Abstract
A key question in theoretical neuroscience is the relation between the connectivity structure and the collective dynamics of a network of neurons. Here we study the connectivity-dynamics relation as reflected in the distribution of eigenvalues of the covariance matrix of the dynamic fluctuations of the neuronal activities, which is closely related to the network’s Principal Component Analysis (PCA) and the associated effective dimensionality. We consider the spontaneous fluctuations around a steady state in a randomly connected recurrent network of stochastic neurons. An exact analytical expression for the covariance eigenvalue distribution in the large-network limit can be obtained using results from random matrices. The distribution has a finitely supported smooth bulk spectrum and exhibits an approximate power-law tail for coupling matrices near the critical edge. We generalize the results to include connectivity motifs and discuss extensions to Excitatory-Inhibitory networks. The theoretical results are compared with those from finite-size networks and and the effects of temporal and spatial sampling are studied. Preliminary application to whole-brain imaging data is presented. Using simple connectivity models, our work provides theoretical predictions for the covariance spectrum, a fundamental property of recurrent neuronal dynamics, that can be compared with experimental data.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
New results on the outliers due to low rank perturbations (Fig. 5EF, Supplement Fig. S3-5), and preliminary applications to calcium imaging data (Fig. 8); Improved organization and clarity throughout the manuscript