Full Length Research Paper
References
| Ahmad R, Kazem M, Hossein K (2010). Modeling of a Hybrid Power System for Economic Analysis and Environmental Impact in HOMER. IEEE. 978-1-4244-6760-0. | ||||
|
Ahmed MAH, Priscilla NJ and Mohd S (2011). Optimal conï¬guration assessment of renewable energy in Malaysia. Renewable Energy. 36:881-888. Crossref |
||||
| Ajay KB, Gupta RA, Rajesh K (2011). Optimization of Hybrid PV/wind Energy System using Meta Particle Swarm Optimization (MPSO). IEEE. 978-1-4244-7882-8. | ||||
|
Alam HM, Manfred D (2010). Hybrid systems for decentralized power generation in Bangladesh. Energy for Sustainable Development. 14:48–55. Crossref |
||||
|
Anvari Moghaddam A, Seifi A, Niknam T, Alizadeh Pahlavani MR (2011). Multiobjective operation management of a renewable MG (micro-grid) with backup micro-turbine/fuel cell/battery hybrid power source. Energy 36:6490-6507. Crossref |
||||
|
Ayong H, Rudi K, Managam R, Yohannes MS, Junaidi M (2013). Techno-economic analysis of photovoltaic/wind hybrid system for onchore/ remote area in Indonesia. Energy 59:652-657. Crossref |
||||
|
Azizipanah-Abarghooee R, Niknam T, Roosta A, Malekpour AR, Zare M (2012). Probabilistic multiobjective wind-thermal economic emission dispatch based on point estimated method. Energy 37:322-335. Crossref |
||||
|
Bahtiyar D (2012). Determination of the optimum hybrid renewable power generating systems for Kavakli campus of Kirklareli University, Turkey. Renewable Sustainable Energy Rev. 16:6183–6190. Crossref |
||||
|
Bekele G, Palm G (2010). Feasibility study for a standalone solar–wind-based hybrid energy system for application in Ethiopia. Appl. Energy. 87(2):487–495. Crossref |
||||
|
Belfkira R, Zhang L, Barakat G (2011). Optimal sizing study of hybrid wind/PV/diesel power generation unit. Solar Energy 85:100-110. Crossref |
||||
|
Belgin ET, Ali YT (2011). Economic analysis of standalone and grid connected hybrid energy systems. Renewable Energy 36:1931-1943. Crossref |
||||
|
Chong L, Xinfeng G, Yuan Z, Chang X, Yan R, Chenguang S, Chunxia Y (2013). Techno-economic feasibility study of autonomus hybrid wind-PV-battery power system for a household in Urumqi, China. Energy 55:263-272. Crossref |
||||
|
Coello CA, Veldhuizen DAV, Lamont GB (2002). Evolutionary algorithms for solving multi-objective problems. New York: Kluwer Academic/Plenum Publishers. Crossref |
||||
|
Colle S, Abreu SL, Ruther R (2004). Economic evaluation and optimisation of hybrid diesel/photovoltaic systems integrated to electricity grid. Solar Energy 76:295–299. Crossref |
||||
| Dalton GJ, Lockington DA and Baldock TE (2009). Feasibility analysis of renewable energy supply options for a grid-connected large hotel. Renewable Energy 34:955–964. | ||||
|
Diaf S, Notton G, Belhamel M, Haddadi M, Louche A (2008). Design and techno-economical optimization for hybrid PV/wind system under various meteorological conditions. Appl. Energy 85(10):968–987. Crossref |
||||
|
Duffo-Lopes R, Bernal- Agustin JL (2008). Multio-bjective design of wind-diesel-hydrogen-battery systems. Renewable Energy 33:2559-2572. Crossref |
||||
|
Duffo-Lopes R, Bernal- Agustin JL (2005). Design and control strategies of PV-Diesel systems using genetic algorithm. Solar Energy 79:33-46. Crossref |
||||
|
Eyad SH (2009). Techno-economic analysis of autonomous hybrid photovoltaic-diesel-battery system. Energy for Sustainable Development. 13:143–150. Crossref |
||||
|
Ekren O, Ekren BY (2010). Size optimization of a PV/wind hybrid energy conversion system with battery storage using simulated annealing. Appl. Energy 87(2):592–598. Crossref |
||||
|
Ekren O, Ekren BY (2008). Size optimization of a PV/wind hybrid energy conversion system with battery storage using response surface methodology. Appl. Energy 85:1086-1101. Crossref |
