- IUT Repository Home
- →
- Electrical and Electronics Engineering (EEE)
- →
- Thesis
- →
- Undergraduate
- →
- 2021
- →
- View Item
JavaScript is disabled for your browser. Some features of this site may not work without it.
| dc.contributor.author | Kobir, MD. Irteeja | |
| dc.contributor.author | Rahman, MD. Mahfuzur | |
| dc.contributor.author | Hassan, S.M Nahid | |
| dc.date.accessioned | 2022-04-20T06:57:12Z | |
| dc.date.available | 2022-04-20T06:57:12Z | |
| dc.date.issued | 2021-03-30 | |
| dc.identifier.citation | [1] B. A. Hamilton, J. Miller, and B. Renz, “Understanding the benefits of smart grid,” Tech. Rep. DOE/NETL-2010/1413, U.S. Department of Energy, 2010. [2] L.T. Berger and K. Iniewski, Smart Grid—Applications, Communications and Security, John Wiley & Sons, 2012. [3] M. Burns, “NIST SGIP catalog of standards” October 2010, http://collaborate.nist.gov/twiki-sggrid/bin/view/SmartGrid SGIP Catalog of Standards. [4] P. A. Brown, “Power line communications—past present and future” in Proceedings of the International Symposium on Power Line Communications and Its Applications (ISPLC ’99), pp.1–8, September1999. [5] S. Galli, A. Scaglione and Z. Wang, “For the grid and through the grid: the role of power line communications in the smart grid” Proceedings of the IEEE, vol.99, no.6, pp.998– 1027, 2011. [6] The OPEN meter Consortium, “Description of current state-of-the-art of technology and protocols description of state-of-the-art of PLC-based access technology,” European Union Project Deliverable FP7-ICT-2226369, d 2.1 Part 2, Version 2.3, March 2009, http://www.openmeter.com/files/deliverables/OPENMeter%20WP2%20D2.1%20part2 % 20v2.3.pdf. [7] IEEE Communication Society, “Best readings in power line communications” http://www.comsoc.org/best-readings. [8] SMB Smart Grid Strategic Group (SG3) “IEC smart grid standardization roadmap” June 2010, http://www.iec.ch/smart grid/downloads/sg3 roadmap.pdf. [9] ITU Telecommunication Standardization Bureau Policy & Technology watch Division, “Activities in smart grid standardization repository” version 1.0, April 2010, http://www.itu.int/dmspub/itu-t/oth/48/01/T48010000020002PDFE.pdf. 55 [10] DKE German Commission for Electrical, Electronic & Information Technologies of DIN and VDE, “The roadmap-energy/smart grid” April 2010, http://www.eenergy.de/documents/DKE%20Roadmap%20Smartgrid%20230410%20English.pdf. [11] State Grid Corporation of China, “SGCC framework and roadmap for strong and smart grid standards” August 2010, http://collaborate.nist.gov/twiki- sggrid/pub/SmartGrid/SGIPDocumentsandReferencesSGAC/ChinaStateGridFrame work and Roadmap for SG Standards.pdf. [12] International Energy Agency, “Technology roadmap smart grids” April 2011, http://www.iea.org/publications/freepublications/publication/smartgrids roadmap.pdf. [13] National Institute of Standards and Technology (NIST) and U.S. Department of Commerce, “NIST framework and roadmap for smart grid interoperability standards” NIST Draft Publication, Release1.0, January2010. [14] K. Dostert, Powerline Communications, Prentice-Hall,2001. [15] G. Held, Understanding Broadband Over Powerline, CRC Press, 2006. [16] P. Sobotka, R. Taylor and K. Iniewski, “Broadband over power line communications: Home networking, broadband access, and smart power grids” in Internet Networks: Wired, Wireless, and Optical Technologies, K. Iniewski, Ed. Devices, Circuits, and Systems, chapter8, CRC Press, New York, NY, USA, 2009. [17] R. Pighi and R. Raheli, “On multicarrier signal transmission for high- voltage power lines” in Proceedings of the 9th International Symposium on Power Line Communications and Its Applications (ISPLC’05), pp.32–36, Vancouver, Canada, April2005. [18] H. Duckhwa and L. Younghun, “A study on the compound communication network over the high voltage power line for distribution automation system,” in Proceedings of the 2nd International Conference on Information Security and Assurance (ISA’08), pp.410– 414, Busan, Korea, April 2008. [19] R. Aquilu, I.G.J. Pijoan, and G. Sanchez, “High voltage multicarrier spread-spectrum system field test” IEEE Transactions on Power Delivery, vol.24, no.3, pp.1112–1121, 2009. [20] N. Strandberg and N. Sadan, “HV-BPLphase2fieldtestreport” Tech.Rep.DOE/NETL2009/1388, U.S. Department of Energy, 2009. 