Multiboundary wormholes and OPE statistics
de Boer, J
Liška, D
Post, B
Journal of High Energy Physics
volume 2024
issue 10
(29 Oct 2024)
A principle of maximum ignorance for semiclassical gravity
de Boer, J
Liska, D
Post, B
Sasieta, M
Journal of High Energy Physics
volume 2024
issue 2
(01 Feb 2024)
Quantum chaos in 2D gravity
Altland, A
Post, B
Sonner, J
van der Heijden, J
Verlinde, E
SciPost Physics
volume 15
issue 2
(16 Aug 2023)
A non-rational Verlinde formula from Virasoro TQFT
Post, B
Tsiares, I
Journal of High Energy Physics
volume 2025
issue 4
(01 Apr 2025)
A universe field theory for JT gravity
Post, B
van der Heijden, J
Verlinde, E
Journal of High Energy Physics
volume 2022
issue 5
(18 May 2022)
Congratulations to Ulrike who has received an honorary doctorate from the University of Copenhagen.
Ulrike is a Professor of Mathematics here in Oxford specialising in algebraic topology and also Director of the Isaac Newton Institute in Cambridge.
TRACKING SINUSOIDAL SIGNALS WITH TIME VARYING FREQUENCY USING OPTIMAL CONTROL
Evans, R
Liu, C
Nair, G
Suvorova, S
Moran, B
Communications in Optimization Theory
volume 2025
(01 Jan 2025)
Dynamic Length FSK Waveforms for Joint Communications and Radar
Han, T
Smith, P
Mitra, U
Evans, J
Evans, R
Senanayake, R
IEEE Transactions on Wireless Communications
(01 Jan 2025)
Broadband Flexible Sensor for Microwave Dielectric Spectroscopy of Liquids in Vials
Harkinezhad, B
Markovic, T
Evans, R
Ghorbani, K
Skafidas, E
Schreurs, D
IEEE Transactions on Microwave Theory and Techniques
(01 Jan 2025)
Thu, 26 Feb 2026
16:00 -
17:00
L5
Deep learning for pricing and hedging: robustness and foundations
Lukas Gonon
(University of St. Gallen)
Abstract
In the past years, deep learning algorithms have been applied to numerous classical problems from mathematical finance. In particular, deep learning has been employed to numerically solve high-dimensional derivatives pricing and hedging tasks. Theoretical foundations of deep learning for these tasks, however, are far less developed. In this talk, we start by revisiting deep hedging and introduce a recently developed adversarial training approach for making it more robust. We then present our recent results on theoretical foundations for approximating option prices, solutions to jump-diffusion PDEs and optimal stopping problems using (random) neural networks, allowing to obtain more explicit convergence guarantees. We address neural network expressivity, highlight challenges in analysing optimization errors and show the potential of random neural networks for mitigating these difficulties.