Proof. We first prove the existence result. We shall follow the arguments of [Reference Hu and Tang13, Theorem 3.1]. Let us fix $n\in N^*$ and $p\in N^*$ . Set

\begin{alignat*}{3}\xi^{n,p} & \;:\!=\; \xi^+\wedge n-\xi^-\wedge p, &\quad L^{n,p} &\;:\!=\; L^+\wedge n-L^-\wedge p,\\[5pt] g_0^{n,p} &\;:\!=\; g_0^+\wedge n-g_0^-\wedge p, &\quad g^{n,p} &\;:\!=\; g-g_0+g_0^{n,p}.\end{alignat*}

As the terminal value $\xi^{n,p}$ , the barrier $L^{n,p}$ and $g^{n,p}(\cdot,0,0)$ are bounded (hence square-integrable) and $g^{n,p}$ is Lipschitz-continuous, in view of the existence result in [Reference El Karoui, Kapoudjian, Pardoux, Peng and Quenez9], the RBSDE $(\xi^{n,p},L^{n,p},g^{n,p})$ has a unique solution $(Y^{n,p},Z^{n,p},K^{n,p})$ in $\mathbb S^2\times \mathbb H^2\times\mathbb I^2$ . In particular, there exists a $\mathbb R$ -valued (resp. $\mathbb R^d$ -valued) adapted process $\beta_s^{n,p}$ (resp. $\gamma_s^{n,p}$ ), with $|\beta_s^{n,p}|\le \beta$ (resp. $|\gamma_s^{n,p}|\le\gamma$ ) such that

\begin{equation*}g^{n,p}(s,Y_s^{n,p},Z_s^{n,p})-g^{n,p}(s,0,0)=g_0^{n,p}(s)+\beta_s^{n,p}Y_s^{n,p}+\cdot Z_s^{n,p}\gamma_s^{n,p}.\end{equation*}

Let us define

\begin{align*}X_t^{n,p} & \;:\!=\; \exp\biggl(\int_0^t \beta_r^{n,p}\,{\mathrm{d}} r\biggr),\\[5pt] \dfrac{{\mathrm{d}}\mathbb P^{n,p}}{{\mathrm{d}}\mathbb P} & \;:\!=\; \exp\biggl(\int_0^{T}\gamma_s^{n,p}\cdot {\mathrm{d}} B_s-\dfrac{1}{2}\int_0^T |\gamma_s^{n,p}|^2 \,{\mathrm{d}} s\biggr),\\[5pt] B^{\mathbb P^{n,p}} & =B_{\cdot}-\int_0^{\cdot}\gamma_s^{n,p}\,{\mathrm{d}} s.\end{align*}

Then, by the Girsanov theorem, $B^{\mathbb P^{n,p}}$ is a $\mathbb P^{n,p}$ -Brownian motion, and we can rewrite the solution of RBSDE $(\xi^{n,p},L^{n,p},g^{n,p})$ as

\begin{equation*} \begin{cases}X_t^{n,p}Y_t^{n,p}=X_T^{n,p}\xi^{n,p}+\int_t^T X_s^{n,p}g_0^{n,p}(s)\,{\mathrm{d}} s-\int_t^T X_s^{n,p}Z_s^{n,p}\,{\mathrm{d}} B_s^{\mathbb P^{n,p}}+\int_t^T X_s^{n,p}\,{\mathrm{d}} K_s^{n,p},\\[5pt] X_t^{n,p}Y_t^{n,p}\ge X_t^{n,p}L_t^{n,p},\quad \int_0^T X_s^{n,p}(Y_s^{n,p}-L_s^{n,p})\,{\mathrm{d}} K_s^{n,p}=0.\end{cases}\end{equation*}

Using the Snell envelope representation of solutions to RBSDEs (see e.g. [Reference El Karoui, Kapoudjian, Pardoux, Peng and Quenez9, Proposition 2.3]), we have

\begin{equation*}X_t^{n,p}Y_t^{n,p}=\mathop{\mathrm{ess\sup}}_{\tau\in\mathbb T^{t,T}}\mathbb E_t^{\mathbb P^{n,p}}\biggl[\int_t^{\tau}X_s^{n,p}g_0^{n,p}(s)\,{\mathrm{d}} s+X_{\tau}^{n,p}L_{\tau}^{n,p}\textbf1_{\tau<T}+X_T^{n,p}\xi^{n,p}\textbf 1_{\tau=T}\biggr].\end{equation*}