56 [21] P.A.A.F. Wouters, P.C.J.M. Vander Wielen, J.Veen, P. Wagenaars, and E.F. Wagenaars, “Effect of cable load impedance on coupling schemes for MV power line communication,” IEEE Transactions on Power Delivery, vol.20, no.2, pp.638–645, 2005. [22] R. Benato and R. Caldon, “Application of PLC for the control and the protection of future distribution networks” in Proceedings of the IEEE International Symposium on Power Line Communications and Its Applications (ISPLC’07), pp.499–504, Pisa, Italy, March 2007. [23] A. Cataliotti, A. Daidone, and G. Tin`e, “Power line communication in medium voltage systems: characterization of MV cables” IEEE Transactions on Power Delivery, vol.23, no.4, pp.1896– 1902, 2008. [24] P. Meier, M. Bittner, H. Widmeretal., “Path loss as a function of frequency, distance and network topology for various LV and MV European power line networks” The OPERA Consortium, Project Deliverable, EC/IST FP6 Project no. 507667 D5v0.9, April 2005. [25] A. Rubinstein, F. Rachidi, M. Rubinsteinetal., “EMC guidelines” The OPERA Consortium, IST Integrated Project Deliverable D9v1.1, IST Integrated Project No 026920, October 2008. [26] Broadband Forum, “Next generation broadband access,” White Paper MR-185, Issue: 1, August 2009, http://www.broadband-forum.org/marketing/download. [27] D.E. Nordell, “Communication systems for distribution automation” in Proceedings of the IEEE Transmission and Distribution Conference and Exposition, Bogota, Colombia, April 2008. [28] S. Mak and D. Reed, “TWACS, a new viable two-way automatic communication system for distribution networks. Part I: outbound communication” IEEE Transactions on Power Apparatus and Systems, vol.101, no.8, pp.2941–2949, 1982. [29] S. Mak and T. Moore, “TWACS, a new viable two-way automatic communication system for distribution networks. Part II: inbound communication” IEEE Transactions on Power Apparatus and Systems, vol.103, no.8, pp.2141–2147, 1984. [30] The OPEN meter Consortium, “Open Public Extended Network Metering, Homepage” http://www.openmeter.com/. [31] PRIME Alliance, “Power line related intelligent metering evolution (PRIME)” http://www.prime-alliance.org. [32] ´Electricit´e R´eseau Distribution France, “G3- plc: Open standard for smart grid implementation” http://www.maximintegrated.com/products/powerline/g3-plc/. 57 [33] K. Razazian, M. Umari, A. Kamalizad, V. Loginov, and M. Navid, “G3-PLC specification for powerline communication: Overview, system simulation and field trial results” in Proceedings of the 14th Annual International Symposium on Power Line Communications and its Applications (ISPLC ’10), pp.313–318, Rio de Janeiro, Brazil, March 2010. [34] P. Siohan, A. Zeddam, G. Avriletal., “State of the art, application scenario and specific requirements for PLC” OMEGA, European Union Project Deliverable D3.1 v1.0, IST Integrated Project No ICT-213311, 2008, http://www.ictomega.eu/publications/ deliverables.html. [35] G. Wood and M. Newborough, “Dynamic energy-consumption indicators for domestic appliances: environment, behavior and design” Energy and Buildings, vol.35, no.8, pp.821–841, 2003. [36] International Organization for Standardization, “Building automation and control systems — part5: data communication protocol” international standard ISO 16484-5, 2010. [37] International Organization for Standardization, “Information technology— Home electronic system (HES) architecture—part 3–5: Media and media dependent layers Power line for network-based control of HES class 1” international standard ISO/IEC 14543-3-5, First edition, May2007. [38] International