826 research outputs found
Multilevel compression of random walks on networks reveals hierarchical organization in large integrated systems
To comprehend the hierarchical organization of large integrated systems, we
introduce the hierarchical map equation, which reveals multilevel structures in
networks. In this information-theoretic approach, we exploit the duality
between compression and pattern detection; by compressing a description of a
random walker as a proxy for real flow on a network, we find regularities in
the network that induce this system-wide flow. Finding the shortest multilevel
description of the random walker therefore gives us the best hierarchical
clustering of the network, the optimal number of levels and modular partition
at each level, with respect to the dynamics on the network. With a novel search
algorithm, we extract and illustrate the rich multilevel organization of
several large social and biological networks. For example, from the global air
traffic network we uncover countries and continents, and from the pattern of
scientific communication we reveal more than 100 scientific fields organized in
four major disciplines: life sciences, physical sciences, ecology and earth
sciences, and social sciences. In general, we find shallow hierarchical
structures in globally interconnected systems, such as neural networks, and
rich multilevel organizations in systems with highly separated regions, such as
road networks.Comment: 11 pages, 5 figures. For associated code, see
http://www.tp.umu.se/~rosvall/code.htm
Navigating Networks with Limited Information
We study navigation with limited information in networks and demonstrate that
many real-world networks have a structure which can be described as favoring
communication at short distance at the cost of constraining communication at
long distance. This feature, which is robust and more evident with limited than
with complete information, reflects both topological and possibly functional
design characteristics. For example, the characteristics of the networks
studied derived from a city and from the Internet are manifested through
modular network designs. We also observe that directed navigation in typical
networks requires remarkably little information on the level of individual
nodes. By studying navigation, or specific signaling, we take a complementary
approach to the common studies of information transfer devoted to broadcasting
of information in studies of virus spreading and the like.Comment: 6 pages, 6 figures. For associated Java applet, see
http://cmol.nbi.dk/models/bit/bit.htm
The map equation
Many real-world networks are so large that we must simplify their structure
before we can extract useful information about the systems they represent. As
the tools for doing these simplifications proliferate within the network
literature, researchers would benefit from some guidelines about which of the
so-called community detection algorithms are most appropriate for the
structures they are studying and the questions they are asking. Here we show
that different methods highlight different aspects of a network's structure and
that the the sort of information that we seek to extract about the system must
guide us in our decision. For example, many community detection algorithms,
including the popular modularity maximization approach, infer module
assignments from an underlying model of the network formation process. However,
we are not always as interested in how a system's network structure was formed,
as we are in how a network's extant structure influences the system's behavior.
To see how structure influences current behavior, we will recognize that links
in a network induce movement across the network and result in system-wide
interdependence. In doing so, we explicitly acknowledge that most networks
carry flow. To highlight and simplify the network structure with respect to
this flow, we use the map equation. We present an intuitive derivation of this
flow-based and information-theoretic method and provide an interactive on-line
application that anyone can use to explore the mechanics of the map equation.
We also describe an algorithm and provide source code to efficiently decompose
large weighted and directed networks based on the map equation.Comment: 9 pages and 3 figures, corrected typos. For associated Flash
application, see http://www.tp.umu.se/~rosvall/livemod/mapequation
Searchability of Networks
We investigate the searchability of complex systems in terms of their
interconnectedness. Associating searchability with the number and size of
branch points along the paths between the nodes, we find that scale-free
networks are relatively difficult to search, and thus that the abundance of
scale-free networks in nature and society may reflect an attempt to protect
local areas in a highly interconnected network from nonrelated communication.
In fact, starting from a random node, real-world networks with higher order
organization like modular or hierarchical structure are even more difficult to
navigate than random scale-free networks. The searchability at the node level
opens the possibility for a generalized hierarchy measure that captures both
the hierarchy in the usual terms of trees as in military structures, and the
intrinsic hierarchical nature of topological hierarchies for scale-free
networks as in the Internet.Comment: 9 pages, 10 figure
Networks and Cities: An Information Perspective
Traffic is constrained by the information involved in locating the receiver
and the physical distance between sender and receiver. We here focus on the
former, and investigate traffic in the perspective of information handling. We
re-plot the road map of cities in terms of the information needed to locate
specific addresses and create information city networks with roads mapped to
nodes and intersections to links between nodes. These networks have the broad
degree distribution found in many other complex networks. The mapping to an
information city network makes it possible to quantify the information
associated with locating specific addresses.Comment: 4 pages, 4 figure
The Architecture of a Novel Weighted Network: Knowledge Network
Networked structure emerged from a wide range of fields such as biological
systems, World Wide Web and technological infrastructure. A deeply insight into
the topological complexity of these networks has been gained. Some works start
to pay attention to the weighted network, like the world-wide airport network
and the collaboration network, where links are not binary, but have
intensities. Here, we construct a novel knowledge network, through which we
take the first step to uncover the topological structure of the knowledge
system. Furthermore, the network is extended to the weighted one by assigning
weights to the edges. Thus, we also investigate the relationship between the
intensity of edges and the topological structure. These results provide a novel
description to understand the hierarchies and organizational principles in
knowledge system, and the interaction between the intensity of edges and
topological structure. This system also provides a good paradigm to study
weighted networks.Comment: 5 figures 11 page
A simple model for self organization of bipartite networks
We suggest a minimalistic model for directed networks and suggest an
application to injection and merging of magnetic field lines. We obtain a
network of connected donor and acceptor vertices with degree distribution
, and with dynamical reconnection events of size occurring
with frequency that scale as . This suggest that the model is in
the same universality class as the model for self organization in the solar
atmosphere suggested by Hughes et al.(PRL {\bf 90} 131101)
Networks and Our Limited Information Horizon
In this paper we quantify our limited information horizon, by measuring the
information necessary to locate specific nodes in a network. To investigate
different ways to overcome this horizon, and the interplay between
communication and topology in social networks, we let agents communicate in a
model society. Thereby they build a perception of the network that they can use
to create strategic links to improve their standing in the network. We observe
a narrow distribution of links when the communication is low and a network with
a broad distribution of links when the communication is high.Comment: 5 pages and 5 figure
Hide and seek on complex networks
Signaling pathways and networks determine the ability to communicate in
systems ranging from living cells to human society. We investigate how the
network structure constrains communication in social-, man-made and biological
networks. We find that human networks of governance and collaboration are
predictable on teat-a-teat level, reflecting well defined pathways, but
globally inefficient. In contrast, the Internet tends to have better overall
communication abilities, more alternative pathways, and is therefore more
robust. Between these extremes the molecular network of Saccharomyces cerevisea
is more similar to the simpler social systems, whereas the pattern of
interactions in the more complex Drosophilia melanogaster, resembles the robust
Internet.Comment: 5 pages, 5 figure
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