Abstract
Aircraft engine condition monitoring is a key technology for increasing safety and reducing maintenance expenses. Current engine condition monitoring approaches use a minimum of one steady-state snapshot per flight. Whilst being appropriate for trending gradual engine deterioration, snapshots result in a detrimental latency in fault detection. The increased availability of non-mandatory data acquisition hardware in modern airplanes provides so-called full-flight data sampled continuously during flight. These datasets enable the detection of engine faults within one flight by deriving a statistically relevant set of steady-state data points, thus, allowing the application of machine-learning approaches. It is shown that low-pass filtering before steady-state detection significantly increases the success rate in detecting steady-state data points. The application of Principal Component Analysis halves the number of relevant dimensions and provides a coordinate system of principal components retaining most of the variance. Consequently, clusters of data points with and without engine fault can be separated visually and numerically using a One-Class Support Vector Machine. High detection rates are demonstrated for various component faults and even for a minimum instrumentation suite using synthesized datasets derived from full-flight data of commercially operated flights. In addition to the tests conducted with synthesized data, the algorithm is verified based on operational in-flight measurements providing a proof-of-concept. Consequently, the availability of continuously sampled in-flight measurements combined with machine-learning methods allows fault detection within a single flight.
Highlights
About one-third of the direct operating cost of an aircraft engine is related to maintenance, repair, and overhaul [1]
Processing Multi-Variate Datasets: Several gas path measurements are available for fault detection leading to a multi-dimensional dataset to be processed
Efficiency: Analyzing full-flight data requires a considerable amount of data to be processed [42]; fast and efficient approaches are required for analyzing the datasets
Summary
About one-third of the direct operating cost of an aircraft engine is related to maintenance, repair, and overhaul [1]. Only discrete data points gathered during take-off and cruise are provided for condition monitoring. Engine condition monitoring systems are applied to the long-term trending of gradual performance deterioration as well as to the detection, isolation and identification of faults [2]. Gradual performance deterioration results from minuscule changes caused by erosion, corrosion, or fouling [3] and accumulates over a large number of flights. Due to this nature, the availability of one single steady-state snapshot per flight is good enough to determine the associated long-term trends in performance parameters. Faults are discrete events that occur at a defined point in time during a flight and lead to a step-change in performance parameters
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