Intelligent Fault Diagnosis Method for Blade Damage of Quad-Rotor UAV Based on Stacked Pruning Sparse Denoising Autoencoder and Convolutional Neural Network

Yang, Pu; Wen, ChenWan; Geng, Huilin; Liu, Peng

doi:10.3390/machines9120360

Cited by 19 publications

(8 citation statements)

References 40 publications

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“…parameters, LC. parameter) (12) Save the best model on D val (13) End for (14) Testing: (15) Input: D test (16) and 13 th , i.e., normal and d 1 � 0.3 (30% efciency of the right-wing control surface), and nine states (normal, d 1 � 0.3, and d 2 � 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9) were simulated on 21 st and 23 rd .…”

Section: Data Processingmentioning

confidence: 99%

“…Deep learning, with strong nonlinear feature extraction ability, has yielded excellent results in many felds including fault diagnosis [11] and is increasingly considered for UAV faults. To give full play to the advantages of deep learning, many researchers try to collect available data through various methods, such as artifcially destroying the blades of drones and collecting data in a safe area [12][13][14], obtaining fault data through simulation [15][16][17], and injecting faults into fying drones through software [18,19]. Nevertheless, due to the multiple limitations of the UAVs themselves and the diversity and complexity of their mission environment, it still faces problems such as scarcity of fault samples, sample imbalance, and difculty in obtaining samples from complex environments.…”

Section: Introductionmentioning

confidence: 99%

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An Intelligent Fault Detection Framework for FW-UAV Based on Hybrid Deep Domain Adaptation Networks and the Hampel Filter

Zhang

et al. 2023

International Journal of Intelligent Systems

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Fixed-wing unmanned aerial vehicles (FW-UAVs) play an essential role in many fields, but the faults of FW-UAV components lead to severe accidents frequently; so, there is a need to continuously explore more intelligent fault detection methods to improve the safety and reliability of FW-UAVs. Deep learning provides advanced solution ideas for future UAV fault detection, but the current lack of UAV monitoring data limits the advantages of deep learning in UAV fault detection, which are both a challenge and an opportunity. In this paper, we mainly consider the data availability of deep learning under various practical flight conditions of FW-UAVs and propose a fault detection framework based on hybrid deep domain adaptation BiLSTM networks and the Hampel filter (HDBNH), the main purpose of which is to learn the knowledge of acquired data for detecting FW-UAV faults in other unknown operating conditions. HDBNH consists of three modules: feature extractor, domain adaptor, and fault detector. The feature extractor is two BiLSTM networks constructed to extract the past and future state features from the time-series flight data. The discrepancy of feature distribution between different domains is effectively reduced in the domain adaptor by a hybrid adversarial and the maximum mean discrepancy (MMD) domain adaptation method. The fault detector consists of a fault classification module and a Hampel filter. According to the continuous and dynamic characteristics of FW-UAV state changes, the Hampel filter is used to detect and correct the predicted values of the fault classification module. Meanwhile, a new state sample preparation strategy is proposed to support the work of HDBNH better. Finally, the effectiveness of HDBNH is confirmed by conducting extensive experiments in real FW-UAV flight data.

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Section: Data Processingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

An Intelligent Fault Detection Framework for FW-UAV Based on Hybrid Deep Domain Adaptation Networks and the Hampel Filter

Zhang

et al. 2023

International Journal of Intelligent Systems

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“…As they are data-driven and work in an end-to-end fashion, such approaches do not require the development of system models or the design of fault classifiers based on these models. Much of the previous work in this area [7], [8] has focused on designing powerful DNN models that can learn the complex nonlinear relationship between the input features and use this knowledge to identify propeller faults.…”

Section: Introductionmentioning

confidence: 99%

Simulation-to-reality UAV Fault Diagnosis with Deep Learning

Zhang¹,

Tong²,

Liao³

et al. 2023

Preprint

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Accurate diagnosis of propeller faults is crucial for ensuring the safe and efficient operation of quadrotors. Training a fault classifier using simulated data and deploying it on a real quadrotor is a cost-effective and safe approach. However, the simulation-to-reality gap often leads to poor performance of the classifier when applied in real flight. In this work, we propose a deep learning model that addresses this issue by utilizing newly identified features (NIF) as input and utilizing domain adaptation techniques to reduce the simulation-to-reality gap. In addition, we introduce an adjusted simulation model that generates training data that more accurately reflects the behavior of real quadrotors. The experimental results demonstrate that our proposed approach achieves an accuracy of 96% in detecting propeller faults. To the best of our knowledge, this is the first reliable and efficient method for simulation-to-reality fault diagnosis of quadrotor propellers.

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“…The most common class of actuator fault is a Loss of Effectiveness (LOE), i.e., the produced thrust is lower than the expected one. In fact, LOE may be the consequence of many issues: battery voltage drop [ 15 ], increased drag due to the blade pitch [ 5 ], and of course any physical damage to the blades [ 16 ]. However, as for the specific case of fault diagnosis and tolerant control for VPQs, few works can be found in the literature.…”

Section: Introductionmentioning

confidence: 99%

Fault-Tolerant Control of a Variable-Pitch Quadrotor under Actuator Loss of Effectiveness and Wind Perturbations

Baldini

Felicetti

Freddi

et al. 2023

Sensors

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The actuator fault-tolerant control problem for a variable-pitch quadrotor is addressed under uncertain conditions. Following a model-based approach, the plant nonlinear dynamics are faced with a disturbance observer-based control and a sequential quadratic programming control allocation, where only kinematic data of the onboard inertial measurement unit are required for the fault-tolerant control, i.e., it does not require the measurement of the motor speed nor the current drawn by the actuators. In the case of almost horizontal wind, a single observer handles both faults and the external disturbance. The estimation of the wind is fed forward by the controller, while the actuator fault estimation is exploited in the control allocation layer, which copes with the variable-pitch nonlinear dynamics, thrust saturation, and rate limits. Numerical simulations in the presence of measurement noise show the capability of the scheme to handle multiple actuator faults in a windy environment.

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Intelligent Fault Diagnosis Method for Blade Damage of Quad-Rotor UAV Based on Stacked Pruning Sparse Denoising Autoencoder and Convolutional Neural Network

Cited by 19 publications

References 40 publications

An Intelligent Fault Detection Framework for FW-UAV Based on Hybrid Deep Domain Adaptation Networks and the Hampel Filter

An Intelligent Fault Detection Framework for FW-UAV Based on Hybrid Deep Domain Adaptation Networks and the Hampel Filter

Simulation-to-reality UAV Fault Diagnosis with Deep Learning

Fault-Tolerant Control of a Variable-Pitch Quadrotor under Actuator Loss of Effectiveness and Wind Perturbations

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