The quadratic rough Heston model and the joint S&P 500/Vix smile calibration problem

The quadratic rough Heston model and the joint S&P 500/VIX smile calibration problem (arXiv link) was published on the Cutting Edge section of Risk.net:

Risk – Cutting Edge – The quadratic rough Heston model and the joint S&P 500/VIX smile calibration problem

Authors: Jim Gatheral, Paul Jusselin, Mathieu Rosenbaum

Abstract: Fitting simultaneously SPX and VIX smiles is known to be one of the most challenging problems in volatility modeling. A long-standing conjecture due to Julien Guyon is that it may not be possible to calibrate jointly these two quantities with a model with continuous sample-paths. We present the quadratic rough Heston model as a counterexample to this conjecture. The key idea is the combination of rough volatility together with a price-feedback (Zumbach) effect.

Super-Heston rough volatility, Zumbach effect and the Guyon’s conjecture

Mathieu Rosenbaum will present “Super-Heston rough volatility, Zumbach effect and the Guyon’s conjecture” on Apr 23: https://ethz.zoom.us/meeting/register/tJ0kfu6trD0oGtHBTVyMkSJDp-XRy1tblo3d?fbclid=IwAR1NIBwk2Q4j481dI7FJGnyV9Ekw61sTWi6LbCcRzTampfTAVdwDIkLqbYs

Reference paper: From quadratic Hawkes processes to super-Heston rough volatility models with Zumbach effect

Work with Paul Jusselin, Aditi Dandapani and Jim Gatheral

How to build a cross-impact model from first principles: Theoretical requirements and empirical results

Published on SSRN:

How to build a cross-impact model from first principles: Theoretical requirements and empirical results

Abstract: Cross-impact, namely the fact that on average buy (sell) trades on a financial instrument induce positive (negative) price changes in other correlated assets, can be measured from abundant, although noisy, market data. In this paper we propose a principled approach that allows to perform model selection for cross-impact models, showing that symmetries and consistency requirements are particularly effective in reducing the universe of possible models to a much smaller set of viable candidates, thus mitigating the effect of noise on the properties of the inferred model. We review the empirical performance of a large number of cross-impact models, comparing their strengths and weaknesses on a number of asset classes (futures, stocks, calendar spreads). Besides showing which models perform better, we argue that in presence of comparable statistical performance, which is often the case in a noisy world, it is relevant to favor models that provide ex-ante theoretical guarantees on their behavior in limit cases. From this perspective, we advocate that the empirical validation of universal properties (symmetries, invariances) should be regarded as holding a much deeper epistemological value than any measure of statistical performance on specific model instances.

From microscopic price dynamics to multidimensional rough volatility models

Published on arxiv:

From microscopic price dynamics to multidimensional rough volatility models

Abstract: Rough volatility is a well-established statistical stylised fact of financial assets. This property has lead to the design and analysis of various new rough stochastic volatility models. However, most of these developments have been carried out in the mono-asset case. In this work, we show that some specific multivariate rough volatility models arise naturally from microstructural properties of the joint dynamics of asset prices. To do so, we use Hawkes processes to build microscopic models that reproduce accurately high frequency cross-asset interactions and investigate their long term scaling limits. We emphasize the relevance of our approach by providing insights on the role of microscopic features such as momentum and mean-reversion on the multidimensional price formation process. We in particular recover classical properties of high-dimensional stock correlation matrices.