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Finance and Stochastics

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17-11-2023

Dispersion-constrained martingale Schrödinger problems and the exact joint S&P 500/VIX smile calibration puzzle

Author: Julien Guyon

Published in: Finance and Stochastics | Issue 1/2024

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Abstract

We solve for the first time a longstanding puzzle of quantitative finance that has often been described as the holy grail of volatility modelling: build a model that jointly and exactly calibrates to the prices of S&P 500 (SPX) options, VIX futures and VIX options. We use a nonparametric discrete-time approach: given a VIX future maturity \(T_{1}\), we consider the set \({\mathcal {P}}\) of all probability measures on the SPX at \(T_{1}\), the VIX at \(T_{1}\) and the SPX at \(T_{2} = T_{1} + 30\) days which are perfectly calibrated to the full SPX smiles at \(T_{1}\) and \(T_{2}\) and the full VIX smile at \(T_{1}\), and which also satisfy the martingality constraint on the SPX as well as the requirement that the VIX is the implied volatility of the 30-day log-contract on the SPX.

By casting the superreplication problem as a dispersion-constrained martingale optimal transport problem, we first establish a strong duality theorem and prove that the absence of joint SPX/VIX arbitrage is equivalent to \({\mathcal {P}}\neq \emptyset \). Should they arise, joint arbitrages are identified using classical linear programming. In their absence, we then provide a solution to the joint calibration puzzle by solving a dispersion-constrained martingale Schrödinger problem: we choose a reference measure and build the unique jointly calibrating model that minimises the relative entropy. We establish several duality results. The minimum-entropy jointly calibrating model is explicit in terms of the dual Schrödinger portfolio, i.e., the maximiser of the dual problem, should the latter exist, and is numerically computed using an extension of the Sinkhorn algorithm. Numerical experiments show that the algorithm performs very well in both low and high volatility regimes.

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Avellaneda, M.: Minimum-relative-entropy calibration of asset pricing models. Int. J. Theor. Appl. Finance 1, 447–472 (1998)

Avellaneda, M., Buff, R., Friedman, C., Grandchamp, N., Kruk, L., Newman, J.: Weighted Monte Carlo: a new technique for calibrating asset-pricing models. Int. J. Theor. Appl. Finance 4, 91–119 (2001) MathSciNet

Baldeaux, J., Badran, A.: Consistent modelling of VIX and equity derivatives using a 3/2 plus jumps model. Appl. Math. Finance 21, 299–312 (2014) MathSciNet

Bardgett, C., Gourier, E., Leippold, M.: Inferring volatility dynamics and risk premia from the S&P 500 and VIX markets. J. Financ. Econ. 131, 593–618 (2019)

Beiglböck, M., Henry-Labordère, P., Penkner, F.: Model-independent bounds for option prices: a mass-transport approach. Finance Stoch. 17, 477–501 (2013) MathSciNet

Bergomi, L.: Smile dynamics III. Risk, October 2008, 90–96 (2008)

Bergomi, L.: Stochastic Volatility Modeling. Chapman & Hall/CRC, Boca Raton (2016)

Blaschke, W., Pick, G.: Distanzschätzungen im Funktionenraum II. Math. Ann. 77, 277–302 (1916) MathSciNet

Borwein, J., Lewis, A.: Duality relationships for entropy-like minimization problems. SIAM J. Control Optim. 29, 325–338 (1991) MathSciNet

10.

Bourgey, F., Guyon, J.: Fast exact joint S&P 500/VIX smile calibration in discrete and continuous time. Preprint (2022). https://ssrn.com/abstract=4315084

11.

Bregman, L.M.: A relaxation method of finding a common point of convex sets and its application to the solution of problems in convex programming. Ž. Vyčisl. Mat. Mat. Fiz. 7, 620–631 (1967) MathSciNet

12.

Carr, P., Madan, D.: Towards a theory of volatility trading. In: Jarrow, R. (ed.) Volatility, pp. 417–427. Risk Publications (1998)

13.

