An ordinary differential equation is often used to model the movement of a particle. Similarly, partial differential equation can be used to describe the evolution of a total of trajectories of particles. It is natural to add randomness to such models: sometimes because this is a more realistic description which takes into account random noise, sometimes because this randomness is fundamental to the model itself as is the case for financial markets.

A good model of random noise, such as the celebrated Brownian motion, cannot evolve smoothly in time, otherwise the noise would be predictable on a small scale! As a result, stochastic perturbations of differential equations are intrinsically irregular and require fundamentally new methods and theories. The ground-breaking contributions of Ito, which allowed to make all this possible, are one of the great achievements of 20th century mathematics. The analysis of stochastic differential equations including their numerical treatment is nowadays of crucial importance for applications in finance, modeling of particle systems for solving non-linear kinetic equations, and other areas in applied mathematics.

A good model of random noise, such as the celebrated Brownian motion, cannot evolve smoothly in time, otherwise the noise would be predictable on a small scale! As a result, stochastic perturbations of differential equations are intrinsically irregular and require fundamentally new methods and theories. The ground-breaking contributions of Ito, which allowed to make all this possible, are one of the great achievements of 20th century mathematics. The analysis of stochastic differential equations including their numerical treatment is nowadays of crucial importance for applications in finance, modeling of particle systems for solving non-linear kinetic equations, and other areas in applied mathematics. Rough path ideas have become a game-changer for our understanding of stochastic differential equations. A balance is kept between concrete applications, including numerical schemes, and further development of the required theory. On the theoretical side, for instance, we are seeing many applications in the field of stochastic partial differential equations. Turning to applied topics, market micro structure and recently the analysis of lithium-ion batteries require models in the form of realistic stochastic evolutionary equations.

Highlights

Large classes of stochastic differential equations have been analyzed with rough path methods and there is a fruitful interplay with classic techniques of stochastic analysis, notably a new theory of rough stochastic differential equations, with surprising application to the analysis of local rough volatility models.

Publications

  Monographs

  • A.H. Erhardt, K. Tsaneva-Atanasova, G.T. Lines, E.A. Martens, eds., Dynamical Systems, PDEs and Networks for Biomedical Applications: Mathematical Modeling, Analysis and Simulations, Special Edition, articles published in Frontiers of Physics, Frontiers in Applied Mathematics and Statistics, and Frontiers in Physiology, Frontiers Media SA, Lausanne, Switzerland, 2023, 207 pages, (Collection Published), DOI 10.3389/978-2-8325-1458-0 .

  • P. Friz, M. Hairer, A Course on Rough Paths: With an Introduction to Regularity Structures, Universitext, Springer International Publishing, Basel, 2020, 346 pages, (Monograph Published), DOI 10.1007/978-3-030-41556-3 .

  • D. Belomestny, J. Schoenmakers, Advanced Simulation-Based Methods for Optimal Stopping and Control: With Applications in Finance, Macmillan Publishers Ltd., London, 2018, 364 pages, (Monograph Published), DOI 10.1057/978-1-137-03351-2 .

  • P. Friz, J. Gatheral, A. Gulisashvili, A. Jaquier, J. Teichmann, eds., Large Deviations and Asymptotic Methods in Finance, 110 of Springer Proceedings in Mathematics & Statistics, Springer, Berlin et al., 2015, ix+590 pages, (Collection Published).

  • J. Diehl, P. Friz, H. Mai , H. Oberhauser, S. Riedel, W. Stannat, Chapter 8: Robustness in Stochastic Filtering and Maximum Likelihood Estimation for SDEs, in: Extraction of Quantifiable Information from Complex Systems, S. Dahlke, W. Dahmen, M. Griebel, W. Hackbusch, K. Ritter, R. Schneider, Ch. Schwab, H. Yserentant, eds., 102 of Lecture Notes in Computational Science and Engineering, Springer International Publishing Switzerland, Cham, 2014, pp. 161--178, (Chapter Published).

  • P. Friz, M. Hairer, A Course on Rough Paths: With an Introduction to Regularity Structures, Universitext, Springer, Berlin et al., 2014, 251 pages, (Monograph Published).

  • P. Friz, N.B. Victoir, Multidimensional Stochastic Processes as Rough Paths, 120 of Cambridge Studies in Advanced Mathematics, Cambridge University Press, Cambridge, 2010, 670 pages, (Monograph Published).

  Articles in Refereed Journals

  • M. Fradon, J. Kern, S. Rœlly, A. Zass, Diffusion dynamics for an infinite system of two-type spheres and the associated depletion effect, Stochastic Processes and their Applications, 171 (2024), 104319, DOI 10.1016/j.spa.2024.104319 .
    Abstract
    We consider a random diffusion dynamics for an infinite system of hard spheres of two different sizes evolving in ℝd, its reversible probability measure, and its projection on the subset of the large spheres. The main feature is the occurrence of an attractive short-range dynamical interaction --- known in the physics literature as a depletion interaction -- between the large spheres, which is induced by the hidden presence of the small ones. By considering the asymptotic limit for such a system when the density of the particles is high, we also obtain a constructive dynamical approach to the famous discrete geometry problem of maximisation of the contact number of n identical spheres in ℝd. As support material, we propose numerical simulations in the form of movies.

  • CH. Bayer, Ch. Ben Hammouda, R.F. Tempone, Numerical smoothing with hierarchical adaptive sparse grids and quasi-Monte Carlo methods for efficient option pricing, Quantitative Finance, 23 (2023), pp. 209--227, DOI 10.1080/14697688.2022.2135455 .
    Abstract
    When approximating the expectation of a functional of a stochastic process, the efficiency and performance of deterministic quadrature methods, such as sparse grid quadrature and quasi-Monte Carlo (QMC) methods, may critically depend on the regularity of the integrand. To overcome this issue and reveal the available regularity, we consider cases in which analytic smoothing cannot be performed, and introduce a novel numerical smoothing approach by combining a root finding algorithm with one-dimensional integration with respect to a single well-selected variable. We prove that under appropriate conditions, the resulting function of the remaining variables is a highly smooth function, potentially affording the improved efficiency of adaptive sparse grid quadrature (ASGQ) and QMC methods, particularly when combined with hierarchical transformations (i.e., Brownian bridge and Richardson extrapolation on the weak error). This approach facilitates the effective treatment of high dimensionality. Our study is motivated by option pricing problems, and our focus is on dynamics where the discretization of the asset price is necessary. Based on our analysis and numerical experiments, we show the advantages of combining numerical smoothing with the ASGQ and QMC methods over ASGQ and QMC methods without smoothing and the Monte Carlo approach.

  • M. Heida, S. Neukamm, M. Varga, Stochastic two-scale convergence and Young measures, Networks and Heterogeneous Media, 17 (2022), pp. 227--254, DOI 10.3934/nhm.2022004 .
    Abstract
    In this paper we compare the notion of stochastic two-scale convergence in the mean (by Bourgeat, Mikelić and Wright), the notion of stochastic unfolding (recently introduced by the authors), and the quenched notion of stochastic two-scale convergence (by Zhikov and Pyatnitskii). In particular, we introduce stochastic two-scale Young measures as a tool to compare mean and quenched limits. Moreover, we discuss two examples, which can be naturally analyzed via stochastic unfolding, but which cannot be treated via quenched stochastic two-scale convergence.

  • C. Bellingeri, P.K. Friz, S. Paycha, R. Preiss, Smooth rough paths, their geometry and algebraic renormalization, Vietnam Journal of Mathematics, 50 (2022), pp. 719--761, DOI 10.1007/s10013-022-00570-7 .
    Abstract
    We introduce the class of smooth rough paths and study their main properties. Working in a smooth setting allows us to discard sewing arguments and focus on algebraic and geometric aspects. Specifically, a Maurer Cartan perspective is the key to a purely algebraic form of Lyons extension theorem, the renormalization of rough paths following up on [Bruned et al.: A rough path perspective on renormalization, J. Funct. Anal. 277(11), 2019], as well as a related notion of sum of rough paths. We first develop our ideas in a geometric rough path setting, as this best resonates with recent works on signature varieties, as well as with the renormalization of geometric rough paths. We then explore extensions to the quasi-geometric and the more general Hopf algebraic setting.

  • I. Chevyrev, P.K. Friz, A. Korepanov, I. Melbourne, H. Zhang, Deterministic homogenization under optimal moment assumptions for fast-slow systems. Part 2, Annales de l'Institut Henri Poincare. Probabilites et Statistiques, 58 (2022), pp. 1328--1350, DOI 10.1214/21-AIHP1203 .

  • N. Perkowski, W. van Zuijlen, Quantitative heat kernel estimates for diffusions with distributional drift, Potential Analysis, published online on 27.01.2022, DOI 10.1007/s11118-021-09984-3 .
    Abstract
    We consider the stochastic differential equation on ℝ d given by d X t = b(t,Xt ) d t + d Bt, where B is a Brownian motion and b is considered to be a distribution of regularity > - 1/2. We show that the martingale solution of the SDE has a transition kernel Γt and prove upper and lower heat kernel bounds for Γt with explicit dependence on t and the norm of b.

  • CH. Bayer, S. Breneis, Markovian approximations of stochastic Volterra equations with the fractional kernel, Quantitative Finance, 23 (2023), pp. 53--70 (published online on 24.11.2022), DOI 10.1080/14697688.2022.2139193 .
    Abstract
    We consider rough stochastic volatility models where the variance process satisfies a stochastic Volterra equation with the fractional kernel, as in the rough Bergomi and the rough Heston model. In particular, the variance process is therefore not a Markov process or semimartingale, and has quite low Hölder-regularity. In practice, simulating such rough processes thus often results in high computational cost. To remedy this, we study approximations of stochastic Volterra equations using an N-dimensional diffusion process defined as solution to a system of ordinary stochastic differential equation. If the coefficients of the stochastic Volterra equation are Lipschitz continuous, we show that these approximations converge strongly with superpolynomial rate in N. Finally, we apply this approximation to compute the implied volatility smile of a European call option under the rough Bergomi and the rough Heston model.

  • CH. Bayer, M. Fukasawa, S. Nakahara, Short communication: On the weak convergence rate in the discretization of rough volatility models, SIAM Journal on Financial Mathematics, ISSN 1945-497X, 13 (2022), pp. SC66--SC73, DOI 10.1137/22M1482871 .

  • CH. Bayer, J. Qiu, Y. Yao, Pricing options under rough volatility with backward SPDEs, SIAM Journal on Financial Mathematics, ISSN 1945-497X, 13 (2022), pp. 179--212, DOI 10.1137/20M1357639 .
    Abstract
    In this paper, we study the option pricing problems for rough volatility models. As the framework is non-Markovian, the value function for a European option is not deterministic; rather, it is random and satisfies a backward stochastic partial differential equation (BSPDE). The existence and uniqueness of weak solutions is proved for general nonlinear BSPDEs with unbounded random leading coefficients whose connections with certain forward-backward stochastic differential equations are derived as well. These BSPDEs are then used to approximate American option prices. A deep learning-based method is also investigated for the numerical approximations to such BSPDEs and associated non-Markovian pricing problems. Finally, the examples of rough Bergomi type are numerically computed for both European and American options.

  • P.K. Friz, J. Gatheral, R. Radoičić, Forests, cumulants, martingales, The Annals of Probability, 50 (2022), pp. 1418--1445, DOI 10.1214/21-AOP1560 .
    Abstract
    This work is concerned with forest and cumulant type expansions of general random variables on a filtered probability spaces. We establish a "broken exponential martingale" expansion that generalizes and unifies the exponentiation result of Alòs, Gatheral, and Radoičić and the cumulant recursion formula of Lacoin, Rhodes, and Vargas. Specifically, we exhibit the two previous results as lower dimensional projections of the same generalized forest expansion, subsequently related by forest reordering. Our approach also leads to sharp integrability conditions for validity of the cumulant formula, as required by many of our examples, including iterated stochastic integrals, Lévy area, Bessel processes, KPZ with smooth noise, Wiener-Itô chaos and "rough" stochastic (forward) variance models.

  • P.K. Friz, B. Seeger, P. Zorin-Kranich , Besov rough path analysis, Journal of Differential Equations, 339 (2022), pp. 152--231, DOI 10.1016/j.jde.2022.08.008 .
    Abstract
    Rough path analysis is developed in the full Besov scale. This extends, and essentially concludes, an investigation started by Prömel and Trabs (2016) [49], further studied in a series of papers by Liu, Prömel and Teichmann. A new Besov sewing lemma, a real-analysis result of interest in its own right, plays a key role, and the flexibility in the choice of Besov parameters allows for the treatment of equations not available in the Hölder or variation settings. Important classes of stochastic processes fit in the present framework.

  • W. König, N. Perkowski, W. van Zuijlen, Longtime asymptotics of the two-dimensional parabolic Anderson model with white-noise potential, Annales de l'Institut Henri Poincare. Probabilites et Statistiques, 58 (2022), pp. 1351--1384, DOI 10.1214/21-AIHP1215 .
    Abstract
    We consider the parabolic Anderson model (PAM) in ℝ ² with a Gaussian (space) white-noise potential. We prove that the almost-sure large-time asymptotic behaviour of the total mass at time t is given asymptotically by Χ t log t, with the deterministic constant Χ identified in terms of a variational formula. In earlier work of one of the authors this constant was used to describe the asymptotic behaviour principal Dirichlet of the eigenvalue the Anderson operator on the t by t box around zero asymptotically by Χ log t.

  • O. Butkovsky, K. Dareiotis, M. Geréncser, Approximation of SDEs: A stochastic sewing approach, Probability Theory and Related Fields, 181 (2021), pp. 975--1034, DOI 10.1007/s00440-021-01080-2 .

  • C. Bellingeri, A. Djurdjevac, P. Friz, N. Tapia, Transport and continuity equations with (very) rough noise, SN Partial Differential Equations and Applications, 2 (2021), pp. 2--26, DOI 10.1007/s42985-021-00101-y .
    Abstract
    Existence and uniqueness for rough flows, transport and continuity equations driven by general geometric rough paths are established.

  • C. Bellingeri, P. Friz, M. Gerencsér, Singular paths spaces and applications, Stochastic Analysis and Applications, 40 (2022), pp. 1126--1149 (published online on 29.10.2021), DOI 10.1080/07362994.2021.1988641 .

  • M. Ghani Varzaneh, S. Riedel, A dynamical theory for singular stochastic delay differential equations II: Nonlinear equations and invariant manifolds, AIMS Mathematics, 26 (2021), pp. 4587--4612, DOI 10.3934/dcdsb.2020304 .
    Abstract
    Building on results obtained in [GVRS], we prove Local Stable and Unstable Manifold Theorems for nonlinear, singular stochastic delay differential equations. The main tools are rough paths theory and a semi-invertible Multiplicative Ergodic Theorem for cocycles acting on measurable fields of Banach spaces obtained in [GVR].

  • CH. Bayer, F. Harang, P. Pigato, Log-modulated rough stochastic volatility models, SIAM Journal on Financial Mathematics, ISSN 1945-497X, 12 (2021), pp. 1257--1284, DOI 10.1137/20M135902X .
    Abstract
    We propose a new class of rough stochastic volatility models obtained by modulating the power-law kernel defining the fractional Brownian motion (fBm) by a logarithmic term, such that the kernel retains square integrability even in the limit case of vanishing Hurst index H. The so-obtained log-modulated fractional Brownian motion (log-fBm) is a continuous Gaussian process even for H = 0. As a consequence, the resulting super-rough stochastic volatility models can be analysed over the whole range of Hurst indices between 0 and 1/2, including H = 0, without the need of further normalization. We obtain the usual power law explosion of the skew as maturity T goes to 0, modulated by a logarithmic term, so no flattening of the skew occurs as H goes to 0.