Then we deduce that

\begin{align*}&\mathbb E_t^{\mathbb P^{n,p}}\biggl[\int_t^T X_s^{n,p}g_0^{n,p}(s)\,{\mathrm{d}} s+X_T^{n,p}\xi^{n,p}\biggr]\le X_t^{n,p}Y_t^{n,p}\\[5pt] &\quad \le \mathop{\mathrm{ess\sup}}_{\tau\in\mathbb T^{t,T}}\mathbb E_t^{\mathbb P^{n,p}}\biggl[\int_t^{\tau}X_s^{n,p}g_0^{n,p}(s)\,{\mathrm{d}} s+X_{\tau}^{n,p}(L_{\tau}^{n,p})^+\textbf 1_{\tau<T}+X_{T}^{n,p}\xi^{n,p}\textbf 1_{\tau=T}\biggr].\end{align*}

This inequality leads to

\begin{align*}|Y_t^{n,p}|&\le \mathop{\mathrm{ess\sup}}_{\tau\in\mathbb T^{t,T}}\mathbb E_t^{\mathbb P^{n,p}}\biggl[\int_t^{\tau}|g_0^{n,p}(s)|\,{\mathrm{e}}^{\beta (s-t)}\,{\mathrm{d}} s+{\mathrm{e}}^{\beta (\tau-t)}(L_{\tau}^{n,p})^+\textbf 1_{\tau<T}+{\mathrm{e}}^{\beta (T-t)}|\xi^{n,p}|\textbf 1_{\tau=T}\biggr]\\[5pt] &\le {\mathrm{e}}^{\beta (T-t)}\mathbb E_t^{\mathbb P^{n,p}}\biggl[\int_t^T |g_0^{n,p}(s)|\,{\mathrm{d}} s+(L_T^{n,p})^{+,*}+|\xi^{n,p}|\biggr]\\[5pt] &\le {\mathrm{e}}^{\beta (T-t)}\mathbb E_t^{\mathbb P^{n,p}}\biggl[\int_t^T |g_0(s)|\,{\mathrm{d}} s+L_T^{+,*}+|\xi|\biggr].\end{align*}

Using Lemmas 2.4 and 2.6 of [Reference Hu and Tang13] and the fact that $\mu>\gamma\sqrt T$ , we deduce that

(6) \begin{align} |Y_t^{n,p}| &\le\bar Y_t \notag \\[5pt] & \;:\!=\; \dfrac{1}{\sqrt{1-({\gamma^2}/{\mu^2})(T-t)}}\,{\mathrm{e}}^{\beta (T-t)}+{\mathrm{e}}^{2\mu^2+\beta (T-t)}\cdot \mathbb E_t\biggl[\psi(|\xi|+L_T^{+,*}+\int_t^T |g_0(s)|\,{\mathrm{d}} s,\mu)\biggr].\end{align}

This estimate, together with the monotone stability theorem (see [Reference Bayraktar and Yao2, Theorem 3.1] or [Reference Kobylanski, Lepeltier, Quenez and Torres16, Theorem 4]) is fundamental to proving our existence result. Since $Y^{n,p}$ is non-decreasing in n and non-increasing in p thanks to the comparison theorem (see [Reference El Karoui, Kapoudjian, Pardoux, Peng and Quenez9, Theorem 4.1]), by the localization method in [Reference Bayraktar and Yao2] and [Reference Lepeltier and Xu17] there exists some process $Z\in L^2(0,T)$ such that $(Y\;:\!=\; \inf_p\sup_n Y^{n,p},Z,K\;:\!=\; \sup_p\inf_n K^{n,p})$ is an adapted solution. The fact that $\psi(|Y|,a)$ belongs to class (D) for some $a>0$ can be proved by following exactly the same method as in [Reference Buckdahn, Hu and Tang4], thanks to (6). Since $\mu>b\sqrt{t}$ , we can choose $a>0$ , $b>\gamma\sqrt{T}$ , and $c>0$ such that $a+b+c=\mu$ . For such a constant a, $\psi(|Y|,a)$ belongs to class (D) (see the proof of Theorem 2.4 of [Reference Buckdahn, Hu and Tang4]).

