Towards an algebra for cascade effects

Author(s)

Adam, Elie M; Dahleh, Munther A; Ozdaglar, Asuman E

Abstract

We introduce a new class of (dynamical) systems that inherently capture cascading effects (viewed as consequential effects) and are naturally amenable to combinations. We develop an axiomatic general theory around those systems, and guide the endeavor towards an understanding of cascading failure. The theory evolves as an interplay of lattices and fixed points, and its results may be instantiated to commonly studied models of cascade effects. We characterize the systems through their fixed points, and equip them with two operators. We uncover properties of the operators, and express global systems through combinations of local systems. We enhance the theory with a notion of failure, and understand the class of shocks inducing a system to failure. We develop a notion of μ-rank to capture the energy of a system, and understand the minimal amount of effort required to fail a system, termed resilience. We deduce a dual notion of fragility and show that the combination of systems sets a limit on the amount of fragility inherited.

Date issued

2017-07

URI

https://hdl.handle.net/1721.1/122977

Department

Massachusetts Institute of Technology. Laboratory for Information and Decision Systems

Journal

Logical Methods in Computer Science

Publisher

Saarbrücken : Int. Fed. of Computational Logic

Citation

Adam, Elie M. et al. "Towards an algebra for cascade effects." Logical Methods in Computer Science 13, 3 (July 2017): 1-31 © The Authors

Version: Final published version

ISSN

1860-5974