Your search keyword '"Boguna, Marian"' showing total 14 results

1. Quantifying randomness in real networks

Author

Orsini, Chiara, Dankulov, Marija Mitrović, Jamakovic, Almerima, Mahadevan, Priya, Colomer-de-Simón, Pol, Vahdat, Amin, Bassler, Kevin E., Toroczkai, Zoltán, Boguñá, Marián, Caldarelli, Guido, Fortunato, Santo, and Krioukov, Dmitri

Subjects

Physics - Physics and Society, Condensed Matter - Statistical Mechanics, Computer Science - Networking and Internet Architecture

Abstract

Represented as graphs, real networks are intricate combinations of order and disorder. Fixing some of the structural properties of network models to their values observed in real networks, many other properties appear as statistical consequences of these fixed observables, plus randomness in other respects. Here we employ the $dk$-series, a complete set of basic characteristics of the network structure, to study the statistical dependencies between different network properties. We consider six real networks---the Internet, US airport network, human protein interactions, technosocial web of trust, English word network, and an fMRI map of the human brain---and find that many important local and global structural properties of these networks are closely reproduced by $dk$-random graphs whose degree distributions, degree correlations, and clustering are as in the corresponding real network. We discuss important conceptual, methodological, and practical implications of this evaluation of network randomness, and release software to generate $dk$-random graphs.

Published

2015

2. Network Cosmology

Author

Krioukov, Dmitri, Kitsak, Maksim, Sinkovits, Robert S., Rideout, David, Meyer, David, and Boguna, Marian

Subjects

General Relativity and Quantum Cosmology, Condensed Matter - Disordered Systems and Neural Networks, Computer Science - Networking and Internet Architecture, Computer Science - Social and Information Networks, Physics - Physics and Society

Abstract

Prediction and control of the dynamics of complex networks is a central problem in network science. Structural and dynamical similarities of different real networks suggest that some universal laws might accurately describe the dynamics of these networks, albeit the nature and common origin of such laws remain elusive. Here we show that the causal network representing the large-scale structure of spacetime in our accelerating universe is a power-law graph with strong clustering, similar to many complex networks such as the Internet, social, or biological networks. We prove that this structural similarity is a consequence of the asymptotic equivalence between the large-scale growth dynamics of complex networks and causal networks. This equivalence suggests that unexpectedly similar laws govern the dynamics of complex networks and spacetime in the universe, with implications to network science and cosmology.

Published

2012

3. Popularity versus Similarity in Growing Networks

Author

Papadopoulos, Fragkiskos, Kitsak, Maksim, Serrano, M. Angeles, Boguna, Marian, and Krioukov, Dmitri

Subjects

Physics - Physics and Society, Condensed Matter - Statistical Mechanics, Computer Science - Networking and Internet Architecture, Computer Science - Social and Information Networks

Abstract

Popularity is attractive -- this is the formula underlying preferential attachment, a popular explanation for the emergence of scaling in growing networks. If new connections are made preferentially to more popular nodes, then the resulting distribution of the number of connections that nodes have follows power laws observed in many real networks. Preferential attachment has been directly validated for some real networks, including the Internet. Preferential attachment can also be a consequence of different underlying processes based on node fitness, ranking, optimization, random walks, or duplication. Here we show that popularity is just one dimension of attractiveness. Another dimension is similarity. We develop a framework where new connections, instead of preferring popular nodes, optimize certain trade-offs between popularity and similarity. The framework admits a geometric interpretation, in which popularity preference emerges from local optimization. As opposed to preferential attachment, the optimization framework accurately describes large-scale evolution of technological (Internet), social (web of trust), and biological (E.coli metabolic) networks, predicting the probability of new links in them with a remarkable precision. The developed framework can thus be used for predicting new links in evolving networks, and provides a different perspective on preferential attachment as an emergent phenomenon.

Published

2011

4. Sustaining the Internet with Hyperbolic Mapping

Author

Boguna, Marian, Papadopoulos, Fragkiskos, and Krioukov, Dmitri

Subjects

Computer Science - Networking and Internet Architecture, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Computer Science - Social and Information Networks, Physics - Physics and Society

Abstract

The Internet infrastructure is severely stressed. Rapidly growing overheads associated with the primary function of the Internet---routing information packets between any two computers in the world---cause concerns among Internet experts that the existing Internet routing architecture may not sustain even another decade. Here we present a method to map the Internet to a hyperbolic space. Guided with the constructed map, which we release with this paper, Internet routing exhibits scaling properties close to theoretically best possible, thus resolving serious scaling limitations that the Internet faces today. Besides this immediate practical viability, our network mapping method can provide a different perspective on the community structure in complex networks.

