Details Details PDF BIBTEX RIS Title Distributed active demand response system for peak power reduction through load shifting Journal title Bulletin of the Polish Academy of Sciences Technical Sciences Yearbook 2016 Volume 64 Issue No 4 (Special Section on Civil Engineering – Ongoing Technical Research. Part I) Authors Benysek, G. ; Jarnut, M. ; Werminski, S. ; Bojarski, J. Divisions of PAS Nauki Techniczne Coverage 925-936 Date 2016 Identifier DOI: 10.1515/bpasts-2016-0101 ; ISSN 2300-1917 Source Bulletin of the Polish Academy of Sciences: Technical Sciences; 2016; 64; No 4 (Special Section on Civil Engineering – Ongoing Technical Research. Part I); 925-936 References Costanzo (2012), A system architecture for autonomous demand side load management in smart buildings Smart Grid, IEEE Trans, 3, 2157. ; Korpikiewicz (2014), Capabilities deliver ancillary services provided by decentralized energy generation Energetica, Acta, 70. ; Chen (2014), A distributed direct load control approach for large - scale residential demand response Transactions on Power Systems, IEEE, 29, 2219. ; Stadler (2009), Modelling and evaluation of control schemes for enhancing load shift of electricity demand for cooling devices, Environ Modell Softw, 24, 285, doi.org/10.1016/j.envsoft.2008.07.003 ; Strbac (2008), Demand side management : Benefits and challenges, Energy Policy, 36, 4419, doi.org/10.1016/j.enpol.2008.09.030 ; Vachirasricirikul (2014), Robust lfc in a smart grid with wind power penetration by coordinated v g control and frequency controller Smart Grid, IEEE Trans, 2, 371. ; Sun (2013), Peak load shifting control using different cold thermal energy storage facilities in commercial buildings, review Energy Conv Manag, 71. ; Kot (2009), Possibilities of losses reduction in medium voltage distribution networks by optimal network configuration, Acta Energetica, 43. ; Shayeghi (2009), Load frequency control strategies : A state - of - the - art survey for the researcher, Energy Conv Manag, 50, 344, doi.org/10.1016/j.enconman.2008.09.014 ; Vlot (2013), Economical regulation power through load shifting with smart energy appliances Smart Grid, IEEE Trans, 4, 1705. ; Su (2009), Quantifying the effect of demand response on electricity markets Transactions on Power Systems, IEEE, 24, 1199. ; Moghadam (2014), Vedady Distributed frequency control in smart grids via randomized demand response Smart Grid, IEEE Trans, 5, 2798. ; Zhao (2014), Design and stability of load - side primary frequency control in power systems Control, IEEE Trans Autom, 59, 1177, doi.org/10.1109/TAC.2014.2298140 ; Wang (2015), Load profiling and its application to demand response, review Tsinghua Sci Technol, 20, 117, doi.org/10.1109/TST.2015.7085625 ; Zhang (2013), Distributed smart grid asset control strategies for providing ancillary services rep Pacific Northwest National Laboratory Richland, tech. ; Chen (2013), Uncertainty - aware household appliance scheduling considering dynamic electricity pricing in smart home Smart Grid, IEEE Trans, 4, 932. ; Vivekananthan (2015), Real - time price based home energy management scheduler Transactions on Power Systems, IEEE, 30, 2149. ; Laghari (2014), Abu A new under - frequency load shedding technique based on combination of fixed and random priority of loads for smart grid applications, IEEE Trans Power Syst, 1. ; Hawary (2014), The smart grid state - of - the - art and future trends special issue : The smart grid state - of - the - art and future trends, Electr Power Compo, 4. ; Aunedi (2013), Economic and environmental benefits of dynamic demand in providing frequency regulation Smart Grid, IEEE Trans, 4, 2036. ; Angeli (2012), A stochastic approach to dynamic - demand refrigerator control, IEEE Trans Control Syst Technol, 20, 581, doi.org/10.1109/TCST.2011.2141994