  • P. Friz, P. Gassiat, P. Pigato, Precise asymptotics: Robust stochastic volatility models, The Annals of Applied Probability, 31 (2021), pp. 896--940, DOI 10.1214/20-AAP1608 .
    Abstract
    We present a new methodology to analyze large classes of (classical and rough) stochastic volatility models, with special regard to short-time and small noise formulae for option prices. Our main tool is the theory of regularity structures, which we use in the form of Bayer et al. (Math. Finance30 (2020) 782--832) In essence, we implement a Laplace method on the space of models (in the sense of Hairer), which generalizes classical works of Azencott and Ben Arous on path space and then Aida, Inahama--Kawabi on rough path space. When applied to rough volatility models, for example, in the setting of Bayer, Friz and Gatheral (Quant. Finance16 (2016) 887--904) and Forde--Zhang (SIAM J. Financial Math.8 (2017) 114--145), one obtains precise asymptotics for European options which refine known large deviation asymptotics.

  • P. Friz, P. Gassiat, P. Pigato, Short-dated smile under rough volatility: Asymptotics and numerics, Quantitative Finance, 22 (2022), pp. 463--480 (published online on 07.12.2021), DOI 10.1080/14697688.2021.1999486 .
    Abstract
    In Friz et al. [Precise asymptotics for robust stochastic volatility models. Ann. Appl. Probab, 2021, 31(2), 896?940], we introduce a new methodology to analyze large classes of (classical and rough) stochastic volatility models, with special regard to short-time and small-noise formulae for option prices, using the framework [Bayer et al., A regularity structure for rough volatility. Math. Finance, 2020, 30(3), 782?832]. We investigate here the fine structure of this expansion in large deviations and moderate deviations regimes, together with consequences for implied volatility. We discuss computational aspects relevant for the practical application of these formulas. We specialize such expansions to prototypical rough volatility examples and discuss numerical evidence.

  • P. Friz, H. Tran, Y. Yuan , Regularity of SLE in (t,k) and refined GRR estimates, Probability Theory and Related Fields, 180 (2021), pp. 71--112, DOI 10.1007/s00440-021-01058-0 .

  • O. Butkovsky, A. Kulik, M. Scheutzow, Generalized couplings and ergodic rates for SPDEs and other Markov models, The Annals of Applied Probability, 30 (2020), pp. 1--39, DOI 10.1214/19-AAP1485 .
    Abstract
    We establish verifiable general sufficient conditions for exponential or subexponential ergodicity of Markov processes that may lack the strong Feller property. We apply the obtained results to show exponential ergodicity of a variety of nonlinear stochastic partial differential equations with additive forcing, including 2D stochastic Navier-Stokes equations. Our main tool is a new version of the generalized coupling method.

  • O. Butkovsky, M. Scheutzow, Couplings via comparison principle and exponential ergodicity of SPDEs in the hypoelliptic setting, Communications in Mathematical Physics, 379 (2020), pp. 1001--1034, DOI 10.1007/s00220-020-03834-w .
    Abstract
    We develop a general framework for studying ergodicity of order-preserving Markov semigroups. We establish natural and in a certain sense optimal conditions for existence and uniqueness of the invariant measure and exponential convergence of transition probabilities of an order-preserving Markov process. As an application, we show exponential ergodicity and exponentially fast synchronization-by-noise of the stochastic reaction?diffusion equation in the hypoelliptic setting. This refines and complements corresponding results of Hairer and Mattingly (Electron J Probab 16:658?738, 2011).

  • S. Athreya, O. Butkovsky, L. Mytnik, Strong existence and uniqueness for stable stochastic differential equations with distributional drift, The Annals of Probability, 48 (2020), pp. 178--210, DOI 10.1214/19-AOP1358 .

  • D. Belomestny, J.G.M. Schoenmakers, Optimal stopping of McKean--Vlasov diffusions via regression on particle systems, SIAM Journal on Control and Optimization, 58 (2020), pp. 529--550, DOI 10.1137/18M1195590 .
    Abstract
    In this note we consider the problem of using regression on interacting particles to compute conditional expectations for McKean-Vlasov SDEs. We prove general result on convergence of linear regression algorithms and establish the corresponding rates of convergence. Application to optimal stopping and variance reduction are considered.

  • I. Chevyrev, P. Friz, A. Korepanov, I. Melbourne, Superdiffusive limits for deterministic fast-slow dynamical systems, Probability Theory and Related Fields, 178 (2020), pp. 735--770, DOI 10.1007/s00440-020-00988-5 .

  • M. Coghi, J.-D. Deuschel, P. Friz, M. Maurelli, Pathwise McKean--Vlasov theory with additive noise, The Annals of Applied Probability, 30 (2020), pp. 2355--2392, DOI 10.1214/20-AAP1560 .
    Abstract
    We take a pathwise approach to classical McKean-Vlasov stochastic differential equations with additive noise, as e.g. exposed in Sznitmann [34]. Our study was prompted by some concrete problems in battery modelling [19], and also by recent progress on rough-pathwise McKean-Vlasov theory, notably Cass--Lyons [9], and then Bailleul, Catellier and Delarue [4]. Such a “pathwise McKean-Vlasov theory” can be traced back to Tanaka [36]. This paper can be seen as an attempt to advertize the ideas, power and simplicity of the pathwise appproach, not so easily extracted from [4, 9, 36]. As novel applications we discuss mean field convergence without a priori independence and exchangeability assumption; common noise and reflecting boundaries. Last not least, we generalize Dawson--Gärtner large deviations to a non-Brownian noise setting.

  • CH. Bayer, D. Belomestny, M. Redmann, S. Riedel, J.G.M. Schoenmakers, Solving linear parabolic rough partial differential equations, Journal of Mathematical Analysis and Applications, 490 (2020), pp. 124236/1--124236/45, DOI 10.1016/j.jmaa.2020.124236 .
    Abstract
    We study linear rough partial differential equations in the setting of [Friz and Hairer, Springer, 2014, Chapter 12]. More precisely, we consider a linear parabolic partial differential equation driven by a deterministic rough path W of Hölder regularity α with ⅓ < α ≤ ½ . Based on a stochastic representation of the solution of the rough partial differential equation, we propose a regression Monte Carlo algorithm for spatio-temporal approximation of the solution. We provide a full convergence analysis of the proposed approximation method which essentially relies on the new bounds for the higher order derivatives of the solution in space. Finally, a comprehensive simulation study showing the applicability of the proposed algorithm is presented.

  • CH. Bayer, Ch.B. Hammouda, R. Tempone, Hierarchical adaptive sparse grids and quasi-Monte Carlo for option pricing under the rough Bergomi model, Quantitative Finance, published online on 20.04.2020, urlhttps://doi.org/10.1080/14697688.2020.1744700, DOI 10.1080/14697688.2020.1744700 .
    Abstract
    The rough Bergomi (rBergomi) model, introduced recently in Bayer et al. [Pricing under rough volatility. Quant. Finance, 2016, 16(6), 887?904], is a promising rough volatility model in quantitative finance. It is a parsimonious model depending on only three parameters, and yet remarkably fits empirical implied volatility surfaces. In the absence of analytical European option pricing methods for the model, and due to the non-Markovian nature of the fractional driver, the prevalent option is to use the Monte Carlo (MC) simulation for pricing. Despite recent advances in the MC method in this context, pricing under the rBergomi model is still a time-consuming task. To overcome this issue, we have designed a novel, hierarchical approach, based on: (i) adaptive sparse grids quadrature (ASGQ), and (ii) quasi-Monte Carlo (QMC). Both techniques are coupled with a Brownian bridge construction and a Richardson extrapolation on the weak error. By uncovering the available regularity, our hierarchical methods demonstrate substantial computational gains with respect to the standard MC method. They reach a sufficiently small relative error tolerance in the price estimates across different parameter constellations, even for very small values of the Hurst parameter. Our work opens a new research direction in this field, i.e. to investigate the performance of methods other than Monte Carlo for pricing and calibrating under the rBergomi model.

  • P. Friz, T. Nilssen, W. Stannat , Existence, uniqueness and stability of semi-linear rough partial differential equations, Journal of Differential Equations, 268 (2020), pp. 1686--1721, DOI 10.1016/j.jde.2019.09.033 .

  • A. Stephan, H. Stephan, Memory equations as reduced Markov processes, Discrete and Continuous Dynamical Systems, 39 (2019), pp. 2133--2155, DOI 10.3934/dcds.2019089 .
    Abstract
    A large class of linear memory differential equations in one dimension, where the evolution depends on the whole history, can be equivalently described as a projection of a Markov process living in a higher dimensional space. Starting with such a memory equation, we give an explicit construction of the corresponding Markov process. From a physical point of view the Markov process can be understood as the change of the type of some quasiparticles along one-way loops. Typically, the arising Markov process does not have the detailed balance property. The method leads to a more realisitc modeling of memory equations. Moreover, it carries over the large number of investigation tools for Markov processes to memory equations, like the calculation of the equilibrium state, the asymptotic behavior and so on. The method can be used for an approximative solution of some degenerate memory equations like delay differential equations.

  • C. Améndola, P. Friz, B. Sturmfels, Varieties of signature tensors, Forum of Mathematics. Sigma, 7 (2019), pp. e10/1--e10/54, DOI 10.1017/fms.2019.3 .
    Abstract
    The signature of a parametric curve is a sequence of tensors whose entries are iterated integrals. This construction is central to the theory of rough paths in stochastic analysis. It is examined here through the lens of algebraic geometry. We introduce varieties of signature tensors for both deterministic paths and random paths. For the former, we focus on piecewise linear paths, on polynomial paths, and on varieties derived from free nilpotent Lie groups. For the latter, we focus on Brownian motion and its mixtures.

  • P. Goyal, M. Redmann, Time-limited H2-optimal model order reduction, Applied Mathematics and Computation, 355 (2019), pp. 184--197, DOI 10.1016/j.amc.2019.02.065 .

  • W. Dreyer, P. Friz, P. Gajewski, C. Guhlke, M. Maurelli, Stochastic many-particle model for LFP electrodes, Continuum Mechanics and Thermodynamics, 30 (2018), pp. 593--628, DOI 10.1007/s00161-018-0629-7 .
    Abstract
    In the framework of non-equilibrium thermodynamics we derive a new model for porous electrodes. The model is applied to LiFePO4 (LFP) electrodes consisting of many LFP particles of nanometer size. The phase transition from a lithium-poor to a lithium-rich phase within LFP electrodes is controlled by surface fluctuations leading to a system of stochastic differential equations. The model is capable to derive an explicit relation between battery voltage and current that is controlled by thermodynamic state variables. This voltage-current relation reveals that in thin LFP electrodes lithium intercalation from the particle surfaces into the LFP particles is the principal rate limiting process. There are only two constant kinetic parameters in the model describing the intercalation rate and the fluctuation strength, respectively. The model correctly predicts several features of LFP electrodes, viz. the phase transition, the observed voltage plateaus, hysteresis and the rate limiting capacity. Moreover we study the impact of both the particle size distribution and the active surface area on the voltagecharge characteristics of the electrode. Finally we carefully discuss the phase transition for varying charging/discharging rates.

  • M. Heida, M. Röger, Large deviation principle for a stochastic Allen--Cahn equation, Journal of Theoretical Probability, 31 (2018), pp. 364--401, DOI 10.1007/s10959-016-0711-7 .
    Abstract
    The Allen-Cahn equation is a prototype model for phase separation processes, a fundamental example of a nonlinear spatial dynamic and an important approximation of a geometric evolution equation by a reaction-diffusion equation. Stochastic perturbations, especially in the case of additive noise, to the Allen-Cahn equation have attracted considerable attention. We consider here an alternative random perturbation determined by a Brownian flow of spatial diffeomorphism that was introduced by Röger and Weber [Stoch. Partial Differ. Equ. Anal. Comput. 1 (2013)]. We first provide a large deviation principle for stochastic flows in spaces of functions that are Hölder-continuous in time, which extends results by Budhiraja, Dupuis and Maroulas [Ann. Probab. 36 (2008)]. From this result and a continuity argument we deduce a large deviation principle for the Allen-Cahn equation perturbed by a Brownian flow in the limit of small noise. Finally, we present two asymptotic reductions of the large deviation functional.

  • M. Redmann, Energy estimates and model order reduction for stochastic bilinear systems, International Journal of Control, 93 (2020), pp. 1954--1963 (published online on 08.11.2018), DOI 10.1080/00207179.2018.1538568 .
    Abstract
    In this paper, we investigate a large-scale stochastic system with bilinear drift and linear diffusion term. Such high dimensional systems appear for example when discretizing a stochastic partial differential equations in space. We study a particular model order reduction technique called balanced truncation (BT) to reduce the order of spatially-discretized systems and hence reduce computational complexity. We introduce suitable Gramians to the system and prove energy estimates that can be used to identify states which contribute only very little to the system dynamics. When BT is applied the reduced system is obtained by removing these states from the original system. The main contribution of this paper is an L2-error bound for BT for stochastic bilinear systems. This result is new even for deterministic bilinear equations. In order to achieve it, we develop a new technique which is not available in the literature so far.

  • M. Redmann, Type II singular perturbation approximation for linear systems with Lévy noise, SIAM Journal on Control and Optimization, 56 (2018), pp. 2120--2158, DOI 10.1137/17M113160X .
    Abstract
    When solving linear stochastic partial differential equations numerically, usually a high order spatial discretisation is needed. Model order reduction (MOR) techniques are often used to reduce the order of spatially-discretised systems and hence reduce computational complexity. A particular MOR technique to obtain a reduced order model (ROM) is singular perturbation approximation (SPA), a method which has been extensively studied for deterministic systems. As so-called type I SPA it has already been extended to stochastic equations. We provide an alternative generalisation of the deterministic setting to linear systems with Lévy noise which is called type II SPA. It turns out that the ROM from applying type II SPA has better properties than the one of using type I SPA. In this paper, we provide new energy interpretations for stochastic reachability Gramians, show the preservation of mean square stability in the ROM by type II SPA and prove two different error bounds for type II SPA when applied to Lévy driven systems

  • D. Belomestny, J.G.M. Schoenmakers, Projected particle methods for solving McKean--Vlasov equations, SIAM Journal on Numerical Analysis, 56 (2018), pp. 3169--3195, DOI 10.1137/17M1111024 .
    Abstract
    We propose a novel projection-based particle method for solving McKean--Vlasov stochastic differential equations. Our approach is based on a projection-type estimation of the marginal density of the solution in each time step. The projection-based particle method leads in many situations to a significant reduction of numerical complexity compared to the widely used kernel density estimation algorithms. We derive strong convergence rates and rates of density estimation. The convergence analysis, particularly in the case of linearly growing coefficients, turns out to be rather challenging and requires some new type of averaging technique. This case is exemplified by explicit solutions to a class of McKean--Vlasov equations with affine drift. The performance of the proposed algorithm is illustrated by several numerical examples.

  • K. Chouk, P. Friz, Support theorem for a singular SPDE: The case of gPAM, Annales de l'Institut Henri Poincare. Probabilites et Statistiques, 54 (2018), pp. 202-219.
    Abstract
    We consider the generalized parabolic Anderson equation (gPAM) in 2 dimensions with periodic boundary. This is an example of a singular semilinear stochastic partial differential equation in the subcritical regime, with (renormalized) solutions only recently understood via Hairer?s regularity structures and, in some cases equivalently, paracontrollled distributions by Gubinelli, Imkeller and Perkowski. In the present paper we utilise the paracontrolled machinery and obtain a (Stroock?Varadhan) type support description for the law of gPAM. In the spirit of rough paths, the crucial step is to identify the support of the enhanced noise in a sufficiently fine topology. The renormalization is seen to affect the support description.