Published

2010

5. Hyperbolic Geometry of Complex Networks

Author

Krioukov, Dmitri, Papadopoulos, Fragkiskos, Kitsak, Maksim, Vahdat, Amin, and Boguna, Marian

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Disordered Systems and Neural Networks, Computer Science - Networking and Internet Architecture, Physics - Physics and Society

Abstract

We develop a geometric framework to study the structure and function of complex networks. We assume that hyperbolic geometry underlies these networks, and we show that with this assumption, heterogeneous degree distributions and strong clustering in complex networks emerge naturally as simple reflections of the negative curvature and metric property of the underlying hyperbolic geometry. Conversely, we show that if a network has some metric structure, and if the network degree distribution is heterogeneous, then the network has an effective hyperbolic geometry underneath. We then establish a mapping between our geometric framework and statistical mechanics of complex networks. This mapping interprets edges in a network as non-interacting fermions whose energies are hyperbolic distances between nodes, while the auxiliary fields coupled to edges are linear functions of these energies or distances. The geometric network ensemble subsumes the standard configuration model and classical random graphs as two limiting cases with degenerate geometric structures. Finally, we show that targeted transport processes without global topology knowledge, made possible by our geometric framework, are maximally efficient, according to all efficiency measures, in networks with strongest heterogeneity and clustering, and that this efficiency is remarkably robust with respect to even catastrophic disturbances and damages to the network structure.

Published

2010

6. How small are building blocks of complex networks

Author

Jamakovic, Almerima, Mahadevan, Priya, Vahdat, Amin, Boguna, Marian, and Krioukov, Dmitri

Subjects

Physics - Physics and Society, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Computer Science - Networking and Internet Architecture

Abstract

Network motifs are small building blocks of complex networks. Statistically significant motifs often perform network-specific functions. However, the precise nature of the connection between motifs and the global structure and function of networks remains elusive. Here we show that the global structure of some real networks is statistically determined by the probability of connections within motifs of size at most 3, once this probability accounts for node degrees. The connectivity profiles of node triples in these networks capture all their local and global properties. This finding impacts methods relying on motif statistical significance, and enriches our understanding of the elementary forces that shape the structure of complex networks.

Published

2009

7. Extracting the multiscale backbone of complex weighted networks

Author

Serrano, M. Angeles, Boguna, Marian, and Vespignani, Alessandro

Subjects

Physics - Physics and Society, Condensed Matter - Disordered Systems and Neural Networks, Computer Science - Networking and Internet Architecture

Abstract

A large number of complex systems find a natural abstraction in the form of weighted networks whose nodes represent the elements of the system and the weighted edges identify the presence of an interaction and its relative strength. In recent years, the study of an increasing number of large scale networks has highlighted the statistical heterogeneity of their interaction pattern, with degree and weight distributions which vary over many orders of magnitude. These features, along with the large number of elements and links, make the extraction of the truly relevant connections forming the network's backbone a very challenging problem. More specifically, coarse-graining approaches and filtering techniques are at struggle with the multiscale nature of large scale systems. Here we define a filtering method that offers a practical procedure to extract the relevant connection backbone in complex multiscale networks, preserving the edges that represent statistical significant deviations with respect to a null model for the local assignment of weights to edges. An important aspect of the method is that it does not belittle small-scale interactions and operates at all scales defined by the weight distribution. We apply our method to real world network instances and compare the obtained results with alternative backbone extraction techniques.

Published

2009

8. Curvature and temperature of complex networks

Author

Krioukov, Dmitri, Papadopoulos, Fragkiskos, Vahdat, Amin, and Boguna, Marian

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Disordered Systems and Neural Networks, Computer Science - Networking and Internet Architecture, Physics - Physics and Society

Abstract

We show that heterogeneous degree distributions in observed scale-free topologies of complex networks can emerge as a consequence of the exponential expansion of hidden hyperbolic space. Fermi-Dirac statistics provides a physical interpretation of hyperbolic distances as energies of links. The hidden space curvature affects the heterogeneity of the degree distribution, while clustering is a function of temperature. We embed the Internet into the hyperbolic plane, and find a remarkable congruency between the embedding and our hyperbolic model. Besides proving our model realistic, this embedding may be used for routing with only local information, which holds significant promise for improving the performance of Internet routing.

Published

2009

9. Navigating ultrasmall worlds in ultrashort time

Author

Boguna, Marian and Krioukov, Dmitri

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Computer Science - Networking and Internet Architecture, Physics - Physics and Society

Abstract

Random scale-free networks are ultrasmall worlds. The average length of the shortest paths in networks of size N scales as lnlnN. Here we show that these ultrasmall worlds can be navigated in ultrashort time. Greedy routing on scale-free networks embedded in metric spaces finds paths with the average length scaling also as lnlnN. Greedy routing uses only local information to navigate a network. Nevertheless, it finds asymptotically the shortest paths, a direct computation of which requires global topology knowledge. Our findings imply that the peculiar structure of complex networks ensures that the lack of global topological awareness has asymptotically no impact on the length of communication paths. These results have important consequences for communication systems such as the Internet, where maintaining knowledge of current topology is a major scalability bottleneck., Comment: 4 pages, 2 figures

Published

2008

10. Greedy Forwarding in Dynamic Scale-Free Networks Embedded in Hyperbolic Metric Spaces

Author

Papadopoulos, Fragkiskos, Krioukov, Dmitri, Boguna, Marian, and Vahdat, Amin

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Disordered Systems and Neural Networks, Computer Science - Networking and Internet Architecture, Physics - Physics and Society

Abstract

We show that complex (scale-free) network topologies naturally emerge from hyperbolic metric spaces. Hyperbolic geometry facilitates maximally efficient greedy forwarding in these networks. Greedy forwarding is topology-oblivious. Nevertheless, greedy packets find their destinations with 100% probability following almost optimal shortest paths. This remarkable efficiency sustains even in highly dynamic networks. Our findings suggest that forwarding information through complex networks, such as the Internet, is possible without the overhead of existing routing protocols, and may also find practical applications in overlay networks for tasks such as application-level routing, information sharing, and data distribution.

