General mean-field BSDEs with integrable terminal values
Weimin Jiang, Juan Li, Yan Shen
Abstract
This paper investigates $L^{1}$ solutions for mean-field backward stochastic differential equations (MFBSDEs) under different weak assumptions in both one-dimensional and multi-dimensional settings, whose generator $f(ω,t,y,z,μ)$ depends not only on the solution process $(Y,Z)$ but also on the law of $(Y,Z)$. In the one-dimensional case where $f$ depends on the law of $Y$, we show with the help of a test function method and a localization procedure that such type of equations with an integrable terminal condition admits an $L^{1}$ solution, when the generator $f(ω,t,y,z,μ)$ has a one-sided linear growth in $(y,μ)$, and an iterated-logarithmically sub-linear growth in $z$. Furthermore, by leveraging the additional extended monotonicity in $y$ and an iterated-logarithmically uniform continuity in $z$ of the generator $f(ω,t,y,z,μ)$ together with a strengthened nondecreasing condition in $μ$, we derive a comparison theorem for $L^{1}$ solutions, which immediately leads to the uniqueness of the $L^{1}$ solutions. Next, we establish the existence and the uniqueness of $L^{1}$ solutions for multi-dimensional mean-field BSDEs with integrable parameters in which the generator $f(ω,t,y,z,μ)$ depends on $μ=\mathbb{P}_{Y}$ and satisfies a one-sided Osgood condition as well as a general growth condition in $y$, a Lipschitz continuity as well as a sublinear growth condition in $z$, and a Lipschitz condition in $μ$. Finally, the solvability of $L^{1}$ solutions for general MFBSDEs is studied, where the generator $f(ω,t,y,z,μ)$ depends on both the solution process $(Y,Z)$ and its joint law $\mathbb{P}_{(Y,Z)}$.