Methods for analysis and quantification of power system resilience

Aleksandar M. Stankovic; Kevin L. Tomsovic; Fabrizio De Caro; Martin Braun; Joe H. Chow; Ninel Cukalevski; Ian Dobson; Joseph Eto; Blair Fink; Christian Hachmann; David Hill; Chuanyi Ji; James A. Kavicky; Victor Levi; Chen Ching Liu; Lamine Mili; Rodrigo Moreno; Mathaios Panteli; Frederic D. Petit; Giovanni Sansavini; Chanan Singh; Anurag K. Srivastava; Kai Strunz; Hongbo Sun; Yin Xu; Shijia Zhao

doi:10.1109/TPWRS.2022.3212688

Methods for analysis and quantification of power system resilience

Aleksandar M. Stankovic, Kevin L. Tomsovic, Fabrizio De Caro, Martin Braun, Joe H. Chow, Ninel Cukalevski, Ian Dobson, Joseph Eto, Blair Fink, Christian Hachmann, David Hill, Chuanyi Ji, James A. Kavicky, Victor Levi, Chen Ching Liu, Lamine Mili, Rodrigo Moreno, Mathaios Panteli, Frederic D. Petit, Giovanni SansaviniChanan Singh, Anurag K. Srivastava, Kai Strunz, Hongbo Sun, Yin Xu, Shijia Zhao

Research output: Contribution to journal › Article › Research › peer-review

76 Citations (Scopus)

Abstract

This paper summarizes the report prepared by an IEEE PES Task Force. Resilience is a fairly new technical concept for power systems, and it is important to precisely delineate this concept for actual applications. As a critical infrastructure, power systems have to be prepared to survive rare but extreme incidents (natural catastrophes, extreme weather events, physical/cyber-attacks, equipment failure cascades, etc.) to guarantee power supply to the electricity-dependent economy and society. Thus, resilience needs to be integrated into planning and operational assessment to design and operate adequately resilient power systems. Quantification of resilience as a key performance indicator is important, together with costs and reliability. Quantification can analyze existing power systems and identify resilience improvements in future power systems. Given that a 100% resilient system is not economic (or even technically achievable), the degree of resilience should be transparent and comprehensible. Several gaps are identified to indicate further needs for research and development.

Original language	English
Pages (from-to)	4774-4787
Number of pages	14
Journal	IEEE Transactions on Power Systems
Volume	38
Issue number	5
DOIs	https://doi.org/10.1109/TPWRS.2022.3212688
Publication status	Published - Sept 2023
Externally published	Yes

Keywords

emergency response
operation
operator training
planning
Power system resilience
recovery
reliability
restoration

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10.1109/TPWRS.2022.3212688

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Stankovic, A. M., Tomsovic, K. L., De Caro, F., Braun, M., Chow, J. H., Cukalevski, N., Dobson, I., Eto, J., Fink, B., Hachmann, C., Hill, D., Ji, C., Kavicky, J. A., Levi, V., Liu, C. C., Mili, L., Moreno, R., Panteli, M., Petit, F. D., ... Zhao, S. (2023). Methods for analysis and quantification of power system resilience. IEEE Transactions on Power Systems, 38(5), 4774-4787. https://doi.org/10.1109/TPWRS.2022.3212688

@article{d7e8d6d45ad0450880b9db61d25c90fb,

title = "Methods for analysis and quantification of power system resilience",

abstract = "This paper summarizes the report prepared by an IEEE PES Task Force. Resilience is a fairly new technical concept for power systems, and it is important to precisely delineate this concept for actual applications. As a critical infrastructure, power systems have to be prepared to survive rare but extreme incidents (natural catastrophes, extreme weather events, physical/cyber-attacks, equipment failure cascades, etc.) to guarantee power supply to the electricity-dependent economy and society. Thus, resilience needs to be integrated into planning and operational assessment to design and operate adequately resilient power systems. Quantification of resilience as a key performance indicator is important, together with costs and reliability. Quantification can analyze existing power systems and identify resilience improvements in future power systems. Given that a 100% resilient system is not economic (or even technically achievable), the degree of resilience should be transparent and comprehensible. Several gaps are identified to indicate further needs for research and development.",

keywords = "emergency response, operation, operator training, planning, Power system resilience, recovery, reliability, restoration",

author = "Stankovic, {Aleksandar M.} and Tomsovic, {Kevin L.} and {De Caro}, Fabrizio and Martin Braun and Chow, {Joe H.} and Ninel Cukalevski and Ian Dobson and Joseph Eto and Blair Fink and Christian Hachmann and David Hill and Chuanyi Ji and Kavicky, {James A.} and Victor Levi and Liu, {Chen Ching} and Lamine Mili and Rodrigo Moreno and Mathaios Panteli and Petit, {Frederic D.} and Giovanni Sansavini and Chanan Singh and Srivastava, {Anurag K.} and Kai Strunz and Hongbo Sun and Yin Xu and Shijia Zhao",

