Discrete neural altitude control for hypersonic vehicle via flight path angle tracking

Shixing Wang; Bin Xu; Fuchun Sun; Yifu Jiang

Discrete neural altitude control for hypersonic vehicle via flight path angle tracking

Shixing Wang, Bin Xu, Fuchun Sun, Yifu Jiang

Tsinghua University

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

1 Scopus citations

Abstract

In this study, the altitude control is analyzed for the longitudinal dynamics of a generic Hypersonic Flight Vehicle (HFV). By transforming altitude command into the tracking of flight path angle with fast dynamics, the system design is focusing on the control of the attitude subsystem. The virtual control is designed with nominal feedback and Neural Network (NN) approximation via back-stepping. Under the proposed controller, the Semiglobal Uniform Ultimate Boundedness (SGUUB) stability is guaranteed. The slow dynamics are transformed into the parameter estimation problem and the update law is designed. The simulation is presented to show the effectiveness of the proposed control approach.

Original language	English
Pages (from-to)	3930-3936
Number of pages	7
Journal	Research Journal of Applied Sciences, Engineering and Technology
Volume	4
Issue number	20
State	Published - 2012
Externally published	Yes

Keywords

Discrete-time
Hypersonic flight vehicle
Neural network

Cite this

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title = "Discrete neural altitude control for hypersonic vehicle via flight path angle tracking",

abstract = "In this study, the altitude control is analyzed for the longitudinal dynamics of a generic Hypersonic Flight Vehicle (HFV). By transforming altitude command into the tracking of flight path angle with fast dynamics, the system design is focusing on the control of the attitude subsystem. The virtual control is designed with nominal feedback and Neural Network (NN) approximation via back-stepping. Under the proposed controller, the Semiglobal Uniform Ultimate Boundedness (SGUUB) stability is guaranteed. The slow dynamics are transformed into the parameter estimation problem and the update law is designed. The simulation is presented to show the effectiveness of the proposed control approach.",

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AU - Wang, Shixing

AU - Xu, Bin

AU - Sun, Fuchun

AU - Jiang, Yifu

PY - 2012

Y1 - 2012

N2 - In this study, the altitude control is analyzed for the longitudinal dynamics of a generic Hypersonic Flight Vehicle (HFV). By transforming altitude command into the tracking of flight path angle with fast dynamics, the system design is focusing on the control of the attitude subsystem. The virtual control is designed with nominal feedback and Neural Network (NN) approximation via back-stepping. Under the proposed controller, the Semiglobal Uniform Ultimate Boundedness (SGUUB) stability is guaranteed. The slow dynamics are transformed into the parameter estimation problem and the update law is designed. The simulation is presented to show the effectiveness of the proposed control approach.

AB - In this study, the altitude control is analyzed for the longitudinal dynamics of a generic Hypersonic Flight Vehicle (HFV). By transforming altitude command into the tracking of flight path angle with fast dynamics, the system design is focusing on the control of the attitude subsystem. The virtual control is designed with nominal feedback and Neural Network (NN) approximation via back-stepping. Under the proposed controller, the Semiglobal Uniform Ultimate Boundedness (SGUUB) stability is guaranteed. The slow dynamics are transformed into the parameter estimation problem and the update law is designed. The simulation is presented to show the effectiveness of the proposed control approach.

KW - Discrete-time

KW - Hypersonic flight vehicle

KW - Neural network

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JO - Research Journal of Applied Sciences, Engineering and Technology

JF - Research Journal of Applied Sciences, Engineering and Technology

IS - 20

ER -

Discrete neural altitude control for hypersonic vehicle via flight path angle tracking

Abstract

Keywords

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