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Main Authors: Choulli, T., Alsheyab, S.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.04758
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author Choulli, T.
Alsheyab, S.
author_facet Choulli, T.
Alsheyab, S.
contents This paper considers the setting governed by $(\mathbb{F},τ)$, where $\mathbb{F}$ is the "public" flow of information, and $τ$ is a random time which might not be $\mathbb{F}$-observable. This framework covers credit risk theory and life insurance. In this setting, we assume $\mathbb{F}$ being generated by a Brownian motion $W$ and consider a vulnerable claim $ξ$, whose payment's policy depends {\it{essentially}} on the occurrence of $τ$. The hedging problems, in many directions, for this claim led to the question of studying the linear reflected-backward-stochastic differential equations (RBSDE hereafter), \begin{equation*} \begin{split} &dY_t=f(t)d(t\wedgeτ)+Z_tdW_{t\wedgeτ}+dM_t-dK_t,\quad Y_τ=ξ,\\ & Y\geq S\quad\mbox{on}\quad \Lbrack0,τ\Lbrack,\quad \displaystyle\int_0^τ(Y_{s-}-S_{s-})dK_s=0\quad P\mbox{-a.s.}.\end{split} \end{equation*} This is the objective of this paper. For this RBSDE and without any further assumption on $τ$ that might neglect any risk intrinsic to its stochasticity, we answer the following: a) What are the sufficient minimal conditions on the data $(f, ξ, S, τ)$ that guarantee the existence of the solution to this RBSDE? b) How can we estimate the solution in norm using $(f, ξ, S)$? c) Is there an $\mathbb F$-RBSDE that is intimately related to the current one and how their solutions are related to each other? This latter question has practical and theoretical leitmotivs.
format Preprint
id arxiv_https___arxiv_org_abs_2408_04758
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Linear reflected backward stochastic differential equations arising from vulnerable claims in markets with random horizon
Choulli, T.
Alsheyab, S.
Probability
Mathematical Finance
This paper considers the setting governed by $(\mathbb{F},τ)$, where $\mathbb{F}$ is the "public" flow of information, and $τ$ is a random time which might not be $\mathbb{F}$-observable. This framework covers credit risk theory and life insurance. In this setting, we assume $\mathbb{F}$ being generated by a Brownian motion $W$ and consider a vulnerable claim $ξ$, whose payment's policy depends {\it{essentially}} on the occurrence of $τ$. The hedging problems, in many directions, for this claim led to the question of studying the linear reflected-backward-stochastic differential equations (RBSDE hereafter), \begin{equation*} \begin{split} &dY_t=f(t)d(t\wedgeτ)+Z_tdW_{t\wedgeτ}+dM_t-dK_t,\quad Y_τ=ξ,\\ & Y\geq S\quad\mbox{on}\quad \Lbrack0,τ\Lbrack,\quad \displaystyle\int_0^τ(Y_{s-}-S_{s-})dK_s=0\quad P\mbox{-a.s.}.\end{split} \end{equation*} This is the objective of this paper. For this RBSDE and without any further assumption on $τ$ that might neglect any risk intrinsic to its stochasticity, we answer the following: a) What are the sufficient minimal conditions on the data $(f, ξ, S, τ)$ that guarantee the existence of the solution to this RBSDE? b) How can we estimate the solution in norm using $(f, ξ, S)$? c) Is there an $\mathbb F$-RBSDE that is intimately related to the current one and how their solutions are related to each other? This latter question has practical and theoretical leitmotivs.
title Linear reflected backward stochastic differential equations arising from vulnerable claims in markets with random horizon
topic Probability
Mathematical Finance
url https://arxiv.org/abs/2408.04758