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2021 | OriginalPaper | Buchkapitel

A Comprehensive Review on Wide-Area Protection, Control and Monitoring Systems

verfasst von : Valabhoju Ashok, Anamika Yadav, Almoataz Y. Abdelaziz

Erschienen in: Wide Area Power Systems Stability, Protection, and Security

Verlag: Springer International Publishing

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Abstract

In recent days electrical power system experiencing a rapid change thereby inclusion of advanced equipment and expansion of transmission/distribution network. Besides the modernisation of existing power system network, a number of renewable energy sources such as wind parks and solar parks etc., have been integrated to balance growing power demand due to the industrialization and digitalization. However, a secure and dependable operation of power system network is not so easy because of its complex nature in terms of control, operation and maintenance of various components in wide-area network. Inspite of gigantic developments in power system operations, components and protection technologies, today’s power systems are more susceptible to blackouts than ever before. In this context some of the recorded major blackout incidents have been classified according to the time and location as of research reference purpose. As per the survey the frequency of occurrence of blackouts is increased over time. Practically, it is not possible to avoid blackouts completely; though, various research studies and number of research articles were acknowledged that by taking some rationally gainful measures, incidence of the blackouts could be abated and/or their effects could be mitigated. The forthright approach is to minimize the peril of unplanned disturbances thereby extenuating opportune paradigms to the extent that possible, the root causes of the disturbances through analyses and audits followed by initiating various preventive and corrective actions. In view of the preventive and corrective actions to avoid wide-area disturbances, a new paradigm has been embraced with Wide-Area Protection, Control and Monitoring (WAPCAM) system. With the rapidly growing capabilities in advanced computer and communication technologies such as Intelligent Electronic Devices (IEDs) enabled Remote Terminal Units (RTUs), Global Positioning System (GPS) enabled Phasor Measurement Units (PMUs); opportunities are now being available to adopt the Wide-Area Protection, Control and Monitoring (WAPCAM) system. Such systems receive wide-range of data or information e.g. system-wide bus voltages, angles, active and reactive power flows, etc., and by analysing them, can estimate whether the system is at stressed condition or not. By taking coordinated actions, the power system network can be saved from proceeding to total collapse, or even, mitigate the wide-area disturbance effects upon the system. WAPCAM system has different level of hierarchies in realization of preventive and corrective actions such as local feeder level, sub-station level and central/regional level. One of the recommended preventive plans against the wide-area disturbances and the blackouts is Wide-Area Protection and Control (WAPC) system that includes Special Protection Schemes (SPS) (or) System Integrated Protection Schemes (SIPS) (or) Remedial Action Schemes (RAS) based on an advanced communication infrastructure etc. To mitigate the impact of wide-area disturbances, the remedial/corrective actions have been initiated by implementing Wide-Area Stability and Control (WASC) system that embraces power system stabilizers (PSS) and ON-Load Tap Changers (OLTC) and Wide-Area Monitoring and Control (WAMC) system. It also includes out-of-step (OSS) bus splitting and optimal islanding schemes etc. Although; the power system exhibits unstable dynamic phenomena at stressed conditions such as Transient Angle Instability, Voltage Instability and Frequency Instability, the WAPCAM has to bring back the power system to normal restorative condition as soon as possible. This chapter enlightens a comprehensive research review and explicates different type of WAPCAM systems that can address the major blackouts to improve stability, reliability and security of power system networks. A comparative assessment has been explicated by summarizing various recently reported conventional and intelligent schemes. It also enlightens the research insights to power system researchers and protection engineers while planning and designing of stable, reliable and secured power system networks.

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Nächstes Kapitel Introduction to WAMS and Its Applications for Future Power System
Literatur
1.
A. Guzman, D. Tziouvaras, E.O. Schweitzer, Ken Martin, Local and wide-area network protection systems improve power system reliability, in Power Systems Conference: Advanced Metering, Protection, Control, Communication, and Distributed Resources (2006)
2.
P. Kundur, Power System Stability and Control (1994)
3.
V. Madani, M. Admiak, M. Thakur, Design and implementation of wide area special protection schemes, in 57th Annual Conference for Protective Relay Engineers, 2004, College Station, TX, USA, pp. 392-402
4.
W. Lu, Y. Besanger, E. Zamai, D. Radu, Blackouts: description, analysis and classification, in Proceedings of the 6th WSEAS International Conference on Power Systems, Lisbon, Portugal, 22–24 September 2006
5.
