Sizing a Hybrid Renewable Energy System by a Coevolutionary Multiobjective Optimization Algorithm

Hybrid renewable energy system (HRES) arises regularly in real life. By optimizing the capacity and running status of the microgrid (MG), HRES can decrease the running cost and improve the efficiency. Such an optimization problem is generally a constrained mixed-integer programming problem, which is usually solved by linear programming method. However, as more and more devices are added into MG, the mathematical model of HRES refers to nonlinear, in which the traditional method is incapable to solve. To address this issue, we first proposed the mathematical model of an HRES. Then, a coevolutionary multiobjective optimization algorithm, termed CMOEA-c, is proposed to handle the nonlinear part and the constraints. By considering the constraints and the objective values simultaneously, CMOEA-c can easily jump out of the local optimal solution and obtain satisfactory results. Experimental results show that, compared to other state-of-the-art methods, the proposed algorithm is competitive in solving HRES problems.

[1]  Tao Zhang,et al.  Localized Weighted Sum Method for Many-Objective Optimization , 2018, IEEE Transactions on Evolutionary Computation.

[2]  Tao Zhang,et al.  Energy Management Model of Charging Station Micro-Grid Considering Random Arrival of Electric Vehicles , 2018, 2018 IEEE International Conference on Energy Internet (ICEI).

[3]  Dirk Thierens,et al.  Exploring trade-offs between target coverage, healthy tissue sparing, and the placement of catheters in HDR brachytherapy for prostate cancer using a novel multi-objective model-based mixed-integer evolutionary algorithm , 2017, GECCO.

[4]  Xunjia Li,et al.  A Knee-Point Driven Multi-objective Evolutionary Algorithm for Flexible Job Shop Scheduling , 2019, 2019 IEEE Symposium Series on Computational Intelligence (SSCI).

[5]  Guohua Wu,et al.  Preference-inspired coevolutionary algorithm with active diversity strategy for multi-objective multi-modal optimization , 2021, Inf. Sci..

[6]  Markus Olhofer,et al.  Test Problems for Large-Scale Multiobjective and Many-Objective Optimization , 2017, IEEE Transactions on Cybernetics.

[7]  Tomoyuki Hiroyasu,et al.  SPEA2+: Improving the Performance of the Strength Pareto Evolutionary Algorithm 2 , 2004, PPSN.

[8]  Marco Laumanns,et al.  SPEA2: Improving the strength pareto evolutionary algorithm , 2001 .

[9]  Qingfu Zhang,et al.  MOEA/D: A Multiobjective Evolutionary Algorithm Based on Decomposition , 2007, IEEE Transactions on Evolutionary Computation.

[10]  Gary G. Yen,et al.  A Multimodal Multiobjective Evolutionary Algorithm Using Two-Archive and Recombination Strategies , 2019, IEEE Transactions on Evolutionary Computation.

[11]  Eckart Zitzler,et al.  Indicator-Based Selection in Multiobjective Search , 2004, PPSN.

[12]  Peter J. Fleming,et al.  Preference-Inspired Coevolutionary Algorithms for Many-Objective Optimization , 2013, IEEE Transactions on Evolutionary Computation.

[13]  Tao Zhang,et al.  Multi-Objective Optimization of Hybrid Renewable Energy System Using an Enhanced Multi-Objective Evolutionary Algorithm , 2017 .

[14]  Ye Tian,et al.  A Decision Variable Clustering-Based Evolutionary Algorithm for Large-Scale Many-Objective Optimization , 2018, IEEE Transactions on Evolutionary Computation.

[15]  Christof Weinhardt,et al.  Designing microgrid energy markets , 2018 .

[16]  Carlos A. Coello Coello,et al.  Evolutionary multi-objective optimization: a historical view of the field , 2006, IEEE Comput. Intell. Mag..