XVA metrics for CCP optimization. (English) Zbl 1459.91211
Summary: Based on an XVA analysis of centrally cleared derivative portfolios, we consider two capital and funding issues pertaining to the efficiency of the design of central counterparties (CCPs). First, we consider an organization of a clearing framework, whereby a CCP would also play the role of a centralized XVA calculator and management center. The default fund contributions would become pure capital at risk of the clearing members, remunerated as such at some hurdle rate, i.e. return-on-equity. Moreover, we challenge the current default fund Cover 2 EMIR sizing rule with a broader risk based approach, relying on a suitable notion of economic capital of a CCP. Second, we compare the margin valuation adjustments (MVAs) resulting from two different initial margin raising strategies. The first one is unsecured borrowing by the clearing member. As an alternative, the clearing member delegates the posting of its initial margin to a so-called specialist lender, which, in case of default of the clearing member, receives back from the CCP the portion of IM unused to cover losses. The alternative strategy results in a significant MVA compression. A numerical case study shows that the volatility swings of the IM funding expenses can even be the main contributor to an economic capital based default fund of a CCP. This is an illustration of the transfer of counterparty risk into liquidity risk triggered by extensive collateralization.
MSC:
| 91G40 | Credit risk |
| 91G10 | Portfolio theory |
| 60H10 | Stochastic ordinary differential equations (aspects of stochastic analysis) |
Keywords:
central counterparty; initial margin; default fund; cost of funding initial margin; cost of capitalReferences:
| [1] | C. Albanese, D. Brigo and F. Oertel, Restructuring counterparty credit risk, Int. J. Theor. Appl. Finance 16 (2013), no. 2, Article ID 1350010. · Zbl 1266.91113 |
| [2] | C. Albanese and S. Crépey, Capital valuation adjustment and funding valuation adjustment, preprint (2019), https://math.maths.univ-evry.fr/crepey (first, very preliminary version: arXiv:1603.03012 and ssrn.2745909, March 2016). |
| [3] | C. Albanese, S. Crépey, R. Hoskinson and B. Saadeddine, XVA analysis from the balance sheet, preprint (2019), https://math.maths.univ-evry.fr/crepey. |
| [4] | L. Andersen and A. Dickinson, Funding and credit risk with locally elliptical portfolio processes: An application to central counterparties, J. Financ. Market Infrastruc. 7 (2019), no. 4, 27-70. |
| [5] | L. Andersen, M. Pykhtin and A. Sokol, Rethinking the margin period of risk, J. Credit Risk 13 (2017), no. 1, 1-45. |
| [6] | F. Anfuso, D. Aziz, K. Loukopoulos and P. Giltinan, A sound modelling and backtesting framework for forecasting initial margin requirements, Risk Magazine (2017). |
| [7] | A. Antonov, S. Issakov and A. McClelland, Efficient SIMM-MVA calculations for callable exotics, Risk Magazine (2018). |
| [8] | Y. Armenti and S. Crépey, Central clearing valuation adjustment, SIAM J. Financial Math. 8 (2017), no. 1, 274-313. · Zbl 1367.91185 |
| [9] | Y. Armenti, S. Crépey, S. Drapeau and A. Papapantoleon, Multivariate shortfall risk allocation and systemic risk, SIAM J. Financial Math. 9 (2018), no. 1, 90-126. · Zbl 1408.91236 |
| [10] | M. Arnsdorf, Quantification of central counterparty risk, J. Risk Management Financ. Inst. 5 (2012), no. 3, 273-287. |
| [11] | M. Arnsdorf, Central counterparty CVA, Risk Magazine (2019). |
| [12] | R. Barker, A. Dickinson, A. Lipton and R. Virmani, Systemic risks in CCP networks, Risk Magazine (2017). |
| [13] | P. Collin-Dufresne, R. Goldstein and J. Hugonnier, A general formula for valuing defaultable securities, Econometrica 72 (2004), no. 5, 1377-1407. · Zbl 1141.91431 |