A. Atputharajah, T. Kumar Saha, Power system blackouts-literature review, in 2009 International Conference on Industrial and Information Systems (ICIIS), Sri Lanka, 2009, pp. 460–465
6.
L.C. White, J.A. Carver, L.1 Connor, C.R. Ross., C.E. Bagge, Prevention of power failures, Volume 1- Report of the commission submitted to the President by Federal Power Commission. July 1967
7.
US Department of Energy federal energy regulatory commission, The Con Edison power failure of July 13 and 14, 1977. Final staff report. June 1978
8.
A.Kurita, T. Sakurai, The power system failure on July 23, 1987 in Tokyo, in Proceedings of the 27th IEEE Conference on Decision and Control, Austin, TX, USA, 1988, vol. 3, pp. 2093–2097
9.
T. Ohno, S. Imai, The 1987 Tokyo blackout, in Power Systems Conference and Exposition (2006)
10.
M.Z. El-Sadek, Prevention of repetitive blackouts in the Egyptian power system, in First International conference on Engineering Research, Development and Application ERDA, Port-Said, Egypt, 26–28 November 1992
11.
12.
G. Andersson, P. Donalek, R. Farmer, N. Hatziargriou, I. Kamwa, P. Kundur, N. Martins, J. Paserba, P. Pourbeik, J. Sanchez-Gasca, R. Shulz, A. Stankovic, C. Taylor, V. Vittal, Causes of the 2003 major grid blackouts in North America and Europe and recommended means to improve system dynamic performance. IEEE Trans. Power Syst. 20(4), 1922–1928 (2005). (Nov)CrossRef
13.
U.S.-Canada Power System Outage Task Force, Final Report on the August 14, 2003 Blackout in the United States and Canada: Causes and Recommendations (2004). https://​www.​nerc.​com
14.
S. Larsson, A. Danell, The blackout in southern Sweden and eastern Denmark, September 23, 2003, in IEEE Power Engineering Society General Meeting, Denver, CO, 2004
15.
A. Berizzi, The Italian 2003 blackout, in IEEE Power Engineering Society General Meeting, 2004., Denver, CO, 2004, Vol. 2, pp. 1673–1679
16.
O.P. Veloza, F. Santamaria, Analysis of major blackouts from 2003 to 2015: Classification of incidents and review of main causes. Electr. J. 29, 42–49 (2016)CrossRef
17.
18.
E.C. Portante, S.F. Folga, J.A. Kavicky, L.T. Malone, Simulation of the september 8, 2011, san diego blackout, in Proceedings of the 2014 Winter Simulation Conference (WSC), Savannah, GA USA, 7–10 December 2014, pp. 1527–1538
19.
M. Papic, Pacific southwest blackout on September 8, 2011 at 15: 27, in Proceedings of the IEEE PES General Meeting, Vancouver, BC, Canada, 21–25 July 2013
20.
W. Lin, Y. Tang, H. Sun, Q. Guo, H. Zhao, B. Zeng, Blackout in Brazil power grid on February 4, 2011 and inspirations for stable operation of power grid. Autom. Electr. Power Syst. 35, 1–5 (2011)
21.
S.P. Trung, N. Voropai, The major outage in South Vietnam in 2013: the nature of blackout, security measures and strategy of national power system modernization, in Proceedings of the International Conference on Problems of Critical Infrastructures (ICCIP 2015), Arlington, VA, USA, 16–18 March 2015
22.
H. Haes Alhelou, M.E. Hamedani-Golshan, T. Cuthbert Njenda, P. Siano, A survey on power system blackout and cascading events: research motivations and challenges. Energies 12, 682, 1–28 (2019)
23.
P. Gomes, New strategies to improve bulk power system security: lessons learned from large blackouts, in Proceedings of the 2004 IEEE Power Engineering Society General Meeting, Denver, CO, USA, 6–10 June 2004, pp. 1703–1708
24.
N. Phuangpornpitak, S. Tia, Opportunities and challenges of integrating renewable energy in smart grid system. Energy Procedia 34, 282–290 (2013)CrossRef
25.
M.A. Kabir, M.M.H. Sajeeb, M.N. Islam, A.H. Chowdhury, Frequency transient analysis of countrywide blackout of Bangladesh power system on 1st November, 2014, in Proceedings of the 2015 International Conference on Advances in Electrical Engineering (ICAEE), Dhaka, Bangladesh, 17–19 December 2015, pp. 267–270
26.
