A novel derivative search political optimization algorithm for multi-area economic dispatch incorporating renewable energy.

Multi-area economic dispatch (MAED) incorporating renewable energy has become an important issue in the power system optimization. Existing intelligent optimization algorithms often suffer from poor solution accuracy or slow convergence when dealing with MAED problems. In this paper, a novel derivative search-based political optimization (DSPO) algorithm is proposed to handle the MAED problem incorporating renewable energy including wind and solar energy. In the renewable energy modeling, the Weibull and log-normal probability density functions are used to calculate available wind and solar power respectively. In order to improve the search performance, DSPO adopts two strategies: leader guide strategy and derivative search mechanism. The former adds the leader's global optimal information which can direct candidate solutions to more promising regions and speed up convergence. The latter derives neighborhood solutions around some high-quality solutions to improve the exploitation ability. The DSPO algorithm is applied to solve four MAED problems which take into account valve point effect, prohibited operating zone, power loss and so on. The simulation results show that the DSPO algorithm achieves the overall best results in terms of convergence speed, solution accuracy and stability when compared with several well-established algorithms. • Multi-area economic dispatch with wind and solar energy (MAEDWS) is studied. • Novel derivative search political optimization (DSPO) algorithm is developed. • A leader guide strategy and a derivative-search mechanism are embedded into DSPO. • DSPO achieves the best results regarding convergence, accuracy and stability. [ABSTRACT FROM AUTHOR]