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Sovereign, Bank, and Insurance Credit Spreads: Connectedness and System Networks

7th Framework Programme (FP7) SYRTO. Funded by the European Union. Sovereign, Bank, and Insurance Credit Spreads: Connectedness and System Networks. M. Billio, M. Getmansky , D. Gray A.W. Lo, R.C. Merton, L. Pelizzon

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Sovereign, Bank, and Insurance Credit Spreads: Connectedness and System Networks

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  1. 7th Framework Programme (FP7) SYRTO Funded by the European Union Sovereign, Bank, and Insurance Credit Spreads: Connectedness and System Networks M. Billio, M. Getmansky, D. Gray A.W. Lo, R.C. Merton, L. Pelizzon The research leading to these results has received funding from the European Union, Seventh Framework Programme FP7/2007-2013 under grant agreement SYRTO-SSH-2012-320270.

  2. Objectives • The risks of the banking and insurance systems have become increasingly interconnected with sovereign risk • Highlight interconnections: • Among countries and financial institutions • Consider both explicit and implicit connections • Quantify the effects of: • Asset-liability mismatches within and across countries and financial institutions

  3. Methodology • We propose to measure and analyze interactions between financial institutions, sovereigns using: • Contingent claims analysis (CCA) • Network approach

  4. Background • Existing methods of measuring financial stability have been heavily criticized by Cihak (2007) and Segoviano and Goodhart (2009): • A good measure of systemic stability has to incorporate two fundamental components: • The probability of individual financial institution or country defaults • The probability and speed of possible shocks spreading throughout the industry and countries

  5. Background • Most policy efforts have not focused in a comprehensive way on: • Assessing network externalities • Interconnectedness between financial institutions, financial markets, and sovereign countries • Effect of network and interconnectedness on systemic risk

  6. Background: Feedback Loops of Risk from Explicit and Implicit Guarantees 6 Source: IMF GFSR 2010, October Dale Gray

  7. Background • The size, interconnectedness, and complexity of individual financial institutions and their inter-relationships with sovereign risk create vulnerabilitiesto systemic risk • We propose Expected Loss Ratios (based on CCA) and network measures to analyze financial system interactions and systemic risk

  8. Core Concept of CCA: Merton Model Expected Loss Ratio = Cost of Guar/RF Debt = PUT/B exp[-rT] = ELR Fair Value CDS Spread = -log (1 – ELR)/ T

  9. Moody’s KMV CreditEdge for Banks and Insurance Companies • MKMV uses equity and equity volatility and default barrier (from accounting information) to get “distance-to- distress” which it maps to a default probability (EDF) using a pool of 30 years of default information • It then converts the EDF to a risk neutral default probability (using the market price of risk), then using the sector loss given default (LGD) it calculates the Expected Loss Ratio (EL) for banks and Insurances: • EL Ratio = RNDP*LGDSector • It calculates the Fair Value CDS Spread • Fair Value CDS Spread = -1/T ln (1 – EL Ratio)

  10. Why EL Values? EL Values are used because they do not have the distortions which affect observed CDS Spreads For banks and some other financial institutions: The fair-value CDS spreads (implied credit spreads derived from CCA models, i.e. derived from equity information) are frequently > than the observed market CDS This is due to the depressing effect of implicit and explicit government guarantees

  11. Why EL Values? In other cases, e.g. in the Euro area periphery countries, bank and insurance company CDS appear to be affected by spillover from high sovereign spreads (observed CDS > FVCDS). For these reasons we use the EL associated with the FVCDS spreads for banks and insurance companies which do not contain the distortions of sovereign guarantees or sovereign credit risk spillovers

  12. Sovereign Expected Loss Ratio CCA has been applied to sovereigns, both emerging market and developed sovereigns Sovereign CDS spreads can be modeled from sovereign CCA models where the spread is associated with the expected loss value and sovereign default barrier For this study the formula for estimating sovereign EL is simply derived from sovereign CDS EL Ratio Sovereign = 1-exp(-(Sovereign CDS/10000)*T) EL ratios for both banks and sovereigns have a horizon of 5 years (5-year CDS most liquid)

  13. Linear Granger Causality Tests ELRk(t) = ak + bkELRk(t-1) + bjkELRj(t-1) + Ɛt ELRj(t) = aj+ bjELRj(t-1) + bkjELRk(t-1) + ζt If bjk is significantly > 0, then j influences k If bkj is significantly > 0, then k influences j If both are significantly > 0, then there is feedback, mutual influence, between j and k.

  14. Data Sample: Jan 01-Mar12 Monthly frequency Entities: 17 Sovereigns (10 EMU, 4 EU, CH, US, JA) 59Banks (31EMU, 11EU, 2CH, 12US, 4JA) 42Insurance Companies (12EMU, 6EU, 16US, 2CH, 5CA) CCA - Moody’s KMV CreditEdge: Expected Loss (EL)

  15. Mar 12 Blue Insurance Black Sovereign Red Bank Blue Insurance Black Sovereign Red Bank

  16. Mar 12 Blue Insurance Black Sovereign Red Bank Blue Insurance Black Sovereign Red Bank

  17. Network Measures Degrees Connectivity Centrality • Indegree (IN): number of incoming connections • Outdegree (FROM): number of outgoing • connections • Totdegree: Indegree + Outdegree • Number of node connected: Number of nodes reachable following the directed path • Average Shortest Path: The average number of steps required to reach the connected nodes • Eigenvector Centrality (EC): The more the node is connected to central nodes (nodes with high EC) the more is central (higher EC)

  18. Network Measures: FROM and TO Sovereign 17 X 102= 1734 potential connections FROM (idem for TO)

  19. From GIIPS minus TO GIIPS

  20. June 07 Blue Insurance Black Sovereign Red Bank

  21. March 08 Blue Insurance Black Sovereign Red Bank

  22. August 08 Blue Insurance Black Sovereign Red Bank Greece

  23. December 11 Spain Blue Insurance Black Sovereign Red Bank

  24. March 12 US Blue Insurance Black Sovereign Red Bank IT

  25. March 12 Blue Insurance Black Sovereign Red Bank

  26. Early Warning Signals

  27. Early Warning Signals t=March 2008 t+1=March 2009; t= Jul 2011; t+1= Feb 2012 Cumulated Exp. Loss ≡ Expected Loss of institution i + Expected losses of institutions caused by i

  28. CDS data

  29. Comparison CDS-KMV

  30. Comparison CDS-KMV

  31. CDS: Dec 11 Spain Blue Insurance Black Sovereign Red Bank

  32. Dec 11 : EL-KMV Spain Blue Insurance Black Sovereign Red Bank

  33. CDS:Mar 12 Blue Insurance Black Sovereign Red Bank IT

  34. US Mar 12:EL-KMV Blue Insurance Black Sovereign Red Bank IT

  35. Conclusion The system of banks, insurance companies, and countries in our sample is highly dynamically connected Insurance companies are becoming highly connected… We show how one country is spreading risk to another sovereign Network measures allow for early warnings and assessment of the system complexity

  36. Thank You!

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