M. Xiang, Yu. Dongzhen, W. Wang, J. Zuo, Y. Shen, X. Xie, The Reason analysis of holland blackout on March 27, 2015 and lessons for hunan power grid. J. Clean Energy Technol. 6(3), 263–267 (2018)CrossRef
27.
B. Liu, B. Zhou, D. Jiang, Z. Yu, X. Yang, X. Ma, Distributed accommodation for distributed generation—from the view of power system blackouts, in ICSEE2018/IMIOT2018, CCIS925 (2018), pp. 236–246
28.
L. Baojie, L. Jinbo, L. Hongjie, Analysis of Turkey blackout on March 31 2015 and lessons on China power grid. Proc. CSEE 36, 5788–5795 (2016)
29.
Y. Shao, Y. Tang, J. Yi, A. Wang, Analysis and lessons of blackout in Turkey power grid on March 31, 2015, Autom. Electr. Power Syst. 40, 9–14 (2016)
30.
G. Liang, S.R. Weller, J. Zhao, F. Luo, Z.Y. Dong, The 2015 Ukraine blackout: Implications for false data injection attacks. IEEE Trans. Power Syst. 32, 3317–3318 (2017)CrossRef
31.
E. Miguel, C. Wolfram, K. Lee, Experimental evidence on the demand for and costs of rural electrification (National Bureau of Economic Research, Cambridge, MA, USA, 2016)
32.
J.O. Okumu, A. Hood, Strategic Management Factors Affecting Performance of Thermal Power Generation Companies in Kenya (Elixir Publisher, Tamilnadu State, India, 2017)
33.
T. Bambaravanage, S. Kumarawadu, A. Rodrigo, Comparison of three under-frequency load shedding schemes referring to the power system of Sri Lanka. Eng. J. Inst. Eng. 49, 41–52 (2016)
34.
N. Marikkar, T. Jayath, K. Egodawatta, M. Vierling, M. Aboujaib, D. Sokolov, D. Meskers, R. Russell, M. Moliere, A review of the experience achieved at the Yugadanavi 300 MW CCGT in Sri Lanka: increasing the firing temperature of gas turbines using a novel vanadium inhibitor, in Proceedings of the ASME Turbo Expo 2017: Turbomachinery Technical Conference and Exposition, Charlotte, NC, USA, 26–30 June 2017; American Society of Mechanical Engineers: New York, NY, USA, 2017; p. V003T03A005
35.
R. Yan, N. Al Masood, T.K. Saha, F. Bai, H. Gu, The anatomy of the 2016 South Australia blackout: a catastrophic event in a high renewable network. IEEE Trans. Power Syst. (2018)
36.
A. Lucas, Confected conflict in the wake of the South Australian blackout: diversionary strategies and policy failure in Australia’s energy sector. Energy Res. Soc. Sci. 29, 149–159 (2017)CrossRef
37.
38.
I. Dobson, D.E. Newman, Cascading blackout overall structure and some implications for sampling and mitigation. Int. J. Electr. Power Energy Syst. 86, 29–32 (2017)CrossRef
39.
40.
41.
42.
M.A.A. Osman, Contingency analysis in presence of SVC controller of Sudan national grid for electricity. Ph.D. Thesis, Sudan University of Science and Technology, Khartoum, Sudan (2018)
43.
M.A. Yagoub, Z. Tao, Modelling and mitigation of geomagnetically induced currents (GICs) for single-phase power transformer, in Proceedings of the 2018 International Conference on Computer, Control, Electrical, and Electronics Engineering (ICCCEEE), Khartoum, Sudan, 12–14 August 2018, pp. 1–6
44.
K.E. Mohammed, An intelligent load shedding system application in sudan national grid. Ph.D. Thesis, Sudan University of Science and Technology, Khartoum, Sudan (2018)
45.
46.
J. Hyndle-Hussein, S. Kardas´, K. Kłysin´ski, Troublesome INVESTMent. The Belarusian nuclear power plant in astravyets. OSW Studies 74, July 2018; University of Pittsburgh: Pittsburgh, PA, USA, 2018
47.
S. Carlson, Powerful ties: Eu-turkey energy relations. Turk. Policy Q. 17, 105–115 (2018)
48.
J.D. Hunt, D. Stilpen, M.A.V. de Freitas, A review of the causes, impacts and solutions for electricity supply crises in Brazil. Renew. Sustain. Energy Rev. 88, 208–222 (2018)CrossRef
49.
