{ "id": "1111.1475", "version": "v1", "published": "2011-11-07T03:07:21.000Z", "updated": "2011-11-07T03:07:21.000Z", "title": "Zero forcing, linear and quantum controllability for systems evolving on networks", "authors": [ "Daniel Burgarth", "Domenico D'Alessandro", "Leslie Hogben", "Simone Severini", "Michael Young" ], "comment": "12 pages, 1 figure", "journal": "IEEE Transactions on Automatic Control 58, 2349 (2013)", "doi": "10.1109/TAC.2013.2250075", "categories": [ "quant-ph", "cond-mat.dis-nn", "cond-mat.stat-mech", "math.CO" ], "abstract": "We study the dynamics of systems on networks from a linear algebraic perspective. The control theoretic concept of controllability describes the set of states that can be reached for these systems. Under appropriate conditions, there is a connection between the quantum (Lie theoretic) property of controllability and the linear systems (Kalman) controllability condition. We investigate how the graph theoretic concept of a zero forcing set impacts the controllability property. In particular, we prove that if a set of vertices is a zero forcing set, the associated dynamical system is controllable. The results open up the possibility of further exploiting the analogy between networks, linear control systems theory, and quantum systems Lie algebraic theory. This study is motivated by several quantum systems currently under study, including continuous quantum walks modeling transport phenomena. Additionally, it proposes zero forcing as a new notion in the analysis of complex networks.", "revisions": [ { "version": "v1", "updated": "2011-11-07T03:07:21.000Z" } ], "analyses": { "keywords": [ "quantum controllability", "systems evolving", "zero forcing set", "quantum systems lie algebraic theory", "theoretic concept" ], "tags": [ "journal article" ], "note": { "typesetting": "TeX", "pages": 12, "language": "en", "license": "arXiv", "status": "editable", "adsabs": "2011arXiv1111.1475B" } } }