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| Format: | Preprint |
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2024
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| Online Access: | https://arxiv.org/abs/2408.04758 |
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| _version_ | 1866911982678966272 |
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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 |
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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 |