Model-Rebuilt Disturbance Observer of a Tracking System Based on Acceleration Fusion for Laser Power Transmission

Abstract

When using laser energy to power long-distance and fast-moving targets, it requires a fast-response and high-precision acquisition, pointing and tracking (APT) system. A fast-steering mirror (FSM) system was used in this paper to track the solar cell array as laser power receiver. The disturbance suppression performance is a key indicator for the FSM stabilization. Generally, a fiber-optic gyroscope (FOG) is employed in the high-sampling-rate velocity loop to enhance the anti-interference ability. However, with the expansion of miniaturized applications, a relatively large, heavy, and high-power FOG is hard to be installed on the small mirror. With this case, this paper used a small-size and high-bandwidth MEMS linear accelerometer in the acceleration loop, substituting the gyroscope. However, the drift and high-frequency noise of the MEMS accelerometer in low frequency will cause APT disturbance. Therefore, an acceleration fusion method with a modified complementary filter was proposed to blend signals of the charge-coupled device and the accelerometers. The fused virtual acceleration can eliminate drift and reduce noise in low frequency and was eventually used in the model-rebuilt disturbance observer loop. At last, the measured results show that the disturbance suppression performance is improved using the presented method, and low-price and small-size MEMS accelerometer can be applied in the APT system.