Random Threshold Graphs

Reilly, Elizabeth P.; Scheinerman, Edward R.

doi:10.37236/219

Cited by 8 publications

(11 citation statements)

References 11 publications

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“…The goal of this paper is to extend the work on random threshold graphs [12] (see also [11]) to directed graphs. (See also [11] and [13] which consider a variant of the random threshold model for bipartite graphs; such graphs are known as random difference graphs.…”

Section: Overview Of Resultsmentioning

confidence: 99%

“…We use the transformation T to create a natural model of random threshold graphs. One simply selects a point in x ∈ [0, 1] n uniformly at random and apply T to yield a random threshold graph; see [11] and [12]. Specifically, we define the random graph G n to be a random variable taking values in G n such that…”

Section: Background: Undirected (Random) Threshold Graphsmentioning

confidence: 99%

“…Of course, if G is not a threshold graph, Pr[G n = G] = 0. In [11,12] an equivalent, purely combinatorial model for random threshold graphsbased on creation sequences-provides a route to proving various exact and asymptotic results about random threshold graphs.…”

Section: Background: Undirected (Random) Threshold Graphsmentioning

confidence: 99%

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Random Threshold Digraphs

Reilly

Scheinerman

Zhang

2014

Electron. J. Combin.

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This paper introduces a notion of a random threshold directed graph, extending the work of Reilly and Scheinerman in the undirected case and closely related to random Ferrers digraphs.We begin by presenting the main definition: $D$ is a threshold digraph provided we can find a pair of weighting functions $f,g:V(D)\to\mathbb{R}$ such that for distinct $v,w\in V(D)$ we have $v\to w$ iff $f(v)+g(w)\ge1$. We also give an equivalent formulation based on an order representation that is purely combinatorial (no arithmetic). We show that our formulations are equivalent to the definition in the work of Cloteaux, LaMar, Moseman, and Shook in which the focus is on the degree sequence, and present a new characterization theorem for threshold digraphs.We then develop the notion of a random threshold digraph formed by choosing vertex weights independently and uniformly at random from $[0,1]$. We show that this notion of a random threshold digraph is equivalent to a purely combinatorial approach, and present a formula for the probability of a digraph based on counting linear extensions of an auxiliary partially ordered set.We capitalize on this equivalence to develop exact and asymptotic properties of random threshold digraphs such as the number of vertices with in-degree (or out-degree) equal to zero, domination number, connectivity and strong connectivity, clique and independence number, and chromatic number.

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Section: Overview Of Resultsmentioning

confidence: 99%

Section: Background: Undirected (Random) Threshold Graphsmentioning

confidence: 99%

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Random Threshold Digraphs

Reilly

Scheinerman

Zhang

2014

Electron. J. Combin.

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“…The problem of analyzing complex behaviors of large social, economic and biological networks based on generative recursive and probabilistic models has been the subject of intense research in graph theory, machine learning and statistics. In these settings, one often assumes the existence of attachment and preference rules for network formation, or imposes constraints on subgraph structures as well as vertex and edge features that govern the creation of network communities [1,2,3,4,5]. Models of this type have been used to predict network dynamics and topology fluctuations, infer network community properties and preferences, determine the bottlenecks and rates of spread of information and commodities and elucidate functional and structural properties of individual network modules [6,7,8].…”

Section: Introductionmentioning

confidence: 99%

Paired threshold graphs

Ravanmehr

Puleo

Bolouki

et al. 2018

Discrete Applied Mathematics

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“…Difference graphs were formally defined by Hammer, Peled, and Sun [5] in 1990, although they had been independently explored prior to that point [3], a result of the multiple equivalent characterizations for this class of graphs [6]. They are closely related to threshold graphs, which can be viewed as difference graphs without the bipartitioning; this similarity enables us to adapt the techniques used in the study of random threshold graphs, notably those of Reilly and Scheinerman [7]. Here, we focus on difference graphs with a specified bipartition, also known as bipartite threshold graphs (Diaconis, Holmes, Janson [4]).…”

Section: Introductionmentioning

confidence: 99%

Properties of Random Difference Graphs

Ross

2012

Electron. J. Combin.

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Generate a bipartite graph on a partitioned set of vertices by randomly assigning to each vertex $v$ some weight $w(v) \in [0,1]$ and adding an edge between vertices $u$ and $v$ (in distinct parts) if and only if $w(v) + w(v) > 1$; the results of such processes are known as difference graphs.Random difference graphs of a given size can be produced either by uniformly random generation of weights or by choosing a graph uniformly at random from the set of all such graphs. We prove that these two methods give rise to the same distribution, and use this equivalence to find exact results for the likelihood of connectivity and Hamiltonicity. We also find the distribution of other properties, such as matching number and degeneracy.

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Random Threshold Graphs

Cited by 8 publications

References 11 publications

Random Threshold Digraphs

Random Threshold Digraphs

Paired threshold graphs

Properties of Random Difference Graphs

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