  • CH. Bayer, H. Mai, J.G.M. Schoenmakers, Forward-reverse expectation-maximization algorithm for Markov chains: Convergence and numerical analysis, Advances in Applied Probability, 2 (2018), pp. 621--644, DOI 10.1017/apr.2018.27 .
    Abstract
    We develop a forward-reverse expectation-maximization (FREM) algorithm for estimating parameters of a discrete-time Markov chain evolving through a certain measurable state-space. For the construction of the FREM method, we develop forward-reverse representations for Markov chains conditioned on a certain terminal state. We prove almost sure convergence of our algorithm for a Markov chain model with curved exponential family structure. On the numerical side, we carry out a complexity analysis of the forward-reverse algorithm by deriving its expected cost. Two application examples are discussed.

  • P. Friz, H. Zhang, Differential equations driven by rough paths with jumps, Journal of Differential Equations, 264 (2018), pp. 6226--6301, DOI 10.1016/j.jde.2018.01.031 .
    Abstract
    We develop the rough path counterpart of Itô stochastic integration and differential equations driven by general semimartingales. This significantly enlarges the classes of (Itô/forward) stochastic differential equations treatable with pathwise methods. A number of applications are discussed.

  • M. Redmann, P. Benner, Singular perturbation approximation for linear systems with Lévy noise, Stochastics and Dynamics, published online on 10.08.2017, urlhttps://doi.org/10.1142/S0219493718500338, DOI 10.1142/S0219493718500338 .
    Abstract
    To solve a stochastic linear evolution equation numerically, finite dimensional approximations are commonly used. For a good approximation, one might end up with a sequence of ordinary stochastic linear equations of high order. To reduce the high dimension for practical computations, we consider the singular perturbation approximation as a model order reduction technique in this paper. This approach is well-known from deterministic control theory and here we generalize it for controlled linear systems with Lévy noise. Additionally, we discuss properties of the reduced order model, provide an error bound, and give some examples to demonstrate the quality of this model order reduction technique.

  • G. Cannizzaro, P. Friz, P. Gassiat, Malliavin calculus for regularity structures: The case of gPAM, Journal of Functional Analysis, 272 (2017), pp. 363--419, DOI 10.1016/j.jfa.2016.09.024 .
    Abstract
    Malliavin calculus is implemented in the context of Hairer (2014) [16]. This involves some constructions of independent interest, notably an extension of the structure which accommodates a robust, and purely deterministic, translation operator, in -directions, between ?models?. In the concrete context of the generalized parabolic Anderson model in 2D ? one of the singular SPDEs discussed in the afore-mentioned article ? we establish existence of a density at positive times.

  • J.-D. Deuschel, P. Friz, M. Maurelli, M. Slowik, The enhanced Sanov theorem and propagation of chaos, Stochastic Processes and their Applications, 128 (2018), pp. 2228--2269 (published online on 21.09.2017), DOI 10.1016/j.spa.2017.09.010 .
    Abstract
    We establish a Sanov type large deviation principle for an ensemble of interacting Brownian rough paths. As application a large deviations for the (k-layer, enhanced) empirical measure of weakly interacting diffusions is obtained. This in turn implies a propagation of chaos result in a space of rough paths and allows for a robust analysis of the particle system and its McKean?Vlasov type limit, as shown in two corollaries.

  • A. Münch, B. Wagner, L.P. Cook, R.R. Braun, Apparent slip for an upper convected Maxwell fluid, SIAM Journal on Applied Mathematics, 77 (2017), pp. 537--564, DOI 10.1137/16M1056869 .
    Abstract
    In this study the flow field of a nonlocal, diffusive upper convected Maxwell (UCM) fluid with a polymer in a solvent undergoing shearing motion is investigated for pressure driven planar channel flow and the free boundary problem of a liquid layer on a solid substrate. For large ratios of the zero shear polymer viscosity to the solvent viscosity, it is shown that channel flows exhibit boundary layers at the channel walls. In addition, for increasing stress diffusion the flow field away from the boundary layers undergoes a transition from a parabolic to a plug flow. Using experimental data for the wormlike micelle solutions CTAB/NaSal and CPyCl/NaSal, it is shown that the analytic solution of the governing equations predicts these signatures of the velocity profiles. Corresponding flow structures and transitions are found for the free boundary problem of a thin layer sheared along a solid substrate. Matched asymptotic expansions are used to first derive sharp-interface models describing the bulk flow with expressions for an em apparent slip for the boundary conditions, obtained by matching to the flow in the boundary layers. For a thin film geometry several asymptotic regimes are identified in terms of the order of magnitude of the stress diffusion, and corresponding new thin film models with a slip boundary condition are derived.

  • P. Friz, J. Diehl, P. Gassiat, Stochastic control with rough paths, Applied Mathematics and Optimization. An International Journal with Applications to Stochastics, 75 (2017), pp. 285--315, DOI 10.1007/s00245-016-9333-9 .

  • P. Friz, S. Gerhold, A. Pinter, Option pricing in the moderate deviations regime, Mathematical Finance. An International Journal of Mathematics, Statistics and Financial Economics, published online on 25.08.2017, urlhttps://doi.org/10.1111/mafi.12156, DOI 10.1111/mafi.12156 .

  • P. Friz, A. Shekhar, General rough integration, Lévy rough paths and a Lévy--Kintchine type formula, The Annals of Probability, 45 (2017), pp. 2707--2765, DOI 10.1214/16- AOP1123 .

  • P. Friz, A. Shekhar, On the existence of SLE trace: Finite energy drivers and non-constant $kappa$, Probability Theory and Related Fields, 169 (2017), pp. 353--376.

  • P. Friz, H. Tran , On the regularity of SLE trace, Forum of Mathematics. Sigma, 5 (2017), pp. e19/1--e19/17, DOI 10.1017/fms.2017.18 .
    Abstract
    We revisit regularity of SLE trace, for all , and establish Besov regularity under the usual half-space capacity parametrization. With an embedding theorem of Garsia?Rodemich?Rumsey type, we obtain finite moments (and hence almost surely) optimal variation regularity with index , improving on previous works of Werness, and also (optimal) Hölder regularity à la Johansson Viklund and Lawler.

  • E. Meca Álvarez, A. Münch, B. Wagner, Sharp-interface formation during lithium intercalation into silicon, European Journal of Applied Mathematics, 29 (2018), pp. 118--145, DOI 10.1017/S0956792517000067 .
    Abstract
    In this study we present a phase-field model that describes the process of intercalation of Li ions into a layer of an amorphous solid such as a-Si. The governing equations couple a viscous Cahn-Hilliard-Reaction model with elasticity in the framework of the Cahn-Larché system. We discuss the parameter settings and flux conditions at the free boundary that lead to the formation of phase boundaries having a sharp gradient in ion concentration between the initial state of the solid layer and the intercalated region. We carry out a matched asymptotic analysis to derive the corresponding sharp-interface model that also takes into account the dynamics of triple points where the sharp interface in the bulk of the layer intersects the free boundary. We numerically compare the interface motion predicted by the sharp-interface model with the long-time dynamics of the phase-field model.

  • Z. Brzezniak, F. Flandoli, M. Maurelli, Existence and uniqueness for stochastic 2D Euler flows with bounded vorticity, Archive for Rational Mechanics and Analysis, 221 (2016), pp. 107--142.

  • J. Diehl, P. Friz, H. Mai, Pathwise stability of likelihood estimators for diffusions via rough paths, The Annals of Applied Probability, 26 (2016), pp. 2169--2192.
    Abstract
    We consider the estimation problem of an unknown drift parameter within classes of non-degenerate diffusion processes. The Maximum Likelihood Estimator (MLE) is analyzed with regard to its pathwise stability properties and robustness towards misspecification in volatility and even the very nature of noise. We construct a version of the estimator based on rough integrals (in the sense of T. Lyons) and present strong evidence that this construction resolves a number of stability issues inherent to the standard MLEs.

  • G.N. Milstein, J.G.M. Schoenmakers, Uniform approximation of the CIR process via exact simulation at random times, Advances in Applied Probability, 48 (2016), pp. 1095--1116.
    Abstract
    In this paper we uniformly approximate the trajectories of the Cox-Ingersoll-Ross (CIR) process. At a sequence of random times the approximate trajectories will be even exact. In between, the approximation will be uniformly close to the exact trajectory. From a conceptual point of view the proposed method gives a better quality of approximation in a path-wise sense than standard, or even exact simulation of the CIR dynamics at some deterministic time grid.

  • CH. Bayer, P. Friz, J. Gatheral, Pricing under rough volatility, Quantitative Finance, 16 (2016), pp. 887--904.
    Abstract
    From an analysis of the time series of volatility using recent high frequency data, Gatheral, Jaisson and Rosenbaum [SSRN 2509457, 2014] previously showed that log-volatility behaves essentially as a fractional Brownian motion with Hurst exponent H of order 0.1, at any reasonable time scale. The resulting Rough Fractional Stochastic Volatility (RFSV) model is remarkably consistent with financial time series data. We now show how the RFSV model can be used to price claims on both the underlying and integrated volatility. We analyze in detail a simple case of this model, the rBergomi model. In particular, we find that the rBergomi model fits the SPX volatility markedly better than conventional Markovian stochastic volatility models, and with fewer parameters. Finally, we show that actual SPX variance swap curves seem to be consistent with model forecasts, with particular dramatic examples from the weekend of the collapse of Lehman Brothers and the Flash Crash.

  • CH. Bayer, P. Friz, S. Riedel, J.G.M. Schoenmakers, From rough path estimates to multilevel Monte Carlo, SIAM Journal on Numerical Analysis, 54 (2016), pp. 1449--1483.
    Abstract
    Discrete approximations to solutions of stochastic differential equations are well-known to converge with strong rate 1/2. Such rates have played a key-role in Giles' multilevel Monte Carlo method [Giles, Oper. Res. 2008] which gives a substantial reduction of the computational effort necessary for the evaluation of diffusion functionals. In the present article similar results are established for large classes of rough differential equations driven by Gaussian processes (including fractional Brownian motion with H>1/4 as special case).

  • P. Friz, B. Gess, A. Gulisashvili, S. Riedel, The Jain--Monrad criterion for rough paths and applications to random Fourier series and non-Markovian Hörmander theory, The Annals of Probability, 44 (2016), pp. 684--738.
    Abstract
    We discuss stochastic calculus for large classes of Gaussian processes, based on rough path analysis. Our key condition is a covariance measure structure combined with a classical criterion due to Jain and Monrad [Ann. Probab. 11 (1983) 46?57]. This condition is verified in many examples, even in absence of explicit expressions for the covariance or Volterra kernels. Of special interest are random Fourier series, with covariance given as Fourier series itself, and we formulate conditions directly in terms of the Fourier coefficients. We also establish convergence and rates of convergence in rough path metrics of approximations to such random Fourier series. An application to SPDE is given. Our criterion also leads to an embedding result for Cameron?Martin paths and complementary Young regularity (CYR) of the Cameron?Martin space and Gaussian sample paths. CYR is known to imply Malliavin regularity and also Itô-like probabilistic estimates for stochastic integrals (resp., stochastic differential equations) despite their (rough) pathwise construction. At last, we give an application in the context of non-Markovian Hörmander theory.

  • P. Friz, B. Gess, Stochastic scalar conservation laws driven by rough paths, Annales de l'Institut Henri Poincare. Analyse Non Lineaire, 33 (2016), pp. 933--963, DOI 10.1016/j.anihpc.2015.01.009 .

  • R. Allez, L. Dumaz, Random matrices in non-confining potentials, Journal of Statistical Physics, 160 (2015), pp. 681--714.
    Abstract
    We consider invariant matrix processes diffusing in non-confining cubic potentials of the form Va(x)=x3/3?ax,a??. We construct the trajectories of such processes for all time by restarting them whenever an explosion occurs, from a new (well chosen) initial condition, insuring continuity of the eigenvectors and of the non exploding eigenvalues. We characterize the dynamics of the spectrum in the limit of large dimension and analyze the stationary state of this evolution explicitly. We exhibit a sharp phase transition for the limiting spectral density ?a at a critical value a=a?. If a?a?, then the potential Va presents a well near x=a?? deep enough to confine all the particles inside, and the spectral density ?a is supported on a compact interval. If a

  • Z. Grbac, A. Papapantoleon, J.G.M. Schoenmakers, D. Skovmand, Affine LIBOR models with multiple curves: Theory, examples and calibration, SIAM Journal on Financial Mathematics, ISSN 1945-497X, 6 (2015), pp. 984--1025.
    Abstract
    We introduce a multiple curve LIBOR framework that combines tractable dynamics and semi-analytic pricing formulas with positive interest rates and basis spreads. The dynamics of OIS and LIBOR rates are specified following the methodology of the affine LIBOR models and are driven by the wide and flexible class of affine processes. The affine property is preserved under forward measures, which allows to derive Fourier pricing formulas for caps, swaptions and basis swaptions. A model specification with dependent LIBOR rates is developed, that allows for an efficient and accurate calibration to a system of caplet prices.

  • D. Belomestny, M. Ladkau, J.G.M. Schoenmakers, Simulation based policy iteration for American style derivatives -- A multilevel approach, SIAM ASA J. Uncertainty Quantification, 3 (2015), pp. 460--483.
    Abstract
    This paper presents a novel approach to reduce the complexity of simulation based policy iteration methods for pricing American options. Typically, Monte Carlo construction of an improved policy gives rise to a nested simulation algorithm for the price of the American product. In this respect our new approach uses the multilevel idea in the context of the inner simulations required, where each level corresponds to a specific number of inner simulations. A thorough analysis of the crucial convergence rates in the respective multilevel policy improvement algorithm is presented. A detailed complexity analysis shows that a significant reduction in computational effort can be achieved in comparison to standard Monte Carlo based policy iteration.

  • G.N. Milstein, J.G.M. Schoenmakers, Uniform approximation of the Cox--Ingersoll--Ross process, Advances in Applied Probability, 47 (2015), pp. 1132--1156.
    Abstract
    The Doss-Sussmann (DS) approach is used for simulating the Cox-Ingersoll-Ross (CIR) process. The DS formalism allows for expressing trajectories of the CIR process by solutions of some ordinary differential equation (ODE) that depend on realizations of the Wiener process involved. Via simulating the first-passage times of the increments of the Wiener process to the boundary of an interval and solving an ODE, we approximately construct the trajectories of the CIR process. From a conceptual point of view the proposed method may be considered as an exact simulation approach.

  • R. Allez, L. Dumaz, Tracy--Widom at high temperature, Journal of Statistical Physics, 156 (2014), pp. 1146--1183.
    Abstract
    We investigate the marginal distribution of the bottom eigenvalues of the stochastic Airy operator when the inverse temperature ? tends to 0. We prove that the minimal eigenvalue, whose fluctuations are governed by the Tracy?Widom ? law, converges weakly, when properly centered and scaled, to the Gumbel distribution. More generally we obtain the convergence in law of the marginal distribution of any eigenvalue with given index k. Those convergences are obtained after a careful analysis of the explosion times process of the Riccati diffusion associated to the stochastic Airy operator. We show that the empirical measure of the explosion times converges weakly to a Poisson point process using estimates proved in Dumaz and Virág (Ann Inst H Poincaré Probab Statist 49(4):915?933, 2013). We further compute the empirical eigenvalue density of the stochastic Airy ensemble on the macroscopic scale when ??0. As an application, we investigate the maximal eigenvalues statistics of ?N-ensembles when the repulsion parameter ?N?0 when N?+?. We study the double scaling limit N?+?,?N?0 and argue with heuristic and numerical arguments that the statistics of the marginal distributions can be deduced following the ideas of Edelman and Sutton (J Stat Phys 127(6):1121?1165, 2007) and Ramírez et al. (J Am Math Soc 24:919?944, 2011) from our later study of the stochastic Airy operator.

  • J.D. Deuschel, P. Friz, A. Jacquier, S. Violante , Marginal density expansions for diffusions and stochastic volatility: Part I, Communications on Pure and Applied Mathematics, 67 (2014), pp. 40--82.

