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Water Resources Management
Erschienen in: Water Resources Management 12/2019

05.11.2019

Optimizing Multiple Linear Rules for Multi-Reservoir Hydropower Systems Using an Optimization Method with an Adaptation Strategy

verfasst von: Iman Ahmadianfar, Omid Bozorg-Haddad, Xuefeng Chu

Erschienen in: Water Resources Management | Ausgabe 12/2019

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Abstract

Water resources crisis has a significant impact on hydropower energy production, which highlights the importance of water resources management. Reservoirs are effective and powerful systems to manage water resources. Due to the growing water demands and the limited water resources, optimizing these systems to maximize the production of hydropower energy is an essential task. In this study, an effective differential evolution (DE) algorithm with mutation strategy adaptation (MSA-DE) is developed to promote the local and global search capabilities in a feasible domain. In addition, an elitist strategy is applied to escape local optimum trap. In the present study, the MSA-DE algorithm was applied to optimize the multiple linear rules for two multi-reservoir operation systems (3- and 4-reservoir systems) in Iran. In the 3-reservoir system, the best objective function value in 10 runs was 123.57 for the MSA-DE, while the corresponding values for the DE, artificial bee colony (ABC), and genetic algorithm (GA) were 126.42, 147.38, and 126.68, respectively. For the 4-reservoir system, the best objective function values for the MSA-DE, DE, ABC, and GA were 130.50, 159.75, 174.41, and 140.63, respectively. The results demonstrated that the MSA-DE algorithm can be used to derive optimal operating rules for multi-reservoir systems by enhancing appropriate solutions, while it still preserves the accuracy and efficiency of the solutions.
Vorheriger Artikel Quantile Regression Based Methods for Investigating Rainfall Trends Associated with Flooding and Drought Conditions
Nächster Artikel Process-based Analysis of the Climate Change Impacts on Primary Hydro-Salinity of the River Ecosystems

