Asymptotic Degree Distribution of a Kind of Asymmetric Evolving Network

Scale-Free Property for Degrees and Weights in a Preferential Attachment Random Graph Model

Journal of Probability and Statistics ◽

10.1155/2013/707960 ◽

2013 ◽

Vol 2013 ◽

pp. 1-12 ◽

Cited By ~ 5

Author(s):

István Fazekas ◽

Bettina Porvázsnyik

Keyword(s):

Asymptotic Behaviour ◽

Random Graph ◽

Power Law ◽

Degree Distribution ◽

Preferential Attachment ◽

Graph Model ◽

Random Graph Model ◽

Scale Free ◽

Attachment Model ◽

Law Degree

A random graph evolution mechanism is defined. The evolution studied is a combination of the preferential attachment model and the interaction of four vertices. The asymptotic behaviour of the graph is described. It is proved that the graph exhibits a power law degree distribution; in other words, it is scale-free. It turns out that any exponent in(2,∞)can be achieved. The proofs are based on martingale methods.

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Preferential Attachment with Location-Based Choice: Degree Distribution in the Noncondensation Phase

Journal of Statistical Physics ◽

10.1007/s10955-021-02782-6 ◽

2021 ◽

Vol 184 (1) ◽

Author(s):

Arne Grauer ◽

Lukas Lüchtrath ◽

Mark Yarrow

Keyword(s):

Phase Transition ◽

Power Law ◽

Degree Distribution ◽

Maximum Degree ◽

Preferential Attachment ◽

Critical Value ◽

Time Step ◽

Power Law Exponent ◽

Attachment Model ◽

Sampling Probability

AbstractWe consider the preferential attachment model with location-based choice introduced by Haslegrave et al. (Random Struct Algorithms 56(3):775–795, 2020) as a model in which condensation phenomena can occur. In this model, each vertex carries an independent and uniformly distributed location. Starting from an initial tree, the model evolves in discrete time. At every time step, a new vertex is added to the tree by selecting r candidate vertices from the graph with replacement according to a sampling probability proportional to these vertices’ degrees. The new vertex then connects to one of the candidates according to a given probability associated to the ranking of their locations. In this paper, we introduce a function that describes the phase transition when condensation can occur. Considering the noncondensation phase, we use stochastic approximation methods to investigate bounds for the (asymptotic) proportion of vertices inside a given interval of a given maximum degree. We use these bounds to observe a power law for the asymptotic degree distribution described by the aforementioned function. Hence, this function fully characterises the properties we are interested in. The power law exponent takes the critical value one at the phase transition between the condensation–noncondensation phase.

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EMERGENCE OF MULTISCALING IN HETEROGENEOUS COMPLEX NETWORKS

International Journal of Modern Physics C ◽

10.1142/s0129183107011571 ◽

2007 ◽

Vol 18 (10) ◽

pp. 1591-1607 ◽

Cited By ~ 13

Author(s):

A. SANTIAGO ◽

R. M. BENITO

Keyword(s):

Complex Networks ◽

Power Law ◽

Degree Distribution ◽

Preferential Attachment ◽

Threshold Model ◽

Specific Form ◽

Numerical Evidence ◽

Attachment Model ◽

Attachment Mechanism

In this paper we provide numerical evidence of the richer behavior of the connectivity degrees in heterogeneous preferential attachment networks in comparison to their homogeneous counterparts. We analyze the degree distribution in the threshold model, a preferential attachment model where the affinity between node states biases the attachment probabilities of links. We show that the degree densities exhibit a power-law multiscaling which points to a signature of heterogeneity in preferential attachment networks. This translates into a power-law scaling in the degree distribution, whose exponent depends on the specific form of heterogeneity in the attachment mechanism.

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Network growth with preferential attachment and without “rich get richer” mechanism

International Journal of Modern Physics C ◽

10.1142/s0129183116500200 ◽

2015 ◽

Vol 27 (02) ◽

pp. 1650020

Author(s):

A. Lachgar ◽

A. Achahbar

Keyword(s):

Power Law ◽

Degree Distribution ◽

Preferential Attachment ◽

Target Node ◽

Network Growth ◽

Perfect Agreement ◽

Equation Solution ◽

Attachment Model ◽

Law Degree ◽

Growing Network

We propose a simple preferential attachment model of growing network using the complementary probability of Barabási–Albert (BA) model, i.e. [Formula: see text]. In this network, new nodes are preferentially attached to not well connected nodes. Numerical simulations, in perfect agreement with the master equation solution, give an exponential degree distribution. This suggests that the power law degree distribution is a consequence of preferential attachment probability together with “rich get richer” phenomena. We also calculate the average degree of a target node at time t[Formula: see text] and its fluctuations, to have a better view of the microscopic evolution of the network, and we also compare the results with BA model.

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Models of network formation

10.1093/oso/9780198805090.003.0013 ◽

2018 ◽

Author(s):

Mark Newman

Keyword(s):

Degree Distribution ◽

Network Formation ◽

Preferential Attachment ◽

Network Size ◽

Large Network ◽

Citation Networks ◽

Airline Networks ◽

Attachment Model ◽

Delivery Networks

This chapter describes models of the growth or formation of networks, with a particular focus on preferential attachment models. It starts with a discussion of the classic preferential attachment model for citation networks introduced by Price, including a complete derivation of the degree distribution in the limit of large network size. Subsequent sections introduce the Barabasi-Albert model and various generalized preferential attachment models, including models with addition or removal of extra nodes or edges and models with nonlinear preferential attachment. Also discussed are node copying models and models in which networks are formed by optimization processes, such as delivery networks or airline networks.