D. Novosel, M.M. Begovic, V. Madani, Shedding light on blackouts. IEEE Power Energy Mag. 2 (2004)
50.
P. Pourbeik, P.S. Kudnur, C.W. Taylor, The anatomy of a power grid blackout. IEEE Power Energy Mag. 4 (2006)
51.
D. Zhong Meng, Recommendations to prevent power system cascading blackout, in IEEE PES Power Systems Conference and Exposition, New York, NY, 2004, vol. 1, pp. 533–542
52.
P. Kundur, J. Paserba, V. Ajjarapu, G. Anderson, A. Bose, C. Canizares, N. Hatziargyriou, D. Hill, A. Stankovic, C. Taylor, T. Van Cutsem, V. Vittal, Definition and classification of power system stability IEEE/CIGRE joint task force on stability terms and definitions. IEE Trans. Power Syst. 19(3), 1387–1401 (2004)CrossRef
53.
Z.Q. Bo, J.A.S.A.B. Jayasinge, R.K. Aggrawal, Anew Scheme for monitoring and protection of power transmission system based on global positioning system, in Proceeding of the 31st University Power Engineering Conference, Crete, Greece, 1996, pp. 21–24
54.
Z.Q. Bo, G. Weller, T. Lomas, M.A. Redfem, Positional protection of transmission systems using global positioning system. IEEE Trans. Power Deliv. 15(04), 1163–1168 (2000). (Oct)CrossRef
55.
M. Begovic, D. Novosel, D. Karlsson, C. Henville, G. Michel, Wide area protection and emergency control. Proc. IEEE 93(5), 867–891 (2005)CrossRef
56.
D. Yan, Wide-area protection and control system with WAMS based, in Proceeding of International Conference on Power System Technology-2006, 2006, pp. 1–5
57.
Q. Wang, Z. Bo, Y. Zhao, X. Ma, M. Zhang, H. Zheng, L. Wang, Integrated wide-area-protection and control for power grid security. CSEE J. Power Energy Syst. 5(2) (June 2019)
58.
IEEE Standard for Synchrophasor Measurements for Power Systems; IEEE: Piscataway, NJ, USA (2011)
59.
S.T. Mini, J.D. McDonald, Power System SCADA and Smart Grids, 1st edn. (CRC Press, Boca Raton, FL, USA, 2015)
60.
J. Bertsch, C. Carnal, D. Karlsson, J. Mcdaniel, K. Vu, Wide-area protection and power system utilization. Proc. IEEE 93(5), 997–1003 (May 2005)
61.
V. Madani, M. Adamiak, M. Thakur, Design and implementation of wide-area special protection schemes, in 57th Annual Conference for Protective Relay Engineers (1 April 2004), pp. 35–44
62.
X. Yin, Z. Zhang, Z. Li, X. Qi, W. Cao, Q. Guo, The research and the development of the wide-area relaying protection based on fault element identification, in Protection and Control of Modern Power Systems (2016), pp. 1–12
63.
K. Seethalekshmi, S.N. Singh, S.C. Srivastava, Wide-area protection and control: present status and key challenges, in Fifteenth National Power System Conference (NPSC), IIT Bombay, December 2008, pp. 169–175
64.
A.G. Phadke, P. Wall, L. Ding, V. Terzija, Improving the performance of power system protection using wide area monitoring. J. Mod. Power Syst. Clean Energy 4(3), 319–331 (2016)
65.
J. Wen, W.-H. Edwin Liu, P.L. Arons, S.K. Pandey, Evolution pathway towards wide-area monitoring and protection- a real-world implementation of centralized RAS system. IEEE Trans. Smart Grid 5, 1506-1513 (May 2014)
66.
M.A.M. Ariff, B.C. Pal, Adaptive protection and controlling power system for wide-area blackout prevention. IEEE Trans. Power Deliv. 31(4), 1815–18251-10 (Aug 2016)
67.
C. Rehtanz, J. Bertsch, A new wide-area protection system, in 2001 IEEE Porto Power Tech Proceedings, 10–13 Sept 2001, pp. 1–5
68.
I. Ivankovic, I. Kuzle, N. Holjevac, Key performance indices for angle stability protection function in WAMPAC system, in 2018 IEEE Power & Energy Society General Meeting (PESGM), 5–10 Aug 2018, pp. 1–6
69.
