Integrating Systemic Risk and Risk Analysis Using Copulas

Stefan Hochrainer-Stigler; Georg Pflug; Ulf Dieckmann; Elena Rovenskaya; Stefan Thurner; Sebastian Poledna; Gergely Boza; Joanne Linnerooth-Bayer; Åke Brännström

doi:10.1007/s13753-018-0198-1

Article Contents

Article Navigation > International Journal of Disaster Risk Science > 2018 > 6(4): 561-567

Stefan Hochrainer-Stigler, Georg Pflug, Ulf Dieckmann, Elena Rovenskaya, Stefan Thurner, Sebastian Poledna, Gergely Boza, Joanne Linnerooth-Bayer, Åke Brännström. Integrating Systemic Risk and Risk Analysis Using Copulas[J]. International Journal of Disaster Risk Science, 2018, 6(4): 561-567. doi: 10.1007/s13753-018-0198-1

Citation:

Stefan Hochrainer-Stigler, Georg Pflug, Ulf Dieckmann, Elena Rovenskaya, Stefan Thurner, Sebastian Poledna, Gergely Boza, Joanne Linnerooth-Bayer, Åke Brännström. Integrating Systemic Risk and Risk Analysis Using Copulas[J]. International Journal of Disaster Risk Science, 2018, 6(4): 561-567. doi: 10.1007/s13753-018-0198-1

Citation:

Stefan Hochrainer-Stigler, Georg Pflug, Ulf Dieckmann, Elena Rovenskaya, Stefan Thurner, Sebastian Poledna, Gergely Boza, Joanne Linnerooth-Bayer, Åke Brännström. Integrating Systemic Risk and Risk Analysis Using Copulas[J]. International Journal of Disaster Risk Science, 2018, 6(4): 561-567. doi: 10.1007/s13753-018-0198-1

PDF

Integrating Systemic Risk and Risk Analysis Using Copulas

doi: 10.1007/s13753-018-0198-1

1 International Institute for Applied Systems Analysis(IIASA), 2361 Laxenburg, Austria;
2 Department of Statistics and Operations Research, University of Vienna, 1010 Vienna, Austria;
3 Complexity Science Hub, 1080 Vienna, Austria;
4 Faculty of Computational Mathematics and Cybernetics, Lomonosov Moscow State University, Moscow, Russia 119234;
5 Medical University of Vienna, 1090 Vienna, Austria;
6 Santa Fe Institute, Santa Fe, NM 87501, USA;
7 Evolutionary Systems Research Group, MTA-ÖK-BLI Centre for Ecological Research, Hungarian Academy of Sciences, Tihany, 8237, Hungary;
8 Department of Mathematics and Mathematical Statistics, Umeå University, 90187, Umeå, Sweden

Available Online: 2021-04-26

Abstract

Abstract

Systemic risk research is gaining traction across diverse disciplinary research communities, but has as yet not been strongly linked to traditional, well-established risk analysis research. This is due in part to the fact that systemic risk research focuses on the connection of elements within a system, while risk analysis research focuses more on individual risk to single elements. We therefore investigate how current systemic risk research can be related to traditional risk analysis approaches from a conceptual as well as an empirical point of view. Based on Sklar’s Theorem, which provides a one-to-one relationship between multivariate distributions and copulas, we suggest a reframing of the concept of copulas based on a network perspective. This provides a promising way forward for integrating individual risk (in the form of probability distributions) and systemic risk (in the form of copulas describing the dependencies among such distributions) across research domains. Copulas can link continuous node states, characterizing individual risks, with a gradual dependency of the coupling strength between nodes on their states, characterizing systemic risk. When copulas are used for describing such refined coupling between nodes, they can provide a more accurate quantification of a system’s network structure. This enables more realistic systemic risk assessments, and is especially useful when extreme events (that occur at low probabilities, but have high impacts) affect a system’s nodes. In this way, copulas can be informative in measuring and quantifying changes in systemic risk and therefore be helpful in its management. We discuss the advantages and limitations of copulas for integrative risk analyses from the perspectives of modeling, measurement, and management.
- Copulas,
- Individual risk,
- Risk analysis,
- Systemic risk

FullText(HTML)

References(48)

References

Allen, F., and D. Gale. 2000. Financial contagion. Journal of Political Economy 108(1): 1–33.

