Our work introduces an approach for estimating the contribution of attachment mechanisms to the formation of growing networks. We present a generic model in which growth is driven by the continuous attachment of new nodes according to random and preferential linkage with a xed probability. Past approaches apply likelihood analysis to estimate the probability of occurrence of each mechanism at a particular network instance, exploiting the concavity of the likelihood function at each point in time. However, the probability of connecting to existing nodes, and consequently the likelihood function itself, varies as networks grow. We establish conditions under which applying likelihood analysis guarantees the existence of a local maxim...
One of the best-known models in network science is preferential attachment. In this model, the proba...
A key ingredient of many current models proposed to capture the topological evolution of complex net...
We present a continuum formalism for modeling growing random networks under addition and deletion of...
We propose a preferential attachment model for network growth where new entering nodes hav...
We obtain closed form expressions for the expected conditional degree distribution and the joint deg...
PACS 89.75.Fb – Structures and organization in complex systems Abstract – We study the growth of bip...
International audienceThe degree distributions of complex networks are usually considered to follow ...
<p>We consider a statistical model for directed network formation that features both node-specific p...
Preferential attachment drives the evolution of many complex networks. Its analytical studies mostly...
Networks with bimodal degree distribution are most robust to targeted and random attacks. We present...
Many complex networks from the World Wide Web to biological networks grow taking into account the he...
We introduce a collection of complex networks generated by a combination of preferential attachment ...
We study a class of network growth models in which the choice of attachment by new nodes is governed...
We introduce the PAPER (Preferential Attachment Plus Erd\H{o}s--R\'{e}nyi) model for random networks...
We present a simple model of network growth and solve it by writing the dynamic equations for its ma...
One of the best-known models in network science is preferential attachment. In this model, the proba...
A key ingredient of many current models proposed to capture the topological evolution of complex net...
We present a continuum formalism for modeling growing random networks under addition and deletion of...
We propose a preferential attachment model for network growth where new entering nodes hav...
We obtain closed form expressions for the expected conditional degree distribution and the joint deg...
PACS 89.75.Fb – Structures and organization in complex systems Abstract – We study the growth of bip...
International audienceThe degree distributions of complex networks are usually considered to follow ...
<p>We consider a statistical model for directed network formation that features both node-specific p...
Preferential attachment drives the evolution of many complex networks. Its analytical studies mostly...
Networks with bimodal degree distribution are most robust to targeted and random attacks. We present...
Many complex networks from the World Wide Web to biological networks grow taking into account the he...
We introduce a collection of complex networks generated by a combination of preferential attachment ...
We study a class of network growth models in which the choice of attachment by new nodes is governed...
We introduce the PAPER (Preferential Attachment Plus Erd\H{o}s--R\'{e}nyi) model for random networks...
We present a simple model of network growth and solve it by writing the dynamic equations for its ma...
One of the best-known models in network science is preferential attachment. In this model, the proba...
A key ingredient of many current models proposed to capture the topological evolution of complex net...
We present a continuum formalism for modeling growing random networks under addition and deletion of...