Misfire Detection in Spark Ignition Engine Using Transfer Learning

Sridharan, Naveen Venkatesh; Chakrapani, G.; Senapti, S Babudeva; Annamalai, K.; Elangovan, M; Indira, V; Sugumaran, V.; Mahamuni, Vetri Selvi

doi:10.1155/2022/7606896

Cited by 8 publications

(5 citation statements)

References 24 publications

(24 reference statements)

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“…Furthermore, confusion matrices comparing the predicted and actual classes (i.e., travelled distances) of the testing data in its rows and columns as illustrated in Figure 4a-c were employed to assess the level of prediction of each model. Despite featuring good overall accuracy, the MobileNet V2 featured more than double or even triple the number of misclassifications (12), which indicates a lack of confidence throughout the classification in all four categories (300, 600, 900, and 1200 km), in comparison with Inception V3 (5) and Xception (4). In comparison to the individually trained DL approaches, the ensemble methods combining the three pre-trained deep neural networks featured a superior accuracy of 98.75%, which points towards a higher generalizability of the technique.…”

Section: Resultsmentioning

confidence: 95%

“…The spatial size of the convolved features could be decreased by the pooling layer, lowering the dimensions allowed to decrease the computational costs of data processing. After the convolutional layer, the output was passed through one or more fully connected layers to perform the classification task [12]. The final output was a probability distribution over the possible classes.…”

Section: Deep Learningmentioning

confidence: 99%

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Ensemble Deep Learning for Wear Particle Image Analysis

Shah,

Sridharan,

Mahanta

et al. 2023

Lubricants

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This technical note focuses on the application of deep learning techniques in the area of lubrication technology and tribology. This paper introduces a novel approach by employing deep learning methodologies to extract features from scanning electron microscopy (SEM) images, which depict wear particles obtained through the extraction and filtration of lubricating oil from a 4-stroke petrol internal combustion engine following varied travel distances. Specifically, this work postulates that the amalgamation of ensemble deep learning, involving the combination of multiple deep learning models, leads to greater accuracy compared to individually trained techniques. To substantiate this hypothesis, a fusion of deep learning methods is implemented, featuring deep convolutional neural network (CNN) architectures including Xception, Inception V3, and MobileNet V2. Through individualized training of each model, accuracies reached 85.93% for MobileNet V2 and 93.75% for Inception V3 and Xception. The major finding of this study is the hybrid ensemble deep learning model, which displayed a superior accuracy of 98.75%. This outcome not only surpasses the performance of the singularly trained models, but also substantiates the viability of the proposed hypothesis. This technical note highlights the effectiveness of utilizing ensemble deep learning methods for extracting wear particle features from SEM images. The demonstrated achievements of the hybrid model strongly support its adoption to improve predictive analytics and gain insights into intricate wear mechanisms across various engineering applications.

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Section: Resultsmentioning

confidence: 95%

Section: Deep Learningmentioning

confidence: 99%

Ensemble Deep Learning for Wear Particle Image Analysis

Shah,

Sridharan,

Mahanta

et al. 2023

Lubricants

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“…Technique used Mechanical system [23] Recurrent Neural Network [24] Optimized Transfer Learning Bearings [25] Hierarchical diagnosis networks [26] Transfer Learning Internal Combustion Engine [27] Deep Residual Learning Planetary Gearbox [28] Deep Learning Induction Motors [29] Convolution Neural Network Hydraulic Pump [30] Deep Learning Wind turbines a real-world dry friction clutch system, enabling accurate fault diagnosis. The detailed methodology employed for the fault diagnosis of the clutch system is outlined in figure 1.…”

Section: Referencesmentioning

confidence: 99%

Deep learning based fault detection of automobile dry clutch system using spectrogram plots

Sai S,

Sridharan,

Chakrapani

et al. 2024

Eng. Res. Express

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In this research study, a novel approach that leverages the power of transfer learning (a famous deep learning technique) is proposed to diagnose multiple types of clutch faults including, worn release fingers, fractured pressure plates, deteriorated pressure plates, loss of friction material and distorted tangential strips using spectrogram plots. To train and validate the diagnostic system, vibration readings were taken from a specially designed test rig with the help of piezoelectric accelerometer while the clutch system was operated under different load conditions of 0 (no load), 5 and 10 kg This procedure of data collection was then repeated to acquire the vibration data for all of the fault conditions by replacing the good with fault components individually. These vibration signals were further processed and transformed into spectrogram plots that serves as the input data for the deep learning models considered. Fine-tuning techniques were applied on pretrained networks to maximise the prediction accuracy of the models to effectively determine and diagnose faults in the clutch system. For this study 12 pre-trained networks were chosen namely, Xception, InceptionResNet, DenseNet, AlexNet, VGG16, GoogLeNet, VGG19, ResNet101, ResNet50, InceptionV3, MobileNetV2 and ShuffleNet. To optimize the performance of deep learning models, a systematic adjustment of hyperparameters such as the train-test split ratio, learning rate, optimizer and batch size for each network model was carried out. Through careful experimentation and analysis, significant improvements in fault classification accuracy were achieved thereby enhancing the reliability and effectiveness of the diagnostic system. From the results it was noted that 100% classification accuracy was displayed by AlexNet (for the no load condition and the 10kg load condition) and GoogLeNet (for 5 kg load condition) with extremely low computation times.

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“…Deep Learning Techniques Used Mechanical System [31] Optimized deep belief network Rolling Bearing [32] Deep convolution neural network [33] Ensemble learning method [34] Stacked auto encoder Gearbox [35] Transfer learning Spark ignition engine [36] Stacked denoising auto encoder Centrifugal Pumps [37] Deep belief network Induction Motor [38] Artificial neural networks Wind Turbines…”

Section: Referencementioning

confidence: 99%

Transfer Learning Based Fault Detection for Suspension System Using Vibrational Analysis and Radar Plots

et al. 2023

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The suspension system is of paramount importance in any automobile. Thanks to the suspension system, every journey benefits from pleasant rides, stable driving and precise handling. However, the suspension system is prone to faults that can significantly impact the driving quality of the vehicle. This makes it essential to find and diagnose any faults in the suspension system and rectify them immediately. Numerous techniques have been used to identify and diagnose suspension faults, each with drawbacks. This paper’s proposed suspension fault detection system aims to detect these faults using deep transfer learning techniques instead of the time-consuming and expensive conventional methods. This paper used pre-trained networks such as Alex Net, ResNet-50, Google Net and VGG16 to identify the faults using radar plots of the vibration signals generated by the suspension system in eight cases. The vibration data were acquired using an accelerometer and data acquisition system placed on a test rig for eight different test conditions (seven faulty, one good). The deep learning model with the highest accuracy in identifying and detecting faults among the four models was chosen and adopted to find defects. The results state that VGG16 produced the highest classification accuracy of 96.70%.

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Misfire Detection in Spark Ignition Engine Using Transfer Learning

Cited by 8 publications

References 24 publications

Ensemble Deep Learning for Wear Particle Image Analysis

Ensemble Deep Learning for Wear Particle Image Analysis

Deep learning based fault detection of automobile dry clutch system using spectrogram plots

Transfer Learning Based Fault Detection for Suspension System Using Vibrational Analysis and Radar Plots

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