Parameter Uncertainty Analysis in Precise Pointing Control of Flexible Spacecraft
János Bezsilla (Computer and Automation Research Institute Hungarian Academy of Sciences, Student TU Delft)
Bela Takarics (Computer and Automation Research Institute Hungarian Academy of Sciences)
Bálint Vanek (Computer and Automation Research Institute Hungarian Academy of Sciences)
J Guo (TU Delft - Space Systems Egineering)
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Abstract
This article focuses on the validation of a classical PID controller scheme for flexible spacecraft with regards to the effect of parameter uncertainty on system stability and pointing precision. A high-fidelity simulation environment with external disturbances was built in Simulink using a control-oriented model of an Earth-observing satellite with a flexible appendage and on-board microvibration sources in orbit around the planet. Then, a PID control loop was designed with sensor dynamics, time delay behaviour, and a smooth trajectory generator. After declaring the natural frequencies, damping ratio, and rotation angle of the appendage, as well as the propellant tank mass to be uncertain, two worst-case scenarios were identified. Comparing the response of worst-case systems with nominal settings, only a minor drop has been found in the phase margins, with little to no difference in the pointing errors (smaller than ±2 arcsec for both roll and pitch).
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