extracellular matrix, mechanotransduction and structural hierarchies in heart tissue engineering.Modularity and anti-modularity in networks with arbitrary degree distribution.Resilience to damage of graphs with degree correlations.Complete trails of coauthorship network evolution.Epidemic thresholds in dynamic contact networks.Genome-wide networks of amino acid covariances are common among viruses.A Unified Framework for Complex Networks with Degree Trichotomy Based on Markov Chains.Degree-ordered percolation on a hierarchical scale-free network.Graph spectral analysis of protein interaction network evolution.Artefacts in statistical analyses of network motifs: general framework and application to metabolic networks.Generative model selection using a scalable and size-independent complex network classifier.Hidden variables in bipartite networks.Percolation of partially interdependent scale-free networks.Oscillatory epidemic prevalence in growing scale-free networks.Growth dominates choice in network percolation.Quantitative modeling of degree-degree correlation in complex networks.Multiple power-law structures in heterogeneous complex networks.Complex reaction networks in high temperature hydrocarbon chemistry.Growing optimal scale-free networks via likelihood.Evolutionary dynamics of the traveler's dilemma and minimum-effort coordination games on complex networks.A Preferential Attachment Paradox: How Preferential Attachment Combines with Growth to Produce Networks with Log-normal In-degree Distributions.Explosive percolation transitions in growing networks.Diversity and critical behavior in prisoner's dilemma game.
P2860
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P2860
description
article
@en
im September 2001 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована у вересні 2001
@uk
name
Are randomly grown graphs really random?
@en
Are randomly grown graphs really random?
@nl
type
label
Are randomly grown graphs really random?
@en
Are randomly grown graphs really random?
@nl
prefLabel
Are randomly grown graphs really random?
@en
Are randomly grown graphs really random?
@nl
P2093
P2860
P1433
P1476
Are randomly grown graphs really random?
@en
P2093
Duncan S. Callaway
John E. Hopcroft
Jon M. Kleinberg
M. E. J. Newman
P2860
P356
10.1103/PHYSREVE.64.041902
P407
P577
2001-09-20T00:00:00Z
P698
P818
cond-mat/0104546