Organization for Standardization, “Interconnection of information technology equipment—Control network protocol—Part 3: Power line channel specification” international standard ISO/IEC149083, Revision11, January 2011. [39] American National Standards Institute/Electronic Industries Association (ANSI/EIA), “Control network power line (PL) channel specification” ANSI/CEA-709.2A, September 2006. [40] L.T. Berger and Moreno-Rodr´ıguez, “Power line communication channel modelling through concatenated IIR-filter elements” Academy Publisher Journal of Communications, vol. 4, no.1, pp.41–51, 2009. [41] S. Galli, “A simplified model for the indoor power line channel” in Proceedings of the IEEE International Symposium on Power Line Communications and its Applications (ISPLC’09), pp.13– 19, Dresden, Germany, April2009. [42] F.J. Ca˜nete Corripio, L.D´ıezdel R´ıo, and J.T. Entrambasaguas Muˇnoz, “A time variant model for indoor powerline channels” in Proceedings of the International Symposium on power Line Communications (ISPLC’01), pp.85–90, Malmo, Sweden, March 2001. 58 [43] F.J. Ca˜nete, L. D´ıez, J.A. Cort˜ns, and J.T. Entrambasaguas, “Broadband modelling of indoor powerline channels,” IEEE Transactions on Consumer Electronics, vol.48, no.1, pp.175–183, 2002. [44] J.A. Cort˜ns, F.J. Ca˜nete, L. D´ıez, and J.T. Entrambasaguas, “Characterization of the cyclic short time variation of indoor power-line channels response” in Proceedings of the International Symposium on Power Line Communications and Its Applications (ISPLC ’05), pp.326–330, Vancouver, Canada, April 2005. [45] F.J. Ca˜nete Corripio, J.A. Cort˜ns Arrabal, L. D´ıezdel R´ıo, and J.T. Entrambasaguas Muˇnoz, “Analysis of the cyclic short-term variation of indoor power line channels” IEEE Journal on Selected Areas in Communications, vol.24, no.7, pp.1327–1338, 2006. [46] M. Zimmermann and K. Dostert, “A multipath model for the power line channel” IEEE Transactions on Communications, vol. 50, no.4, pp.553–559, 2002. [47] M. Babic, M. Hagenau, K. Dostert, and J. Bausch, “Theoretical postulation of PLC channel model” The OPERA Consortium, IST Integrated Project Deliverable D4v2.0, March 2005. [48] H. Liu, J. Song, B. Zhao, and X. Li, “Channel study for medium voltage power networks” in Proceedings of the IEEE International Symposium on Power Line Communications (ISPLC’06), pp.245–250, Orlando, Fla, USA, March 2006. [49] European Telecommunication Standards Institute (ETSI), “Powerline Telecommunications (PLT); MIMOPLT; Part 1: Measurement Methods of MIMOPLT” February 2012. [50] C.R. Paul, Analysis of Multiconductor Transmission Lines, John Wiley & Sons, 1994. [51] T. Magesacher, P. ¨Odling, P.O. B¨orjessonetal., “On the capacity of the copper cable channel using the common mode,” in Proceedings of the IEEE Global Telecommunications Conference, pp.1269–1273, November 2002. [52] T. Sartenaer, Multi user communications over frequencys elective wired channels and applications to the power line access network [Ph.D. thesis], Faculty of Applied Sciences of the Universit´e Catholique de Louvain, Louvain-la-Neuve, Belgium 2004. [53] D. Sabolic, A. Bazant, and R. Malaric, “Signal propagation modeling in power-line communication networks” IEEE Transactions on Power Delivery, vol.20, no.4, pp.2429–2436, 2005. 59 [54] T. Banwell and S. Galli, “A novel approach to the modeling of the indoor power line channel part I: circuit analysis and companion model,” IEEE Transactions on Power Delivery, vol.20, no.2, pp.655–663, 2005. [55] S. Galli and T. Banwell, “A novel approach to the modeling of the indoor power line channel—part II: transfer function and its properties” IEEE Transactions on Power Delivery, vol.20, no.3, pp.1869–1878, 2005. [56] T. Magesacher, P. ¨Odling, P.O. B¨orjesson, and S. Shamai, “Information rate bounds in common-mode aided wireline communications” European Transactions on Telecommunications, vol.17, pp.533–545, 