Abstract
In this paper, we study the indefinite linear-quadratic (LQ) stochastic optimal control problem for stochastic differential equations (SDEs) with jump diffusions and random coefficients driven by both the Brownian motion and the (compensated) Poisson process. In our problem setup, the coefficients in the SDE and the objective functional are allowed to be random, and the jump-diffusion part of the SDE depends on the state and control variables. Moreover, the cost parameters in the objective functional need not be (positive) definite matrices. Although the solution to this problem can also be obtained through the stochastic maximum principle or the dynamic programming principle, our approach is simple and direct. In particular, by using the Itô-Wentzell’s formula, together with the integro-type stochastic Riccati differential equation (ISRDE) and the backward SDE (BSDE) with jump diffusions, we obtain the equivalent objective functional that is quadratic in control u under the positive definiteness condition, where the approach is known as the completion of squares method. Then the explicit optimal solution, which is linear in state characterized by the ISRDE and the BSDE jump diffusions, and the associated optimal cost are derived by eliminating the quadratic term of u in the equivalent objective functional. We also verify the optimality of the proposed solution via the verification theorem, which requires solving the stochastic HJB equation, a class of stochastic partial differential equations with jump diffusions.
Highlights
We first provide the precise problem statement
The completion of squares method and the validation of the optimal solution for (P) via the verification theorem have not been studied in the existing literature, which we address in our paper
We verify the optimality of the proposed solution by the verification theorem solving the stochastic Hamilton-Jacobi-Bellman equation with jump diffusions
Summary
Let Rn be the n-dimensional Euclidean space. For x, y ∈ Rn , x > denotes the transpose of x, h x, yi is the inner product, and | x | := h x, x i1/2. This means that unlike the direct approach (equivalently, the completion of squares method) developed, Proposition 3 needs to solve the complex. Under the positive definiteness condition, we construct the quadratic equivalent objective functional, by which the explicit optimal solution for (P) and the associated optimal cost are characterized via the completion of squares method (see Theorem 1).
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