The CBOE volatility index – VIX. www.cboe.com/micro/vix/vixwhite.pdf

14.

Chizat, L., Peyré, G., Schmitzer, B., Vialard, F.-X.: Scaling algorithms for unbalanced optimal transport problems. Math. Comput. 87, 2563–2609 (2018) MathSciNet

15.

Clason, C., Lorenz, D., Mahler, H., Wirth, B.: Entropic regularization of continuous optimal transport problems. J. Math. Anal. Appl. 494, 124432-1–22 (2021) MathSciNet

16.

Cont, R., Kokholm, T.: A consistent pricing model for index options and volatility derivatives. Math. Finance 23, 248–274 (2013) MathSciNet

17.

Csiszár, I.: \(I\)-Divergence geometry of probability distributions and minimization problems. Ann. Probab. 3, 146–158 (1975) MathSciNet

18.

Cuturi, M.: Sinkhorn distances: lightspeed computation of optimal transport. In: Burges, C. (ed.) Advances in Neural Information Processing Systems, vol. 26, pp. 2292–2300. Neural Information Processing Systems Foundation, Inc. (2013)

19.

Delbaen, F., Grandits, P., Rheinländer, T., Samperi, D., Schweizer, M., Stricker, C.: Exponential hedging and entropic penalties. Math. Finance 12, 99–123 (2002) MathSciNet

20.

De March, A.: Entropic approximation for multi-dimensional martingale optimal transport. Preprint (2018). https://arxiv.org/abs/1812.11104

21.

De March, A., Henry-Labordère, P.: Building arbitrage-free implied volatility: Sinkhorn’s algorithm and variants. Preprint (2019). https://ssrn.com/abstract=3326486

22.

De Marco, S., Henry-Labordère, P.: Linking vanillas and VIX options: a constrained martingale optimal transport problem. SIAM J. Financ. Math. 6, 1171–1194 (2015) MathSciNet

23.

Dembo, A., Zeitouni, O.: Large Deviations Techniques and Applications, 2nd edn. Springer, New York (1998)

24.

Di Marino, S., Gerolin, A.: An optimal transport approach for the Schrödinger bridge problem and convergence of Sinkhorn algorithm. J. Sci. Comput. 85, 27-1–28 (2020)

25.

Eckstein, S., Nutz, M.: Quantitative stability of regularized optimal transport and convergence of Sinkhorn’s algorithm. SIAM J. Math. Anal. 54, 5922–5948 (2022) MathSciNet

26.

Essid, M., Pavon, M.: Traversing the Schrödinger bridge strait: Robert Fortet’s marvelous proof redux. J. Optim. Theory Appl. 181, 23–60 (2019) MathSciNet

27.

Feydy, J., Séjourné, T., Vialard, F.-X., Amari, S., Trouvé, A., Peyré, G.: Interpolating between optimal transport and MMD using Sinkhorn divergences. In: Chaudhuri, K., Sugiyama, M. (eds.) Proceedings of Machine Learning Research, vol. 89, pp. 2681–2690. PMLR (2019)

28.

Föllmer, H.: Random fields and diffusion processes. In: Hennequin, P.L. (ed.) École d’Été de Probabilités de Saint-Flour XV–XVII, 1985–87. Lecture Notes in Mathematics, vol. 1362, pp. 101–203. Springer, Berlin (1988)

29.

Föllmer, H., Gantert, N.: Entropy minimization and Schrödinger processes in infinite dimensions. Ann. Probab. 25, 901–926 (1997) MathSciNet

30.

Forde, M., Smith, B.: Rough Heston with jumps – joint calibration to SPX/VIX level and skew as \(T \rightarrow 0\), and issues with the quadratic rough Heston model. Preprint (2022). https://nms.kcl.ac.uk/Martin.forde/RoughHestonCGMY-SPXVIXcalibration.pdf

31.

Fortet, R.: Résolution d’un système d’équations de M. Schrödinger. J. Math. Pures Appl. IX, 83–105 (1940)

32.

