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Literature DB >> 23030123

Collective dynamics in sparse networks.

Stefano Luccioli¹, Simona Olmi, Antonio Politi, Alessandro Torcini.

Abstract

The microscopic and macroscopic dynamics of random networks is investigated in the strong-dilution limit (i.e., for sparse networks). By simulating chaotic maps, Stuart-Landau oscillators, and leaky integrate-and-fire neurons, we show that a finite connectivity (of the order of a few tens) is able to sustain a nontrivial collective dynamics even in the thermodynamic limit. Although the network structure implies a nonadditive dynamics, the microscopic evolution is extensive (i.e., the number of active degrees of freedom is proportional to the number of network elements).

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Year: 2012 PMID： 23030123 DOI： 10.1103/PhysRevLett.109.138103

Source DB: PubMed Journal: Phys Rev Lett ISSN： 0031-9007 Impact factor: 9.161

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Cited

9 in total

Collective dynamics in sparse networks.

1. Synchronization of Electrically Coupled Resonate-and-Fire Neurons.

2. Average synaptic activity and neural networks topology: a global inverse problem.

3. Sparse short-distance connections enhance calcium wave propagation in a 3D model of astrocyte networks.

4. Structured chaos shapes spike-response noise entropy in balanced neural networks.

5. Encoding in Balanced Networks: Revisiting Spike Patterns and Chaos in Stimulus-Driven Systems.

6. Weak connections form an infinite number of patterns in the brain.

7. Maintaining extensivity in evolutionary multiplex networks.

8. Structured patterns of activity in pulse-coupled oscillator networks with varied connectivity.

9. Linear stability in networks of pulse-coupled neurons.