An indicator preselection based evolutionary algorithm with auxiliary angle selection for many-objective optimization

TL;DR: This paper proposes CEEA, a many-objective evolutionary algorithm that balances convergence and diversity through a cascading elimination mechanism and variable classification mutation, outperforming peers on various benchmark test suites and real-world applications.

TL;DR: This paper proposes MaOEA/LSD-DD, a many-objective evolutionary algorithm that balances convergence and diversity through dynamic decomposition and local shifted density estimation, outperforming six existing algorithms on 28 benchmark problems and a practical water resource planning problem.

TL;DR: A space sampling based large-scale many-objective evolutionary algorithm (LSMaOEA) is proposed to address the challenges of large-scale multiobjective optimization problems, especially many-objective problems. LSMaOEA alleviates excessively dense sampling at boundaries and improves the diversity of existing space sampling based algorithms.

TL;DR: Experimental results have demonstrated that MOEA/D with simple decomposition methods outperforms or performs similarly to MOGLS and NSGA-II on multiobjective 0-1 knapsack problems and continuous multiobjectives optimization problems.

TL;DR: The proof-of-principle results obtained on two artificial problems as well as a larger problem, the synthesis of a digital hardware-software multiprocessor system, suggest that SPEA can be very effective in sampling from along the entire Pareto-optimal front and distributing the generated solutions over the tradeoff surface.

TL;DR: A reference-point-based many-objective evolutionary algorithm that emphasizes population members that are nondominated, yet close to a set of supplied reference points is suggested that is found to produce satisfactory results on all problems considered in this paper.

TL;DR: In this paper, an alternate method for finding several Pareto optimal points for a general nonlinear multicriteria optimization problem is proposed, which can handle more than two objectives while retaining the computational efficiency of continuation-type algorithms.