148 research outputs found
Economic networks in and out of equilibrium
Economic and financial networks play a crucial role in various important
processes, including economic integration, globalization, and financial crises.
Of particular interest is understanding whether the temporal evolution of a
real economic network is in a (quasi-)stationary equilibrium, i.e.
characterized by smooth structural changes rather than abrupt transitions.
Smooth changes in quasi-equilibrium networks can be generally controlled for,
and largely predicted, via an appropriate rescaling of structural quantities,
while this is generally not possible for abrupt transitions in non-stationary
networks. Here we study whether real economic networks are in or out of
equilibrium by checking their consistency with quasi-equilibrium
maximum-entropy ensembles of graphs. As illustrative examples, we consider the
International Trade Network (ITN) and the Dutch Interbank Network (DIN). We
show that, despite the globalization process, the ITN is an almost perfect
example of quasi-equilibrium network, while the DIN is clearly an
out-of-equilibrium network undergoing major structural changes and displaying
non-stationary dynamics. Among the out-of-equilibrium properties of the DIN, we
find striking early-warning signals of the interbank crisis of 2008.Comment: Preprint, accepted for SITIS 2013 (http://www.sitis-conf.org/). Final
version to be published by IEEE Computer Society as conference proceeding
Analytical maximum-likelihood method to detect patterns in real networks
In order to detect patterns in real networks, randomized graph ensembles that
preserve only part of the topology of an observed network are systematically
used as fundamental null models. However, their generation is still
problematic. The existing approaches are either computationally demanding and
beyond analytic control, or analytically accessible but highly approximate.
Here we propose a solution to this long-standing problem by introducing an
exact and fast method that allows to obtain expectation values and standard
deviations of any topological property analytically, for any binary, weighted,
directed or undirected network. Remarkably, the time required to obtain the
expectation value of any property is as short as that required to compute the
same property on the single original network. Our method reveals that the null
behavior of various correlation properties is different from what previously
believed, and highly sensitive to the particular network considered. Moreover,
our approach shows that important structural properties (such as the modularity
used in community detection problems) are currently based on incorrect
expressions, and provides the exact quantities that should replace them.Comment: 26 pages, 10 figure
Stationarity, non-stationarity and early warning signals in economic networks
Economic integration, globalization and financial crises represent examples
of processes whose understanding requires the analysis of the underlying
network structure. Of particular interest is establishing whether a real
economic network is in a state of (quasi)stationary equilibrium, i.e.
characterized by smooth structural changes rather than abrupt transitions.
While in the former case the behaviour of the system can be reasonably
controlled and predicted, in the latter case this is generally impossible.
Here, we propose a method to assess whether a real economic network is in a
quasi-stationary state by checking the consistency of its structural evolution
with appropriate quasi-equilibrium maximum-entropy ensembles of graphs. As
illustrative examples, we consider the International Trade Network (ITN) and
the Dutch Interbank Network (DIN). We find that the ITN is an almost perfect
example of quasi-equilibrium network, while the DIN is clearly
out-of-equilibrium. In the latter, the entity of the deviation from
quasi-stationarity contains precious information that allows us to identify
remarkable early warning signals of the interbank crisis of 2008. These early
warning signals involve certain dyadic and triadic topological properties,
including dangerous 'debt loops' with different levels of interbank
reciprocity.Comment: 12 pages, 9 figures. Extended version of the paper "Economic networks
in and out of equilibrium" (arXiv:1309.1875
Exact maximum-likelihood method to detect patterns in real networks
In order to detect patterns in real networks, randomized graph ensembles that preserve only part of the topology of an observed network are systematically used as fundamental null models. However, their generation is still problematic. The existing approaches are either computationally demanding and beyond analytic control, or analytically accessible but highly approximate. Here we propose a solution to this long-standing problem by introducing an exact and fast method that allows to obtain expectation values and standard deviations of any topological property analytically, for any binary, weighted, directed or undirected network. Remarkably, the time required to obtain the expectation value of any property is as short as that required to compute the same property on the single original network. Our method reveals that the null behavior of various correlation properties is different from what previously believed, and highly sensitive to the particular network considered. Moreover, our approach shows that important structural properties (such as the modularity used in community detection problems) are currently based on incorrect expressions, and provides the exact quantities that should replace them.
