A method for identifying the load transfer function of flexible connections based on active frequency sweep excitation

By combining active frequency sweep excitation and high-bandwidth fiber optic gyroscopes, the payload transfer function is identified and control parameters are optimized, solving the problem of control system oscillation caused by blind parameter tuning and realizing high-precision and high-stability control of large high-resolution optical remote sensing satellites.

CN121879136BActive Publication Date: 2026-06-30BEIJING INST OF CONTROL ENG

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
BEIJING INST OF CONTROL ENG
Filing Date
2026-01-13
Publication Date
2026-06-30

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Abstract

This invention relates to a method for identifying the transfer function of a flexible connection load based on active frequency sweep excitation, relating to the field of spacecraft attitude control. The method includes the following steps: several triple-platform actuators sequentially output sinusoidal frequency sweep excitation torques in three rotational directions of the load; a high-bandwidth fiber optic gyroscope simultaneously measures the three-axis angular velocities of the load; the obtained time-domain results are converted to frequency-domain results, followed by load transfer function model identification; based on the identified model, the controller parameters in the triple-platform control unit are adjusted to increase the control bandwidth and enhance secondary control capabilities while ensuring the stability margin of the controller in the triple-platform control unit. This invention has the advantage of maximizing secondary control capabilities, providing a technical foundation for ultra-high precision pointing, ultra-high stability control, and high-quality imaging of future spacecraft optical payloads.
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