Abstract
Timely detection and isolation of the failures in attitude sensor is a critical task to ensure the normal operation of the satellite. This article proposes a fault detection and isolation scheme for the four-axis fiber-optic gyroscopes using a hybrid method. Based on the attitude kinematics and gyro model, a sensor fault detector is developed using an adaptive Kalman filter. The process noise covariance can be autonomously tuned by the proposed adaptive mechanism, which makes the filter more robust to the uncertain covariance parameters. The constant drift estimations obtained by the adaptive Kalman filter are applied to detect sensor faults. At the same time, the value of parity equation is computed in real-time using the signals of the four-axis gyroscopes. Then fault diagnosis rules are presented to isolate the faulty sensor. Using the proposed hybrid fault detection and isolation method, fault in gyroscopes can be detected and isolated reliably, and the fault in angle sensor can be detected as well. Thus the results of fault detection and isolation provide the criterions for fiber-optic gyroscopes reconstruction. Finally, the effectiveness of the developed scheme is demonstrated by numerical simulations of four-axis gyroscopes and star sensor with some typical faults.
Highlights
The gyroscope is designed for rotation rate sensing
This paper proposes a health monitoring scheme for the space-borne minimal redundancy configuration fiber-optic gyroscopes
The fault detector is established based on attitude kinematics and adaptive Kalman filter, which is more robust to the model uncertainties when being used for practical applications
Summary
The gyroscope is designed for rotation rate sensing. With the characters of small size, low cost, wide range of precision and no moving parts, the interferometric fiber-optic gyroscope (FOG) is still the best choice for space applications at this stage [1]–[4]. Due to the longterm operation in harsh environments, gyroscope in satellite inevitably suffers from various types of failures. These failures may lead to the performance degradation of the attitude determination system or even cause a catastrophe to the satellite. Hardware redundancy usually makes the system complicated This technique is constrained by the cost, space, power consumption and other factors. Different from the hardware redundancy, analytic redundancy uses the mathematical model of the system for fault diagnosis. Due to no requirements for extra hardware, analytic redundancy scheme has been widely applied for the sensor fault detection and isolation in various dynamic systems [7]-[11]
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