We now prove the uniqueness of the solution. For $i=1,2$ , let $(Y^i,Z^i,K^i)$ be a solution to RBSDE (4) such that $\psi (|Y^i|,a^i)$ belongs to class (D) for some $a^i>0$ . Define

\begin{equation*}a\;:\!=\; a^1\wedge a^2,\quad \delta Y\;:\!=\; Y^1-Y^2,\quad \delta Z\;:\!=\; Z^1-Z^2,\quad \delta K\;:\!=\; K^1-K^2.\end{equation*}

Then both $\psi (|Y^1|,a)$ and $\psi (|Y^2|,a)$ belong to class (D), since $\psi (x,\mu)$ is non-decreasing in $\mu$ . Moreover, in view of Proposition 2.3 of [Reference Buckdahn, Hu and Tang4], we have

\begin{align*} \psi(|\delta Y_t|,a)&\le \psi(|Y_t^1|+|Y_t^2|,a)\\[5pt] &=\psi\biggl(\dfrac{1}{2}\times 2|Y_t^1|+\dfrac{1}{2}\times 2|Y_t^2|,a\biggr)\\[5pt] &\le \dfrac{1}{2}\psi(2|Y_t^1|,a)+\dfrac{1}{2}\psi(2|Y_t^2|,a)\\[5pt] &\le \dfrac{1}{2}\psi(2,a)[\psi(|Y_t^1|,a)+\psi(|Y_t^2|,a)],\end{align*}

from which we deduce that $\psi(|\delta Y|,a)$ belongs to class (D).

By a standard linearization argument, we see that there exist two adapted processes u and v such that $|u_s|\le \beta$ , $|v_s|\le\gamma$ , and $g(s,Y_s^1,Z_s^1)-g(s,Y_s^2,Z_s^2)=u_s\delta Y_s+\delta Z_s v_s$ and the triple $(\delta Y,\delta Z,\delta K)$ satisfies

\begin{equation*}\delta Y_t=\int_t^T [u_s\delta Y_s+\delta Z_s v_s]\,{\mathrm{d}} s-\int_t^T \delta Z_s \,{\mathrm{d}} B_s+\delta K_T-\delta K_t,\ t\in [0,T].\end{equation*}

Set $\theta\;:\!=\; {a^2}/{(4\gamma^2)}$ . Let us define

\begin{equation*}\dfrac{{\mathrm{d}}\mathbb Q}{{\mathrm{d}}\mathbb P}\;:\!=\; \exp\biggl(\int_{T-\theta}^{T} v_s\cdot {\mathrm{d}} B_s-\dfrac{1}{2}\int_{T-\theta}^T|v_s|^2 \,{\mathrm{d}} s\biggr),\quad B_t^{\mathbb Q}\;:\!=\; B_{t}-\int_{T-\theta}^{t}v_s \,{\mathrm{d}} s,\quad t\in [T-\theta, T].\end{equation*}

Then, by the Girsanov theorem, $B^{\mathbb Q}$ is a $\mathbb Q$ -Brownian motion on $[T-\theta,T]$ . Therefore we have $\mathbb Q$ -a.s.

(7) \begin{equation}\delta Y_t=\int_t^T u_s\delta Y_s \,{\mathrm{d}} s-\int_t^T \delta Z_s \,{\mathrm{d}} B_s^{\mathbb Q}+\delta K_T-\delta K_t,\quad t\in [T-\theta,T].\end{equation}

