Energy Conversion and Management, Vol.59, 9-18, 2012
Decision tree ensembles for online operation of large smart grids
Smart grids utilise omnidirectional data transfer to operate a network of energy resources. Associated technologies present operators with greater control over system elements and more detailed information on the system state. While these features may improve the theoretical optimal operating performance, determining the optimal operating strategy becomes more difficult. In this paper, we show how a decision tree ensemble or 'forest' can produce a near-optimal control strategy in real time. The approach substitutes the decision forest for the simulation-optimisation sub-routine commonly employed in receding horizon controllers. The method is demonstrated on a small and a large network, and compared to controllers employing particle swarm optimisation and evolutionary strategies. For the smaller network the proposed method performs comparably in terms of total energy usage, but delivers a greater demand deficit. On the larger network the proposed method is superior with respect to all measures. We conclude that the method is useful when the time required to evaluate possible strategies via simulation is high. (C) 2012 Elsevier Ltd. All rights reserved.
Keywords:Smart grids;Optimization;Particle swarm optimization;Optimal scheduling;Machine learning;Decision trees;Receding horizon;Optimal control