Robustness of flow networks against cascading failures under partial load redistribution

Abstract

We study the robustness of flow networks against cascading failures under a partial load redistribution model. In particular, we consider a flow network of N lines with initial loads L1, …, LN and free-spaces (i.e., redundant space) S1, …, SN that are independent and identically distributed with joint distribution PLS(x,y)=P(L ≤ x, S ≤ y). The capacity Ci is the maximum load allowed on line i, and is given by Ci=Li + Si. When a line fails due to overloading, it is removed from the system and (1-)-fraction of the load it was carrying (at the moment of failing) gets redistributed equally among all remaining lines in the system; hence we refer to this as the partial load redistribution model. The rest (i.e., -fraction) of the load is assumed to be lost or absorbed, e.g., due to advanced circuitry disconnecting overloaded power lines or an inter-connected network/material absorbing a fraction of the flow from overloaded lines. We analyze the robustness of this flow network against random attacks that remove a p-fraction of the lines. Our contributions include (i) deriving the final fraction of alive lines n∞(p,) for all p, ∈ (0,1) and confirming the results via extensive simulations; (ii) showing that partial redistribution might lead to (depending on the parameter 0< ≤ 1) the order of transition at the critical attack size p* changing from first to second-order; and (iii) proving analytically that flow networks achieve maximum robustness (quantified by the area ∫01 n∞(p,) dp) when all lines have the same free-space regardless of their initial load. The optimality of equal free-space allocation is also confirmed on real-world data from the UK National Power Grid.