| [14] | R. Cont, Central clearing and risk transformation, Financ. Stabil. Rev. 21 (2017), 141-147. |
| [15] | S. Crépey, T. R. Bielecki and D. Brigo, Counterparty Risk and Funding, a Tale of Two Puzzles, Chapman & Hall/CRC Financial Math. Ser., CRC Press, Boca Raton, 2014. · Zbl 1294.91005 |
| [16] | S. Crépey and S. Song, Counterparty risk and funding: immersion and beyond, Finance Stoch. 20 (2016), no. 4, 901-930. · Zbl 1380.91139 |
| [17] | S. Crépey and S. Song, Invariance times, Ann. Probab. 45 (2017), no. 6B, 4632-4674. · Zbl 1387.60061 |
| [18] | Y. Elouerkhaoui, Pricing and hedging in a dynamic credit model, Int. J. Theor. Appl. Finance 10 (2007), no. 4, 703-731. · Zbl 1291.91223 |
| [19] | Y. Elouerkhaoui, Credit Correlation. Theory and Practice, Appl. Quant. Finance, Palgrave Macmillan, Cham, 2017. |
| [20] | S. Ghamami, Static models of central counterparty risk, Int. J. Financ. Eng. 2 (2015), no. 2, Article ID 1550011. |
| [21] | A. Green and C. Kenyon, MVA by replication and regression, Risk Magazine (2015). |
| [22] | J. Gregory, Central Counterparties: Mandatory Central Clearing and Initial Margin Requirements for OTC Derivatives, Wiley, New York, 2014. |
| [23] | J. Gregory, The xVA Challenge: Counterparty Credit Risk, Funding, Collateral and Capital, Wiley, New York, 2015. |
| [24] | S. W. He, J. G. Wang and J. A. Yan, Semimartingale Theory and Stochastic Calculus, CRC Press, Boca Raton, 1992. · Zbl 0781.60002 |
| [25] | J. A. Hoeting, D. Madigan, A. E. Raftery and C. T. Volinsky, Bayesian model averaging: A tutorial, Statist. Sci. 14 (1999), no. 4, 382-417. · Zbl 1059.62525 |
| [26] | C. Kenyon and H. Iida, Behavioural effects on XVA, preprint (2018), https://arxiv.org/abs/1803.03477. |
| [27] | A. Khwaja, CCP initial margin models—A comparison, preprint (2016), https://www.clarusft.com/ccp-initial-margin-models-a-comparison/. |
| [28] | A. Kondratyev and G. Giorgidze, Evolutionary algos for optimising MVA, Risk Magazine (2017); preprint version available at https://ssrn.com/abstract=2921822. |
| [29] | T. Kruse and A. Popier, BSDEs with monotone generator driven by Brownian and Poisson noises in a general filtration, Stochastics 88 (2016), no. 4, 491-539. · Zbl 1337.60123 |
| [30] | D. Murphy and P. Nahai-Williamson, Dear prudence, won’t you come out to play? Approaches to the analysis of central counterparty default fund adequacy, Bank of England Financial Stability Paper, 2014. |
| [31] | N. Sherif, Banks turn to synthetic derivatives to cut initial margin, preprint (2017), http://www.risk.net/derivatives/5290756/banks-turn-to-synthetic-derivatives-to-cut-initial-margin. |
| [32] | Basel Committee on Banking Supervision, Capital requirements for bank exposures to central counterparties, 2014, http://www.bis.org/publ/bcbs282.pdf. |
| [33] | BIS technical committee of the international organization of securities commissions, Principles for financial market infrastructure, Bank for International Settlements, 2012, http://www.bis.org/cpmi/publ/d101a.pdf. |
| [34] | European Parliament, Regulation (EU) no 648/2012 of the European parliament and of the council of 4 July 2012 on OTC derivatives, central counterparties and trade repositories, 2012. |
This reference list is based on information provided by the publisher or from digital mathematics libraries. Its items are heuristically matched to zbMATH identifiers and may contain data conversion errors. In some cases that data have been complemented/enhanced by data from zbMATH Open. This attempts to reflect the references listed in the original paper as accurately as possible without claiming completeness or a perfect matching.