2006. [57] R. Hashmat, P. Pagani, A. Zeddam, and T. Chonave, “MIMO communications for in- home PLC Networks: Measurements and results up to 100 MHz” in Proceedings of the 14th Annual International Symposium on Power Line Communications and its Applications (ISPLC’10), pp.120–124, Rio de Janeiro, Brazil, March 2010. [58] R. Hashmat, P. Pagani, A. Zeddam, and T. Chonave, “A channel model for multiple input multiple output in-home power line networks” in Proceedings of the IEEE International Symposium on Power Line Communications and Its Applications (ISPLC’11), pp.35–41, April 2011. [59] F. Versolatto and A.M. Tonello, “A MIMO PLC random channel generator and capacity analysis,” in Proceedings of the IEEE International Symposium on Power Line Communications and Its Applications (ISPLC’11), pp.66–71, Udine, Italy, April 2011. [60] L.T. Berger, A. Schwager, P. Pagani, and D. Schneider, MIMO Power Line Communications: Narrow and Broadband Standards, EMC, and Advanced Processing, CRC Press, 2013. [61] A. Schwager, W. B¨aschlin, J. Morenoetal., “European MIMO PLC field measurements: overview of the ETSI STF410 campaign & EMI analysis,” in Proceedings of the International Symposium on Power Line Communications and Its Applications (ISPLC’12), Beijing, China, 2012. [62] D. Schneider, A. Schwager, W. Baschlin, and P. Pagani, “European MIMO PLC field measurements: channel analysis,” in Proceedings of the 16th IEEE International Symposium on Power Line Communications and Its Applications (ISPLC’12), pp.304– 309, March 2012. 60 [63] A. Schwager, Power line communications: significant technologies to become ready for integration [Ph.D. thesis], Universit¨ at Duisburg-Essen, Fakult¨atf¨ur Ingenieur wissenschaften, Duisburg Essen, Germany, 2010. [64] A. Schwager, D. Schneider, W. Baschlin, A. Dilly, and J. Speidel, “MIMO PLC: theory, measurements and system setup” in IEEE International Symposium on Power Line Communications and Its Applications (ISPLC’11), pp.48–53, April 2011. [65] M. Zimmermann and K. Dostert, “An analysis of the broadband noise scenario in power-line networks,” in Proceedings of the International Symposium on Power Line Communications and Its Applications (ISPLC’00), pp.131– 138, Limerick, Ireland, April 2000. [66] F.J. Ca˜nete, J.A. Cort˜ns, L. D´ıez, and J.T. Entrambasaguas, “Modeling and evaluation of the indoor power line transmission medium” IEEE Communications Magazine, vol.41, no.4, pp.41–47, 2003. [67] R. Hashmat, P. Pagani, A. Zeddam, and T. Chonavel, “Measurement and analysis of inhome MIMO PLC channel noise,” in Proceedings of the 4th Workshop on Power Line Communications, Boppard, Germany, September 2010. [68] P. Pagani, R. Hashmat, A. Schwager, D. Schneider, and W. Baschlin, “European MIMO PLC field measurements: noise analysis” in Proceedings of the 16th IEEE International Symposium on Power Line Communications and Its Applications (ISPLC’12), pp.310– 315, March 2012. [69] L.T. Berger, “Broadband power line communications” in Convergence of Mobile and Stationary Next Generation Networks, K. Iniewski, Ed., chapter 10, pp. 289–316, John Wiley & Sons, Hoboken, NJ, USA, 2010. [70] A. Schwager, L. Stadelmeier, and M. Zumkeller, “Potential of broadband power line home networking,” in Proceedings of the 2nd IEEE Consumer Communications and Networking Conference (CCNC’05), pp.359–363, January 2005. [71] M. Tlich, P. Pagani, G. Avril et al., “PLC channel characterization and modelling,” OMEGA, European Union Project Deliverable D3.3v1.0, IST Integrated Project No ICT213311, December 2008, http://www.ict-omega.eu/publications/ deliverables.html. [72] European Committee for Electrotechnical Standardization (CENELEC), “Signaling on low-voltage electrical installations in the frequency range 3 kHz to 148, 5 kHz - Part 1: 61 General requirements, frequency bands and electromagnetic disturbances” Standard EN50065-1, September 2010. [73] National Institute of Standards and Technology (NIST), “Priority Action Plan 15 (PAP15): Harmonize Power Line Carrier Standards for Appliance Communications in the Home” Coexistence of narrow band power line communication technologies in the unlicensed FCC band, April 2010, http://www.fcc.gov/encyclopedia/rulesregulations-title-47. [74] L.T. Berger, “Wireline communications in smart grids” in Smart Grid—Applications, Communications and Security, L.T. Berger and K. Iniewski, Eds., chapter 7, John Wiley & Sons, Hoboken, NJ, USA, 2012. [75] FCC, “Title 47 of the code of federal regulations (CFR)” Tech. Rep. 47CFR§15, Federal Communications Commission, 2008, http://www.fcc.gov/encyclopedia/rulesregulations-title-47. [76] Association of Radio Industries and Businesses (ARIB), “Power line communication equipment (10kHz-450kHz)” STD-T84, Ver.1.0, (in Japanese), November 2002, http://www.arib.or.jp/english/html/overview/doc/1STD-T84v10.pdf. [77] Comit´e International Sp´ecial des Perturbations Radio´electriques, “Information technology equipment; Radio disturbance characteristics; Limits and methods of measurement” ICS CISPR, International Standard Norme CISPR22:1997, 1997. [78] Comit´e International Sp´ecial des Perturbations Radio´ electriques, “Specification for radio disturbance and immunity measuring apparatus and methods part 1-1: Radio disturbance and immunity measuring apparatus—Measuring apparatus” 2003. [79] Comit´e International Sp´ecial des Perturbations Radio´ electriques, “Amendment to CISPR 22: Clarification of its application to telecommunication system on the method of disturbance measurement at ports used for PLC” 2003. [80] Comit´e International Sp´ecial des Perturbations Radio´ electriques, “CISPR 22am3f1ed.5.0, Limits and method of measurement of broadband telecommunication equipment over power lines” February 2008. [81] Comit´e International Sp´ecial des Perturbations Radio´ electriques, “Report on mitigation factors and methods for power line telecommunications” February 2008. [82] European Telecommunication Standards Institute (ETSI), “Power Line Telecommunications (PLT); Coexistence between PLT Modems and Short-Wave Radio broadcasting services” August 2008. | en_US |
| dc.identifier.uri | http://hdl.handle.net/123456789/1368 | |
| dc.description | Supervised by Md. Mehedi Hassan Galib Assistant Professor, Department of Electrical and Electronic Engineering, Islamic University of Technology(IUT), Boardbazar, Gazipur -1704. | en_US |
| dc.description.abstract | Although views on the specific technology options for smart grids are still divided, there is agreement that heterogeneous communications networks are best suited. Power line communication (PLC) is promising as it is readily available and aligns with the power distribution network's natural topology. One of the new facts is that the smart grid communication system must be energy efficient. This research uses a cross-layer approach in multiple smart grid settings to discuss the energy efficiency of PLC networks. This work utilizes three phases of data collection works to prove and analyze the probability of efficient network-wide packet delivery. Improving the distribution of packets effectively eliminates waste of energy. This work proposes an energy-efficient multi-carrier modulation scheme OFDM at the physical layer. This thesis work was done by 3 phases of data collection. From these stages, the feasibility of the PLC using OFDM for smart grid has been proved. We have studied PLC networks for energy efficient purpose in the application of Smart Grid. | en_US |
| dc.language.iso | en | en_US |
| dc.publisher | Department of Electrical and Electronic Engineering, Islamic University of Technology (IUT), Board Bazar, Gazipur-1704, Bangladesh | en_US |
| dc.title | Power line communication for smart grid using orthogonal frequency division multiplexing | en_US |
| dc.type | Thesis | en_US |
Files in this item
This item appears in the following Collection(s)
-
2021 [63]