Abstract
The trajectory optimization technology is one of the key technologies for hypersonic air-vehicle. There are multiple constraints in the process of hypersonic flight, such as uncertainty of flight environment, thermal current, dynamic pressure and overload. The trajectory optimization of hypersonic air-vehicle is facing with a great challenge. This article studies the direct shooting method, the Gauss pseudo spectral method and sequential gradient-restoration algorithm, among which the direct shooting method simply makes the control variables discrete in the time domain, and obtains the status value by explicit numerical integration; Gauss pseu- do spectral method makes the status variable and control variable discrete in a series of Gauss points, and con- structs multinomial to approximate to the status and control variable by taking the discrete points as the nodes; sequential gradient-restoration algorithm uses iteration to meet the constraints and minimize the increment of initial value of control and status variable in order to constantly approximate to the optimal solution on condition that the constraints meet first order approximation. Finally this article conducts a numerical simulation by taking the diving segment of hypersonic air-vehicle as an example for comparative analysis on those three algorithms respectively from, such as, the initial value selection, constraint handling, convergence speed and calculation accuracy. The simulation result indicates Gauss pseudo spectral method is a method with fairly good comprehen- sive performance.
Highlights
With the development of propulsion, material and control technology, the hypersonic air-vehicle, as an advanced aerial air-vehicle, has been becoming the wide focus of various global military powers [1]
The hypersonic flight trajectory is very sensitive to the change of parameters, which largely tests the trajectory optimization technology of hypersonic air-vehicle [2]
In terms of the given optimization model of trajectory with multiple constraints in the diving segment of hypersonic air-vehicle, we use the direct shooting method, Gauss pseudo spectral method and sequential gradient-restoration algorithm respectively to solve the minimum time problem, where the parameters planning problem obtained by conversion from direct shooting method and Gauss pseudo spectral method is solved by secondary planning of sequence
Summary
With the development of propulsion, material and control technology, the hypersonic air-vehicle, as an advanced aerial air-vehicle, has been becoming the wide focus of various global military powers [1]. Hao Zhou uses maximum value problem to obtain the first order necessary condition for optimal trajectory and applies genetic algorithm to. Flaws and adaptation of different optimization algorithm, this article uses respectively direct shooting method, Gauss pseudo spectral method in the direct method and sequential gradient-restoration algorithm in the indirect method to conduct an optimization analysis on minimum time problem in the diving segment of hypersonic air-vehicle, and comprehensively considers multiple constraints such as dynamic pressure, overload, angle of attack and route angle of terminal flight. In this equation set(2), there are equation of system status, equation constraint, inequality constraint, initial condition of status variable and terminal condition of status variable and parameter
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