Optimization of Glide Trajectory of Guided Bombs Using a Radau Pseudo-spectral Method

doi:10.3969/j.issn.1000-1093.2014.08.007

Abstract

Abstract: The problem of optimizing the maximum range of a glide guided bomb is studied based on the principle of solving optimal control problems using the Radau pseudo-spectral method. The dynamic model of the guided bomb is nondimensionalized. Combining with the Pontryagin minimum principle, the analytic solution of the optimal control and the first-order necessary condition are derived. The trajectory optimization problem is translated to a nonlinear programming via the Radau pseudo-spectral method. Based on covector mapping principle, an optimality verification method is presented for the numerical solution. Simulation results show that the Radau pseudo-spectral method can provide a highly valuable optimal solution for engineering application. Compared with the conventional maximum lift-to-drag ratio gliding trajectory, the trajectory after optimization can be extended by more than 10%.

Key words: ordnance science and technology, glide guided bomb, trajectory optimization, Radau pseudo-spectral method

CLC Number:

TJ765.5

YUAN Yan-bo， ZHANG Ke， XUE Xiao-dong. Optimization of Glide Trajectory of Guided Bombs Using a Radau Pseudo-spectral Method[J]. Acta Armamentarii, 2014, 35(8): 1179-1186.

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