Fouque, J.-P., Saporito, Y.: Heston stochastic vol-of-vol model for joint calibration of VIX and S&P 500 options. Quant. Finance 18, 1003–1016 (2018) MathSciNet

33.

Frittelli, M.: The minimal entropy martingale measure and the valuation problem in incomplete markets. Math. Finance 10, 39–52 (2000) MathSciNet

34.

Galichon, A., Henry-Labordère, P., Touzi, N.: A stochastic control approach to no-arbitrage bounds given marginals, with an application to lookback options. Ann. Appl. Probab. 24, 312–336 (2014) MathSciNet

35.

Gatheral, J.: Consistent modeling of SPX and VIX options. Presentation at the Bachelier congress London, July 18 (2008). http://faculty.baruch.cuny.edu/jgatheral/Bachelier2008.pdf

36.

Gatheral, J., Jusselin, P., Rosenbaum, M.: The quadratic rough Heston model and the joint S&P 500/VIX smile calibration problem. Risk, May 2020. Preprint (2020). https://arxiv.org/abs/2001.01789

37.

Gentil, I., Léonard, C., Ripani, L.: About the analogy between optimal transport and minimal entropy. Ann. Fac. Toulouse, Sér. 6 26, 569–600 (2017) MathSciNet

38.

Gerolin, A., Kausamo, A., Rajala, T.: Multi-marginal entropy-transport with repulsive cost. Calc. Var. Partial Differ. Equ. 59, 1–20 (2020) MathSciNet

39.

Goutte, S., Ismail, A., Pham, H.: Regime-switching stochastic volatility model: estimation and calibration to VIX options. Appl. Math. Finance 24, 38–75 (2017) MathSciNet

40.

Guo, G., Obłój, J.: Computational methods for martingale optimal transport problems. Ann. Appl. Probab. 29, 3311–3347 (2019) MathSciNet

41.

Guo, I., Loeper, G., Obłój, J., Wang, S.: Joint modeling and calibration of SPX and VIX by optimal transport. SIAM J. Financ. Math. 13, 1–31 (2022) MathSciNet

42.

Guyon, J., Menegaux, R., Nutz, M.: Bounds for VIX futures given S&P 500 smiles. Finance Stoch. 21, 593–630 (2017) MathSciNet

43.

Guyon, J.: On the joint calibration of SPX and VIX options. Presentation at QuantMinds 2018, Lisbon, May 16 (2018). https://cermics.enpc.fr/~guyon/documents/JointCalibrationSPXoptionsVIXoptions_slides_QuantMinds_16may2018_v4.pdf

44.

Guyon, J.: Inversion of convex ordering in the VIX market. Quant. Finance 20, 1597–1623 (2020) MathSciNet

45.

Guyon, J.: The joint SPX/VIX smile calibration puzzle solved. Risk, April 2020. https://ssrn.com/abstract=3397382

46.

Guyon, J.: Dispersion-constrained martingale Schrödinger bridges: joint entropic calibration of stochastic volatility models to S&P 500 and VIX smiles. Preprint (2022). https://ssrn.com/abstract=4165057

47.

Guyon, J.: The VIX future in Bergomi models: fast approximation formulas and joint calibration with S&P 500 skew. SIAM J. Financ. Math. 13, 1418–1485 (2022) MathSciNet

48.

Guyon, J., Lekeufack, J.: Volatility is (mostly) path-dependent. Quant. Finance 23, 1221–1258 (2023) MathSciNet

49.

Henry-Labordère, P.: Automated option pricing: numerical methods. Int. J. Theor. Appl. Finance 16, 1350042-1–27 (2013) MathSciNet

50.

Henry-Labordère, P.: Model-Free Hedging: A Martingale Optimal Transport Viewpoint. Chapman & Hall/CRC, Boca Raton (2017)

51.

Henry-Labordère, P.: From (martingale) Schrödinger bridges to a new class of stochastic volatility models. Preprint (2019). https://ssrn.com/abstract=3353270

52.

