航空学报 > 1982, Vol. 3 Issue (4): 71-83

具有二阶环节的导弹最优导引律

李忠应   

  1. 北京航空学院
  • 收稿日期:1981-05-01 修回日期:1900-01-01 出版日期:1982-12-25 发布日期:1982-12-25

OPTIMAL GUIDANCE LAWS FOR MISSILES WITH SECOND ORDER CHARACTERISTICS

Li Zhongying   

  1. Beijing Institute of Aeronautics and Astronautics
  • Received:1981-05-01 Revised:1900-01-01 Online:1982-12-25 Published:1982-12-25

摘要: 本文研究了具有二阶环节的导弹其对目标的最优导引律。利用极小值原理分别研究了1)脱靶量为零、最小控制能量指标的最优导引律;2)终态为零控拦截曲面、最小能量指标的最优导引律。最后得出了与具有一阶延迟环导弹所得结果类似,但计算工作量更大,结果应更准确。

Abstract: The problem of optimal intercept guidance laws for missiles have been studied by a lot of authors at home and abroad. But the mathematical models for missiles were assumed too simple, i. e. either as an ideal particle or as a first order delay link.As a primary contribution this paper has made researches on the optimal intercept guidance laws based on a mathematical model with second order charac- teristics. By taking minimum control energy consumption as the performance index, the optimal intercept guidance laws have been derived from the minimum principle in the following two cases of terminal state:1. The terminal miss-distance is zero;2. The intercepting curved surface of out-of-control.The conjugate state equations and the state equations have been solved by use of Laplace Transformation. Through considerably complex computation, the optimal intercept guidance laws have been deduced in the following analytical formsThrough appropriate selection of the terminal time lf or the time of lead T, the results obtained above may be transformed into the optimal guidance laws which are composed of the proportional navigation with varied coefficients and the correctional terms associated with acceleration and angular acceleration of sight-line rotation. These results are similar to those of missiles with first order delay link in form and have no need of any additional parameter. However, the computation is more complex and the results are more accurate.Finally, the optimal intercept guidance laws are studied in the case of the proper frequency of a missile ω approaching to infinity, i. e. in the case of an ideal particle. The results are the same as those obtained by the other authors.