We now show that $\{\delta Y_t,t\in[T-\theta,T]\}$ belongs to class (D) under $\mathbb Q$ . To do this, we note that $\psi(|\delta Y|,a)$ belongs to class (D). Using Lemmas 2.4 and 2.6 of [Reference Hu and Tang13], we have for any $\tau\in\mathbb T^{T-\theta,T}$ and $A\in\mathcal F_T$ ,

\begin{align*}\mathbb E^{\mathbb Q}[\textbf 1_A|\delta Y_{\tau}|]&\le \mathbb E\biggl[\textbf 1_A |\delta Y_{\tau}|\exp\biggl(\int_{T-\theta}^T v_s\cdot \,{\mathrm{d}} B_s\biggr)\biggr]\\[5pt] &\le \mathbb E\biggl[\textbf 1_A\exp\biggl( \dfrac{\bigl|\int_{T-\theta}^T v_s\cdot {\mathrm{d}} B_s\bigr|^2}{2a^2} \biggr)\biggr]+\mathbb E\bigl[{\mathrm{e}}^{2a^2}\textbf 1_A\psi (|\delta Y_{\tau}|,a)\bigr]\\[5pt] &\le \mathbb E\biggl[\exp\biggl( \dfrac{\bigl|\int_{T-\theta}^T \sqrt 2 v_s\cdot {\mathrm{d}} B_s\bigr|^2}{2a^2} \biggr)\biggr]^{1/2}\cdot \mathbb P(A)^{1/2}+\mathbb E\bigl[{\mathrm{e}}^{2a^2}\textbf 1_A\psi (|\delta Y_{\tau}|,a)\bigr]\\[5pt] &\le \biggl(1-\dfrac{2\gamma^2}{a^2}\theta\biggr)^{-1/4}\cdot \mathbb P(A)^{1/2}+{\mathrm{e}}^{2a^2}\mathbb E[\textbf 1_A\psi (|\delta Y_{\tau}|,a)]\\[5pt] &= 2^{1/4}\cdot\mathbb P(A)^{1/2} +{\mathrm{e}}^{2a^2}\mathbb E[\textbf 1_A\psi (|\delta Y_{\tau}|,a)].\end{align*}

We then have

(8) \begin{equation}\sup_{\tau\in \mathbb T^{T-\theta,T}}\mathbb E^{\mathbb Q}[|\delta Y_{\tau}|]\le 2^{1/4}+{\mathrm{e}}^{2a^2}\sup_{\tau\in\mathbb T^{T-\theta,T}}\mathbb E[\psi(|\delta Y_{\tau}|,a)]<+\infty.\end{equation}

On the other hand, for any $\varepsilon>0$ , there exists $ \vartheta_1>0$ such that, for all $ A\in\mathcal F_T$ $(\mathbb P(A)<\vartheta_1)$ , we have

\begin{equation*}{ \sup_{\tau\in\mathbb T^{T-\theta,T}}\mathbb E[\textbf 1_A\psi(|\delta Y_{\tau}|,a)]<\dfrac{\varepsilon}{2{\mathrm{e}}^{2a^2}}.}\end{equation*}

Since $\mathbb Q$ is equivalent to $\mathbb P$ , $\mathbb P$ is totally continuous with respect to $\mathbb Q$ (see e.g. [Reference Klenke14, Definition 7.35 and Theorem 7.37]). Thus there exists $ \vartheta_2>0$ such that, for any A $(\mathbb Q(A)<\vartheta_2)$ , we have

\begin{equation*}{\mathbb P(A)<\min\{\vartheta_1,2^{-5/2}\varepsilon\}.}\end{equation*}

Consequently we deduce that, for any $ \varepsilon>0$ , there exists $\vartheta_2>0$ such that, for any A $(\mathbb Q(A)<\vartheta_2)$ , we have

(9) \begin{equation}{ \sup_{\tau\in\mathbb T^{T-\theta,T}}\mathbb E^{\mathbb Q}[\textbf 1_A |\delta Y_{\tau}|]\le 2^{1/4}\cdot \mathbb P(A)^{1/2}+{\mathrm{e}}^{2a^2}\cdot \dfrac{\varepsilon}{2{\mathrm{e}}^{2a^2}}< \varepsilon.}\end{equation}

In view of (8) and (9), we deduce that $\{\delta Y_t,t\in [T-\theta, T]\}$ belongs to class (D) under $\mathbb Q$ . We define the stopping times

