Trajectory Dispersion Control for Precision Landing Guidance of Reusable Rockets
Abstract
This article is an engineering note, and formal abstract is omitted in accordance with the requirements of the journal. The main idea of this note is as follows. In endoatmospheric landing of reusable rockets, there exist various kinds of disturbances that can induce the trajectory dispersion. The trajectory dispersion propagates with flight time and ultimately determines landing accuracy. Therefore, to achieve high-precision landing, this note proposes a novel online trajectory dispersion control method. Based on a Parameterized Optimal Feedback Guidance Law (POFGL), two key components of the proposed method are designed: online trajectory dispersion prediction and real-time guidance parameter tuning for trajectory dispersion optimization. First, by formalizing a parameterized probabilistic disturbance model, the closed-loop trajectory dispersion under the POFGL is predicted online. Compared with the covariance control guidance method, a more accurate trajectory dispersion prediction is achieved by using generalized Polynomial Chaos (gPC) expansion and pseudospectral collocation methods. Second, to ensure computational efficiency, a gradient descent based real-time guidance parameter tuning law is designed to simultaneously optimize the performance index and meet the landing error dispersion constraint, which significantly reduces the conservativeness of guidance design compared with the robust trajectory optimization method. Numerical simulations indicate that the trajectory dispersion prediction method can achieve the same accuracy as the Monte Carlo method with smaller computational resource; the guidance parameter tuning law can improve the optimal performance index and meet the desired accuracy requirements through directly shaping the trajectory dispersion.