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The structure of co-publications multilayer network

Computational Social Networks ◽

10.1186/s40649-021-00089-w ◽

2021 ◽

Vol 8 (1) ◽

Author(s):

Ghislain Romaric Meleu ◽

Paulin Yonta Melatagia

Keyword(s):

Power Law ◽

Degree Distribution ◽

Preferential Attachment ◽

Small World ◽

Generation Model ◽

Small World Network ◽

Power Law Distribution ◽

Multilayer Networks ◽

Multilayer Network ◽

Scientific Papers

AbstractUsing the headers of scientific papers, we have built multilayer networks of entities involved in research namely: authors, laboratories, and institutions. We have analyzed some properties of such networks built from data extracted from the HAL archives and found that the network at each layer is a small-world network with power law distribution. In order to simulate such co-publication network, we propose a multilayer network generation model based on the formation of cliques at each layer and the affiliation of each new node to the higher layers. The clique is built from new and existing nodes selected using preferential attachment. We also show that, the degree distribution of generated layers follows a power law. From the simulations of our model, we show that the generated multilayer networks reproduce the studied properties of co-publication networks.

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Phase Transitions for Random Geometric Preferential Attachment Graphs

Advances in Applied Probability ◽

10.1239/aap/1435236988 ◽

2015 ◽

Vol 47 (2) ◽

pp. 565-588 ◽

Cited By ~ 3

Author(s):

Jonathan Jordan ◽

Andrew R. Wade

Keyword(s):

Phase Transitions ◽

Preferential Attachment ◽

Geometric Model ◽

Degree Sequence ◽

Spatial Proximity ◽

Nearest Neighbour ◽

Intermediate Regime ◽

On Line ◽

Attachment Model ◽

Preferential Rule

Vertices arrive sequentially in space and are joined to existing vertices at random according to a preferential rule combining degree and spatial proximity. We investigate phase transitions in the resulting graph as the relative strengths of these two components of the attachment rule are varied.Previous work of one of the authors showed that when the geometric component is weak, the limiting degree sequence mimics the standard Barabási-Albert preferential attachment model. We show that at the other extreme, in the case of a sufficiently strong geometric component, the limiting degree sequence mimics a purely geometric model, the on-line nearest-neighbour graph, for which we prove some extensions of known results. We also show the presence of an intermediate regime, with behaviour distinct from both the on-line nearest-neighbour graph and the Barabási-Albert model; in this regime, we obtain a stretched exponential upper bound on the degree sequence.

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GROWING HIERARCHICAL SCALE-FREE NETWORKS BY MEANS OF NONHIERARCHICAL PROCESSES

International Journal of Bifurcation and Chaos ◽

10.1142/s0218127407018518 ◽

2007 ◽

Vol 17 (07) ◽

pp. 2447-2452 ◽

Cited By ~ 10

Author(s):

S. BOCCALETTI ◽

D.-U. HWANG ◽

V. LATORA

Keyword(s):

Power Law ◽

Degree Distribution ◽

Preferential Attachment ◽

Rate Equations ◽

Scale Free ◽

Scale Free Networks ◽

Degree Correlations ◽

Law Degree ◽

Hierarchical Scale

We introduce a fully nonhierarchical network growing mechanism, that furthermore does not impose explicit preferential attachment rules. The growing procedure produces a graph featuring power-law degree and clustering distributions, and manifesting slightly disassortative degree-degree correlations. The rigorous rate equations for the evolution of the degree distribution and for the conditional degree-degree probability are derived.

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Directed preferential attachment models: Limiting degree distributions and their tails

Journal of Applied Probability ◽

10.1017/jpr.2019.80 ◽

2020 ◽

Vol 57 (1) ◽

pp. 122-136

Author(s):

Tom Britton

Keyword(s):

Explicit Expression ◽

Empirical Evidence ◽

Explicit Form ◽

Degree Distribution ◽

Preferential Attachment ◽

Outgoing Edge ◽

Tail Probabilities ◽

Attachment Model ◽

Birth Processes

AbstractThe directed preferential attachment model is revisited. A new exact characterization of the limiting in- and out-degree distribution is given by two independent pure birth processes that are observed at a common exponentially distributed time T (thus creating dependence between in- and out-degree). The characterization gives an explicit form for the joint degree distribution, and this confirms previously derived tail probabilities for the two marginal degree distributions. The new characterization is also used to obtain an explicit expression for tail probabilities in which both degrees are large. A new generalized directed preferential attachment model is then defined and analyzed using similar methods. The two extensions, motivated by empirical evidence, are to allow double-directed (i.e. undirected) edges in the network, and to allow the probability of connecting an ingoing (outgoing) edge to a specified node to also depend on the out-degree (in-degree) of that node.

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Percolation phase transition in weight-dependent random connection models

Advances in Applied Probability ◽

10.1017/apr.2021.13 ◽

2021 ◽

Vol 53 (4) ◽

pp. 1090-1114

Author(s):

Peter Gracar ◽

Lukas Lüchtrath ◽

Peter Mörters

Keyword(s):

Phase Transition ◽

Poisson Process ◽

Random Graphs ◽

Power Law ◽

Degree Distribution ◽

Preferential Attachment ◽

Dimensional Space ◽

Geometric Model ◽

Scale Free ◽

Power Law Exponent

AbstractWe investigate spatial random graphs defined on the points of a Poisson process in d-dimensional space, which combine scale-free degree distributions and long-range effects. Every Poisson point is assigned an independent weight. Given the weight and position of the points, we form an edge between any pair of points independently with a probability depending on the two weights of the points and their distance. Preference is given to short edges and connections to vertices with large weights. We characterize the parameter regime where there is a non-trivial percolation phase transition and show that it depends not only on the power-law exponent of the degree distribution but also on a geometric model parameter. We apply this result to characterize robustness of age-based spatial preferential attachment networks.

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