M.M. Eissa, A novel centralized wide-area protection “CWAP” in phase portrait based on pilot wire including phase comparison. IEEE Trans. Smart Grid 10(3), 2671–2682 (May 2019)
70.
J. He, L. Liu, W. Li, M. Zhang, Development and research on integrated protection system based on redundant Information analysis. J. Protect. Control Modern Power Syst. 1–13 (2016)
71.
I. Ivankovic, I. Kuzle, N. Holjevac, Wide-area information-based transmission system centralized out-of-step protection scheme. Energies 10, 633 (2017)CrossRef
72.
G. Jurisic, J. Havelka, T. Capuder, S. Sucic, Laboratory test bed for analysing fault detection reaction times of protection relays in different substation topologies. Energies 11(9), 2482, 1–14 (2018)
73.
Z. Zbunjak, I. Kuzle, System Integrity Protection Scheme (SIPS) development and optimal bus splitting scheme supported by Phasor Measurement Units (PMUs). Energies, 1–21 (Sept 2019)
74.
M.-H. Song, S.-H. Kang, N.-H. Lee, S.-R. Nam, IEC 61850_ based centralized busbar differential protection with data desynchronization compensation. Energies, 1–15 (Feb 2020)
75.
J. Won Lee, W.-K. Kim, J. Han, W.-H. Jang, Fault area estimation using travelling wave for wide-area protection. J. Mod. Power Syst. Clean Energy 4(3), 478–486 (2016)
76.
X. Liu, Y. Wang, Hu. Hub, Fault identification algorithm based on zone-division wide-area protection system. J. Eng. Sci. Technol. Rev. 7(2), 80–86 (2014)CrossRef
77.
Z. He, Z. Zhang, W. Chen, O.P. Malik, X. Yin, Wide-area backup protection algorithm based on fault componenet voltage distribution. IEEE Trans. Power Deliv. 26(4) (Oct 2011)
78.
M.S. Srikumar, T. Ananthapadmanbha, F. Zafar Khan, V. Girish, Line outage detection using phasor measurement units. Procedia Technol. 21, 88–95 (2015)
79.
I. Ivankovic, I. Kuzle, N. Holjevac, Multi-functional WAMPAC system concept for out-of-step protection based on syschrophasor. Int. J. Electr. Power Energy 87, 77–88 (2017)CrossRef
80.
Y. Huang, S. Li, X. Liu, Y. Zhang, L. Sun, K. Yang, A probabilistic multi-objective model for phasor measurement units placement in the presence of line outage. Sustainability, 1–12 (Dec 2019)
81.
F. Namdari, S. Jamali, P.A. Crossley, Power differentiation. Iran. J. Electr. Electron. Eng. 1(3), 53–65 (2005)
82.
M.M. Eissa, A new wide-area protection scheme for single and double circuit lines using 3D-phase surface. IEEE Trans. Power Deliv. 33(6), 2613–2623 (Dec 2018)
83.
M. Tamizi Azmi, N. Sofizan Nik Yusuf, Ir., S. Kamar, S. Abdullah, M. Khairun Nizam Mohd Sarmin, N. Saadun, N. Nadia Nor Khairul Azha, Real-time haedware-in-the-loop testing platform for wide-area protection system in large-scale power systems, in IEEE International Conference on Automatic Control and Intelligent Systems (I2CACIS 2019), 29 June 2019, Selangor, Malaysia, pp. 210–215
84.
H.H. Alhelou, M.E. Golshan, N.D. Hatziargyriou, A decentralized functional observer based optimal LFC considering unknown inputs, uncertainties, and cyber-attacks. IEEE Trans. Power Syst. 34(6), 4408–4417 (2019). (May 13)CrossRef
85.
P. Kundu, A.K. Pradhan, Enhanced protection security using system integrity protection scheme (SIPS), in 2016 IEEE Power and Energy Society General Meeting (PESGM), Boston, MA, 17–21 July 2016, pp. 1–1
86.
P. Kundu, A.K. Pradhan, Supervisory protection of islanded network using synchrophasor data. IEEE Trans. Smart Grid 10(2), 1772–1780 (March 2019)
87.
I. Ivankovic, D. Brnobic, S. Skok, I. Sturlic, R. Rubesa, Time delay aspect for basic line protection function with synchrophasor in WAMPAC system, in 2018 IEEE International Energy Conference (ENERGYCON), Limassol, 2018, pp. 1–6
88.