note = "Funding Information: The work of Rodrigo Moreno was supported by ANID, Chile, under Grants PIA/APOYO AFB180003 (Instituto Sistemas Complejos de Ingenieria (ISCI), and Fondecyt /1181928. The work of Aleksandar M. Stankov{\'i}c was supported in part by NSF under Grant ECCS-1710944, in part by CURENT Engineering Research Center of the National Science Foundation and the Department of Energy under NSF Award EEC-1041877, and in part by ONR under Grant N00014-16-1-3028. Paper no. TPWRS-00576-2022 Publisher Copyright: {\textcopyright} 2022 IEEE.",

year = "2023",

month = sep,

doi = "10.1109/TPWRS.2022.3212688",

language = "English",

volume = "38",

pages = "4774--4787",

journal = "IEEE Transactions on Power Systems",

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Stankovic, AM, Tomsovic, KL, De Caro, F, Braun, M, Chow, JH, Cukalevski, N, Dobson, I, Eto, J, Fink, B, Hachmann, C, Hill, D, Ji, C, Kavicky, JA, Levi, V, Liu, CC, Mili, L, Moreno, R, Panteli, M, Petit, FD, Sansavini, G, Singh, C, Srivastava, AK, Strunz, K, Sun, H, Xu, Y & Zhao, S 2023, 'Methods for analysis and quantification of power system resilience', IEEE Transactions on Power Systems, vol. 38, no. 5, pp. 4774-4787. https://doi.org/10.1109/TPWRS.2022.3212688

TY - JOUR

T1 - Methods for analysis and quantification of power system resilience

AU - Stankovic, Aleksandar M.

AU - Tomsovic, Kevin L.

AU - De Caro, Fabrizio

AU - Braun, Martin

AU - Chow, Joe H.

AU - Cukalevski, Ninel

AU - Dobson, Ian

AU - Eto, Joseph

AU - Fink, Blair

AU - Hachmann, Christian

AU - Hill, David

AU - Ji, Chuanyi

AU - Kavicky, James A.

AU - Levi, Victor

AU - Liu, Chen Ching

AU - Mili, Lamine

AU - Moreno, Rodrigo

AU - Panteli, Mathaios

AU - Petit, Frederic D.

AU - Sansavini, Giovanni

AU - Singh, Chanan

AU - Srivastava, Anurag K.

AU - Strunz, Kai

AU - Sun, Hongbo

AU - Xu, Yin

AU - Zhao, Shijia

N1 - Funding Information: The work of Rodrigo Moreno was supported by ANID, Chile, under Grants PIA/APOYO AFB180003 (Instituto Sistemas Complejos de Ingenieria (ISCI), and Fondecyt /1181928. The work of Aleksandar M. Stankovíc was supported in part by NSF under Grant ECCS-1710944, in part by CURENT Engineering Research Center of the National Science Foundation and the Department of Energy under NSF Award EEC-1041877, and in part by ONR under Grant N00014-16-1-3028. Paper no. TPWRS-00576-2022 Publisher Copyright: © 2022 IEEE.

PY - 2023/9

Y1 - 2023/9

N2 - This paper summarizes the report prepared by an IEEE PES Task Force. Resilience is a fairly new technical concept for power systems, and it is important to precisely delineate this concept for actual applications. As a critical infrastructure, power systems have to be prepared to survive rare but extreme incidents (natural catastrophes, extreme weather events, physical/cyber-attacks, equipment failure cascades, etc.) to guarantee power supply to the electricity-dependent economy and society. Thus, resilience needs to be integrated into planning and operational assessment to design and operate adequately resilient power systems. Quantification of resilience as a key performance indicator is important, together with costs and reliability. Quantification can analyze existing power systems and identify resilience improvements in future power systems. Given that a 100% resilient system is not economic (or even technically achievable), the degree of resilience should be transparent and comprehensible. Several gaps are identified to indicate further needs for research and development.

AB - This paper summarizes the report prepared by an IEEE PES Task Force. Resilience is a fairly new technical concept for power systems, and it is important to precisely delineate this concept for actual applications. As a critical infrastructure, power systems have to be prepared to survive rare but extreme incidents (natural catastrophes, extreme weather events, physical/cyber-attacks, equipment failure cascades, etc.) to guarantee power supply to the electricity-dependent economy and society. Thus, resilience needs to be integrated into planning and operational assessment to design and operate adequately resilient power systems. Quantification of resilience as a key performance indicator is important, together with costs and reliability. Quantification can analyze existing power systems and identify resilience improvements in future power systems. Given that a 100% resilient system is not economic (or even technically achievable), the degree of resilience should be transparent and comprehensible. Several gaps are identified to indicate further needs for research and development.

KW - emergency response

KW - operation

KW - operator training

KW - planning

KW - Power system resilience

KW - recovery

KW - reliability

KW - restoration

UR - http://www.scopus.com/inward/record.url?scp=85169299227&partnerID=8YFLogxK

U2 - 10.1109/TPWRS.2022.3212688

DO - 10.1109/TPWRS.2022.3212688

M3 - Article

AN - SCOPUS:85169299227

SN - 0885-8950

VL - 38

SP - 4774

EP - 4787

JO - IEEE Transactions on Power Systems

JF - IEEE Transactions on Power Systems

IS - 5

ER -

Methods for analysis and quantification of power system resilience

Abstract

Keywords

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