  • J.D. Deuschel, P. Friz, A. Jacquier, S. Violante , Marginal density expansions for diffusions and stochastic volatility: Part II, Communications on Pure and Applied Mathematics, 67 (2014), pp. 321--350.

  • F. Flandoli, M. Maurelli, M. Neklyudov, Noise prevents infinite stretching of the passive field in a stochastic vector advection equation, Journal of Mathematical Fluid Mechanics, 16 (2014), pp. 805--822.

  • A. Gloria, S. Neukamm, F. Otto, An optimal quantitative two-scale expansion in stochastic homogenization of discrete elliptic equations, ESAIM: Mathematical Modelling and Numerical Analysis, 48 (2014), pp. 325--346.
    Abstract
    We establish an optimal, linear rate of convergence for the stochastic homogenization of discrete linear elliptic equations. We consider the model problem of independent and identically distributed coefficients on a discretized unit torus. We show that the difference between the solution to the random problem on the discretized torus and the first two terms of the two-scale asymptotic expansion has the same scaling as in the periodic case. In particular the L2-norm in probability of the H1-norm in space of this error scales like ε, where ε is the discretization parameter of the unit torus. The proof makes extensive use of previous results by the authors, and of recent annealed estimates on the Greens function by Marahrens and the third author.

  • CH. Bayer, H. Hoel, E. VON Schwerin, R. Tempone, On non-asymptotic optimal stopping criteria in Monte Carlo simulations, SIAM Journal on Scientific Computing, 36 (2014), pp. A869--A885.
    Abstract
    We consider the setting of estimating the mean of a random variable by a sequential stopping rule Monte Carlo (MC) method. The performance of a typical second moment based sequential stopping rule MC method is shown to be unreliable in such settings both by numerical examples and through analysis. By analysis and approximations, we construct a higher moment based stopping rule which is shown in numerical examples to perform more reliably and only slightly less efficiently than the second moment based stopping rule.

  • CH. Bayer, J.G.M. Schoenmakers, Simulation of forward-reverse stochastic representations for conditional diffusions, The Annals of Applied Probability, 24 (2014), pp. 1994--2032.
    Abstract
    In this paper we derive stochastic representations for the finite dimensional distributions of a multidimensional diffusion on a fixed time interval, conditioned on the terminal state. The conditioning can be with respect to a fixed point or more generally with respect to some subset. The representations rely on a reverse process connected with the given (forward) diffusion as introduced in Milstein et al. [Bernoulli, 10(2):281-312, 2004] in the context of a forward-reverse transition density estimator. The corresponding Monte Carlo estimators have essentially root-N accuracy, hence they do not suffer from the curse of dimensionality. We provide a detailed convergence analysis and give a numerical example involving the realized variance in a stochastic volatility asset model conditioned on a fixed terminal value of the asset.

  • P. Friz, S. Gerhold, M. Yor, How to make Dupire's local volatility work with jumps, Quantitative Finance, 14 (2014), pp. 1327--1331.
    Abstract
    There are several (mathematical) reasons why Dupire?s formula fails in the non-diffusion setting. And yet, in practice, ad-hoc preconditioning of the option data works reasonably well. In this note, we attempt to explain why. In particular, we propose a regularization procedure of the option data so that Dupire?s local vol diffusion process recreates the correct option prices, even in manifest presence of jumps.

  • P. Friz, H. Oberhauser, Rough path stability of (semi-)linear SPDEs, Probability Theory and Related Fields, 158 (2014), pp. 401--434.

  • P. Friz, S. Riedel, Convergence rates for the full Gaussian rough paths, Annales de l'Institut Henri Poincare. Probabilites et Statistiques, 50 (2014), pp. 154--194.

  • M. Ladkau, J.G.M. Schoenmakers, J. Zhang, Libor model with expiry-wise stochastic volatility and displacement, International Journal of Portfolio Analysis and Management, 1 (2013), pp. 224--249.
    Abstract
    We develop a multi-factor stochastic volatility Libor model with displacement, where each individual forward Libor is driven by its own square-root stochastic volatility process. The main advantage of this approach is that, maturity-wise, each square-root process can be calibrated to the corresponding cap(let)vola-strike panel at the market. However, since even after freezing the Libors in the drift of this model, the Libor dynamics are not affine, new affine approximations have to be developed in order to obtain Fourier based (approximate) pricing procedures for caps and swaptions. As a result, we end up with a Libor modeling package that allows for efficient calibration to a complete system of cap/swaption market quotes that performs well even in crises times, where structural breaks in vola-strike-maturity panels are typically observed.

  • D. Belomestny, J.G.M. Schoenmakers, F. Dickmann, Multilevel dual approach for pricing American style derivatives, Finance and Stochastics, 17 (2013), pp. 717-742.
    Abstract
    In this article we propose a novel approach to reduce the computational complexity of the dual method for pricing American options. We consider a sequence of martingales that converges to a given target martingale and decompose the original dual representation into a sum of representations that correspond to different levels of approximation to the target martingale. By next replacing in each representation true conditional expectations with their Monte Carlo estimates, we arrive at what one may call a multilevel dual Monte Carlo algorithm. The analysis of this algorithm reveals that the computational complexity of getting the corresponding target upper bound, due to the target martingale, can be significantly reduced. In particular, it turns out that using our new approach, we may construct a multilevel version of the well-known nested Monte Carlo algorithm of Andersen and Broadie (2004) that is, regarding complexity, virtually equivalent to a non-nested algorithm. The performance of this multilevel algorithm is illustrated by a numerical example.

  • D. Crisan, J. Diehl, P. Friz, H. Oberhauser, Robust filtering: Correlated noise and multidimensional observation, The Annals of Applied Probability, 23 (2013), pp. 2139--2160.

  • P. Friz, S. Riedel, Integrability of (non-)linear rough differential equations and integrals, Stochastic Analysis and Applications, 31 (2013), pp. 336--358.

  • P. Friz, A. Shekar, Doob--Meyer and rough paths, Bulletin of the Institute of Mathematics. Academia Sinica. Institute of Mathematics, Academia Sinica, Taipei, Taiwan. English. English summary., 8 (2013), pp. 73--84.

  • P. Friz, Ch. Bayer, Functional convergence of the cubature tree on Wiener space, Applied Mathematics and Optimization. An International Journal with Applications to Stochastics, 67 (2013), pp. 261--278.

  • CH. Bayer, P. Friz, Cubature on Wiener space: Pathwise convergence, Applied Mathematics and Optimization. An International Journal with Applications to Stochastics, 67 (2013), pp. 261--278.

  • P. Friz, J. Diehl, Backward stochastic differential equations with rough drivers, The Annals of Probability, 40 (2012), pp. 1715--1758.

  • A. Papapantoleon, J.G.M. Schoenmakers, D. Skovmand, Efficient and accurate log-Lévy approximations to Lévy driven LIBOR models, Journal of Computational Finance, 15 (2012), pp. 3--44.
    Abstract
    The LIBOR market model is very popular for pricing interest rate derivatives, but is known to have several pitfalls. In addition, if the model is driven by a jump process, then the complexity of the drift term is growing exponentially fast (as a function of the tenor length). In this work, we consider a Lévy-driven LIBOR model and aim at developing accurate and efficient log-Lévy approximations for the dynamics of the rates. The approximations are based on truncation of the drift term and Picard approximation of suitable processes. Numerical experiments for FRAs, caps and swaptions show that the approximations perform very well. In addition, we also consider the log-Lévy approximation of annuities, which offers good approximations for high volatility regimes.

  • M. Caruana, P. Friz, H. Oberhauser, A (rough) pathwise approach to a class of nonlinear SPDEs, Annales de l'Institut Henri Poincare. Analyse Non Lineaire, 28 (2011), pp. 27--46.

  • TH. Cass, P. Friz, Malliavin calculus and rough paths, Bulletin des Sciences Mathematiques, 135 (2011), pp. 542--556.

  • P. Friz, S. Riedel, Convergence rates for the full Brownian rough paths with applications to limit theorems for stochastic flows, Bulletin des Sciences Mathematiques, 135 (2011), pp. 613--628.

  • P. Friz, N. Victoir, A note on higher dimensional p-variation, Electronic Journal of Probability, 16 (2011), pp. 1880--1899.

  • H. Oberhauser, P. Friz, On the splitting-up method for rough (partial) differential equations, Journal of Differential Equations, 251 (2011), pp. 316--338.

  • P. Friz, Th. Cass, Densities for rough differential equations under Hoermander's condition, Ann. Math. (2), 171 (2010), pp. 2115--2141.

  • P. Friz, H. Oberhauser, A generalized Fernique theorem and applications, Proceedings of the American Mathematical Society, 138 (2010), pp. 3679--3688.

  • P. Friz, N. Victoir, Differential equations driven by Gaussian signals, Annales de l'Institut Henri Poincare. Probabilites et Statistiques, 46 (2010), pp. 369--413.

  • A.E. Kyprianou, R.L. Loeffen, Refracted Lévy processes, Annales de l'Institut Henri Poincare. Probabilites et Statistiques, 46 (2010), pp. 24--44.

  • P. Friz, E. Breuillard, M. Huesmann, From random walks to rough paths, Proceedings of the American Mathematical Society, 137 (2009), pp. 3487--3496.

  • P. Friz, M. Caruana, Partial differential equations driven by rough paths, Journal of Differential Equations, 247 (2009), pp. 140--173.

  • P. Friz, T. Cass, N. Victoir, Non-degeneracy of Wiener functionals arising from rough differential equations, Transactions of the American Mathematical Society, 361 (2009), pp. 3359--3371.

  • P. Friz, H. Oberhauser, Rough path limits of Wong--Zakai type with modified drift term, Journal of Functional Analysis, 256 (2009), pp. 3236--3256.

  • G.N. Milstein, J.G.M. Schoenmakers, V. Spokoiny, Forward and reverse representations for Markov chains, Stochastic Processes and their Applications, 117 (2007), pp. 1052--1075.
    Abstract
    In this paper we carry over the concept of reverse probabilistic representations developed in Milstein, Schoenmakers, Spokoiny (2004) for diffusion processes, to discrete time Markov chains. We outline the construction of reverse chains in several situations and apply this to processes which are connected with jump-diffusion models and finite state Markov chains. By combining forward and reverse representations we then construct transition density estimators for chains which have root-N accuracy in any dimension and consider some applications.

  • D. Spivakovskaya, A.W. Heemink, J.G.M. Schoenmakers, Two-particle models for the estimation of the mean and standard deviation of concentrations in coastal waters, Stochastic Environmental Research and Risk Assessment (SERRA), 21 (2007), pp. 235--251.

  • E. VAN DEN Berg, A.W. Heemink, H.X. Lin, J.G.M. Schoenmakers, Probability density estimation in stochastic environmental models using reverse representations, Stochastic Environmental Research & Risk Assessment, 20 (2006), pp. 126--139.
    Abstract
    The estimation of probability densities of variables described by stochastic differential equations has long been done using forward time estimators, which rely on the generation of forward in time realizations of the model. Recently, an estimator based on the combination of forward and reverse time estimators has been developed. This estimator has a higher order of convergence than the classical one. In this article, we explore the new estimator and compare the forward and forward? reverse estimators by applying them to a biochemical oxygen demand model. Finally, we show that the computational efficiency of the forward?reverse estimator is superior to the classical one, and discuss the algorithmic aspects of the estimator.

  • D. Spivakovskaya, A.W. Heemink, G.N. Milstein, J.G.M. Schoenmakers, Simulation of the transport of particles in coastal waters using forward and reverse time diffusion, Advances in Water Resources, 28 (2005), pp. 927--938.
    Abstract
    Particle models are often used to simulate the spreading of a pollutant in coastal waters in case of a calamity at sea. Here many different particle tracks starting at the point of release are generated to determine the particle concentration at some critical locations after the release. This Monte Carlo method however consumes a large CPU time. Recently, Milstein, Schoenmakers and Spokoiny (2003) introduced the concept of reverse-time diffusion. They derived a reverse system from the original forward simulation model and showed that the Monte Carlo estimator can also be based on realizations of this reverse system. In this paper we apply this concept to estimate particle concentrations in coastal waters. The results for the experiments considered show that the CPU time compared with the classical method is reduced orders of magnitude.

  • G.N. Milstein, J.G.M. Schoenmakers, V. Spokoiny, Transition density estimation for stochastic differential equations via forward-reverse representations, Bernoulli. Official Journal of the Bernoulli Society for Mathematical Statistics and Probability, 10 (2004), pp. 281--312.
    Abstract
    The general reverse diffusion equations are derived and applied to the problem of transition density estimation of diffusion processes between two fixed states. For this problem we propose density estimation based on forward?reverse representations and show that this method allows essentially better results to be achieved than the usual kernel or projection estimation based on forward representations only.

  • O. Kurbanmuradov, K. Sabelfeld, J.G.M. Schoenmakers, Lognormal approximations to LIBOR market models, Journal of Computational Finance, 6 (2002), pp. 69--100.
    Abstract
    We study several lognormal approximations for LIBOR market models, where special attention is paid to their simulation by direct methods and lognormal random fields. In contrast to conventional numerical solution of SDE's this approach simulates the solution directly at a desired point in time and therefore may be more efficient. As such the proposed approximations provide valuable alternatives to the Euler method, in particular for long dated instruments. We carry out a path-wise comparison of the different lognormal approximations with the 'exact' SDE solution obtained by the Euler scheme using sufficiently small time steps. Also we test approximations obtained via numerical solution of the SDE by the Euler method, using larger time steps. It turns out that for typical volatilities observed in practice, improved versions of the lognormal approximation proposed by Brace, Gatarek and Musiela, citeBrace, appear to have excellent path-wise accuracy. We found out that this accuracy can also be achieved by Euler stepping the SDE using larger time steps, however, from a comparative cost analysis it follows that, particularly for long maturity options, the latter method is more time consuming than the lognormal approximation. We conclude with applications to some example LIBOR derivatives.

  • J.G.M. Schoenmakers, A.W. Heemink, K. Ponnambalm, P.E. Kloeden, Variance reduction for Monte Carlo simulation of stochastic environmental models, Applied Mathematical Modelling. Simulation and Computation for Engineering and Environmental Systems. Elsevier Science Inc., New York, NY. English, English abstracts., 26 (2002), pp. 787--795.
    Abstract
    To determine the probability of exceedence Monte Carlo simulation of stochastic models is often used. Mathematically this requires the evaluation of an expectation of some function of a solution of a stochastic model. This can be reformulated as a Kolmogorov final value problem. It can thus be calculated numerically by either solving a deterministic partial differential equation (Kolmogorov's Backwards equations) or by simulating a large number of trajectories of the stochastic differential equation. Here we discuss a composite method of variance reduced Monte Carlo simulation. The variance reduction is obtained by the Girsanov transformation to modify the stochastic model by a correction term that is obtained from an approximate solution of the partial differential equation computed by a classical numerical method. The composite method is more efficient than either the standard Monte Carlo or the classical numerical method. The approach is applied to estimate the probability of exceedence in a model for biochemical-oxygen demand.

  Contributions to Collected Editions

  • A.H. Erhardt, K. Tsaneva-Atanasova, G.T. Lines, E.A. Martens, Editorial: Dynamical systems, PDEs and networks for biomedical applications: Mathematical modeling, analysis and simulations, 10 of Front. Phys., Sec. Statistical and Computational Physics, Frontiers, Lausanne, Switzerland, 2023, pp. 01--03, DOI 10.3389/fphy.2022.1101756 .