||||
|
Fleck B, Huot M (2009). Comparative life-cycle assessment of a small wind turbine for residential off-grid use. Renewable Energy 34:2688-2696. Crossref |
||||
|
Guasch D, Silvestre S (2003). Dynamic battery model for photovoltaic applications. Prog Photovoltaics: Res. Appl. 11:193–206. Crossref |
||||
|
Gupta A, Saini RP, Sharma MP (2011). Modelling of hybrid energy system d Part I: Problem formulation and model development. Renewable Energy 36:459-465. Crossref |
||||
|
Hongxing Y, Wei Z, Chengshi L (2009). Optimale design and techno-economic analysis of a hybrid solar-wind power generation system. Appl. Energy 86:163-169. Crossref |
||||
|
Ismail MS, Moghavvemi M, Mahlia TMI (2014). Genetic algorithm based optimization on modeling and design of hybrid renewable energy systems. Energy Convers.Manage. 85:120–130. Crossref |
||||
|
Ismail MS, Moghavvemi M, Mahlia TMI (2013). Techno-economic analysis of an optimized photovoltaic and diesel generator hybrid power system for remote houses in a tropical climate. Energy Conversion and Management. 69:163–173. Crossref |
||||
|
Kanase-Patil AB, Saini RP, Sharma MP (2011). Sizing of integrated renewable energy system based on load profilesand reliability index for the state of Uttarakhand in India. Renewable Energy 36:2809-2821. Crossref |
||||
|
Kalantar M, Mousavi GSM (2010). Dynamic behavior of a stand-alone hybrid power generation system of wind turbine, micro turbine, solar array and battery storage. Appl. Energy 87(10):3051–3064. Crossref |
||||
| Kellogg WD, Nehrir NH, Venkataramanan G, Gerez V (1998). Generation unite sinzing and cost analysis for stand-alone wind, photovoltaïque and hybrid wind/PV systems. IEEE transaction on Energy Convers. 13(1):70-75. | ||||
|
Koutroulis E, Kolokotsa D, Potirakis A, Kalaitzakis K (2006). Methodology for optimal sizing of stand-alone photovoltaic/wind generator systems using genetic algorithms. Solar Energy 80:1072-1088. Crossref |
||||
|
Kyoung-Jun L, Dongsul S, Dong-Wook Y, Han-Kyu C, Hee-Je Kim (2013). Hybrid photovoltaic/diesel greenship operating in standalone and grid-connected mode – Expeimental Investigation. Energy. 49:475-483. Crossref |
||||
| Leyland G (2002). Multi-objective optimization applied to industrial energy problems.188p. These EPFL, n°: 2572 Lausanne. | ||||
|
Mei SN, Chee WT (2012). Assessment of economic viability for PV/wind/diesel hybrid energy system in southern Peninsular Malaysia. Renewable Sustainable Energy Rev. 16:634–647. Crossref |
||||
|
Mir-Akbar H, Hugh C, Christopher S (2011). A feasibility study of hybrid wind power systems for remote communities. Energy Policy 39:877–886. Crossref |
||||
| Mohammad RN, Ali AV, Rasoul AA, Mahshid J (2014). Enhanced gravitational search algorithm for multi-objective distribution feeder reconfiguration considering reliability, loss and operational cost. IET Generation, Transmission & Distribution. 1:55–69. | ||||
|
Mohammad RN, Rasoul AA, Behrouz ZMS, Kayvan G (2013). A novel approach to multi-objective optimal power flow by a new hybrid optimization algorithm considering generator constraints and multi-fuel type. Energy 49:119-136. Crossref |
||||
| Molyneaux A (2002). A practical evolutionary method for the multi-objective optimization of complex integrated energy systems including vehicul drive-trains. These EPFL, n°: 2636, Lausanne. 194 pp. | ||||
|
Mukhtaruddin RNSR, Rahman HA, Hassan MY, Jamian JJ (2015). Optimal hybrid renewable energy design in autonomous system usingIterative-Pareto-Fuzzy technique. Electrical Power Energy Systems. 64:242–249. Crossref |
||||
|
Muyiwa SA, Samuel SP and Olanrewaju MO (2014). Assessment of decentralized hybrid PV solar-diesel power system for applications in Northern part of Nigeria. Energy Sustainable Dev. 19:72–82. Crossref |
||||
|
