English

Locally Lipschitz BSDE driven by a continuous martingale: path-derivative approach

Probability 2017-06-20 v4

Abstract

Using a new notion of path-derivative, we study well-posedness of backward stochastic differential equation driven by a continuous martingale MM when f(s,γ,y,z)f(s,\gamma,y,z) is locally Lipschitz in (y,z)(y,z): Yt=ξ(M[0,T])+tTf(s,M[0,s],Ys,Zsms)dtr[M,M]stTZsdMsNT+NtY_{t}=\xi(M_{[0,T]})+\int_{t}^{T}f(s,M_{[0,s]},Y_{s-},Z_{s}m_{s})d{\rm tr}[M,M]_{s}-\int_{t}^{T}Z_{s}dM_{s}-N_{T}+N_{t} Here, M[0,t]M_{[0,t]} is the path of MM from 00 to tt and mm is defined by [M,M]t=0tmsmsdtr[M,M]s[M,M]_{t}=\int_{0}^{t}m_{s}m_{s}^{*}d{\rm tr}[M,M]_{s}. When the BSDE is one-dimensional, we could show the existence and uniqueness of solution. On the contrary, when the BSDE is multidimensional, we show existence and uniqueness only when [M,M]T[M,M]_{T} is small enough: otherwise, we provide a counterexample that has blowing-up solution. Then, we investigate the applications to utility maximization problems.

Keywords

Cite

@article{arxiv.1606.03836,
  title  = {Locally Lipschitz BSDE driven by a continuous martingale: path-derivative approach},
  author = {Kihun Nam},
  journal= {arXiv preprint arXiv:1606.03836},
  year   = {2017}
}

Comments

36 pages

R2 v1 2026-06-22T14:23:42.981Z