Abstract
Fatigue is an important factor affecting modern flight safety. It can easily lead to a decline in pilots’ operational ability, misjudgments, and flight illusions. Moreover, it can even trigger serious flight accidents. In this paper, a wearable wireless physiological device was used to obtain pilots’ electrocardiogram (ECG) data in a simulated flight experiment, and 1440 effective samples were determined. The Friedman test was adopted to select the characteristic indexes that reflect the fatigue state of the pilot from the time domain, frequency domain, and non-linear characteristics of the effective samples. Furthermore, the variation rules of the characteristic indexes were analyzed. Principal component analysis (PCA) was utilized to extract the features of the selected feature indexes, and the feature parameter set representing the fatigue state of the pilot was established. For the study on pilots’ fatigue state identification, the feature parameter set was used as the input of the learning vector quantization (LVQ) algorithm to train the pilots’ fatigue state identification model. Results show that the recognition accuracy of the LVQ model reached 81.94%, which is 12.84% and 9.02% higher than that of traditional back propagation neural network (BPNN) and support vector machine (SVM) model, respectively. The identification model based on the LVQ established in this paper is suitable for identifying pilots’ fatigue states. This is of great practical significance to reduce flight accidents caused by pilot fatigue, thus providing a theoretical foundation for pilot fatigue risk management and the development of intelligent aircraft autopilot systems.
Highlights
IntroductionThe proportion of flight accidents caused by human factors in the overall number of accidents has not decreased [1,2,3]; these are especially caused by pilot fatigue [4,5]
The support vector machine (SVM) based on the radial basis function was used as a classifier to identify the drivers’ mental activity state [29]. These results show that the time domain, frequency domain, and non-linear indexes extracted from the ECG signals could quantitatively measure the fatigue state of pilots, and the fatigue state could be identified based on the classification model
In order to reduce the correlation between feature indexes and improve the speed and accuracy of training, Principal component analysis (PCA) was utilized to extract features from the selected feature indexes
Summary
The proportion of flight accidents caused by human factors in the overall number of accidents has not decreased [1,2,3]; these are especially caused by pilot fatigue [4,5]. The noise and vibration of the cabin, air pressure changes, long-haul flights, high-load work, circadian rhythm disturbance, and lack of sleep lead pilots to often be in a state of fatigue [6]. How to identify the real-time fatigue state of pilots quickly and accurately has become a core scientific problem that needs to be solved urgently in the field of aviation safety. The identification of pilot fatigue is of great theoretical and practical significance for achieving pilot fatigue risk control, health management, and real-time safety warning for autopilot systems
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