Sensor-Based Prognostic Health Management of Advanced Driver Assistance System for Autonomous Vehicles: A Recent Survey
Abstract
:1. Introduction
2. Overview of PHM, ADAS in AVs, and Sensor Faults
2.1. Overview of PHM Technology
2.2. Autonomous Vehicle and Advanced Driver Assistance System
2.3. Sensor Malfunctioning in AVs
2.4. Sensors Uncertainty and PHM
3. Sensor-Based PHM for ADAS System
3.1. PHM of Vision Sensors
S. No | Camera Faults | Detailed Description of Camera Malfunctioning |
---|---|---|
1 | Lens occlusion or soiling | Covering of the lens by solid or fluid |
2 | Weather condition | Rain/snow |
Icing of camera | ||
Fogging of camera | ||
3 | Environmental condition | Time (dawn or dust) |
Crossing by tunnel or over a bridge | ||
Inner-city roads or motorways | ||
4 | Optical faults | Lens occupied by dust |
Lens loss | ||
Interior fogging | ||
Damage or stone impact of the lens | ||
5 | Sensor faults | Smear |
Image element defect (black or white marks) | ||
Thermal disturbance | ||
6 | Visibility distance | Range of distance to detect a clear image |
3.2. PHM of Light Detection and Ranging (LiDAR) Sensor
3.3. Radio Detection and Ranging (RADAR)
3.4. Ultrasonic Sensors
3.5. Positioning Sensors
3.6. Discussion
4. Challenges and Future Perspectives AVs and Its PHM
5. Conclusions
- For the LiDAR system, the sensor-based faults are malfunction of mirror motor, damage to optical filter, misalignment of the optical receiver, security breach, adverse climatic circumstances, intermodulation distortion, and short-circuit and overvoltage of electrical components. Some representative PHM efforts for LiDAR are correlation with sensor framework, output of the monitoring sensor, correlation to passive ground truth, correlation to active ground truth, correlation to another similar sensor, and correlation to a different sensor.
- RADAR is more economical than LiDAR and cameras, and it works on the principle of the Doppler effect. The primary failure modes of RADAR are fault in the range rate signal and sensor fault. Some preventive and corrective measures for RADAR are calibration in relevant service stations, sliding mode observer, sensor fault detection, cyberattack detection observer, and the LSTM-based deep learning approach.
- The ultrasonic sensors used to determine an object in the domain of the sensors are susceptible to acoustic/electronic noise, performance degradation under bright ambient light, vehicle corner error, and cross echoes, among others. Common approaches for detecting faults and corrective measures in ultrasonic sensors are artificial neural networks, parallel parking assist systems, combined ultrasonic sensors and three-dimensional vision sensors, and grid maps.
- The positioning sensors and systems employed to locate the position of AVs are prone to jumps in GPS observation, satellite and received signal faults, and sensor data with/without curbs on the roadsides. The techniques employed for the fault detection and isolation of positioning sensors and systems are the Kalman filter, Markov blanket (MB) algorithm, and sensor redundancy fault detection model.