(10) \begin{equation}\tau_n\;:\!=\; \inf \biggl\{t\ge T-\theta\colon |\delta Y_t|+\int_{T-\theta}^t |\delta Z_s|^2\,{\mathrm{d}} s\ge n\biggr\}\wedge T,\end{equation}

with the convention that $\inf\phi=+\infty$ . Applying Itô’s formula to $|\delta Y_t|$ (see e.g. [Reference Hamadène and Popier12, Corollary 1]), we obtain for any $t\in [T-\theta,T]$

\begin{align*}|\delta Y_{t\wedge\tau_n}|&\le |\delta Y_{\tau_n}|+\int_{t\wedge\tau_n}^{\tau_n} \text{sgn}(\delta Y_s)u_s\delta Y_s\,{\mathrm{d}} s-\int_{t\wedge\tau_n}^{\tau_n}\text{sgn}(\delta Y_s)\delta Z_s \,{\mathrm{d}} B_s^{\mathbb Q}+\int_{t\wedge\tau_n}^{\tau_n}\text{sgn}(\delta Y_s)\,{\mathrm{d}}\delta K_s\\[5pt] &\le |\delta Y_{\tau_n}|+\int_{t\wedge\tau_n}^{\tau_n} \beta |\delta Y_s|\,{\mathrm{d}} s-\int_{t\wedge\tau_n}^{\tau_n}\text{sgn}(\delta Y_s)\delta Z_s \,{\mathrm{d}} B_s^{\mathbb Q}+\int_{t\wedge\tau_n}^{\tau_n}\text{sgn}(\delta Y_s)\,{\mathrm{d}}\delta K_s.\end{align*}

Observe that

\begin{align*}\text{sgn}(\delta Y_s)\,{\mathrm{d}}(\delta K)_s&=\textbf 1_{\delta Y_s\neq 0}\dfrac{\delta Y_s}{|\delta Y_s|}\,{\mathrm{d}}(\delta K)_s\\[5pt] &=\textbf 1_{\delta Y_s\neq 0}\dfrac{Y_s^1-L_s}{|\delta Y_s|}\,{\mathrm{d}}(\delta K)_s-\textbf 1_{\delta Y_s\neq 0}\dfrac{Y_s^2-L_s}{|\delta Y_s|}\,{\mathrm{d}}(\delta K)_s\\[5pt] &=-\textbf 1_{\delta Y_s\neq 0}\dfrac{Y_s^1-L_s}{|\delta Y_s|}\,{\mathrm{d}} K_s^2-\textbf 1_{\delta Y_s\neq 0}\dfrac{Y_s^2-L_s}{|\delta Y_s|}\,{\mathrm{d}} K_s^1\\[5pt] &\le 0,\quad s\in [T-\theta,T].\end{align*}

Therefore, for any $T-\theta\le u\le t\le T$ ,

\begin{equation*}\mathbb E_u^{\mathbb Q}[|\delta Y_{t\wedge\tau_n}|]\le \mathbb E_u^{\mathbb Q}\biggl[|\delta Y_{\tau_n}|+\int_{t\wedge\tau_n}^{\tau_n} \beta |\delta Y_s|\,{\mathrm{d}} s\biggr].\end{equation*}

Observe that $\delta Y_{\tau_n}\to \delta Y_T=0$ and $\delta Y_{t\wedge\tau_n}\to \delta Y_{t}$ . Since $\{\delta Y_t,t\in [T-\theta,T]\}$ belongs to class (D) under $\mathbb Q$ , by sending $n\to\infty$ in the above inequality and taking a subsequence if necessary, we get

\begin{equation*}\mathbb E_u^{\mathbb Q}[|\delta Y_{t}|]\le \mathbb E_u^{\mathbb Q}\biggl[\int_{t}^{T} \beta |\delta Y_s|\,{\mathrm{d}} s\biggr]=\int_{t}^{T} \beta \mathbb E_u^{\mathbb Q}[|\delta Y_s|]\,{\mathrm{d}} s,\quad t\in [T-\theta,T].\end{equation*}

By virtue of Gronwall’s inequality, we obtain for all $T-\theta\le u\le t\le T $

\begin{equation*}\mathbb E_u^{\mathbb Q}[|\delta Y_t|]=0\quad \text{$\mathbb Q$-a.s.}\end{equation*}

In particular, we have at $u=t$ , $\delta Y_t=0$ , $\mathbb Q$ -a.s. Since $\mathbb Q$ is equivalent to $\mathbb P$ , this holds up to a set of $\mathbb P$ -measure zero. It is then clear that $\delta Z_t=0$ and $\delta K_t=0$ for all $t\in [T-\theta,T]$ . The uniqueness is obtained on the interval $[T-\theta,T]$ . In an identical way, we have the uniqueness of the solution on the interval $[T-2\theta,T-\theta]$ . By a finite number of steps, we cover in this way the whole interval [0, T], and we conclude the uniqueness of the solution on the interval [0, T].