Published

2008

11. Self-similarity of complex networks and hidden metric spaces

Author

Serrano, M. Angeles, Krioukov, Dmitri, and Boguna, Marian

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Computer Science - Networking and Internet Architecture, Physics - Physics and Society

Abstract

We demonstrate that the self-similarity of some scale-free networks with respect to a simple degree-thresholding renormalization scheme finds a natural interpretation in the assumption that network nodes exist in hidden metric spaces. Clustering, i.e., cycles of length three, plays a crucial role in this framework as a topological reflection of the triangle inequality in the hidden geometry. We prove that a class of hidden variable models with underlying metric spaces are able to accurately reproduce the self-similarity properties that we measured in the real networks. Our findings indicate that hidden geometries underlying these real networks are a plausible explanation for their observed topologies and, in particular, for their self-similarity with respect to the degree-based renormalization.

Published

2007

12. Navigability of Complex Networks

Author

Boguna, Marian, Krioukov, Dmitri, and claffy, kc

Subjects

Physics - Physics and Society, Condensed Matter - Disordered Systems and Neural Networks, Computer Science - Networking and Internet Architecture

Abstract

Routing information through networks is a universal phenomenon in both natural and manmade complex systems. When each node has full knowledge of the global network connectivity, finding short communication paths is merely a matter of distributed computation. However, in many real networks nodes communicate efficiently even without such global intelligence. Here we show that the peculiar structural characteristics of many complex networks support efficient communication without global knowledge. We also describe a general mechanism that explains this connection between network structure and function. This mechanism relies on the presence of a metric space hidden behind an observable network. Our findings suggest that real networks in nature have underlying metric spaces that remain undiscovered. Their discovery would have practical applications ranging from routing in the Internet and searching social networks, to studying information flows in neural, gene regulatory networks, or signaling pathways.

Published

2007

13. Decoding the structure of the WWW: facts versus sampling biases

Author

Serrano, M. Angeles, Maguitman, Ana, Boguna, Marian, Fortunato, Santo, and Vespignani, Alessandro

Subjects

Computer Science - Networking and Internet Architecture, Condensed Matter - Disordered Systems and Neural Networks, Physics - Physics and Society, H.4.m, G.3

Abstract

The understanding of the immense and intricate topological structure of the World Wide Web (WWW) is a major scientific and technological challenge. This has been tackled recently by characterizing the properties of its representative graphs in which vertices and directed edges are identified with web-pages and hyperlinks, respectively. Data gathered in large scale crawls have been analyzed by several groups resulting in a general picture of the WWW that encompasses many of the complex properties typical of rapidly evolving networks. In this paper, we report a detailed statistical analysis of the topological properties of four different WWW graphs obtained with different crawlers. We find that, despite the very large size of the samples, the statistical measures characterizing these graphs differ quantitatively, and in some cases qualitatively, depending on the domain analyzed and the crawl used for gathering the data. This spurs the issue of the presence of sampling biases and structural differences of Web crawls that might induce properties not representative of the actual global underlying graph. In order to provide a more accurate characterization of the Web graph and identify observables which are clearly discriminating with respect to the sampling process, we study the behavior of degree-degree correlation functions and the statistics of reciprocal connections. The latter appears to enclose the relevant correlations of the WWW graph and carry most of the topological information of theWeb. The analysis of this quantity is also of major interest in relation to the navigability and searchability of the Web., Comment: 10 pages 19 figures. Values in Table 2 and Figure 1 corrected. Figure 7 updated. Minor changes in the text

Published

2005

14. Competition and adaptation in an Internet evolution model

Author

Serrano, M. Angeles, Boguna, Marian, and Diaz-Guilera, Albert

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Computer Science - Networking and Internet Architecture

Abstract

We model the evolution of the Internet at the Autonomous System level as a process of competition for users and adaptation of bandwidth capability. We find the exponent of the degree distribution as a simple function of the growth rates of the number of autonomous systems and the total number of connections in the Internet, both empirically measurable quantities. This fact place our model apart from others in which this exponent depends on parameters that need to be adjusted in a model dependent way. Our approach also accounts for a high level of clustering as well as degree-degree correlations, both with the same hierarchical structure present in the real Internet. Further, it also highlights the interplay between bandwidth, connectivity and traffic of the network., Comment: Minor content changes and inset of fig.2

Published

2004