Time-to-go weighted optimal guidance with impact angle constraints

Chang Kyung Ryoo; Hangju Cho; Min Jea Tahk

doi:10.1109/TCST.2006.872525

Time-to-go weighted optimal guidance with impact angle constraints

Chang Kyung Ryoo, Hangju Cho, Min Jea Tahk

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

451 Scopus citations

Abstract

In this paper, the optimal guidance law with terminal constraints of miss distance and impact angle is presented for a constant speed missile against the stationary target. The proposed guidance law is obtained as the solution of a linear quadratic optimal control problem with the energy cost weighted by a power of the time-to-go. Systematic selection of guidance gains and trajectory shaping are possible by adjusting the exponent of the weighting function. A new time-to-go calculation method taking account of the trajectory curve is also proposed for implementation of the proposed law. Nonlinear and adjoint simulations are performed to investigate the performance of the proposed guidance law and time-to-go calculation method.

Original language	English
Pages (from-to)	483-492
Number of pages	10
Journal	IEEE Transactions on Control Systems Technology
Volume	14
Issue number	3
DOIs	https://doi.org/10.1109/TCST.2006.872525
State	Published - May 2006
Externally published	Yes

Keywords

Impact angle control
Optimal guidance
Time-to-go calculation

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10.1109/TCST.2006.872525

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abstract = "In this paper, the optimal guidance law with terminal constraints of miss distance and impact angle is presented for a constant speed missile against the stationary target. The proposed guidance law is obtained as the solution of a linear quadratic optimal control problem with the energy cost weighted by a power of the time-to-go. Systematic selection of guidance gains and trajectory shaping are possible by adjusting the exponent of the weighting function. A new time-to-go calculation method taking account of the trajectory curve is also proposed for implementation of the proposed law. Nonlinear and adjoint simulations are performed to investigate the performance of the proposed guidance law and time-to-go calculation method.",

keywords = "Impact angle control, Optimal guidance, Time-to-go calculation",

author = "Ryoo, {Chang Kyung} and Hangju Cho and Tahk, {Min Jea}",

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AU - Ryoo, Chang Kyung

AU - Cho, Hangju

AU - Tahk, Min Jea

PY - 2006/5

Y1 - 2006/5

N2 - In this paper, the optimal guidance law with terminal constraints of miss distance and impact angle is presented for a constant speed missile against the stationary target. The proposed guidance law is obtained as the solution of a linear quadratic optimal control problem with the energy cost weighted by a power of the time-to-go. Systematic selection of guidance gains and trajectory shaping are possible by adjusting the exponent of the weighting function. A new time-to-go calculation method taking account of the trajectory curve is also proposed for implementation of the proposed law. Nonlinear and adjoint simulations are performed to investigate the performance of the proposed guidance law and time-to-go calculation method.

AB - In this paper, the optimal guidance law with terminal constraints of miss distance and impact angle is presented for a constant speed missile against the stationary target. The proposed guidance law is obtained as the solution of a linear quadratic optimal control problem with the energy cost weighted by a power of the time-to-go. Systematic selection of guidance gains and trajectory shaping are possible by adjusting the exponent of the weighting function. A new time-to-go calculation method taking account of the trajectory curve is also proposed for implementation of the proposed law. Nonlinear and adjoint simulations are performed to investigate the performance of the proposed guidance law and time-to-go calculation method.

KW - Impact angle control

KW - Optimal guidance

KW - Time-to-go calculation

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SP - 483

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JO - IEEE Transactions on Control Systems Technology

JF - IEEE Transactions on Control Systems Technology

IS - 3

ER -

Time-to-go weighted optimal guidance with impact angle constraints

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Keywords

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