Robust fault detection and diagnosis of primary air data sensors in the presence of atmospheric turbulence

S. Prabhu, G. Anitha
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Abstract

This paper presents a fault detection and diagnosis (FDD) algorithm for various faults in the primary air data sensors (PADS) of an aircraft in the presence of external disturbances such as atmospheric turbulence. Rapid wind variations due to turbulence induce excessive error in the externally fitted air data probe measurements, which may lead to loss of control and misinterpretations by the flight crew. In adverse environmental conditions, the FDD of air data prefers robust and adaptive air data estimates that use an analytical redundancy approach with fewer computations. The proposed method considers the kinematics of the aircraft instead of the dynamics used in the state-of-the-art algorithms. The advantage of using kinematics is that it can reduce modeling errors significantly, avoiding high false alarm rates in the FDD process. For the estimation of stable and accurate air data under external disturbance, the inertial navigation system and global positioning system (INS/GPS) output are considered instead of actual air data probe or sensor measurements. The proposed algorithm uses estimates of air data using an exponentially weighted adaptive extended Kalman filter (EW-AEKF) to detect and diagnose PADS faults, which can perform well even in the presence of uncertain noise due to atmospheric turbulence experienced during flight. The simulation was carried out to validate the algorithm with flight data obtained from the X-Plane flight simulator under moderate atmospheric turbulence. The simulation experiments were carried out using the MATLAB programming platform. The results show that the proposed method achieves satisfactory FDD performance with lower root mean square error (RMSE) and computation time than traditional EKF-based algorithms.
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大气湍流条件下初级空气数据传感器的鲁棒故障检测与诊断
本文提出了在大气湍流等外界干扰下飞机初级空气数据传感器(PADS)各种故障的故障检测与诊断算法。由于湍流引起的快速风向变化导致外部安装的空气数据探头测量误差过大,这可能导致飞行机组失去控制和误解。在不利的环境条件下,空气数据的FDD更倾向于稳健和自适应的空气数据估计,使用分析冗余方法,计算量更少。所提出的方法考虑了飞机的运动学,而不是最先进的算法中使用的动力学。使用运动学的优点是它可以显著减少建模误差,避免FDD过程中的高虚警率。为了在外界干扰下估计稳定和准确的空气数据,考虑了惯性导航系统和全球定位系统(INS/GPS)的输出,而不是实际的空气数据探头或传感器测量。该算法利用指数加权自适应扩展卡尔曼滤波器(EW-AEKF)对空气数据的估计来检测和诊断PADS故障,即使在飞行过程中遇到大气湍流造成的不确定噪声存在的情况下,该算法也能很好地工作。利用X-Plane飞行模拟器在中等大气湍流条件下的飞行数据进行了仿真验证。利用MATLAB编程平台进行仿真实验。结果表明,与传统的基于ekf的算法相比,该方法具有较低的均方根误差(RMSE)和较短的计算时间,具有较好的FDD性能。
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