Emission-constrained Dynamic Economic Dispatch using Opposition-based Self-adaptive Differential Evolution Algorithm
Abstract
This paper presents an opposition-based self-adaptive differential evolution algorithm for emission-constrained dynamic economic dispatch (ECDED) problem with non-smooth fuel cost and emission level functions. ECDED is an optimization problem with an objective to determine optimal combination of power outputs for all committed generating units over a certain period of time in order to minimize the total fuel cost and emission while satisfying dynamic operational constraints and load demand in each interval. A multi-objective function is formulated by assigning the relative weight to each of the objective and then optimized by opposition-based self-adaptive differential evolution algorithm. The convergence rate of differential evolution is improved by employing opposition-based learning scheme and a self-adaptive procedure for control parameter settings. The validity and effectiveness of the proposed approach is demonstrated by a test system with five thermal generating units. The simulation results show that the proposed approach provides a higher quality solution with better performance.
Keywords
Differential evolution, emission-constrained dynamic economic dispatch, multi-objective optimization, ramp-rate limits, valve-point effects