Jacquier, A., Martini, C., Muguruza, A.: On the VIX futures in the rough Bergomi model. Quant. Finance 18, 45–61 (2018) MathSciNet

53.

Johansen, S.: The extremal convex functions. Math. Scand. 34, 61–68 (1974) MathSciNet

54.

Kantorovich, L.V.: On a problem of Monge. Zap. Nauchn. Sem. S.-Peterburg. Otdel. Mat. Inst. Steklov. (POMI) 3, 226–255 (1948) (in Russian)

55.

Kokholm, T., Stisen, M.: Joint pricing of VIX and SPX options with stochastic volatility and jump models. J. Risk Finance 16, 27–48 (2015)

56.

Léonard, C.: Minimization of energy functionals applied to some inverse problems. Appl. Math. Optim. 44, 273–297 (2001) MathSciNet

57.

Léonard, C.: A survey of the Schrödinger problem and some of its connections with optimal transport. Discrete Contin. Dyn. Syst. 34, 1533–1574 (2014) MathSciNet

58.

Monge, G.: Mémoire sur la théorie des déblais et des remblais. Histoire de l’Académie Royale des Sciences de Paris (1781). https://gallica.bnf.fr/ark:/12148/bpt6k35800/f796

59.

Musiela, M., Zariphopoulou, T.: An example of indifference prices under exponential preferences. Finance Stoch. 8, 229–239 (2004) MathSciNet

60.

Nutz, M., Wiesel, J., Zhao, L.: Martingale Schrödinger bridges and optimal semistatic portfolios. Finance Stoch. 27, 233–254 (2023) MathSciNet

61.

Pacati, C., Pompa, P., Renò, R.: Smiling twice: the Heston++ model. J. Bank. Finance 96, 185–206 (2018)

62.

Papanicolaou, A., Sircar, R.: A regime-switching Heston model for VIX and S&P 500 implied volatilities. Quant. Finance 14, 1811–1827 (2014) MathSciNet

63.

Pennanen, T., Perkkiö, A.-P.: Convex duality in nonlinear optimal transport. J. Funct. Anal. 277, 1029–1060 (2019) MathSciNet

64.

Peyré, G., Cuturi, M.: Computational Optimal Transport: With Applications to Data Science. Now Publishers, Hanover (2019)

65.

Rosenbaum, M., Zhang, L.: Deep calibration of the quadratic rough Heston model. Risk, October 2022. https://arxiv.org/abs/2107.01611

66.

Rüschendorf, L., Thomsen, W.: Note on the Schrödinger equation and I-projections. Stat. Probab. Lett. 17, 369–375 (1993)

67.

Sepp, A.: Achieving consistent modeling of VIX and equity derivatives. Presentation at Global Derivatives Trading & Risk Management 2012, April 17–19 (2012). https://artursepp.com/wp-content/uploads/2017/09/artur-sepp-global-derivatives-12.pdf

68.

Sinkhorn, R.: Diagonal equivalence to matrices with prescribed row and column sums. Am. Math. Mon. 74, 402–405 (1967) MathSciNet

69.

Sion, M.: On general minimax theorems. Pac. J. Math. 8, 171–176 (1958) MathSciNet

70.

Strassen, V.: The existence of probability measures with given marginals. Ann. Math. Stat. 36, 423–439 (1965) MathSciNet

71.

Villani, C.: Topics in Optimal Transportation. Am. Math. Soc., Providence (2003)

72.

Villani, C.: Optimal Transport. Old and New. Springer, Berlin (2009)

Title: Dispersion-constrained martingale Schrödinger problems and the exact joint S&P 500/VIX smile calibration puzzle
Author: Julien Guyon
Publication date: 17-11-2023
Publisher: Springer Berlin Heidelberg
Published in: Finance and Stochastics / Issue 1/2024
Print ISSN: 0949-2984
Electronic ISSN: 1432-1122
DOI: https://doi.org/10.1007/s00780-023-00524-y

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