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Computer vision and deep transfer learning for automatic gauge reading detection.

Hitesh Ninama1,2, Jagdish Raikwal1, Ananda Ravuri3

  • 1Institute of Engineering and Technology, Devi Ahilya University, Indore, M.P., 452001, India.

Scientific Reports
|October 3, 2024
PubMed
Summary
This summary is machine-generated.

This study introduces an AI system for automatic analogue gauge reading using deep learning. DenseNet 169 achieved superior precision and generalization for accurate gauge interpretation.

Keywords:
Computer visionDeep learningDenseNet 169Gauge detectionInceptionNet V3VGG19

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Area of Science:

  • Computer Vision
  • Artificial Intelligence
  • Machine Learning

Background:

  • Manual analogue gauge reading is prone to errors and time-consuming.
  • Automating gauge reading is essential for efficiency and accuracy in various industries.
  • Existing methods struggle with unsupervised data and achieving high precision.

Purpose of the Study:

  • To develop an automatic reading detection system for analogue gauges.
  • To leverage deep learning and image processing for enhanced gauge reading accuracy.
  • To compare the performance of different deep transfer learning models for this task.

Main Methods:

  • Utilized a combination of deep learning, machine learning, and image processing techniques.
  • Employed image processing to generate supervised data for training.
  • Trained and evaluated deep transfer learning models including DenseNet 169, InceptionNet V3, and VGG19 on 1011 labeled images.

Main Results:

  • DenseNet 169 demonstrated superior precision and generalization capabilities compared to InceptionNet V3 and VGG19.
  • VGG19 showed high training precision (97.00%) but lower testing precision (75.00%), indicating overfitting.
  • InceptionNet V3 exhibited consistent precision across training and testing datasets.

Conclusions:

  • DenseNet 169 is the most effective model for automatic analogue gauge reading detection.
  • The proposed system offers a robust solution for accurate and automated gauge interpretation.
  • AI-powered systems can significantly improve the efficiency and reliability of analogue gauge analysis.