Optimal guidance law based on inverse optimal problem and performance analysis

Hui Wang; Jiang Wang; Tao Guo; Guang Shuai Wang

doi:10.7673/j.issn.1006-2793.2014.05.001

Optimal guidance law based on inverse optimal problem and performance analysis

Hui Wang, Jiang Wang^*, Tao Guo, Guang Shuai Wang

^*Corresponding author for this work

School of Aerospace Engineering

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

Based on the typical energy optimal guidance laws (TEOGL), the two characteristic roots (CR) of the TEOGL were extended from a limited points/lines area to all the possible positive-real-roots area and the inverse optimal guidance problem was proposed. The construction procedure of the weighting matrices in the performance index of the inverse optimal problem was discussed and the calculation equations of those weighting matrices and Riccati matrix were also present. As an example, the calculation procedure was demonstrated when the control weighting matrix was chosen as -n power of time-to-go. It is concluded that, for the eight pairs of different CR, although every possible pair of CR may have an optimal explanation, it can't guarantee a similar guidance performance with the TEOGL, except a pair of CR which is chosen to be close to the CR of the TEOGL.

Original language	English
Pages (from-to)	587-593
Number of pages	7
Journal	Guti Huojian Jishu/Journal of Solid Rocket Technology
Volume	37
Issue number	5
DOIs	https://doi.org/10.7673/j.issn.1006-2793.2014.05.001
Publication status	Published - 1 Oct 2014

Keywords

Characteristic root
Energy optimal guidance law
Guidance performance
Inverse optimal problem
Weighting matrix

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Cite this

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title = "Optimal guidance law based on inverse optimal problem and performance analysis",

abstract = "Based on the typical energy optimal guidance laws (TEOGL), the two characteristic roots (CR) of the TEOGL were extended from a limited points/lines area to all the possible positive-real-roots area and the inverse optimal guidance problem was proposed. The construction procedure of the weighting matrices in the performance index of the inverse optimal problem was discussed and the calculation equations of those weighting matrices and Riccati matrix were also present. As an example, the calculation procedure was demonstrated when the control weighting matrix was chosen as -n power of time-to-go. It is concluded that, for the eight pairs of different CR, although every possible pair of CR may have an optimal explanation, it can't guarantee a similar guidance performance with the TEOGL, except a pair of CR which is chosen to be close to the CR of the TEOGL.",

keywords = "Characteristic root, Energy optimal guidance law, Guidance performance, Inverse optimal problem, Weighting matrix",

author = "Hui Wang and Jiang Wang and Tao Guo and Wang, {Guang Shuai}",

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TY - JOUR

T1 - Optimal guidance law based on inverse optimal problem and performance analysis

AU - Wang, Hui

AU - Wang, Jiang

AU - Guo, Tao

AU - Wang, Guang Shuai

PY - 2014/10/1

Y1 - 2014/10/1

N2 - Based on the typical energy optimal guidance laws (TEOGL), the two characteristic roots (CR) of the TEOGL were extended from a limited points/lines area to all the possible positive-real-roots area and the inverse optimal guidance problem was proposed. The construction procedure of the weighting matrices in the performance index of the inverse optimal problem was discussed and the calculation equations of those weighting matrices and Riccati matrix were also present. As an example, the calculation procedure was demonstrated when the control weighting matrix was chosen as -n power of time-to-go. It is concluded that, for the eight pairs of different CR, although every possible pair of CR may have an optimal explanation, it can't guarantee a similar guidance performance with the TEOGL, except a pair of CR which is chosen to be close to the CR of the TEOGL.

AB - Based on the typical energy optimal guidance laws (TEOGL), the two characteristic roots (CR) of the TEOGL were extended from a limited points/lines area to all the possible positive-real-roots area and the inverse optimal guidance problem was proposed. The construction procedure of the weighting matrices in the performance index of the inverse optimal problem was discussed and the calculation equations of those weighting matrices and Riccati matrix were also present. As an example, the calculation procedure was demonstrated when the control weighting matrix was chosen as -n power of time-to-go. It is concluded that, for the eight pairs of different CR, although every possible pair of CR may have an optimal explanation, it can't guarantee a similar guidance performance with the TEOGL, except a pair of CR which is chosen to be close to the CR of the TEOGL.

KW - Characteristic root

KW - Energy optimal guidance law

KW - Guidance performance

KW - Inverse optimal problem

KW - Weighting matrix

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Optimal guidance law based on inverse optimal problem and performance analysis

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