Proof. Set $a\;:\!=\; a^1\wedge a^2$ . Then both $\psi (|Y^1|,a)$ and $\psi (|Y^2|,a)$ belong to class (D). We also define

\begin{equation*}\delta Y\;:\!=\; Y^1-Y^2,\quad \delta Z\;:\!=\; Z^1-Z^2,\quad \delta g_t\;:\!=\; g^1(t,Y_t^1,Z_t^1)-g^2(t,Y_t^1,Z_t^1),\quad \delta K_t\;:\!=\; K_t^1-K_t^2.\end{equation*}

By the Lipschitz assumption, we have two adapted processes $u_s$ and $v_s$ such that $|u_s|\le\beta$ , $|v_s|\le\gamma$ , and $g^2(s,Y_s^1,Z_s^1)-g^2(s,Y_s^2,Z_s^2)=u_s\delta Y_s+\delta Z_s v_s$ . We define the stopping times

\begin{equation*}\tau_n\;:\!=\; \inf\{t\ge 0\colon |\delta Y_t|+\int_0^t |\delta Z_s|\,{\mathrm{d}} s+|\delta K_t|\ge n\}\wedge T,\quad n=1,2,\ldots,\end{equation*}

with the convention that $\inf \phi=\infty$ . Since $(\delta Y,\delta Z)$ satisfies the linear BSDE

\begin{equation*}\delta Y_t=\delta \xi+\int_t^T (\delta g_t+u_s\delta Y_s+\delta Z_s v_s)\,{\mathrm{d}} s-\int_t^T \delta Z_s\,{\mathrm{d}} B_s+\delta K_T-\delta K_t,\quad t\in [0,T],\end{equation*}

we have

\begin{equation*}\delta Y_{t\wedge\tau_n}=\mathbb E_t\biggl[\Gamma_{t\wedge\tau_n,\tau_n}\delta Y_{\tau_n}+\int_{t\wedge\tau_n}^{\tau_n}\Gamma_{t\wedge\tau_n,r}\delta g_r \,{\mathrm{d}} r+\int_{t\wedge\tau_n}^{\tau_n}\Gamma_{t\wedge\tau_n,r}\,{\mathrm{d}} (\delta K)_r\biggr],\end{equation*}

where

\begin{equation*}\Gamma_{s,t}\;:\!=\; \exp\biggl(\int_{s}^{t}u_r \,{\mathrm{d}} r+\int_{s}^{t}v_r\cdot \,{\mathrm{d}} B_r-\dfrac{1}{2}\int_{s}^{t}|v_r|^2 \,{\mathrm{d}} r\biggr),\quad 0\le s\le t\le T.\end{equation*}

Since $\delta g_r\le 0$ and ${\mathrm{d}}(\delta K)_r\le 0$ ,

(11) \begin{equation}\delta Y_{t\wedge\tau_n}\le \mathbb E_t[\Gamma_{t\wedge\tau_n,\tau_n}\delta Y_{\tau_n}]\le {\mathrm{e}}^{\beta T}\mathbb E_t\biggl[\exp\biggl(\int_{t\wedge\tau_n}^{\tau_n}v_s\cdot {\mathrm{d}} B_s\biggr)|\delta Y_{\tau_n}|\biggr].\end{equation}

