AbstractLet G be a given graph (modelling a communication network) which we assume suffers from static edge faults: That is we let each edge of G be present independently with probability p (or absent with fault probability f=1−p). In particular, we are interested in robustness results for the case that the graph G itself is a random member of the class of all regular graphs with given degree. Our result is: If the degree d is fixed then p=1/(d−1) is a threshold probability for the existence of a linear-sized component in a faulty version of almost all random regular graphs. We show: If each edge of an arbitrary graph G with maximum degree bounded above by d is present with probability p=λ/(d−1) where λ<1 is fixed then the faulted version o...
First published in Proc. Amer. Math. Soc. 146 (2018), 3321-3332, published by the American Mathemati...
Consider random graph with $N+ 1$ vertices as follows. The degrees of vertices $1,2,\ldots, N$ are t...
For a fixed degree sequence D=(d1,…,dn) , let G(D) be a uniformly chosen (simple) graph on {1,…,n} w...
AbstractLet G be a given graph (modelling a communication network) which we assume suffers from stat...
AbstractLet G be a given graph (modelling a communication network) which we assume suffers from stat...
AbstractRandom regular graphs are, at least theoretically, popular communication networks. The reaso...
2002 Elsevier Science B.V. All rights reserved. journal homepage website http://www.informatik.uni-t...
AbstractWe investigate the following vertex percolation process. Starting with a random regular grap...
We consider the issue of protection in very large networks displaying randomness in topology. We emp...
We consider some models of random graphs and directed graphs and investigate their behavior near thr...
We study the problem of the existence of a giant component in a random multipartite graph. We consid...
International audienceIn this contribution, we investigate the giant component problem in random gra...
In this paper, we investigate the appearance of the giant component in random subgraphs G(p) of a gi...
We study a special case of the configuration model, in which almost all the vertices of the graph ha...
We consider bond percolation on random graphs with given degrees and bounded average degree. In part...
First published in Proc. Amer. Math. Soc. 146 (2018), 3321-3332, published by the American Mathemati...
Consider random graph with $N+ 1$ vertices as follows. The degrees of vertices $1,2,\ldots, N$ are t...
For a fixed degree sequence D=(d1,…,dn) , let G(D) be a uniformly chosen (simple) graph on {1,…,n} w...
AbstractLet G be a given graph (modelling a communication network) which we assume suffers from stat...
AbstractLet G be a given graph (modelling a communication network) which we assume suffers from stat...
AbstractRandom regular graphs are, at least theoretically, popular communication networks. The reaso...
2002 Elsevier Science B.V. All rights reserved. journal homepage website http://www.informatik.uni-t...
AbstractWe investigate the following vertex percolation process. Starting with a random regular grap...
We consider the issue of protection in very large networks displaying randomness in topology. We emp...
We consider some models of random graphs and directed graphs and investigate their behavior near thr...
We study the problem of the existence of a giant component in a random multipartite graph. We consid...
International audienceIn this contribution, we investigate the giant component problem in random gra...
In this paper, we investigate the appearance of the giant component in random subgraphs G(p) of a gi...
We study a special case of the configuration model, in which almost all the vertices of the graph ha...
We consider bond percolation on random graphs with given degrees and bounded average degree. In part...
First published in Proc. Amer. Math. Soc. 146 (2018), 3321-3332, published by the American Mathemati...
Consider random graph with $N+ 1$ vertices as follows. The degrees of vertices $1,2,\ldots, N$ are t...
For a fixed degree sequence D=(d1,…,dn) , let G(D) be a uniformly chosen (simple) graph on {1,…,n} w...