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Literatur
Afshar A, Emami Skardi MJ, Masoumi F (2015) Optimizing water supply and hydropower reservoir operation rule curves: an imperialist competitive algorithm approach. Eng Optim 47:1208–1225CrossRef
Ahmadi Najl A, Haghighi A, Mohammadvali-Samani H (2016) Simultaneous optimization of operating rules and rule curves for multireservoir systems using a self-adaptive simulation-GA model. J Water Resour Plan Manag 142:04016041CrossRef
Ahmadianfar I, Adib A, Salarijazi M (2015) Optimizing multireservoir operation: Hybrid of bat algorithm and differential evolution. J Water Resour Plan Manag 142:05015010CrossRef
Barros MT, Tsai FT, Yang S-L, Lopes JE, Yeh WW (2003) Optimization of large-scale hydropower system operations. J Water Resour Plan Manag 129:178–188CrossRef
Bellman R (1954) The theory of dynamic programming. RAND Corp, Santa MonicaCrossRef
Bozorg-Haddad O, Afshar A, Mariño MA (2008) Design-operation of multi-hydropower reservoirs: HBMO approach. Water Resour Manag 22:1709–1722CrossRef
Bozorg-Haddad O, Hosseini-Moghari S-M, Loáiciga HA (2015) Biogeography-based optimization algorithm for optimal operation of reservoir systems. J Water Resour Plan Manag 142:04015034CrossRef
Bozorg-Haddad O, Janbaz M, Loáiciga HA (2016) Application of the gravity search algorithm to multi-reservoir operation optimization. Adv Water Resour 98:173–185CrossRef
Cervellera C, Chen VC, Wen A (2006) Optimization of a large-scale water reservoir network by stochastic dynamic programming with efficient state space discretization. Eur J Oper Res 171:1139–1151CrossRef
Dai C, Cai Y, Lu W, Liu H, Guo H (2016) Conjunctive water use optimization for watershed-Lake water distribution system under uncertainty: a case study. Water Resour Manag 30:4429–4449CrossRef
Ehteram M, Karami H, Mousavi SF, Farzin S, Celeste AB, Shafie A-E (2018) Reservoir operation by a new evolutionary algorithm: Kidney algorithm. Water Resour Manag 32:4681–4706CrossRef
Fan H-Y, Lampinen J (2003) A trigonometric mutation operation to differential evolution. J Glob Optim 27:105–129CrossRef
Hakimi-Asiabar M, Seyyed HG, Reza K (2010) Deriving operating policies for multi-objective reservoir systems: application of self-learning genetic algorithm. Applied Soft Computing 10.4(2010):1151–1163CrossRef
He D, Wang F, Mao Z (2008) A hybrid genetic algorithm approach based on differential evolution for economic dispatch with valve-point effect. Int J Electr Power Energy Syst 30:31–38CrossRef
Hınçal O, Altan-Sakarya AB, Ger AM (2011) Optimization of multireservoir systems by genetic algorithm. Water Resour Manag 25:1465–1487CrossRef
Hossain MS, El-Shafie A (2013) Intelligent systems in optimizing reservoir operation policy: a review. Water Resour Manag 27:3387–3407CrossRef
Jabr RA, Coonick AH, Cory BJ (2000) A homogeneous linear programming algorithm for the security constrained economic dispatch problem. IEEE Trans Power Syst 15:930–936CrossRef
Karaboga D, Basturk B (2007) A powerful and efficient algorithm for numerical function optimization: artificial bee colony (ABC) algorithm. J Glob Optim 39:459–471CrossRef
Karamouz M, Houck MH, Delleur JW (1992) Optimization and simulation of multiple reservoir systems. J Water Resour Plan Manag 118:71–81CrossRef
Lin C, Qing A, Feng Q (2011) A comparative study of crossover in differential evolution. J Heuristics 17:675–703CrossRef
Moravej M, Hosseini-Moghari S-M (2016) Large scale reservoirs system operation optimization: the interior search algorithm (ISA) approach. Water Resour Manag 30:3389–3407CrossRef
Pandit M, Srivastava L, Pal K (2013) Static/dynamic optimal dispatch of energy and reserve using recurrent differential evolution. IET Gener Transm Distrib 7:1401–1414CrossRef
Puterman ML (1994) Markov Decision Processes. J. Wiley and Sons, HobokenCrossRef
Samadi-koucheksaraee, A., Ahmadianfar, I., Bozorg-Haddad, O., & Asghari-pari, S. A. (2019). Gradient Evolution Optimization Algorithm to Optimize Reservoir Operation Systems. Water resources management, 33, 603-625
Sayah S, Zehar K (2008) Modified differential evolution algorithm for optimal power flow with non-smooth cost functions. Energy Convers Manag 49:3036–3042CrossRef
Sharif M, Wardlaw R (2000) Multireservoir systems optimization using genetic algorithms: case study. J Comput Civ Eng
Storn R, Price K (1995) Differential evolution-a simple and efficient adaptive scheme for global optimization over continuous spaces. ICSI Berkeley, Berkeley
Taghian M, Ahmadianfar I (2018) Maximizing the Firm Energy Yield Preserving Total Energy Generation Via an Optimal Reservoir Operation. Water Resour Manag 32:141–154CrossRef
Takriti S, Krasenbrink B (1999) A decomposition approach for the fuel-constrained economic power-dispatch problem. Eur J Oper Res 112:460–466CrossRef
Xin B, Chen J, Zhang J, Fang H, Peng Z-H (2012) Hybridizing differential evolution and particle swarm optimization to design powerful optimizers: a review and taxonomy. IEEE Transactions on Systems, Man, and Cybernetics. Part C (Applications and Reviews) 42:744–767
Yang Z, Liu P, Cheng L, Wang H, Ming B, Gong W (2018) Deriving operating rules for a large-scale hydro-photovoltaic power system using implicit stochastic optimization. J Clean Prod
Yazdi J, Moridi A (2018) Multi-Objective Differential Evolution for Design of Cascade Hydropower Reservoir Systems. Water Resour Manag 32:4779–4791CrossRef
Yeh WWG (1985) Reservoir management and operations models: A state-of-the-art review. Water Resour Res 21:1797–1818CrossRef
Zhang R, Zhou J, Ouyang S, Wang X, Zhang H (2013) Optimal operation of multi-reservoir system by multi-elite guide particle swarm optimization. Int J Electr Power Energy Syst 48:58–68CrossRef
Zhao T, Zhao J, Yang D (2012) Improved dynamic programming for hydropower reservoir operation. J Water Resour Plan Manag 140:365–374CrossRef
Metadaten
Titel
Optimizing Multiple Linear Rules for Multi-Reservoir Hydropower Systems Using an Optimization Method with an Adaptation Strategy
verfasst von
Iman Ahmadianfar
Omid Bozorg-Haddad
Xuefeng Chu
Publikationsdatum
05.11.2019
Verlag
Springer Netherlands
Erschienen in
Water Resources Management / Ausgabe 12/2019
Print ISSN: 0920-4741
Elektronische ISSN: 1573-1650
DOI
https://doi.org/10.1007/s11269-019-02364-y

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