Allen, F., A. Babus, and E. Carletti. 2012. Asset commonality, debt maturity and systemic risk. Journal of Financial Economics 104(3): 519–534.

Aven, T. 2016. What defines us as professionals in the field of risk analysis? Risk Analysis 37(5): 854–860.

Bak, P., and M. Paczuski. 1995. Complexity, contingency, and criticality. Proceedings of the National Academy of Sciences of the USA 92(15): 6689–6696.

Battiston, S., D.D. Gatti, M. Gallegati, B. Greenwald, and J.E. Stiglitz. 2012. Liaisons dangereuses: Increasing connectivity, risk sharing, and systemic risk. Journal of Economic Dynamics and Control 36(8): 1121–1141.

Battiston, S., M. Puliga, R. Kaushik, P. Tasca, and G. Caldarelli. 2012. Debtrank: Too central to fail? Financial networks, the FED and systemic risk. Scientific Reports 2(8): Article 541.

Bedford, T., and R. Cooke. 2002. Vines: A new graphical model for dependent random variables. Annals of Statistics 30(4): 1031–1068.

Borgomeo, E., G. Pflug, J.W. Hall, and S. Hochrainer-Stigler. 2015. Assessing water resource system vulnerability to unprecedented hydrological drought using copulas to characterize drought duration and deficit. Water Resources Research 51(11): 8927–8948.

Borrvall, C., B. Ebenman, and T. Jonsson. 2000. Biodiversity lessens the risk of cascading extinction in model food webs. Ecology Letters 3(2): 131–136.

Boss, M., M. Summer, and S. Thurner. 2004. Contagion flow through banking networks. In Computational Science—ICCS 2004, Proceedings, Part Ⅲ, ed. M. Bubak, G.D. van Albada, P.M.A. Sloot, and J. Dongarra, 1070–1077. Berlin: Springer.

Centeno, M.A., M. Nag, T.S. Patterson, A. Shaver, and A.J. Windawi. 2015. The emergence of global systemic risk. Annual Review of Sociology 41(1): 65–85.

Folke, C., S. Carpenter, B. Walker, M. Scheffer, T. Elmqvist, L. Gunderson, and C.S. Holling. 2004. Regime shifts, resilience, and biodiversity in ecosystem management. Annual Review of Ecology, Evolution, and Systematics 35(1): 557–581.

Gai, P., and S. Kapadia. 2010. Contagion in financial networks. Proceedings of the Royal Society A 466: 2401–2423.

Gardner, M.R., and W.R. Ashby. 1970. Connectance of large dynamic (cybernetic) systems: Critical values for stability. Nature 228(5273): 784.

Grossi, P., and H. Kunreuther (eds.). 2005. Catastrophe modeling: A new approach to managing risk. Boston, MA: Springer.

Haefeli, D., and P.M. Liedtke (eds.). 2012. Insurance and resolution in light of the systemic risk debate. Geneva, Switzerland: The Geneva Association.

Haldane, A.G., and R.M. May. 2011. Systemic risk in banking ecosystems. Nature 469(7330): 351–355.

Hanel, R., S.A. Kauffman, and S. Thurner. 2007. Towards a physics of evolution: Critical diversity dynamics at the edges of collapse and bursts of diversification. Physical Review E 76: Article 030101.

Helbing, D. 2013. Globally networked risks and how to respond. Nature 497(7447): 51–59.

Hochrainer-Stigler, S., G. Boza, C. Colon, S. Poledna, E. Rovenskaya, and U. Dieckmann. 2018. Resilience of systems to individual risk and systemic risk. In Resource guide on resilience, Volume 2, ed. M.-V. Florin, and I. Linkov. Lausanne, Switzerland: EPFL International Risk Governance Center (IRGC).

Hochrainer-Stigler, S., J. Linnerooth-Bayer, and A. Lorant. 2017. The European Union Solidarity Fund: An assessment of its recent reforms. Mitigation and Adaptation Strategies for Global Change 22(4): 547–563.

Hofert, M., and M. Mächler. 2011. Nested Archimedean copulas meet R: The nacopula package. Journal of Statistical Software 39(9): 1–20.