Note that thanks to Lemmas 2.4 and 2.6 of [Reference Hu and Tang13],

(12) \begin{equation} \exp\biggl(\int_{t\wedge\tau_n}^{\tau_n}v_s\cdot {\mathrm{d}} B_s\biggr)|\delta Y_{\tau_n}|\le \exp\biggl(\frac{1}{2a^2}\biggl(\int_{t\wedge\tau_n}^{\tau_n}v_s\cdot {\mathrm{d}} B_s\biggr)^2\biggr)+ {\mathrm{e}}^{2a^2}\psi (|\delta Y_{\tau_n}|,a),\end{equation}

and for $t\in [T-{a^2}/{(4\gamma^2)},T]$ ,

(13) \begin{align} \mathbb E\biggl[\biggl|\exp\biggl(\frac{1}{2a^2}\biggl(\int_{t\wedge\tau_n}^{\tau_n}v_s\cdot {\mathrm{d}} B_s\biggr)^2\biggr)\biggr|^2\biggr] & =\mathbb E\biggl[\exp\biggl(\frac{1}{a^2}\biggl(\int_{t\wedge\tau_n}^{\tau_n}v_s\cdot {\mathrm{d}} B_s\biggr)^2\biggr)\biggr] \notag \\[5pt] &\le \biggl[1-\dfrac{2\gamma^2}{a^2}(T-t)\biggr]^{-1/2} \notag \\[5pt] &\le \sqrt 2.\end{align}

Moreover, we have

\begin{equation*}\psi(|\delta Y_{\tau_n}|,a)\le \dfrac{1}{2}\psi(2,a)\bigl[\psi\bigl(|Y_{\tau_n}^1|,a\bigr)+\psi\bigl(|Y_{\tau_n}^2|,a\bigr)\bigr].\end{equation*}

From (12) and (13), it follows that for $t\in [T-{a^2}/{(4\gamma^2)},T]$ , the family of random variables

\begin{equation*}\exp\biggl(\int_{t\wedge\tau_n}^{\tau_n}v_s\cdot {\mathrm{d}} B_s\biggr)|\delta Y_{\tau_n}|\end{equation*}

is uniformly integrable. Finally, letting $n\to \infty$ in inequality (11), in view of $\delta\xi\le 0$ , we have $\delta Y_t\le 0$ on the interval $[T-{a^2}/{(4\gamma^2)},T]$ . In an identical way, we have $\delta Y_t\le 0$ on the interval $[T-{a^2}/{(2\gamma^2)},T-{a^2}/{(4\gamma^2)}]$ . By a finite number of steps, we have the comparison principle on the whole interval [0, T].

Proof. Define

\begin{gather*} a\;:\!=\; a^1\wedge a^2,\quad \delta Y\;:\!=\; Y^1-Y^2,\quad \delta Z\;:\!=\; Z^1-Z^2, \\[5pt] \delta K\;:\!=\; K^1-K^2,\quad \delta\xi\;:\!=\; \xi^1-\xi^2,\quad \delta g_t\;:\!=\; g^1(t,Y_t^1,Z_t^1)-g^2(t,Y_t^1,Z_t^1). \end{gather*}

By the Lipschitz assumption, there are two processes u and v such that $|u|\le \beta$ , $|v|\le \gamma$ , and

\begin{equation*} g^2(t,Y_t^1,Z_t^1)-g^2(t,Y_t^2,Z_t^2)=u_t\delta Y_t+\delta Z_s v_s. \end{equation*}

Obviously, $(\delta Y,\delta Z,\delta K)$ satisfies the following equation:

\begin{equation*}\delta Y_t=\delta \xi+\int_t^T[u_s\delta Y_s+\delta Z_s v_s+\delta g_s]\,{\mathrm{d}} s-\int_t^T\delta Z_s \,{\mathrm{d}} B_s+\delta K_T-\delta K_t,\quad t\in [0,T].\end{equation*}

Define $\theta\;:\!=\; {a^2}/{(4\gamma^2)}$ . By following the same arguments as we did before (more precisely, the uniqueness part of the proof of Theorem 1), $\psi (|\delta Y|,a)$ belongs to class (D) and there exists a probability measure $\mathbb Q$ equivalent to $\mathbb P$ such that $(\delta Y,\delta Z,\delta K)$ satisfies $\mathbb Q$ -a.s.

