Title :
Optimal Solution Stability in Dynamic, Distributed Constraint Optimization
Author :
Petcu, Adrian ; Faltings, Boi
Author_Institution :
EPFL, Lausanne
Abstract :
We define the distributed, continuous-time combinatorial optimization problem. We propose a new notion of solution stability in dynamic optimization, based on the cost of change from an already-implemented solution to the new one. Change costs are modeled with stability constraints, and can evolve over time. We present RSDPOP, a self-stabilizing optimization algorithm which guarantees optimal solution stability in dynamic environments, based on this definition. In contrast to current approaches which solve sequences of static CSPs, our mechanism has a lot more flexibility: each variable can be assigned and reassigned its own commitment deadlines at any point in time. Therefore, the optimization process is continuous, rather than a sequence of solving problem snapshots. We present experimental results from the distributed meeting scheduling domain.
Keywords :
combinatorial mathematics; constraint theory; optimisation; stability; commitment deadline; continuous-time combinatorial optimization; distributed meeting scheduling; dynamic distributed constraint optimization; dynamic environment; optimal solution stability; self-stabilizing optimization algorithm; stability constraint; Application software; Constraint optimization; Cost function; Dynamic scheduling; Fuels; Intelligent agent; Mission critical systems; Multimedia systems; Stability; Vehicle dynamics;
Conference_Titel :
Intelligent Agent Technology, 2007. IAT '07. IEEE/WIC/ACM International Conference on
Conference_Location :
Fremont, CA
Print_ISBN :
978-0-7695-3027-7
DOI :
10.1109/IAT.2007.11
