Modeling Food Webs: Exploring Unexplained Structure Using Latent Traits

Rohr, Rudolf P.; Scherer, Heike; Kehrli, Patrik; Mazza, Christian; Bersier, Louis‐Félix

doi:10.1086/653667

Cited by 91 publications

(130 citation statements)

References 25 publications

(34 reference statements)

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“…Specifically, the decomposition is implemented at the node level, with each node characterized by latent traits of matching and centrality. Latent traits are variables whose values are unknown a priori, but can be estimated a posteriori from the network adjacency matrix itself [19,20]. The model, called the matching-centrality model, is implemented in such a way that the closer the matching traits of two nodes, the greater the probability that they are linked, and the higher the centrality trait of a node, the greater the probability that this node makes links.…”

Section: Introductionmentioning

confidence: 99%

Matching–centrality decomposition and the forecasting of new links in networks

et al. 2016

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Networks play a prominent role in the study of complex systems of interacting entities in biology, sociology, and economics. Despite this diversity, we demonstrate here that a statistical model decomposing networks into matching and centrality components provides a comprehensive and unifying quantification of their architecture. The matching term quantifies the assortative structure in which node makes links with which other node, whereas the centrality term quantifies the number of links that nodes make. We show, for a diverse set of networks, that this decomposition can provide a tight fit to observed networks. Then we provide three applications. First, we show that the model allows very accurate prediction of missing links in partially known networks. Second, when node characteristics are known, we show how the matching-centrality decomposition can be related to this external information. Consequently, it offers us a simple and versatile tool to explore how node characteristics explain network architecture. Finally, we demonstrate the efficiency and flexibility of the model to forecast the links that a novel node would create if it were to join an existing network.

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Section: Introductionmentioning

confidence: 99%

Matching–centrality decomposition and the forecasting of new links in networks

et al. 2016

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“…Even if we could define a single abstract feeding niche to characterize trophic links in a food web, body size may not correlate strongly with the niche parameters (Williams et al, 2010). Moreover, multidimensional niches requiring additional traits can describe the topology of empirical food webs with higher likelihood than one-dimensional niche models, including those based on body size (Alessina et al, 2008;Rohr et al, 2010;Williams and Purves, 2011;Eklöf et al, 2013). In less abstract terms, the presence and strengths of trophic links are affected by temperature (Henri et al, 2012;Rall et al, 2012), species identity (Nakazawa et al, 2011, Gilljam et al, 2011Rall et al, 2011), evolutionary history (Bersier and Kehrli, 2008), and predator and prey traits more mechanistically tied to the predation process (Winemiller, 1991;Wirtz, 2012;Klecka and Boukal, 2013).…”

Section: Introductionmentioning

confidence: 99%

Trait- and size-based descriptions of trophic links in freshwater food webs: current status and perspectives

Boukal

2014

J Limnol

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“…Williams et al elaborated the probabilistic niche model that reveals the niche structure and the role of body size in foodwebs [13]. Rohr et al developed a model to capture the architecture of food-webs to uncover the major factors underlying food-web organization [14]. Thierry et al analysed the consequences of the body mass distribution for food web topology [15].…”

Section: Introductionmentioning

confidence: 99%

Structural Network Properties of Niche-Overlap Graphs

Sokhn

Baltensperger

Bersier

et al. 2013

2013 International Conference on Signal-Image Technology &Amp; Internet-Based Systems

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Abstract-The structure of networks has always been interesting for researchers. Investigating their unique architecture allows to capture insights and to understand the function and evolution of these complex systems. Ecological networks such as food-webs and niche-overlap graphs are considered as complex systems. The main purpose of this work is to compare the topology of 15 real niche-overlap graphs with random ones. Five measures are treated in this study: (1) the clustering coefficient, (2) the betweenness centrality, (3) the assortativity coefficient, (4) the modularity and (5) the number of chordless cycles. Significant differences between real and random networks are observed. Firstly, we show that niche-overlap graphs display a higher clustering and a higher modularity compared to random networks. Moreover we find that random networks have barely nodes that belong to a unique subgraph (i.e betweenness centrality equal to 0) and highlight the presence of a small number of chordless cycles compared to real networks. These analyses may provide new insights in the structure of these real niche-overlap graphs and may give important implications on the functional organization of species competing for some resources and on the dynamics of these systems.

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Modeling Food Webs: Exploring Unexplained Structure Using Latent Traits

Cited by 91 publications

References 25 publications

Matching–centrality decomposition and the forecasting of new links in networks

Matching–centrality decomposition and the forecasting of new links in networks

Trait- and size-based descriptions of trophic links in freshwater food webs: current status and perspectives

Structural Network Properties of Niche-Overlap Graphs

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