Jain, S., and S. Krishna. 2001. A model for the emergence of cooperation, interdependence, and structure in evolving networks. Proceedings of the National Academy of Sciences of the USA 98(2): 543–547.

Joe, H. 2014. Dependence modeling with copulas. Chapman and Hall/CRC.

Jeong, B., W. Lee, D.S. Kim, and H. Shin. 2016. Copula-based approach to synthetic population generation. PLoS ONE 11(8): Article e0159496.

Jongman, B., S. Hochrainer-Stigler, L. Feyen, J.C.J.H. Aerts, R. Mechler, W.J.W. Botzen, and L.M. Bouwer, et al. 2014. Increasing stress on disaster-risk finance due to large floods. Nature Climate Change 4(4): 264–268.

Kessler, D. 2014. Why (re)insurance is not systemic. Journal of Risk and Insurance 81(3): 477–488.

Kovacevic, R.M., G.C. Pflug, and A. Pichler. 2014. Measuring and managing risk. In Investment risk management, ed. H.K. Baker, and G. Filbeck, 17–41. Oxford: Oxford University Press.

Kurowicka, D., and R. Cooke. 2006. Uncertainty analysis with high dimensional dependence modelling. West Sussex, UK: Wiley.

Kurowicka, D., and H. Joe. 2010. Dependence modeling: Vine copula handbook. Singapore: World Scientific Publishing Co.

Little, R.G. 2002. Controlling cascading failure: Understanding the vulnerabilities of interconnected infrastructures. Journal of Urban Technology 9(1): 109–123.

May, R.M. 1972. Will a large complex system be stable? Nature 238(5364): 413–414.

May, R.M., and N. Arinaminpathy. 2010. Systemic risk: The dynamics of model banking systems. Journal of the Royal Society Interface 7(46): 823–838.

McCann, K.S. 2000. The diversity-stability debate. Nature 405(6783): 228–233.

McNeil, A.J., R. Frey, and P. Embrechts (eds.). 2015. Quantitative risk management: Concepts, techniques and tools. Princeton, NJ: Princeton University Press.

Nelsen, R.B. 2006. An introduction to copulas. New York: Springer.

Page, S.E. 2015. What sociologists should know about complexity. Annual Review of Sociology 41(1): 21–41.

Pimm, S.L., and J.H. Lawton. 1978. On feeding on more than one trophic level. Nature 275(5680): 542–544.

Pflug, G., and A. Pichler. 2018. Systemic risk and copula models. Central European Journal of Operations Research 26(2): 465–483.

Pflug, G.C., and W. Römisch. 2007. Modeling, measuring and managing risk. Singapore: World Scientific Publishing Co.

Poledna, S., and S. Thurner. 2016. Elimination of systemic risk in financial networks by means of a systemic risk transaction tax. Quantitative Finance 16(10): 1599–1613.

Scheffer, M., and S.R. Carpenter. 2003. Catastrophic regime shifts in ecosystems: Linking theory to observation. Trends in Ecology & Evolution 18(12): 648–656.

Sklar, A. 1959. Distribution functions with n dimensions and their margins (Fonctions de répartition à n dimensions et leurs marges). Publications de l’Institut Statistique de l’Université de Paris 8: 229–231 (in French).

Sklar, A. 1973. Random variables, bivariate distribution functions and copulas. Kybernetika 9: 449–460.

Thurner, S., and S. Poledna. 2013. DebtRank-transparency: Controlling systemic risk in financial networks. Scientific Reports 3(5): Article 1888.

Tilman, D., and J.A. Downing. 1996. Biodiversity and stability in grasslands. In Ecosystem management, ed. F.B. Samson and F.L. Knopf, 3–7. New York: Springer.

Timonina, A., S. Hochrainer-Stigler, G. Pflug, B. Jongman, and R. Rojas. 2015. Structured coupling of probability loss distributions: Assessing joint flood risk in multiple river basins. Risk Analysis 35(11): 2102–2119.

WEF (World Economic Forum). 2018. The global risk report. Geneva, Switzerland: WEF.

Relative Articles

Supplements(0)

Cited By

Proportional views