Tackling information asymmetry in networks: a new entropy-based ranking index
Information is a valuable asset for agents in socio-economic systems, a
significant part of the information being entailed into the very network of
connections between agents. The different interlinkages patterns that agents
establish may, in fact, lead to asymmetries in the knowledge of the network
structure; since this entails a different ability of quantifying relevant
systemic properties (e.g. the risk of financial contagion in a network of
liabilities), agents capable of providing a better estimate of (otherwise)
unaccessible network properties, ultimately have a competitive advantage. In
this paper, we address for the first time the issue of quantifying the
information asymmetry arising from the network topology. To this aim, we define
a novel index - InfoRank - intended to measure the quality of the information
possessed by each node, computing the Shannon entropy of the ensemble
conditioned on the node-specific information. Further, we test the performance
of our novel ranking procedure in terms of the reconstruction accuracy of the
(unaccessible) network structure and show that it outperforms other popular
centrality measures in identifying the "most informative" nodes. Finally, we
discuss the socio-economic implications of network information asymmetry.Comment: 12 pages, 8 figure
Unbiased sampling of network ensembles
Sampling random graphs with given properties is a key step in the analysis of
networks, as random ensembles represent basic null models required to identify
patterns such as communities and motifs. An important requirement is that the
sampling process is unbiased and efficient. The main approaches are
microcanonical, i.e. they sample graphs that match the enforced constraints
exactly. Unfortunately, when applied to strongly heterogeneous networks (like
most real-world examples), the majority of these approaches become biased
and/or time-consuming. Moreover, the algorithms defined in the simplest cases,
such as binary graphs with given degrees, are not easily generalizable to more
complicated ensembles. Here we propose a solution to the problem via the
introduction of a "Maximize and Sample" ("Max & Sam" for short) method to
correctly sample ensembles of networks where the constraints are `soft', i.e.
realized as ensemble averages. Our method is based on exact maximum-entropy
distributions and is therefore unbiased by construction, even for strongly
heterogeneous networks. It is also more computationally efficient than most
microcanonical alternatives. Finally, it works for both binary and weighted
networks with a variety of constraints, including combined degree-strength
sequences and full reciprocity structure, for which no alternative method
exists. Our canonical approach can in principle be turned into an unbiased
microcanonical one, via a restriction to the relevant subset. Importantly, the
analysis of the fluctuations of the constraints suggests that the
microcanonical and canonical versions of all the ensembles considered here are
not equivalent. We show various real-world applications and provide a code
implementing all our algorithms.Comment: MatLab code available at
http://www.mathworks.it/matlabcentral/fileexchange/46912-max-sam-package-zi
Entropy-based approach to missing-links prediction
Link-prediction is an active research field within network theory, aiming at
uncovering missing connections or predicting the emergence of future
relationships from the observed network structure. This paper represents our
contribution to the stream of research concerning missing links prediction.
Here, we propose an entropy-based method to predict a given percentage of
missing links, by identifying them with the most probable non-observed ones.
The probability coefficients are computed by solving opportunely defined
null-models over the accessible network structure. Upon comparing our
likelihood-based, local method with the most popular algorithms over a set of
economic, financial and food networks, we find ours to perform best, as pointed
out by a number of statistical indicators (e.g. the precision, the area under
the ROC curve, etc.). Moreover, the entropy-based formalism adopted in the
present paper allows us to straightforwardly extend the link-prediction
exercise to directed networks as well, thus overcoming one of the main
limitations of current algorithms. The higher accuracy achievable by employing
these methods - together with their larger flexibility - makes them strong
competitors of available link-prediction algorithms
A GDP-driven model for the binary and weighted structure of the International Trade Network
Recent events such as the global financial crisis have renewed the interest
in the topic of economic networks. One of the main channels of shock
propagation among countries is the International Trade Network (ITN). Two
important models for the ITN structure, the classical gravity model of trade
(more popular among economists) and the fitness model (more popular among
networks scientists), are both limited to the characterization of only one
representation of the ITN. The gravity model satisfactorily predicts the volume
of trade between connected countries, but cannot reproduce the observed missing
links (i.e. the topology). On the other hand, the fitness model can
successfully replicate the topology of the ITN, but cannot predict the volumes.
This paper tries to make an important step forward in the unification of those
two frameworks, by proposing a new GDP-driven model which can simultaneously
reproduce the binary and the weighted properties of the ITN. Specifically, we
adopt a maximum-entropy approach where both the degree and the strength of each
node is preserved. We then identify strong nonlinear relationships between the
GDP and the parameters of the model. This ultimately results in a weighted
generalization of the fitness model of trade, where the GDP plays the role of a
`macroeconomic fitness' shaping the binary and the weighted structure of the
ITN simultaneously. Our model mathematically highlights an important asymmetry
in the role of binary and weighted network properties, namely the fact that
binary properties can be inferred without the knowledge of weighted ones, while
the opposite is not true
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