Abstract
Diagnosing faults in electric vehicles (EVs) is a great challenge. The purpose of this paper is to demonstrate the detection of faults in an electromechanical conversion chain for conventional or autonomous EVs. The information and data coming from different sensors make it possible for EVs to recover a series of information including currents, voltages, speeds, and so on. This information is processed to detect any faults in the electromechanical conversion chain. The novelty of this study is to develop an architecture for a fault diagnosis model by means of the feature extraction technique. In this regard, the long short-term memory (LSTM) approach for the fault diagnosis is proposed. This approach has been tested for an EV prototype in practice, is superior in accuracy over other fault diagnosis techniques, and is based on machine learning. An EV in an urban context is modeled, and then the fault diagnosis approach is applied based on deep learning architectures. The EV and the fault diagnosis model is simulated in Matlab software. It is also revealed how deep learning contributes to the fault diagnosis of EVs. The simulation and practical results confirm that higher accuracy in the fault diagnosis is obtained by applying the LSTM.
Highlights
Control of smart cities is becoming more difficult due to widespread use of electric vehicles (EVs) along with development of electricity generation
A fault diagnosis (FD) approach is necessary to be applied. Several techniques such as multiple sensors, the probability approach, algorithmic approach, artificial intelligence (AI), and machine deep learning [3,10,11,12] have been proposed for the FD
The deep learning method successfully extracted the features from the sensor data collected from the EV in practice and simulation
Summary
Control of smart cities is becoming more difficult due to widespread use of electric vehicles (EVs) along with development of electricity generation. EVs have several electrical parts and energy conversion chains. To maximize their lifetimes, a fault diagnosis (FD) approach is necessary to be applied. Several techniques such as multiple sensors, the probability approach, algorithmic approach, artificial intelligence (AI), and machine deep learning [3,10,11,12] have been proposed for the FD. These techniques can be even used simultaneously. An FD approach has evolved rapidly to become a viable alternative to traditional health care solutions [1,2,3,4,5]
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