Ould Bilal B, Ndiaye PA, Kebe CMF, Sambou V, Ndongo M (2012a). Methodology to Size an Optimal Standalone Hybrid Solar-Wind-Battery System using Genetic Algorithm. Int. J. Phys. Sci. 7(18):2647-2655. Crossref |
||||
|
Ould Bilal B, Sambou V, Kebe CMF, Ndiaye PA and Ndongo M (2012b). Methodology to Size an Optimal Stand-Alone PV/wind/diesel/battery System Minimizing the Levelized cost of Energy and the CO2 Emissions. Energy Procedia 14:1636-1647. Crossref |
||||
|
Ould Bilal B, Sambou V, Ndiaye PA, Kebe CMF, Ndongo M (2010). Optimal design of a hybrid Solar-Wind-Battery System using the minimization of the annualized cost system and the minimization of the loss of power supply probability (LPSP). Renewable Energy 35:2388-2390. Crossref |
||||
|
Patrick MM, Sennoga T and Ines SM (2014). Analysis of the cost of reliabkle electricity: A new method for analyzing grid connected solar, diesel and hybrid distributed electricity systems considering an unreliable electric grid with exemples in Uganda. Energy 66:523-534. Crossref |
||||
|
Prabodh B, Vaishalee D (2012). hybrid renewable energy systems for power generation in stand-alone application: A review. Renewable Sustainable Energy Rev. 16:2926-2939. Crossref |
||||
|
Rohit S, Subhes CB (2014). Off-grid electricity generation with renewable energy technologies in India: An application of HOMER. Renewable Energ. 62:388-398. Crossref |
||||
|
Saheb-Koussa D, Haddadi M, Belhamel M (2009). Economic and technical study of a hybrid system (wind–photovoltaic–diesel) for rural electriï¬cation in Algeria. Appl. Energy 86:1024-1030. Crossref |
||||
| Sambou V (2008). Transferts thermiques instationnaires: vres une optimisation de parois de bâtiments. Thèse, PHASE, Université Paul Sabatier. 195 pp. | ||||
|
Sanjoy K, Himangshu RG (2009). A wind–PV-battery hybrid power system at Sitakunda in Bangladesh. Energy Policy. 37:3659–3664. Crossref |
||||
|
Senjyu T, Hayashi D, Yona A, Urasaki N and Funabashi T (2007). Optimal configuration of power generating systems in island with renewable energy. Renewable Energy 32:1917-1933. Crossref |
||||
|
Shen WX (2009). Optimally sizing of solar array and batteriy in a standalone photovoltaic system in Malaysia. Renewable Energy 34:348-352. Crossref |
||||
| Sonntag RE, Borgnakke C, Wylen GJV (2002). Fundamentals of thermodynamics, 6th ed. New York: Wiley. | ||||
|
Suresh-Kumar U, Manoharan PS (2014). Economic analysis of hybrid power systems (PV/diesel) in different climatic zones of Tamil Nadu. Energy Convers. Manage. 80:469–476. Crossref |
||||
|
Yang HX. Burnett L, Weather JL (2003). Data and probability analysis of hybrid photovoltaic–wind power generation systems in Hong Kong. Renewable Energy 28:1813–1824. Crossref |
||||
| Yang HX, Lu L (2004). Study on typical meteorological years and their effect on building energy and renewable energy simulations. ASHRAE Transactions 110(2):424–431. | ||||
|
Yang HX, Lu L, Zhou WA (2007). Novel optimization sizing model for hybrid solar–wind power generation system. Solar Energy 81(1):76–84. Crossref |
||||
|
Yang HX, Zhou W, Lu L, Fang Z (2008). Optimal sizing method for stand-alone hybrid solar-wind system with LPSP technology by using genetic algorithm. Solar Energy 82:354-367. Crossref |
||||
| Zeinab AME, Muhammad FMZ, Kamaruzzaman S, Abass AA (2012). Design and performance of photovoltaic power system as a renewable energy source for residential in Khartoum. Int. J. Phys. Sci. 7(25):4036-4042. | ||||
|
Zhou W, Lou C, Li Z, Lu L, Yang H (2010). Current status of research on optimum sizing of stand-alone hybrid solar–wind power generation systems. Appl. Energy 87:380–389. Crossref |
||||
Copyright © 2024 Author(s) retain the copyright of this article.
This article is published under the terms of the Creative Commons Attribution License 4.0