  • D. Peschka, M. Thomas, T. Ahnert, A. Münch, B. Wagner, Gradient structures for flows of concentrated suspensions, in: Topics in Applied Analysis and Optimisation, M. Hintermüller, J.F. Rodrigues, eds., CIM Series in Mathematical Sciences, Springer Nature Switzerland AG, Cham, 2019, pp. 295--318, DOI 10.1007/978-3-030-33116-0 .
    Abstract
    In this work we investigate a two-phase model for concentrated suspensions. We construct a PDE formulation using a gradient flow structure featuring dissipative coupling between fluid and solid phase as well as different driving forces. Our construction is based on the concept of flow maps that also allows it to account for flows in moving domains with free boundaries. The major difference compared to similar existing approaches is the incorporation of a non-smooth two-homogeneous term to the dissipation potential, which creates a normal pressure even for pure shear flows.

  • Y. Bruned, I. Chevyrev, P. Friz, Examples of renormalized SDEs, in: Stochastic Partial Differential Equations and Related Fields, A. Eberle, M. Grothaus, W. Hoh, M. Kassmann, W. Stannat, G. Trutnau, eds., 229 of Springer Proceedings in Mathematics & Statistics, Springer Nature Switzerland AG, Cham, 2018, pp. 303--317, DOI 10.1007/978-3-319-74929-7 .

  • P. Friz, P. Gassiat, Geometric foundations of rough paths, in: Geometry, Analysis and Dynamics on Sub-Riemannian Manifolds, Vol. 2, D. Barilari, U. Boscain, M. Sigalotti, eds., EMS Series of Lectures in Mathematics, European Mathematical Society, Zurich, 2016, pp. 171--210.

  • CH. Bayer, P. Friz, P. Laurence, On the probability density function of baskets, in: Large Deviations and Asymptotic Methods in Finance, P. Friz, J. Gatheral, A. Gulisashvili, A. Jaquier, J. Teichmann, eds., 110 of Springer Proceedings in Mathematics & Statistics, Springer, Berlin et al., 2015, pp. 449-472.

  • D. Becherer, J.G.M. Schoenmakers, E3 -- Stochastic simulation methods for optimal stopping and control -- Towards multilevel approaches, in: MATHEON -- Mathematics for Key Technologies, M. Grötschel, D. Hömberg, J. Sprekels, V. Mehrmann ET AL., eds., 1 of EMS Series in Industrial and Applied Mathematics, European Mathematical Society Publishing House, Zurich, 2014, pp. 317--331.

  • J.G.M. Schoenmakers, SHOWCASE 17 -- Expiry-wise Heston LIBOR model, in: MATHEON -- Mathematics for Key Technologies, M. Grötschel, D. Hömberg, J. Sprekels, V. Mehrmann ET AL., eds., 1 of EMS Series in Industrial and Applied Mathematics, European Mathematical Society Publishing House, Zurich, 2014, pp. 314--315.

  • D. Spivakovskaya, A.W. Heemink, J.G.M. Schoenmakers, G.N. Milstein, Stochastic modeling of transport in coastal waters using forward and reverse time diffusion, in: Computational Methods in Water Resources, Proceedings of the 15th International Conference on Computational Methods in Water Resources (CMWR XV), June 13--17 2004, Chapel Hill, North Carolina, C.T. Miller, M.W. Farthing, W.G. Gray, G.F. Pinder, eds., 55 of Developments in Water Science, Elsevier Science, Amsterdam, 2004, pp. 1813--1824.

  Preprints, Reports, Technical Reports

  • E. Abi Jaber, Ch. Cuchiero, L. Pelizzari, S. Pulido, S. Svaluto-Ferro, Polynomial Volterra processes, Preprint no. 3098, WIAS, Berlin, 2024, DOI 10.20347/WIAS.PREPRINT.3098 .
    Abstract, PDF (397 kByte)
    We study the class of continuous polynomial Volterra processes, which we define as solutions to stochas- tic Volterra equations driven by a continuous semimartingale with affine drift and quadratic diffusion matrix in the state of the Volterra process. To demonstrate the versatility of possible state spaces within our framework, we construct polynomial Volterra processes on the unit ball. This construction is based on a stochastic invariance principle for stochastic Volterra equations with possibly singular kernels. Similarly to classical polynomial processes, polynomial Volterra processes allow for tractable expressions of the mo- ments in terms of the unique solution to a system of deterministic integral equations, which reduce to a system of ODEs in the classical case. By applying this observation to the moments of the finite-dimensional distributions we derive a uniqueness result for polynomial Volterra processes. Moreover, we prove that the moments are polynomials with respect to the initial condition, another crucial property shared by classical polynomial processes. The corresponding coefficients can be interpreted as a deterministic dual process and solve integral equations dual to those verified by the moments themselves. Additionally, we obtain a representation of the moments in terms of a pure jump process with killing, which corresponds to another non-deterministic dual process.

  • M. Eigel, Ch. Miranda, Functional SDE approximation inspired by a deep operator network architecture, Preprint no. 3079, WIAS, Berlin, 2023, DOI 10.20347/WIAS.PREPRINT.3079 .
    Abstract, PDF (755 kByte)
    We present a novel approach to solve Stochastic Differential Equations (SDEs) with Deep Neural Networks by a Deep Operator Network (DeepONet) architecture. The notion of Deep-ONets relies on operator learning in terms of a reduced basis. We make use of a polynomial chaos expansion (PCE) of stochastic processes and call the corresponding architecture SDEONet. The PCE has been used extensively in the area of uncertainty quantification with parametric partial differential equations. This however is not the case with SDE, where classical sampling methods dominate and functional approaches are seen rarely. A main challenge with truncated PCEs occurs due to the drastic growth of the number of components with respect to the maximum polynomial degree and the number of basis elements. The proposed SDEONet architecture aims to alleviate the issue of exponential complexity by learning a sparse truncation of the Wiener chaos expansion. A complete convergence analysis is presented, making use of recent Neural Network approximation results. Numerical experiments illustrate the promising performance of the suggested approach in 1D and higher dimensions.

  • J. Kern, B. Wiederhold, A Lambda-Fleming--Viot type model with intrinsically varying population size, Preprint no. 3053, WIAS, Berlin, 2023.
    Abstract, PDF (2956 kByte)
    We propose an extension of the classical ?-Fleming-Viot model to intrinsically varying pop- ulation sizes. During events, instead of replacing a proportion of the population, a random mass dies and a, possibly different, random mass of new individuals is added. The model can also incorporate a drift term, representing infinitesimally small, but frequent events. We investigate el- ementary properties of the model, analyse its relation to the Λ-Fleming-Viot model and describe a duality relationship. Through the lookdown framework, we provide a forward-in-time analysis of fixation and coming down from infinity. Furthermore, we present a new duality argument allowing one to deduce well-posedness of the measure-valued process without the necessity of proving uniqueness of the associated lookdown martingale problem.

  • L. Andreis, T. Iyer, E. Magnanini, Gelation, hydrodynamic limits and uniqueness in cluster coagulation processes, Preprint no. 3039, WIAS, Berlin, 2023, DOI 10.20347/WIAS.PREPRINT.3039 .
    Abstract, PDF (627 kByte)
    We consider the problem of gelation in the cluster coagulation model introduced by Norris [Comm. Math. Phys., 209(2):407-435 (2000)]; this model is general enough to incorporate various inhomogenieties in the evolution of clusters, for example, their shape, or their location in space. We derive general, sufficient criteria for stochastic gelation in this model, and for trajectories associated with this process to concentrate among solutions of a generalisation of the Flory equation; thus providing sufficient criteria for the equation to have gelling solutions. As particular cases, we extend results related to the classical Marcus-Lushnikov coagulation process and Smoluchowski coagulation equation, showing that reasonable 'homogenous' coagulation processes with exponent γ larger than 1 yield gelation. In another special case, we prove a law of large numbers for the trajectory of the empirical measure of the stochastic cluster coagulation process, by means of a uniqueness result for the solution of the aforementioned generalised Flory equation. Finally, we use coupling arguments with inhomogeneous random graphs to deduce sufficient criterion for strong gelation (the emergence of a particle of size O(N)).

  • V. Laschos, A. Mielke, Evolutionary variational inequalities on the Hellinger--Kantorovich and spherical Hellinger--Kantorovich spaces, Preprint no. 2973, WIAS, Berlin, 2022, DOI 10.20347/WIAS.PREPRINT.2973 .
    Abstract, PDF (491 kByte)
    We study the minimizing movement scheme for families of geodesically semiconvex functionals defined on either the Hellinger--Kantorovich or the Spherical Hellinger--Kantorovich space. By exploiting some of the finer geometric properties of those spaces, we prove that the sequence of curves, which are produced by geodesically interpolating the points generated by the minimizing movement scheme, converges to curves that satisfy the Evolutionary Variational Inequality (EVI), when the time step goes to 0.

  Talks, Poster

  • N. Tapia, Stability of deep neural networks via discrete rough paths, Oxford Stochastic Analysis and Mathematical Finance Seminar, University of Oxford, Mathematical Institute, UK, February 13, 2023.

  • E. Magnanini, Gelation and hydrodynamic limits in a spatial Marcus--Lushnikov process, In Search of Model Structures for Non-equilibrium Systems, Münster, April 24 - 28, 2023.

  • E. Magnanini, Gelation and hydrodynamic limits in a spatial Marcus--Lushnikov process, Workshop ``In search of model structures for non-equilibrium systems'', April 24 - 28, 2023, Westfälische Wilhelms-Universität Münster, Fachbereich Mathematik und Informatik, April 25, 2023.

  • E. Magnanini, Gelation in a spatial Marcus--Lushnikov process, Workshop MathMicS 2023: Mathematics and Microscopic Theory for Random Soft Matter Systems, Düsseldorf, February 13 - 15, 2023.

  • E. Magnanini, Gelation in a spatial Marcus--Lushnikov process, Workshop MathMicS 2023: Mathematics and microscopic theory for random Soft Matter systems, February 13 - 15, 2023, Heinrich-Heine-Universität Düsseldorf, Institut für Theoretische Physik II - Soft Matter, February 14, 2023.

  • M. Eigel, Functional SDE approximation inspired by a deep operator network architecture, Mini-Workshop ``Nonlinear Approximation of High-dimensional Functions in Scientific Computing'', October 15 - 20, 2023, Mathematisches Forschungsinstitut Oberwolfach, October 18, 2023.

  • P.K. Friz, Rough paths for local (possibly rough) stochastic volatility, Lie-Størmer Colloquium Analytic and Probabilistic Aspects of Rough Paths, November 27 - 29, 2023, Norwegian Academy of Science and Letters, Oslo, Norway, November 27, 2023.

  • W. van Zuijlen, Anderson models, from Schrödinger operators to singular SPDEs, Oberseminar Analysis und Theoretische Physik, Leibniz Universität Hannover, Institut für Angewandte Mathematik, December 12, 2023.

  • S. Breneis, An error representation formula for the log-ode method, 15th Berlin-Oxford Young Researcher's Meeting on Applied Stochastic Analysis, May 12 - 14, 2022, WIAS & TU Berlin, May 14, 2022.

  • S. Breneis, An error representation formula for the log-ode method, 16th Oxford-Berlin Young Researcher's Meeting on Applied Stochastic Analysis, December 8 - 10, 2022, University of Oxford, UK, December 9, 2022.

  • S. Breneis, Markovian approximations for rough volatility models, Seminar Stochastic Numerics Research Group, King Abdullah University of Science and Technology, Thuval, Saudi Arabia, January 26, 2022.

  • O. Butkovsky, Regularisation by noise for SDEs: State of the art & open problems, Mini-Workshop ``Regularization by Noise: Theoretical Foundations, Numerical Methods and Applications driven by Levy Noise'', February 13 - 20, 2022, Mathematisches Forschungsinstitut Oberwolfach, February 16, 2022.

  • O. Butkovsky, Regularization by noise for $L_p$ drifts: The case for Burkholder--Rosenthal stochastic sewing, Stochastic & Rough Analysis, August 22 - 26, 2022, Harnack House, August 23, 2022.

  • O. Butkovsky, Regularization by noise for SDEs and SPDEs beyond the Brownian case, Open Japanese-German Conference on Stochastic Analysis and Applications, September 19 - 23, 2022, Westfälische Wilhelms-Universität Münster, September 19, 2022.

  • O. Butkovsky, Regularization by noise for SDEs and SPDEs beyond the Brownian case, Oberseminar Analysis - Probability, Max-Planck-Institut für Mathematik in den Naturwissenschaften, Fakultät für Mathematik und Informatik, Lepzig, November 1, 2022.

  • O. Butkovsky, Regularization by noise for SDEs and SPDEs beyond the Brownian case (online talk), Webinar on Stochastic Analysis 2022 (Online Event), Beijing Institute of Technology, School of Mathematics and Statistics, China, November 8, 2022.

  • O. Butkovsky, Strong rate of convergence of the Euler scheme for SDEs with irregular drift driven by Levy noise, 15th Berlin-Oxford Young Researcher's Meeting on Applied Stochastic Analysis, May 12 - 14, 2022, WIAS & TU Berlin, May 12, 2022.

  • O. Butkovsky, Strong rate of convergence of the Euler scheme for SDEs with irregular drift driven by Levy noise, Numerical Analysis and Applications of SDEA, September 25 - October 1, 2022, Banach Center, Bedlewo, Poland, September 28, 2022.

  • O. Butkovsky, Weak and mild solutions of SPDEs with distributional drift (online talk), 42nd Conference on Stochastic Processes and their Applications (Online Event), June 27 - July 1, 2022, Wuhan University, School of Mathematics and Statistics, Chinese Society of Probability and Statistics, China, June 28, 2022.

  • L. Pelizzari, Polynomial Volterra processes, 16th Oxford-Berlin Young Researcher's Meeting on Applied Stochastic Analysis, December 8 - 10, 2022, University of Oxford, UK, December 9, 2022.

  • D. Peschka, Gradient flows coupling order parameters and mechanics (online talk), Colloquium of the SPP 2171 (Online Event), Westfälische Wilhelms-Universität Münster, October 21, 2022.

  • N. Tapia, Signature methods in numerical analysis, International Conference on Scientific Computation and Differential Equation (SciCADE 2022), July 25 - 29, 2022, University of Iceland, Faculty of Physical Sciences, Reykjavík, Iceland, July 25, 2022.

  • N. Tapia, Transport and continuity equations with (very) rough noise, Mini-Workshop ``Regularization by Noise: Theoretical Foundations, Numerical Methods and Applications driven by Levy Noise'', February 13 - 19, 2022, Mathematisches Forschungsinstitut Oberwolfach, February 18, 2022.

  • A.D. Vu, Stochastic Homogenization on Irregularly Perforated Domains (online talk), SIAM 2022 Conference on Analysis of Partial Differential Equations (PD22) (Online Event), March 14 - 18, 2022, Virtual Conference --- Originally scheduled in Berlin, Germany, null.

  • CH. Bayer, Efficient Markovian approximation of rough stochastic volatility models (online talk), Aarhus/SMU Volatility Workshop (Online Event), Aarhus University, Department of Economics and Business, Denmark, May 31, 2022.

  • CH. Bayer, Efficient Markovian approximation to rough volatility models, Rough Volatility Meeting, Imperial College London, UK, March 16, 2022.

  • CH. Bayer, RKHS regularization of singular local stochastic volatility McKean--Vlasov models (online talk), Mini-Workshop ``Regularization by Noise: Theoretical Foundations, Numerical Methods and Applications driven by Levy Noise'', February 13 - 20, 2022, Mathematisches Forschungsinstitut Oberwolfach, February 14, 2022.

  • CH. Bayer, Simulating rough volatility models (online talk), MathFinance 2022 Conference (Online Event), March 21 - 22, 2022, March 22, 2022.

  • CH. Bayer, Stability of deep neural networks via discrete rough paths, New Interfaces of Stochastic Analysis and Rough Paths, September 4 - 9, 2022, Banff International Research Station, Canada, September 8, 2022.

