The aim of this work is to propose an extension of the Deep BSDE solver by Han, E, Jentzen (2017) to the case of FBSDEs with jumps. As in the aforementioned solver, starting from a discretized version of the BSDE and parametrizing the (high dimensional) control processes by means of a family of ANNs, the BSDE is viewed as model-based reinforcement learning problem and the ANN parameters are fitted so as to minimize a prescribed loss function. We take into account both finite and infinite jump activity by introducing, in the latter case, an approximation with finitely many jumps of the forward process.Comment: 31 page
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Backward stochastic differential equations (BSDE) are known to be a powerful tool in mathematical mo...
In this paper, we propose a deep learning based numerical scheme for strongly coupled FBSDEs, stemmi...
The optimal stopping problem is one of the core problems in financial markets, with broad applicatio...
The objective of this Final Year Project is to study deep learning-based numerical methods, with a f...
Solving high-dimensional partial differential equations is a recurrent challenge in economics, scien...
26 pages, to appear in SIAM Journal of Scientific ComputingRecently proposed numerical algorithms f...
International audienceWe present an algorithm to solve BSDEs with jumps based on Wiener Chaos Expans...
In this paper, we propose a deep learning based numerical scheme for strongly coupled forward backwa...
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International audienceThis paper is dedicated to the analysis of backward stochastic differential eq...
The present thesis deals with numerical schemes to solve Markov Decision Problems (MDPs), partial di...
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This paper is dedicated to the analysis of backward stochastic differential equations (BSDEs) with j...
We study a class of reflected backward stochastic differential equations with nonpositive jumps and ...
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