Swarm intelligence
Global Optimization with Polynomials and the Problem of Moments
SIAM Journal on Optimization
Scaling Up Evolutionary Programming Algorithms
EP '98 Proceedings of the 7th International Conference on Evolutionary Programming VII
The Advantages of Evolutionary Computation
Biocomputing and emergent computation: Proceedings of BCEC97
A Note on the Extended Rosenbrock Function
Evolutionary Computation
Design and Analysis of Experiments
Design and Analysis of Experiments
Differential evolution algorithm with strategy adaptation for global numerical optimization
IEEE Transactions on Evolutionary Computation
Differential evolution using a neighborhood-based mutation operator
IEEE Transactions on Evolutionary Computation
Group search optimizer: an optimization algorithm inspired by animal searching behavior
IEEE Transactions on Evolutionary Computation
Self-organizing hierarchical particle swarm optimizer with time-varying acceleration coefficients
IEEE Transactions on Evolutionary Computation
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Group search optimization (GSO) is an efficient algorithm for solving global optimization problems, in which a group of scroungers move to global best member directly causing to premature convergence. In this paper, an improved group search optimization (ISWGSO) is proposed to increase the diversity of scroungers' behavior by introducing small world scheme in complex network. In ISWGSO, each scrounger selects a subset of members as its neighbors according to small world scheme, and evolves with the effects of global best member and local best member within neighbors at each iteration. Since the neighbors of each scrounger increases after each iteration, a dynamic probability scheme is designed to keep small world property of the scroungers. Moreover, factorial design (FD) approach is used to select parameters of ISWGSO for different problems. Some numerical examples show that ISWGSO can obtain a satisfied performance in comparison with six representative algorithms on low and high dimension over 23 benchmark functions. Finally, ISWGSO is applied to train the parameters of neural networks to build a soft sensor model for inferring the outlet ammonia concentration in fertilizer plant.