  • P. Friz, Itô and Lyons in tandem, Open Japanese-German Conference on Stochastic Analysis and Applications, September 19 - 23, 2022, Westfälische Wilhelms-Universität Münster, Institut für Mathematische Stochastik, September 20, 2022.

  • P. Friz, Rough stochastic analysis, Stochastic Analysis and Stochastic Partial Differential Equations: A Celebration of Marta Sanz-Solé's Mathematical Legacy, May 30 - June 3, 2022, Centre de Recerca Matemàtica (CRM), Barcelona, Spain, June 2, 2022.

  • P. Friz, Rough stochastic analysis, Conference in Honor of S. R. S. Varadhan's 80th Birthday, June 13 - 17, 2022, Jeju Shinhwa World Marriott Resort, Seoul, Korea (Republic of), June 13, 2022.

  • P. Friz, Weak rates for rough vol (online talk), New Interfaces of Stochastic Analysis and Rough Paths, September 4 - 9, 2022, Banff International Research Station, Canada, September 6, 2022.

  • R.I.A. Patterson, Large deviations with vanishing reactant concentrations, Workshop on Chemical Reaction Networks, July 6 - 8, 2022, Politecnico di Torino, Department of Mathematical Sciences ``G. L. Lagrange'', Torino, Italy, July 7, 2022.

  • O. Butkovsky, New coupling techniques for exponential ergodicity of SPDEs in the hypoelliptic and effectively elliptic settings (online talk), Applied and Computational Mathematics Research Seminar, Tulane University, School of Science and Engineering, New Orleans, USA, April 30, 2021.

  • O. Butkovsky, Regularization by noise for PDEs: A stochastic sewing approach (online talk), Theory of Probability and Its Applications: P. L. Chebyshev -- 200 (The 6th International Conference on Stochastic Methods) (Online Event), May 17 - 22, 2021, Steklov Mathematical Institute of Russian Academy of Sciences, Moscow, Russian Federation, May 22, 2021.

  • O. Butkovsky, Regularization by noise for SPDEs and SDEs: A stochastic sewing approach (online talk), Bernoulli-IMS 10th World Congress in Probability and Statistics (Online Event), July 19 - 23, 2021, Seoul National University, Korea (Republic of), July 22, 2021.

  • O. Butkovsky, Regularization by noise via stochastic sewing with random controls, German Probability and Statistics Days (GPSD) 2021, September 27 - October 1, 2021, DMV-Fachgruppe Stochastik e.V., Mannheim, September 27, 2021.

  • O. Butkovsky, Skew fractional Brownian motion (online talk), LSA Autumn Meeting 2021 (Online Event), September 20 - 24, 2021, National Research University -- Higher School of Economics (HSE), Laboratory of Stochastic Analysis and its Applications, Moscow, Russian Federation, September 22, 2021.

  • O. Butkovsky, Skew fractional Brownian motion: Going beyond the Catellier--Gubinelli setting (online talk), 14th Oxford-Berlin Young Researchers Meeting on Applied Stochastic Analysis (Online Event), February 10 - 12, 2021, University of Oxford, Mathematical Institute, UK, February 11, 2021.

  • CH. Bayer, A pricing BSPDE for rough volatility (online talk), MATH4UQ Seminar (Online Event), Rheinisch-Westfälische Technische Hochschule Aachen, Mathematics for Uncertainty Quantification, April 6, 2021.

  • P. Friz, Liouville Brownian rough paths (online talk), Probability Seminar, Universität Wien, Fakultät für Mathematik, Austria, November 14, 2021.

  • P. Friz, Local volatility under rough volatility, QuantMinds International 2021, December 6 - 9, 2021, Barcelona, Spain, December 7, 2021.

  • P. Friz, New perspectives on rough paths, signatures and signature cumulants (online talk), DataSig Seminar Series (Online Event), University of Oxford, Mathematical Institute, UK, May 6, 2021.

  • P. Friz, On rough SDEs (online talk), International Seminar on SDEs and Related Topics (Online Event), hosted by University of Jyväskylä, Department of Mathematics and Statistics, October 29, 2021.

  • P. Friz, Rough stochastic differential equations, Probability Seminar, Maxwell Institute for Mathematical Science, Edinburgh, UK, October 7, 2021.

  • P. Friz, Rough stochastic differential equations (online talk), Pathwise Stochastic Analysis and Applications (Online Event), March 8 - 12, 2021, Centre International de Rencontres Mathématiques, France, March 8, 2021.

  • P. Friz, Unified cumulants and Magnus expansions, Noncommutative Algebra, Probability and Analysis in Action (Hybrid Event), September 20 - 25, 2021, Universität Greifswald, Alfried Krupp Wissenschaftskolleg, September 21, 2021.

  • P. Friz, What can mathematics do for artificial intelligence? (online talk), Berlin Research 50 Workshop on Artificial Intelligence in Research (Online Event), December 13, 2021, Berlin Research 50, December 13, 2021.

  • M. Kantner, Noise in semiconductor lasers (online talk), MATH+ Spotlight Seminar (Online Event), MATH+, July 14, 2021.

  • W. van Zuijlen, Large time behaviour of the parabolic Anderson model (online talk), Probability Meeting (Online Event), University of Oxford, Department of Statistics, UK, February 10, 2021.

  • W. van Zuijlen, Large time behaviour of the parabolic Anderson model (online talk), Probability and Statistical Physics Seminar (Online Event), The University of Chicago, Department of Mathematics, Statistics, and Computer Science, USA, February 12, 2021.

  • O. Butkovsky, Regularization by noise for SDEs and related systems: A tale of two approaches, Eighth Bielefeld-SNU joint Workshop in Mathematics, February 24 - 26, 2020, Universität Bielefeld, Fakultät für Mathematik, February 24, 2020.

  • S. Riedel, Runge--Kutta methods for rough differential equations (online talk), The DNA Seminar (spring 2020), Norwegian University of Science and Technology, Department of Mathematical Sciences, Trondheim, Norway, June 24, 2020.

  • W. van Zuijlen, Large time behaviour of the parabolic Anderson model (online talk), Probability Seminar, Universidade Federal da Bahia, Instituto de Matematica Doutorado em Matematica (Online Event), Salvador, Brazil, October 21, 2020.

  • CH. Bayer, Rough volatility, Summer School 2020 and Annual Meeting of the Berlin--Oxford IRTG 2544 ``Stochastic Analysis in Interaction'', September 14 - 17, 2020, Döllnsee, September 15, 2020.

  • G. Dong, Integrated physics-based method, learning-informed model and hyperbolic PDEs for imaging, Efficient Algorithms in Data Science, Learning and Computational Physics, Sanya, China, January 12 - 16, 2020.

  • M. Coghi, Mean field limit of interacting filaments for 3D Euler equations, Second Italian Meeting on Probability and Mathematical Statistics, June 17 - 20, 2019, Università degli Studi di Salerno, Dipartimento di Matematica, Vietri sul Mare, Italy, June 20, 2019.

  • A. Stephan, EDP-convergence for linear reaction-diffusion systems with different time scales, Winter School ``Gradient Flows and Variational Methods in PDEs'', November 25 - 29, 2019, Universität Ulm, November 29, 2019.

  • CH. Bayer, A regularity structure for rough volatility, Vienna Seminar in Mathematical Finance and Probability, Technische Universität Wien, Research Unit of Financial and Actuarial Mathematics, Austria, January 10, 2019.

  • CH. Bayer, Calibration of rough volatility models by deep learning, Rough Workshop 2019, September 4 - 6, 2019, Technische Universität Wien, Financial and Actuarial Mathematics, Austria.

  • CH. Bayer, Deep calibration of rough volatility models, New Directions in Stochastic Analysis: Rough Paths, SPDEs and Related Topics, WIAS und TU Berlin, March 18, 2019.

  • CH. Bayer, Learning rough volatility, Algebraic and Analytic Perspectives in the Theory of Rough Paths and Signatures, November 14 - 15, 2019, University of Oslo, Department of Mathematics, Norway, November 14, 2019.

  • CH. Bayer, Numerics for rough volatility, Stochastic Processes and Related Topics, February 21 - 22, 2019, Kansai University, Senriyama Campus, Osaka, Japan, February 22, 2019.

  • P. Friz, Multiscale systems, homogenization and rough paths, CRC 1114 Colloquium & Lectures, Collaborative Research Center CRC 1114 ``Scaling Cascades in Complex Systems'', Freie Universität Berlin, June 13, 2019.

  • P. Friz, On differential equations with singular forcing, Berliner Oberseminar Nichtlineare partielle Differentialgleichungen (Langenbach-Seminar), WIAS Berlin, January 9, 2019.

  • P. Friz, Rough paths, rough volatility, regularity structures, Rough Workshop 2019, September 4 - 6, 2019, Technische Universität Wien, Financial and Actuarial Mathematics, Austria.

  • P. Friz, Rough transport, revisited, Algebraic and Analytic Perspectives in the Theory of Rough Paths and Signatures, November 14 - 15, 2019, University of Oslo, Department of Mathematics, Norway, November 14, 2019.

  • P. Friz, Some perspectives on harmonic analysis and rough paths, Harmonic Analysis and Rough Paths, November 18 - 19, 2019, Hausdorff Research Institute for Mathematics, Bonn, November 18, 2019.

  • M. Coghi, Pathwise McKean--Vlasov theory, 10th Oxford-Berlin Young Researchers Meeting on Applied Stochastic Analysis, November 29 - December 1, 2018, University of Oxford, Mathematical Institute, UK, December 1, 2018.

  • M. Maurelli, McKean--Vlasov SDEs with irregular drift: Large deviations for particle approximation, University of Oxford, Mathematical Institute, UK, March 5, 2018.

  • M. Maurelli, Sanov theorem for Brownian rough paths and an application to interacting particles, Università di Roma La Sapienza, Dipartimento di Matematica Guido Castelnuovo, Italy, January 18, 2018.

  • M. Maurelli , A McKean--Vlasov SDE with reflecting boundaries, CASA Colloquium, Eindhoven University of Technology, Department of Mathematics and Computer Science, Netherlands, January 10, 2018.

  • M. Redmann, Numerical approximations of parabolic rough PDEs, Harmonic Analysis for Stochastic PDEs, July 10 - 13, 2018, Delft University of Technology, Netherlands, July 10, 2018.

  • W. van Zuijlen, Eigenvalues of the Anderson Hamiltonian with white noise potential in 2D, Leiden University, Institute of Mathematics, Leiden, Netherlands, May 1, 2018.

  • W. van Zuijlen, Mass-asymptotics for the parabolic Anderson model in 2D, Statistical Mechanics Seminar, University of Warwick, Department of Statistics, Coventry, UK, December 6, 2018.

  • P. Friz, From rough paths and regularity structures to short dated option pricing under rough volatility, Workshop on Mathematical Finance and Related Issues, Osaka University, Nakanoshima Center, Japan, March 15, 2018.

  • P. Friz, Rough path analysis of rough volatility, Stochastic Analysis Seminar, Imperial College London, Department of Mathematics, Stochastic Analysis Group, UK, February 13, 2018.

  • P. Friz, Rough paths, stochastics and PDE's, ECMath Colloquium, July 6, 2018, Humboldt-Universität zu Berlin, July 6, 2018.

  • W. Dreyer, J. Fuhrmann, P. Gajewski, C. Guhlke, M. Landstorfer, M. Maurelli, R. Müller, Stochastic model for LiFePO4-electrodes, ModVal14 -- 14th Symposium on Fuel Cell and Battery Modeling and Experimental Validation, Karlsruhe, March 2 - 3, 2017.

  • M. Maurelli, Regularization by noise for scalar conservation laws, Stochastic Analysis Day, February 27, 2017, Università di Pisa, Dipartimento di Matematica, Italy, February 27, 2017.

  • M. Maurelli, Regularization by noise for scalar conservation laws, Berlin-Leipzig Workshop in Analysis and Stochastics, November 29 - December 1, 2017, Max-Planck-Institut für Mathematik in den Naturwissenschaften, Leipzig, November 30, 2017.

  • M. Maurelli, Regularization by noise for scalar conservation laws, Séminaire de Probabilité et Statistique, Université de Nice Sophia-Antipolis, Laboratoire Jean Alexandre Dieudonné, France, September 26, 2017.

  • M. Maurelli, Stochastic 2D Euler equations with transport noise, Chalmers University of Technology, Department of Mathematical Sciences, Gothenburg, Sweden, November 28, 2017.

  • M. Redmann, A regression method to solve parabolic rough PDEs, 7th Annual ERC Berlin-Oxford Young Researchers Meeting on Applied Stochastic Analysis, May 18 - 20, 2017, WIAS-Berlin, May 20, 2017.

  • M. Redmann, A regression method to solve parabolic rough PDEs, Ninth Workshop on Random Dynamical Systems, June 14 - 17, 2017, Universität Bielefeld, Fakultät für Mathematik, June 15, 2017.

  • M. Redmann, Type II singular perturbation approximation for linear systems with Levy noise, London Mathematical Society -- EPSRC Durham Symposium: Model Order Reduction, Durham University, Department of Mathematical Sciences, UK, August 14, 2017.

  • W. van Zuijlen, The principal eigenvalue of the Anderson Hamiltonian in continuous space, Berlin-Leipzig Workshop in Analysis and Stochastics, November 29 - December 1, 2017, Max-Planck-Institut für Mathematik in den Naturwissenschaften, Leipzig, November 29, 2017.

  • CH. Bayer, Numerics for rough volatility models, Ninth Workshop on Random Dynamical Systems, June 14 - 17, 2017, University of Bielefeld, Department of Mathematics, June 14, 2017.

  • P. Friz, An application of regularity structures to the analysis of rough volatility, Fractional Brownian Motion and Rough Models, June 8 - 9, 2017, Barcelona Graduate School of Economics, Spain, June 9, 2017.

  • P. Friz, Aspects of rough volatility, The 5th Imperial -- ETH Workshop on Mathematical Finance, March 27 - 29, 2017, Imperial College London, UK, March 27, 2017.

  • P. Friz, General semimartingales and rough paths, Durham Symposium on Stochastic Analysis, July 10 - 20, 2017, Durham University, Department of Mathematical Sciences, UK, July 13, 2017.

  • P. Friz, Multiscale systems, homogenization and rough paths, Berlin-Leipzig Workshop in Analysis and Stochastics, November 29 - December 1, 2017, Max-Planck-Institut für Mathematik in den Naturwissenschaften, Leipzig, November 29, 2017.

  • P. Friz, Rough differential equations with jumps and their applications, Japanese-German Open Conference on Stochastic Analysis 2017, September 4 - 8, 2017, Technische Universität Kaiserslautern, Fachbereich Mathematik, September 5, 2017.

  • J.G.M. Schoenmakers, Projected particle methods for solving McKean--Vlasov SDEs, Dynstoch 2017, April 5 - 7, 2017, Universität Siegen, Department Mathematik, April 6, 2017.

  • M. Maurelli, Enhanced Sanov theorem and large deviations for interacting particles, Workshop ``Rough Paths, Regularity Structures and Related Topics'', May 1 - 7, 2016, Mathematisches Forschungsinstitut Oberwolfach, May 5, 2016.

  • M. Maurelli, Regularization by noise for continuity equation via Young drivers, Stochastic Partial Differential Equations and Applications, May 30 - June 2, 2016, Centro Internazionale per la Ricerca Matematica (CIRM), Levico, Italy, May 30, 2016.

  • M. Maurelli, Regularization by noise for scalar conservation laws, Mathematical Finance and Stochastic Analysis Seminars, University of York, UK, October 26, 2016.

  • M. Maurelli, Regularization by noise for stochastic scalar conservation laws, The 11th AIMS Conference on Dynamical Systems, Differential Equations and Applications, Special Session 41 ``Stochastic Partial Differential Equations'', July 1 - 5, 2016, The American Institute of Mathematical Science, Orlando (Florida), USA, July 4, 2016.