P. Kundu, A.K. Pradhan, Power network protection using wide-area measurements considering uncertainty in data availability. IEEE Syst. J. 12(4), 3358–3368 (Dec 2018)
89.
C.W. Taylor, D.C. Erickson, K.E. Martin, R.E. Wilson, V. Venkatasubramanian, WACS-wide-area stability and voltage control system: R & D and online demonstration. Proc. IEEE 93(5), 892–906 (2005)CrossRef
90.
G. Cai, D. Yang, C. Liu, adaptive wide-area damping control scheme for smart grids with considering of signal time delay. Energies 6, 4841–4858 (2013). (Sept)CrossRef
91.
S. Mirzazad-Barijough, M. Mashhuri, A. M. Ranjbar, A predictive approach to control frequency instabilities in a wide-area system, in 2009 IEEE/PES Power Systems Conference and Exposition, Seattle, WA, 2009, pp. 1–6
92.
M. Larsson, C. Rehtanz, Predictive frequency stability control based on wide-area phasor measurement, in IEEE Power Engineering Society Summer Meeting, July 2002, pp. 233–238
93.
F.G. Velez, V.A. Centeno, A.G. Phadke, Multiple swing transient stability assessment with phasor measurements, in 2017 IEEE Manchester PowerTech (Manchester, 2017), pp. 1–6
94.
H.H. Alhelou, M.H. Golshan, J. Askari-Marnani, Robust sensor fault detection and isolation scheme for interconnected smart power systems in presence of RER and EVs using unknown input observer. Int. J. Electr. Power Energy Syst. 1(99), 682–694 (2018). (Jul)CrossRef
95.
K. Seethalekshmi, S.N. Singh, S.C. Srivastava, A Synchrophasor assisted frequency and voltage stability based load shedding scheme for self-healing of power system. IEEE Trans. Smart Grid 2, 221–230 (June 2011)
96.
H. Li, A. Bose, V. Venkatasubramanian, Wide-area voltage monitoring and optimization. IEEE Trans. Smart Grid 7(2), 785–793 (2016). (March)CrossRef
97.
M. Mohammadniael, F. Namdari, M.R. Shakarami, A fast voltage collapse detection and prevention based on wide-area monitoring and control. J. Oper. Autom. Power Eng. 1–11 (Dec 2019)
98.
M. Zima, M. Larsson, P. Korba, C. Rehtanz, G. Andersson, Design aspects for wide-area monitoring and control systems. Proc. IEEE 93(5), 980–996 (May 2005)
99.
H.H. Alhelou, M.E. Golshan, N.D. Hatziargyriou. Deterministic dynamic state estimation-based optimal lfc for interconnected power systems using unknown input observer. IEEE Trans. Smart Grid (9 Sep 2019)
100.
H. Song, J. Wu, K. Wu, A wide-area measurement system- based adaptive strategy for controlled islanding in bulk power systems. Energies 7, 2631–2657 (2014)
101.
M.A.M. Ariff, B.C. Pal, Coherency identification in interconnected power system-an independent component analysis approach. IEEE Trans. Power Syst. 28(2), 1747–1755 (2013). (May)CrossRef
102.
E. Baroco, B.C. Pal, N.F. Thornhill, A. Roman Messina, A dynamic mode decomposition framework for global power system oscillations analysis. IEEE Trans. Power Syst. 30(6), 2902–2912 (Nov 2015)
103.
T.B. Liu, X. Chang, X. Guo, L. Wang, C. Cao, Q. Yan, J. Li, Impact of subsynchronous and Supersynchronous frequency components on synchrophasor measurements. J. Mod. Power Syst. Clean Energy 4(3), 362–369 (2016)
104.
K. Tuttelberg, J. Kilter, D. Wilson, Uhlen, Estimation of power system inertia from ambient wide-area measurements. IEEE Trans. Power Syst. 33(6), 7249–7257 (Nov 2018)
105.
P. Ray, Power system low frequency oscillations mode estimation using wide area measurement systems. Int. J. Eng. Sci. Technol. 20(2), 598–615 (2017)
106.
V. Salehi, A. Mazloomzadeh, J.F. Fernandez, O.A. Mohammed, Real-time power system analysis and security monitoring by WAMPAC systems, in IEEE PES Innovative Smart Grid Technologies (ISGT), Washington, DC, 2012, pp. 1-8
107.