Author Contributions
Funding
Conflicts of Interest
References
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Fault Type | Technique | Advantages |
---|---|---|
Noise in sensor data due to weather or geographical changes [21] | Unscented Kalman filter | Decreasing computational cost |
Displacements in sensor data [55] | Support vector machine (SVM) algorithm | Reducing uncertainties using sensor fusion |
Sensor data due to various environmental conditions (rain, fog, lighting) [58] | Deep neural network (DNN) driven | Reducing software complexities using DNN-based model |
Camera-based fog detection [57] | Power spectrum slope | Self-diagnosis mechanism to warn the system against critical conditions |
Possible defects (blooming, smear, picture element defects, thermal noise) [22] | Edge analysis of consecutive frames | Proposed techniques work under diverse weather conditions |
Misalignment [14] | Bayesian belief network approach | The presented model shows good performance and overall navigation can predict accurately |
Subsystem of LiDAR | Fault Conditions | Hazards |
---|---|---|
Position encoder | Failure to read position data | Malfunction of mirror motor |
Electrical | Short-circuit and overvoltage | Electrical component failure |
Optical receiver | Misalignment | Error in the optical receiver |
Optical filter | Damage | Error in the optical receiver |
Mirror motor | Malfunction | LiDAR failure |
PHM Category | Description/References |
---|---|
Fault category | Subcomponent failure [63,64] |
Mechanical fault of the sensor protector [65] | |
Coating on the sensor protector [65,66] | |
Escalating problem [67,68] | |
Security breach [69,70,71] | |
Adverse climatic circumstance [65,71] | |
Intermodulation distortion [72,73] | |
FDI category | Correlation with sensor framework [43] |
Output of the monitoring sensor [63] | |
Correlation to passive ground truth [43] | |
Correlation to active ground truth [43] | |
Correlation to another similar sensor [43] | |
Correlation to another and different sensor [43] | |
Matching of various interfaces [43] | |
Recovery category | Software adjustment [74] |
Hardware adjustment [67] | |
Temperature adjustment [75] | |
Mopping of sensor shield [75] |
Fault Type | Technique |
---|---|
Noise in data due to weather condition [21] | Unscented Kalman filter |
Displacements in sensor data [55] | Support vector machine (SVM) algorithm |
Various faults (failure to read data, short-circuit, overvoltage, or misalignment) [14] | Bayesian belief network approach |
Sensor data due to various environmental conditions (rain, fog, or lighting) [58] | Deep neural network driven |
Fault/Problem | Technique | Consequence |
---|---|---|
Probabilistic fault for an acceleration sensor and RADAR [90] | A longitudinal kinematic model-based probabilistic fault detection and diagnostic algorithm | Unsafe longitudinal control of the AV |
Fault in the range rate signal (mobility of vehicle) [87] | Redundant sensor combined with a specially designed nonlinear filter | Continuously monitors the RADAR sensor, and detects a failure when it happens |
Acceleration sensor fault diagnosis [25] | Using a sliding mode observer, a probabilistic fault diagnosis algorithm is developed | Inaccurate relative displacement and velocity measurement |
Fault in the sensor used for longitudinal control [91] | Multi-sliding mode observer-based predictive fault detection algorithm | Faulty measurements from the environment sensors |
Fault in the sensor used for longitudinal control [24] | Multi-sliding mode observer | Acceleration of the ego vehicles and inaccurate data from the forward objects |
Continuous diagnostics of external factors, such as water layer or dirt on the bumper [16] | Statistical model for RADAR cross-section (RCS) of repetitive targets | Can significantly affect RADAR performance |
A cyberattack on a transmission medium and RADAR health monitoring for a connected vehicle both happening at the same time [15] | Observer-based controller in connected ACC Vehicles | Detect a cyber-attack or a fault in the velocity measurement RADAR channel |
Both RADAR sensor failure and cyber-attack linked to the presence of two unknown inputs [88] | Sensor fault detection and cyber-attack detection observer | Unsmooth operation of ACC vehicles |
Signal processing of RADAR [23] | Multi-input multi-output and cognitive RADAR | Inaccurate detection of still or moving objects, and measurement of their motion parameters |
RADAR fault signal reconstruction [92] | A failsafe architecture that focuses on fault reconstruction, detection, and tolerance control | Insecure functional safety of autonomous vehicle |
Fault/Problem | Techniques | Consequence |
---|---|---|