  • M. Maurelli, Regularization by noise for transport-type equations via stochastic exponentials, Workshop in Stochastic Analysis, June 28 - 30, 2016, Universidade Estadual de Campinas, Instituto de Matemática, Estatística e Computação Científica, Campinas, Brazil, June 29, 2016.

  • E. Valdinoci, Nonlocal minimal surface, Justus-Liebig-Universität Gießen, Fakultät für Mathematik, February 10, 2016.

  • W. van Zuijlen, Mean field Gibbs-non-Gibbs transitions, 6th Berlin--Oxford Meeting, December 8 - 10, 2016, University of Oxford, Mathematics Department, UK, December 9, 2016.

  • CH. Bayer, Pricing under rough volatility, Stochastic Analysis and Mathematical Finance -- A Fruitful Partnership, May 22 - 27, 2016, Banff International Research Station for Mathematical Innovation and Discovery, Oaxaca, Mexico, May 24, 2016.

  • CH. Bayer, SDE based regression for random PDEs, Workshop ``Rough Paths, Regularity Structures and Related Topics'', May 1 - 7, 2016, Mathematisches Forschungsinstitut Oberwolfach, May 3, 2016.

  • P. Friz, A regularity structure for rough volatility, Stochastic Analysis, Rough Paths, Geometry, January 7 - 9, 2016, Imperial College London, UK, January 7, 2016.

  • P. Friz, Signatures, rough paths and probability, Stochastics and Finance Seminar, University of Amsterdam, Korteweg-de Vries Institute for Mathematics, Netherlands, October 18, 2016.

  • P. Friz, Support theorem for singular SPDEs: The case of gPAM, Stochastic Partial Differential Equations and Applications, May 29 - June 3, 2016, Centro Internazionale per la Ricerca Matematica (CIRM), Levico, Italy, May 31, 2016.

  • P. Gajewski, M. Maurelli, Stochastic methods for the analysis of lithium-ion batteries, Matheon Center Days, April 20 - 21, 2015, Technische Universität Berlin, April 21, 2015.

  • M. Maurelli, A large deviation principle for enhanced Brownian empirical measure, 4th Annual ERC Berlin-Oxford Young Researchers Meeting on Applied Stochastic Analysis, December 7 - 9, 2015, WIAS Berlin, December 8, 2015.

  • M. Maurelli, A large deviation principle for interacting particle SDEs via rough paths, 38th Conference on Stochastic Processes and their Applications, July 13 - 17, 2015, University of Oxford, Oxford-Man Institute of Quantitative Finance, UK, July 14, 2015.

  • M. Maurelli, Enhanced Sanov theorem for Brownian rough paths and an application to interacting particles, Seminar Stochastic Analysis, Imperial College London, UK, October 20, 2015.

  • M. Maurelli, Stochastic 2D Euler equations: A poorly correlated multiplicative noise regularizes the two-point motion, Universität Augsburg, Institut für Mathematik, March 24, 2015.

  • M. Maurelli, Transport equation via Young estimates (TBC), 3rd Annual ERC Berlin-Oxford Young Researchers Meeting on Applied Stochastic Analysis, January 27 - 29, 2015, WIAS Berlin, January 29, 2015.

  • CH. Bayer, Rough paths and rough partial differential equations, November 16 - 18, 2015, University of Oslo, Department of Mathematics, Norway.

  • R. Allez, Invariant beta ensembles and beyond, Seminar Mathematische Physik, Universität Bielefeld, Mathematical Physics Group, June 11, 2014.

  • R. Allez, Les ensembles beta invariants, Séminaire de l'équipe Probas/Stats, Institut Élie Cartan de Lorraine, Équipe Probabilités et Statistiques, Nancy, France, May 22, 2014.

  • R. Allez, Liouville Brownian motion, Oberseminar Peter Friz, Technische Universität Berlin, August 20, 2014.

  • R. Allez, Random matrices at high temperature, Probability series, University of Cambridge, UK, February 11, 2014.

  • R. Allez, Random matrices at high temperature, Stochastic Analysis Seminar Series, Oxford-Man Institute, UK, January 20, 2014.

  • R. Allez, Random matrix theory and some applications, WIAS-Day, February 19, 2014.

  • CH. Bayer, From rough path estimates to multilevel Monte Carlo, Eleventh International Conference on Monte Carlo and Quasi-Monte Carlo Methods in Scientific Computing, April 6 - 11, 2014, Catholic University of Leuven, Department of Computer Science, Belgium, April 7, 2014.

  • CH. Bayer, Multilevel Monte Carlo meets rough paths, Berlin-Oxford Young Researchers Meeting on Applied Stochastic Analysis, July 1 - 2, 2014, University of Oxford, Oxford-Man Institute of Quantitative Finance, UK, July 1, 2014.

  • CH. Bayer, Simulation of forward-reverse stochastic representations for conditional diffusions, Foundations of Computational Mathematics Conference 2014, December 11 - 20, 2014, Universidad de la República, Facultad de Ingenieria, Montevideo, Uruguay, December 19, 2014.

  • CH. Bayer, The forward-reverse method for conditional diffusion processes, Numerical Analysis Seminar, Royal Institute of Technology Stockholm, Department of Mathematics, Sweden, October 10, 2014.

  • P. Friz, Basic of rough paths, Workshop ``Stochastic Analysis: Around the KPZ Universality Class '', June 1 - 7, 2014, Mathematisches Forschungsinstitut Oberwolfach, June 2, 2014.

  • P. Friz, Fully-nonlinear SPDEs with rough path dependence, The 10th AIMS Conference on Dynamical Systems, Differential Equations and Applications, Special Session 109: Stochastic Partial Differential Equations, July 7 - August 11, 2014, Madrid, Spain, July 7, 2014.

  • P. Friz, Rough integration with jumps, Berlin-Oxford Young Researchers Meeting on Applied Stochastic Analysis, July 1 - 2, 2014, University of Oxford, Oxford-Man Institute of Quantitative Finance, UK, July 2, 2014.

  • P. Friz, Rough path and stochastic analysis, Trimester Partial Differential Equations & Probability, Week on Rough Paths and PDE, February 10 - 15, 2014, Centre International de Mathématiques et Informatique de Toulouse, France.

  • P. Friz, Rough paths, with jumps, Probability Seminar, The University of Edinburgh, School of Mathematics, UK, October 10, 2014.

  • P. Friz, Signatures, rough paths and probability, BMS Days 2014, February 17 - 18, 2014, The Berlin Mathematical School, February 17, 2014.

  • H. Mai, Pathwise stability of likelihood estimators for diffusions via rough paths, 37th Conference on Stochastic Processes and their Applications, July 28 - August 1, 2014, Buonos Aires, Argentina.

  • H. Mai, Pathwise stability of likelihood estimators for diffusions via rough paths, 37th Conference on Stochastic Processes and their Applications, Buenos Aires, Argentina, July 28 - August 1, 2014.

  • H. Mai, Pathwise stability of likelihood estimators for diffusions via rough paths, International Workshop ``Advances in Optimization and Statistics'', May 15 - 16, 2014, Russian Academy of Sciences, Institute of Information Transmission Problems (Kharkevich Institute), Moscow, May 16, 2014.

  • H. Mai, Robust drift estimation: Pathwise stability under volatility and noise misspecification, Berlin-Oxford Young Researchers Meeting on Applied Stochastic Analysis, July 1 - 2, 2014, University of Oxford, Oxford-Man Institute of Quantitative Finance, UK, July 2, 2014.

  • H. Mai, Robustness and pathwise stability of maximum likelihood estimators for jump diffusions, Universidad de Buenos Aires, Instituto de Calculo, Argentina, August 8, 2014.

  • H. Mai, Robustness of likelihood estimators for diffusions via rough paths, Advances in Stochastic Analysis, September 3 - 5, 2014, National Research University -- Higher School of Economics, Laboratory of Stochastic Analysis and its Applications, Moscow, Russian Federation, September 3, 2014.

  • J.G.M. Schoenmakers, Affine LIBOR models with multiple curves: Theory, examples and calibration, 11th German Probability and Statistics Days 2014, March 5 - 7, 2014, Universität Ulm, March 6, 2014.

  • H. Stephan, Inequalities for Markov operators and applications to forward and backward PDEs, The 10th AIMS Conference on Dynamical Systems, Differential Equations and Applications, Special Session 88: Stochastic Processes and Spectral Theory for Partial Differential Equations and Boundary Value Problems, July 7 - 11, 2014, Madrid, Spain, July 8, 2014.

  • M. Ladkau, A new multi-factor stochastic volatility model with displacement, PreMoLab Workshop on: Advances in predictive modeling and optimization, May 16 - 17, 2013, WIAS-Berlin, May 16, 2013.

  • S. Neukamm, Optimal decay estimate on the semigroup associated with a random walk among random conductances, Dirichlet Forms and Applications, German-Japanese Meeting on Stochastic Analysis, September 9 - 13, 2013, Universität Leipzig, Mathematisches Institut, September 9, 2013.

  • S. Neukamm, Quantitative results in stochastic homogenization, sc Matheon Multiscale Seminar, Technische Universität Berlin, Institut für Mathematik, June 27, 2013.

  • S. Neukamm, Quantitative results in stochastic homogenization, Oberseminar Analysis, Technische Universität Dresden, Fakultät Mathematik und Naturwissenschaften, June 13, 2013.

  • P. Friz, (Rough) pathwise stochastic analysis: Old and new, Stochastic Analysis and its Applications, 60th Birthday of Terry Lyons, September 23 - 27, 2013, University of Oxford, Oxford-Man Institute, UK, September 24, 2013.

  • P. Friz, Information content ot iterated integrals and applications, LUH-Kolloquium "Versicherungs- und Finanzmathematik", Stochastic Analysis Day, June 27, 2013, Leibniz Universität Hannover, Institut für Stochastik, June 27, 2013.

  • P. Friz, Marginal density expansions for diffusions and stochastic volatility and related stuff, Large Deviations and Asymptotic Methods in Finance, April 9 - 11, 2013, Imperial College London, UK, April 10, 2013.

  • P. Friz, Physical Brownian motion in magnetic field as rough path, German-Japanese Meeting on Stochastic Analysis, September 9 - 13, 2013, Universität Leipzig, Mathematisches Institut, September 13, 2013.

  • P. Friz, Rational shapes of the local volatility surface, 20th Annual Global Derivatives & Risk Management, April 15 - 19, 2013, The International Centre for Business Information (ICBI), Amsterdam, Netherlands, April 17, 2013.

  • P. Friz, Rough path analysis, Summer School ``Numerical Methods for Stochastic Differential Equations'', September 2 - 4, 2013, Vienna University of Technology, Institute for Analysis and Scientific Computing E 101, Austria, September 4, 2013.

  • P. Friz, Rough paths, 29th European Meeting of Statisticians (EMS), July 20 - 25, 2013, Eötvös Loránd University, Budapest, Hungary, July 20, 2013.

  • P. Friz, Some aspects of stochastic area, UK Probability Easter Meeting; Geometry and Analysis of Random Processes, April 8 - 12, 2013, University of Cambridge, Department of Pure Mathematics, UK, April 11, 2013.

  • P. Friz, Stochastic control with rough paths, PreMoLab Workshop on: Advances in predictive modeling and optimization, May 16 - 17, 2013, WIAS-Berlin, May 16, 2013.

  • CH. Bayer, Asymptotics beats Monte Carlo: The case of correlated local volatility baskets, Stochastic Methods in Finance and Physics, July 15 - 19, 2013, University of Crete, Department of Applied Mathematics, Heraklion, Greece, July 19, 2013.

  • CH. Bayer, Simulation of conditional diffusions via forward--reverse stochastic representations, Seminar in Mathematical Statistics, Linköping University, Division of Mathematical Statistics, Sweden, September 11, 2013.

  • CH. Bayer, Simulation of conditional diffusions via forward-reverse stochastic representations, King Abdullah University of Science and Technology (KAUST), Computer, Electrical and Mathematical Sciences & Engineering, Thuwal, Saudi Arabia, February 20, 2013.

  • H. Mai, Applications of rough path analysis to robust likelihood inference, Statistikseminar, Humboldt-Universität zu Berlin, Institut für Mathematik, October 18, 2013.

  • H. Mai, Efficient drift estimation for jump diffusion processes and jump filtering, Séminaire de Statistique du CREST, École Nationale de la Statistique et de l'Administration Économique, Centre de Recherche en Économie et Statistique, Paris, France, February 18, 2013.

  • J.G.M. Schoenmakers, Simulation of conditional diffusions via forward-reverse stochastic representations, DynStoch 2013, April 17 - 19, 2013, University of Copenhagen, Department of Mathematical Sciences, Denmark, April 19, 2013.

  • J.G.M. Schoenmakers, Simulation of conditional diffusions via forward-reverse stochastic representations, PreMoLab Workshop on: Advances in predictive modeling and optimization, May 16 - 17, 2013, WIAS-Berlin, May 16, 2013.

  • N. Willrich, Solutions of martingale problems for Lévy-type operators and stochastic differential equations driven by Lévy processes with discontinous coefficients, 29th European Meeting of Statisticians (EMS), July 20 - 25, 2013, Eötvös Loránd University, Budapest, Hungary, July 21, 2013.

  • P. Friz, Applications of rough paths: Physical Brownian in a magnetic fields, Modelling of markets with infinitesimally delayed reactions, Workshop on: Rough Paths and PDEs, August 19 - 25, 2012, Mathematisches Forschungsinstitut Oberwolfach (MFO), August 23, 2012.

  • P. Friz, Generalized sub-Riemannian cut loci and volatility smiles, 6th European Congress of Mathematics, July 2 - 7, 2012, Jagiellonian University, Institute of Mathematics, Cracow, Poland, July 5, 2012.

  • P. Friz, Marginal density expansion with applications to Levy area and the Stein--Stein model, Stochastic Analysis Seminar, University of Warwick, Mathematics Institute, Coventry, UK, November 28, 2012.

  • P. Friz, Rough paths and control, Stochastic Systems Simulation and Control (SSSC2012), November 5 - 9, 2012, Universidad Autónoma de Madrid, Instituto de Ciencias Matemáticas, Spain, November 5, 2012.

  • CH. Bayer, Existence, uniqueness and stability of invariant distributions in continuous-time stochastic models, 12th Conference of the Society for the Advancement of Economic Theory (SAET 2012), June 30 - July 3, 2012, University of Queensland, School of Economics, Australia, July 1, 2012.

  • CH. Bayer, Some applications of the Ninomiya--Victoir scheme in the context of financial engineering, Talks in Financial and Insurance Mathematics, Eidgenössische Technische Hochschule Zürich, Switzerland, April 26, 2012.

  • CH. Bayer, Some applications of the Ninomiya--Victoir scheme in the context of financial engineering, Stochastic Analysis Seminar Series, Oxford University, Oxford-Man Institute of Quantitative Finance, UK, May 21, 2012.

  • H. Mai, Drift estimation for jump diffusion, Haindorf Seminar 2012 (Klausurtagung des SFB 649), February 9 - 12, 2012, Humboldt-Universität zu Berlin, Wirtschaftswissenschaftliche Fakultät, Hejnice, Czech Republic, February 10, 2012.

  • H. Mai, Jump filtering and high-frequency data, Statistical Methods for Dynamical Stochastic Models (DynStoch2012), Paris, France, June 7 - 9, 2012.

  • H. Mai, Jump filtering for semimartingales under high-frequency observations, PreMoLab: Moscow-Berlin Stochastic and Predictive Modeling, May 31 - June 1, 2012, Russian Academy of Sciences, Institute for Information Transmission Problems (Kharkevich Institute), Moscow, May 31, 2012.