Z. Yang, W. Kui, X. Yumin, Z. Buhan, Study of power system online dynamic equivalent based on wide area measurement system. Energy Proceedia 16, 1768–1775 (2012)CrossRef
108.
D. Xinwei, H. Qian, C. Yong, The monitor of inter-area oscillation based on wide area measurement system. Energy Proceedia 16, 2033–2043 (2012)CrossRef
109.
Y. Chompoobutrgoo, L. Vanfretti, Using PMU signals from dominant paths in power system wide-area damping control. Sustain. Energy Grids Netw. 4, 16–28 (2015)CrossRef
110.
H. Haes Alhelou, M. Esmail Hamedani-Golshan, T. Cuthbert Njenda, P. Siano, Wide-area measurement system-based optimal multi-stage under-frequency load-shedding in interconnected smart power systems using evolutionary computing techniques. Appl. Sci. 1–23 (1 Feb 2019)
111.
T. Cuthbert Njenda, M.E.H Golshan, H. Haes Alhelou, WAMS based intelligent under frequency load shedding considering online disturbance estimation, in Smart Grid Conference (SGC-18), Sanandaj, Iran, 2018, pp. 1–5
112.
A. Nageswara Rao, P. Vijaya Priya, M. Kowsalya, R. Gnanadass, Wide area monitoring for energy system: a review. Int. J. Ambient Energy 40(5), 537–553 (2019)
113.
R. Sun, V.A. Centeno, Wide area system islanding contingency detecting and warning scheme. IEEE Trans. Power Syst. 29(6), 2581–2589 (2014). (Nov)CrossRef
114.
Working Group C6, Wide area protection and emergency control. Final report (2002)
115.
F. Hashiesh, H.E. Mostafa, M.M. Mansour, A.-R. Khatib, I. Helal, Wide area transient stability prediction using on-line artificial neural networks, in 2008 IEEE Canada Electric Power Conference, Vancouver, BC, 2008, pp. 1–7
116.
H.H. Alhelou, M.E. Golshan, T.C. Njenda, N.D. Hatziargyriou, An Overview of UFLS in conventional, modern, and future smart power systems: challenges and opportunities. Electr. Power Syst. Res. 1(179), 106054 (2020). (Feb)CrossRef
117.
C. Taylor, WACS-Wide Area stability and voltage control system: R&D and online demonstration. Proc. IEEE 93(5), 892–906 (2005). (May)CrossRef
118.
Y. Wang, Y.-Xia Zhang, S.-Xiao Xu, Wide-area protection against chain over-load trip based on multi-agent technology, in 2008 International Conference on Machine Learning and Cybernetics, Kunming, 2008, pp. 1548–1552
119.
B. Milosevic, M. Begovic, Voltage-stability protection and control using a wide-area network of phasor measurements. IEEE Trans. Power Syst. 18(1), 121–127 (2003). (Feb)CrossRef
120.
J. Sykes, M. Adamiak, G. Brunello, Implementation and operational experience of a wide area special protection scheme on the SRP system, in 2006 Power Systems Conference: Advanced Metering, Protection, Control, Communication, and Distributed Resources, Clemson, SC, 2006, pp. 145-158
121.
C. Rehtanz, Wide area measurement and protection system for emergency voltage stability control, in 2002 IEEE Power Engineering Society Winter Meeting. Conference Proceedings (Cat. No.02CH37309), NY, USA, 2002, vol. 2, pp. 842–847
122.
M. Larsson, C. Rehtanz, Predictive frequency stability control based on wide-area phasor measurements, in 2002 IEEE Power Engineering Society Summer Meeting, Chicago, IL, USA, 2002, vol. 1, pp. 233-238
123.
V. Lohmann, Wide area protection: a strategy to counteract large area disturbances (2003)
124.
W. Cong, A wide area protection system based on “three defensive lines” and its application in power system, in 2004 International Conference on Power System Technology, Power Con 2004, Singapore, 2004, vol. 1, pp. 718–722
Metadaten
Titel
A Comprehensive Review on Wide-Area Protection, Control and Monitoring Systems
verfasst von
Valabhoju Ashok
Anamika Yadav
Almoataz Y. Abdelaziz
Copyright-Jahr
2021
Buch
Wide Area Power Systems Stability, Protection, and Security

Print ISBN: 978-3-030-54274-0

Electronic ISBN: 978-3-030-54275-7

Copyright-Jahr: 2021

DOI
https://doi.org/10.1007/978-3-030-54275-7_1