Acoustic and electronic noise [19] | Levenberg–Marquardt backpropagation artificial neural network (LMBP-ANN) architecture using mean squared error (MSE) and R-values | Major effect on ultrasonic sensor operation and distance measurements |
Vehicle corner error [104] | Parallel parking assist system (PPAS) | The corners of the vehicle are not regular right angles; hence, the ultrasonic sensor has a large error at the corner of the vehicle during the measurement process |
Vehicle corner error [16] | Combined ultrasonic sensors and three-dimensional vision sensors to detect parking spaces | This method uses a vision sensor to make up for the inaccurate measurement of the ultrasonic at the corner of the vehicle. |
Performance degradation under bright ambient light [105] | Processing the data acquired by the three-dimensional time-of-flight (ToF) camera and reconstructing objects around the vehicle | Results in shadows and brightness in the image, which limits the detection of low-reflective objects, such as dark cars |
Cross echoes (direction of sensor) [106] | Error detection model | Unreliable and non-robust sensor assessment |
False echoes caused by turbulence [18] | Signal processing, such as filtering or Hilbert transform | Prevent vehicle collision with pedestrians and other obstacles |
Fault, such as cross-eyed, dreaming, and blind sensor errors [107] | Fault detection based on Grid Map | Sensor calibration error |
Simulated fault in the ultrasonic sensor [108] | Fault detection by statistical estimations | Inaccurate ultrasonic sensor-based parking operation |
Obstacle avoidance [109] | Artificial neural network with supervised learning | Unsuitable classification and pattern recognition of data collected by an ultrasonic sensor |
Obstacle detection and avoidance [110] | Policy-free, model-free Q-learning-based RLalgorithm with the multilayer perceptron neural network (MLP−NN) | Optimal vehicle future action based on the current state of the vehicle through better obstacle prediction |
Fault Type/Faulty Data | Technique | Advantages |
---|---|---|
Jumps in GPS observation and noise due to drift in state evaluation [122] | Kalman filter | Minimize chances of undetected faults |
Disturbance in data due to various traffic (hazardous, risky, and safe events) [123] | Markov blanket (MB) algorithm | Evaluation of the proposed approach in real application of hazardous environmental situation |
Injected error in the GPS sensor via log file [124] | Pseudo-code on inference algorithm | Robust model for timely fault detection and autonomous fault recovery system for sensors |
Satellite and received signal faults [125] | Simultaneous localization and mapping (Graph-SLAM) framework | Applicability in AVs for urban areas |
Sensor data with and without curbs on the roadsides [126] | Unscented Kalman filter (UKF) | Apply to urban areas by improving performance of previous methods for UKF |
Sensor fault (current and voltage), environment (such as skidding, heating up, missing the trace) [127] | Sensor redundancy fault detection model | Evaluating the system in the real environment with experimental testing |
Type of Car | Reason/Consequence | Remarks |
---|---|---|
Hyundai autonomous car [134] | Raining/crashed during testing | The sensors failed to detect street signs, lane markings, and even pedestrian crossings due to the angle of the car switching in the rain, and the orientation of the sun. |
Tesla autonomous car [135] | Image contrast/the driver was killed | Failure of camera and confusion of white truck with clear sky. |
Google autonomous car [136] | Speed estimation failure/collision with bus while lane changing | The car assumed that the bus would stop while merging with the traffic. |
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Raouf, I.; Khan, A.; Khalid, S.; Sohail, M.; Azad, M.M.; Kim, H.S. Sensor-Based Prognostic Health Management of Advanced Driver Assistance System for Autonomous Vehicles: A Recent Survey. Mathematics 2022, 10, 3233. https://doi.org/10.3390/math10183233
Raouf I, Khan A, Khalid S, Sohail M, Azad MM, Kim HS. Sensor-Based Prognostic Health Management of Advanced Driver Assistance System for Autonomous Vehicles: A Recent Survey. Mathematics. 2022; 10(18):3233. https://doi.org/10.3390/math10183233
Chicago/Turabian StyleRaouf, Izaz, Asif Khan, Salman Khalid, Muhammad Sohail, Muhammad Muzammil Azad, and Heung Soo Kim. 2022. "Sensor-Based Prognostic Health Management of Advanced Driver Assistance System for Autonomous Vehicles: A Recent Survey" Mathematics 10, no. 18: 3233. https://doi.org/10.3390/math10183233
APA StyleRaouf, I., Khan, A., Khalid, S., Sohail, M., Azad, M. M., & Kim, H. S. (2022). Sensor-Based Prognostic Health Management of Advanced Driver Assistance System for Autonomous Vehicles: A Recent Survey. Mathematics, 10(18), 3233. https://doi.org/10.3390/math10183233