\begin{equation*}\delta Y_t=\int_t^T (\delta g_s+u_s\delta Y_s)\,{\mathrm{d}} s-\int_t^T \delta Z_s \,{\mathrm{d}} B_s^{\mathbb Q}+\delta K_T-\delta K_t,\quad t\in [T-\theta,T],\end{equation*}

where $B^{\mathbb Q}$ is a $\mathbb Q$ -Brownian motion on $[T-\theta,T]$ . In particular, the process $\{\delta Y_t,t\in [T-\theta,T]\}$ belongs to class (D) under $\mathbb Q$ . We define the stopping times $\tau_n$ as in (10). Applying the Itô–Tanaka formula to $\delta Y_t^+$ , we obtain for any $t\in [T-\theta,T]$

(14) \begin{align} &\delta Y_{t\wedge\tau_n}^+\notag\\[5pt] &\le \delta Y_{\tau_n}^++\int_{t\wedge\tau_n}^{\tau_n} \textbf 1_{\delta Y_s>0}[\delta g_s+u_s\delta Y_s]\,{\mathrm{d}} s-\int_{t\wedge\tau_n}^{\tau_n}\textbf 1_{\delta Y_s>0}\delta Z_s \,{\mathrm{d}} B_s^{\mathbb Q}+\int_{t\wedge\tau_n}^{\tau_n}\textbf 1_{\delta Y_s>0}\,{\mathrm{d}} (\delta K)_s.\end{align}

Using $L_t^1\le L_t^2$ , we have $L_t^1\le Y_t^1\wedge Y_t^2\le Y_t^1$ and

\begin{equation*}\textbf 1_{\delta Y_s>0}\,{\mathrm{d}} K_s^1=\textbf 1_{\delta Y_s>0}\dfrac{Y_s^1-Y_s^1\wedge Y_s^2}{|\delta Y_s|}\,{\mathrm{d}} K_s^1\le \textbf 1_{\delta Y_s>0}\dfrac{Y_s^1-L_s^1}{|\delta Y_s|}\,{\mathrm{d}} K_s^1=0.\end{equation*}

Therefore we have for all $s\in [T-\theta,T]$

\begin{equation*}\textbf 1_{\delta Y_s>0}\,{\mathrm{d}}(\delta K)_s\le \textbf 1_{\delta Y_s>0}\,{\mathrm{d}} K_s^1\le 0.\end{equation*}

Using this and the fact that $\delta g_s\le 0$ , we deduce from (14) that for all $T-\theta\le u\le t\le T$

\begin{equation*}\mathbb E_u^{\mathbb Q}[\delta Y_{t\wedge\tau_n}^+]\le \mathbb E_u^{\mathbb Q}\biggl[\delta Y_{\tau_n}^++\int_{t\wedge\tau_n}^{\tau_n} \beta\delta Y_s^+\,{\mathrm{d}} s\biggr].\end{equation*}

Since $\{\delta Y_t,t\in [T-\theta,T]\}$ belongs to class (D) under $\mathbb Q$ , so do $\{\delta Y_t^+,t\in [T-\theta,T]\}$ . We also know hat $\delta Y_{t\wedge\tau_n}^+\to \delta Y_t^+$ and $\delta Y_{\tau_n}^+\to \delta Y_T^+=\delta \xi^+=0$ . By sending n to $\infty$ in the above inequality, we obtain for all $T-\theta\le u\le t\le T$

\begin{equation*}\mathbb E_u^{\mathbb Q}[\delta Y_{t}^+]\le \mathbb E_u^{\mathbb Q}\biggl[\int_{t}^{T} \beta\delta Y_s^+\,{\mathrm{d}} s\biggr].\end{equation*}

Gronwall’s inequality implies that $\delta Y_t^+=0$ for all $t\in [T-\theta,T]$ , $\mathbb Q$ -a.s. Since $\mathbb Q$ is equivalent to $\mathbb P$ , we see that $\delta Y_t^+=0$ (i.e. $Y_t^1\le Y_t^2$ ) for all $t\in [T-\theta,T]$ , ${\mathbb P}$ -a.s. In an identical way, we obtain the comparison on the interval $[T-2\theta,T-\theta]$ . In a finite number of steps, we have the comparison on the whole interval [0, T]. The proof is then complete.