  • H. Mai, Maximum likelihood estimation for Lévy-driven SDEs, Workshop on Statistics of Lévy-driven Models, Ulm, March 15 - 16, 2012.

  • H. Mai, Maximum likelihood estimation for Lévy-driven SDEs, Workshop on statistics of Lévy-driven models, March 15 - 16, 2012, Universität Ulm, Institute of Mathematical Finance.

  • P. Friz, Gaussian rough paths, Bonn Probability Day, Hausdorf Center for Mathematics, Universität Bonn, January 26, 2012.

  • P. Friz, Rough analysis applied to some classes of SPDEs and related topics, Stochastic Partial Differential Equations: Analysis, Numerics, Geometry and Modeling, September 12 - 17, 2011, Eidgenössische Technische Hochschule Zürich, Forschungsinstitut für Mathematik, Switzerland, September 16, 2011.

  • P. Friz, Rough path analysis and applications, Conference in Honor of the 70th Birthday of S. R. Srinivasa Varadhan, July 11 - 15, 2011, National Taiwan University, Taipeh, July 14, 2011.

  • M. Becker , Random walks and self-intersections, Evolving Complex Networks (ECONS) Phd-Student Meeting, WIAS, August 24, 2010.

  • P. Friz, A (rough) pathwise approach to SPDEs, ICM Satellite Conference on Probability and Stochastic Processes, August 13 - 17, 2010, Indian Statistical Institute, Bangalore, India, August 16, 2010.

  • P. Friz, A (rough) pathwise approach to a class of non-linear stochastic partial diffenrential equations, Workshop ``Stochastic Partial Differential Equations (SPDEs)'', Isaac Newton Institute for Mathematical Sciences, Cambridge, UK, January 4 - 6, 2010.

  • P. Friz, A new pathwise theory of SPDEs, 34th Conference on Stochastic Processes and their Applications (SPA 2010), September 6 - 10, 2010, Bernoulli Society for Mathematical Statistics and Probability, Osaka, Japan, September 9, 2010.

  • P. Friz, Ordinary, partial and backward stochastic differential equations driven by rough paths, Conference in Memory of Paul Malliavin, October 4 - 6, 2010, Institut de Mathématiques de Bourgogne, Dijon, France, October 6, 2010.

  • P. Friz, Ordinary, partial and backward stochastic differential equations driven by rough signals, Analysis, Stochastics, and Applications (AnStAp 2010), July 12 - 16, 2010, Universität Wien, Fakultät für Mathematik, Austria, July 13, 2010.

  • P. Friz, Rough path stability of SPDEs arising in non-linear filtering and beyond, Workshop on Filtering, June 14 - 15, 2010, University of Cambridge, Isaac Newton Institute for Mathematical Sciences, UK, June 15, 2010.

  • P. Friz, Rough viscosity solutions and applications to SPDEs, Workshop on Stochastic Partial Differential Equations (SPDEs): Approximation, Asymptotics and Computation, June 28 - July 2, 2010, University of Cambridge, Isaac Newton Institute for Mathematical Sciences, UK, June 29, 2010.

  • P. Friz, From numerical aspects of stochastic financial models to the foundations of stochastic differential equations (and back), Annual Meeting of the Deutsche Mathematiker-Vereinigung and 17th Congress of the Österreichische Mathematische Gesellschaft, Section ``Financial and Actuarial Mathematics'', September 20 - 25, 2009, Technische Universität Graz, Austria, September 25, 2009.

  • P. Friz, Rough paths and the gap between deterministic and stochastic differential equations, Berlin Mathematical School, Friday Colloquium, December 18, 2009.

  • H. Stephan, Inequalities for Markov operators, Positivity VI (Sixth Edition of the International Conference on Positivity and its Applications), July 20 - 24, 2009, El Escorial, Madrid, Spain, July 24, 2009.

  • H. Stephan, Modeling of diffusion prozesses with hidden degrees of freedom, Workshop on Numerical Methods for Applications, November 5 - 6, 2009, Lanke, November 6, 2009.

  • J.G.M. Schoenmakers, Transition density estimation for stochastic differential equations via forward-reverse representations, Tandem-Workshop Stochastik-Numerik, June 11 - March 26, 2004, Humboldt-Universität zu Berlin, June 11, 2004.

  • J.G.M. Schoenmakers, Transition density estimation for stochastic differential equations via forward reverse representations, IV IMACS Seminar on Monte Carlo Methods (MCM 2003), September 15 - 19, 2003, Berlin, September 16, 2003.

  External Preprints

  • CH. Bayer, M. Fukasawa, N. Shonosuke , On the weak convergence rate in the discretization of rough volatility models, Preprint no. arXiv:2203.02943, Cornell University, 2022, DOI 10.48550/arXiv.2203.02943 .

  • CH. Bayer, P.K. Friz, N. Tapia, Stability of deep neural networks via discrete rough paths, Preprint no. arXiv:2201.07566, Cornell University, 2022, DOI 10.48550/arXiv.2201.07566 .

  • P.K. Friz, A. Hocquet, K. , Rough stochastic differential equations, Preprint no. arXiv:2106.10340, Cornell University, 2022, DOI 10.48550/arXiv.2106.10340 .

  • O. Butkovsky, K. Dareiotis, M. Gerencsér, Optimal rate of convergence for approximations of SPDEs with non-regular drift, Preprint no. arXiv:2110.06148, Cornell University Library, arXiv.org, 2021.

  • O. Butkovsky, V. Margarint, Y. Yuan, Law of the SLE tip, Preprint no. arXiv:2110.11247, Cornell University Library, arXiv.org, 2021.
    Abstract
    We analyse the law of the SLE tip at a fixed time in capacity parametrization. We describe it as the stationary law of a suitable diffusion process, and show that it has a density which is a unique solution of a certain PDE. Moreover, we identify the phases in which the even negative moments of the imaginary value are finite. For the negative second and negative fourth moments we provide closed-form expressions.

  • O. Butkovsky, K. Dareiotis , M. Gerencsér, Approximation of SDEs --- A stochastic sewing approach, Preprint no. arXiv:1909.07961, Cornell University, 2020.

  • B. Gess, M. Maurelli, Well-posedness by noise for scalar conservation laws, Preprint no. arXiv:1701.05393, Cornell University Library, arXiv.org, 2017.
    Abstract
    We consider stochastic scalar conservation laws with spatially inhomogeneous flux. The regularity of the flux function with respect to its spatial variable is assumed to be low, so that entropy solutions are not necessarily unique in the corresponding deterministic scalar conservation law. We prove that perturbing the system by noise leads to well-posedness.

  • J.-D. Deuschel, P. Friz, M. Maurelli, M. Slowik, The enhanced Sanov theorem and propagation of chaos, Preprint no. arxiv:1602.08043, Cornell University Library, arXiv.org, 2016.

  • R. Allez, L. Dumaz, Random matrices in non-confining potentials, Preprint no. arXiv:1404.5265, Cornell University Library, arXiv.org, 2014.

  • R. Allez, J.-P. Bouchaud, Eigenvector dynamics under free addition, Preprint no. arXiv:1301.4939, Cornell University Library, arXiv.org, 2014.

  • R. Allez, J. Bun, J.-P. Bouchaud, The eigenvectors of Gaussian matrices with an external source, Preprint no. arXiv:1412.7108, Cornell University Library, arXiv.org, 2014.

  • L. Beck, F. Flandoli, M. Gubinelli, M. Maurelli, Stochastic ODEs and stochastic linear PDEs with critical drift: Regularity, duality and uniqueness, Preprint no. arXiv:1401.1530, Cornell University Library, arXiv.org, 2014.

  • Z. Brzezniak, F. Flandoli, M. Maurelli, Existence and uniqueness for stochastic 2D Euler flows with bounded vorticity, Preprint no. arXiv:1401.5938, Cornell University Library, arXiv.org, 2014.

  • F. Flandoli, M. Maurelli, M. Neklyudov, Noise prevents infinite stretching of the passive field in a stochastic vector advection equation, Preprint no. arXiv:1403.0022, Cornell University Library, arXiv.org, 2014.

  • P. Friz, B. Gess, Stochastic scalar conservation laws driven by rough paths, Preprint no. arXiv:1403.6785, Cornell University Library, arXiv.org, 2014.

  • S. Neukamm, A. Gloria, F. Otto, An optimal quantitative two-scale expansion in stochastic homogenization of discrete elliptic equations, Preprint no. 41, Max-Planck-Institut für Mathematik in den Naturwissenschaften, 2013.
    Abstract
    We establish an optimal, linear rate of convergence for the stochastic homogenization of discrete linear elliptic equations. We consider the model problem of independent and identically distributed coefficients on a discretized unit torus. We show that the difference between the solution to the random problem on the discretized torus and the first two terms of the two-scale asymptotic expansion has the same scaling as in the periodic case. In particular the L2-norm in probability of the H1-norm in space of this error scales like ε, where ε is the discretization parameter of the unit torus. The proof makes extensive use of previous results by the authors, and of recent annealed estimates on the Greens function by Marahrens and the third author.

  • P. Friz, A. Shekhar, Doob--Meyer for rough paths, Preprint no. arXiv:1205.2505, Cornell University Library, arXiv.org, 2012.

  • P. Friz, A. Shekhar, The Levy--Kintchine formula for rough paths, Preprint no. arXiv:1212.5888, Cornell University Library, arXiv.org, 2012.

  • P. Imkeller, N. Willrich, Solutions of martingale problems for Lévy-type operators and stochastic differential equations driven by Lévy processes with discontinuous coefficients, Preprint no. arXiv:1208.1665, Cornell University Library, arXiv.org, 2012.
    Abstract
    We show the existence of Lévy-type stochastic processes in one space dimension with characteristic triplets that are either discontinuous at thresholds, or are stable-like with stability index functions for which the closures of the discontinuity sets are countable. For this purpose, we formulate the problem in terms of a Skorokhod-space martingale problem associated with non-local operators with discontinuous coefficients. These operators are approximated along a sequence of smooth non-local operators giving rise to Feller processes with uniformly controlled symbols. They converge uniformly outside of increasingly smaller neighborhoods of a Lebesgue nullset on which the singularities of the limit operator are located.

  • J. Diehl , P. Friz, H. Oberhauser, Parabolic comparison revisited and applications, Preprint no. arXiv:1102.5774, Cornell University Library, arXiv.org, 2011.

  • P. Friz, S. Riedel , Integrability of linear rough differential equations, Preprint no. arXiv:1104.0577, Cornell University Library, arXiv.org, 2011.

  • J.D. Deuschel, P. Friz, A. Jacquier, S. Violante , Marginal density expansions for diffusions and stochastic volatility, Preprint no. arXiv:1111.2462, Cornell University Library, arXiv.org, 2011.

  • P. Friz, S. Riedel, Convergence rates for the full Gaussian rough paths, Preprint no. arXiv:1108.1099, Cornell University Library, arXiv.org, 2011.

  • P. Friz, N. Victoir, A note on higher dimensional $p$ variation, Preprint no. arXiv:1102.4587, Cornell University Library, arXiv.org, 2011.

  • CH. Bayer, P. Friz, R.L. Loeffen, Semi-closed form cubature and applications to financial diffusion models, Preprint no. arXiv:1009.4818, Cornell University Library, arXiv.org, 2010.
    Abstract
    Cubature methods, a powerful alternative to Monte Carlo due to Kusuoka [Adv. Math. Econ. 6, 69--83, 2004] and Lyons--Victoir [Proc. R. Soc.
    Lond. Ser. A 460, 169--198, 2004], involve the solution to numerous auxiliary ordinary differential equations. With focus on the Ninomiya-Victoir algorithm [Appl. Math. Fin. 15, 107--121, 2008], which corresponds to a concrete level $5$ cubature method, we study some parametric diffusion models motivated from financial applications, and exhibit structural conditions under which all involved ODEs can be solved explicitly and efficiently. We then enlarge the class of models for which this technique applies, by introducing a (model-dependent) variation of the Ninomiya-Victoir method. Our method remains easy to implement; numerical examples illustrate the savings in computation time.

  • M. Beiglboeck, P. Friz, S. Sturm, Is the minimum value of an option on variance generated by local volatility?, Preprint no. arXiv:1001.4031, Cornell University Library, arXiv.org, 2010.
    Abstract
    We discuss the possibility of obtaining model-free bounds on volatility derivatives, given present market data in the form of a calibrated local volatility model. A counter-example to a wide-spread conjecture is given.

  • J. Diehl, P. Friz, Backward stochastic differential equations with rough drivers, Preprint no. arXiv:1008.0290, Cornell University Library, arXiv.org, 2010.
    Abstract
    Backward stochastic differential equations (BSDEs) in the sense of Pardoux-Peng [Backward stochastic differential equations and quasilinear parabolic partial differential equations, Lecture Notes in Control and Inform. Sci., 176, 200--217, 1992] provide a non-Markovian extension to certain classes of non-linear partial differential equations; the non-linearity is expressed in the so-called driver of the BSDE. Our aim is to deal with drivers which have very little regularity in time. To this end we establish continuity of BSDE solutions with respect to rough path metrics in the sense of Lyons [Differential equations driven by rough signals. Rev. Mat. Iberoamericana 14, no. 2, 215--310, 1998] and so obtain a notion of "BSDE with rough driver". Existence, uniqueness and a version of Lyons' limit theorem in this context are established. Our main tool, aside from rough path analysis, is the stability theory for quadratic BSDEs due to Kobylanski [Backward stochastic differential equations and partial differential equations with quadratic growth. Ann. Probab., 28(2):558--602, 2000].

  • P. Friz, H. Oberhauser, A generalized Fernique theorem and applications, Preprint no. arXiv:1004.1923, Cornell University Library, arXiv.org, 2010.
    Abstract
    We prove a generalisation of Fernique's theorem which applies to a class of (measurable) functionals on abstract Wiener spaces by using the isoperimetric inequality. Our motivation comes from rough path theory where one deals with iterated integrals of Gaussian processes (which are generically not Gaussian). Gaussian integrability with explicitly given constants for variation and Hölder norms of the (fractional) Brownian rough path, Gaussian rough paths and the Banach space valued Wiener process enhanced with its Lévy area [Ledoux, Lyons, Quian. "Lévy area of Wiener processes in Banach spaces". Ann. Probab., 30(2):546--578, 2002] then all follow from applying our main theorem.We prove a generalisation of Fernique's theorem which applies to a class of (measurable) functionals on abstract Wiener spaces by using the isoperimetric inequality. Our motivation comes from rough path theory where one deals with iterated integrals of Gaussian processes (which are generically not Gaussian). Gaussian integrability with explicitly given constants for variation and Hölder norms of the (fractional) Brownian rough path, Gaussian rough paths and the Banach space valued Wiener process enhanced with its Lévy area [Ledoux, Lyons, Quian. "Lévy area of Wiener processes in Banach spaces". Ann. Probab., 30(2):546--578, 2002] then all follow from applying our main theorem.We prove a generalisation of Fernique's theorem which applies to a class of (measurable) functionals on abstract Wiener spaces by using the isoperimetric inequality. Our motivation comes from rough path theory where one deals with iterated integrals of Gaussian processes (which are generically not Gaussian). Gaussian integrability with explicitly given constants for variation and Hölder norms of the (fractional) Brownian rough path, Gaussian rough paths and the Banach space valued Wiener process enhanced with its Lévy area [Ledoux, Lyons, Quian. "Lévy area of Wiener processes in Banach spaces". Ann. Probab., 30(2):546--578, 2002] then all follow from applying our main theorem.

  • P. Friz, H. Oberhauser, On the splitting-up method for rough (partial) differential equations, Preprint no. arXiv:1008.0513, Cornell University Library, arXiv.org, 2010.

  • P. Friz, H. Oberhauser, Rough path stability of SPDEs arising in non-linear filtering, Preprint no. arXiv:1005.1781, Cornell University Library, arXiv.org, 2010.

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