Systemic risk in dynamical networks with stochastic failure criterion

Abstract

Complex non-linear interactions between banks and assets we model by two time-dependent Erdos Renyi network models where each node, representing bank, can invest either to a single asset (model I) or multiple assets (model II). We use dynamical network approach to evaluate the collective financial failure---systemic risk---quantified by the fraction of active nodes. The systemic risk can be calculated over any future time period, divided on sub-periods, where within each sub-period banks may contiguously fail due to links to either (i) assets or (ii) other banks, controlled by two parameters, probability of internal failure p and threshold Th ("solvency" parameter). The systemic risk non-linearly increases with p and decreases with average network degree faster when all assets are equally distributed across banks than if assets are randomly distributed. The more inactive banks each bank can sustain (smaller Th), the smaller the systemic risk---for some Th values in I we report a discontinuity in systemic risk. When contiguous spreading becomes stochastic (ii) controlled by probability p2---a condition for the bank to be solvent (active) is stochastic---the systemic risk decreases with decreasing p2. We analyse asset allocation for the U.S. banks.