Decoupling Control of an Aviation Remote Sensing Stabilization Platform Based on a Cerebellar Model Articulation Controller

Decoupling Control of an Aviation Remote Sensing Stabilization Platform Based on a Cerebellar Model Articulation Controller

To obtain high-resolution and high-precision images, the aviation remote sensing stabilization platform (ARSSP) is used, which enables the isolation of unpredictable aerial camera movements during aerial photography. However, because of the interaxle coupling interference and other nonlinear interfe...

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Bibliographic Details
Published in:Machines (Basel) Vol. 11; no. 1; p. 5
Main Authors: Ran, Tonghuan, Shi, Guangfeng, Lin, Jieqiong, Meng, Linghe
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-01-2023
Subjects:
Aerial photography
ARSSP
Aviation
Cameras
Cerebellar model articulation controller
Control algorithms
Controllers
Coupling
credit allocation
Decoupling
Dynamic models
Image resolution
Interference
Mathematical models
Neural networks
nonlinear cross-feedback decoupling
optimization smoothness
Parameter identification
Proportional integral derivative
Remote control
Remote sensing
Remote sensing systems
sliding-mode CMAC
Stabilization
Velocity
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Description
Summary:To obtain high-resolution and high-precision images, the aviation remote sensing stabilization platform (ARSSP) is used, which enables the isolation of unpredictable aerial camera movements during aerial photography. However, because of the interaxle coupling interference and other nonlinear interferences in the ARSSP system, the imaging quality of the aerial camera is adversely affected. Therefore, we derived the dynamic model of moment coupling between shafts to illustrate the problem. On the basis of the former proportion integration differentiation (PID) controller based on cerebellar neural network, a nonlinear cross feedback decoupling scheme is adopted to reduce the adverse effects of these interferences. The cerebellar model articulation controller (CMAC) based on synovial membrane control (SMC) is used to reduce the nonlinear interferences caused by the new cross-decoupling module. To verify the effectiveness of the scheme, simulation, indoor and outdoor experiments were conducted. The results showed that the SMC-CMAC significantly reduced the interaxle coupling effect and effectively suppressed the nonlinear interference, resulting in a good tracking performance of the ARSSP system.
ISSN:2075-1702
2075-1702
DOI:10.3390/machines11010005