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Automatic visualization of gas leakage in the domestic sector using spacial and temporal models with image processing techniques

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Abstract

The leakage of gas in the domestic sectors is a dangerous issue that causes various hazards. This is due to the damage in the pipelines that affects the overall functioning. Prior detection of leakage can help to avoid various dangerous consequences. The proposed system helps in the detection of gas leakage through artificial intelligence techniques evolving image processing. This includes infrared (IR) cameras that help to detect the leakage of gas. This helps in detecting the gas by analyzing and detecting the temperature of the leaking liquid with that of the surrounding temperature. This is a vision-based sensing system. To obtain accurate images, image enhancement processing with Gaussian filters is used. This helps to enhance the quality of the infrared images. Then the feature extraction phase is implemented to extract the most prominent features that aid to detect the leakage accurately. The proposed system is implemented using deep learning techniques with an optimization algorithm. This helps in obtaining accurate results that help to prevent leakages and protect from various constraints.

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All the data is collected from the simulation reports of the software and tools used by the authors. Authors are working on implementing the same using real world data with appropriate permissions.

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Funding

On Behalf of all authors the corresponding author states that they did not receive any funds for this project.

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Contributions

Author 1: Immanuel John Raja He performed the conceptualization, Methodology, Data collection and writing the study Author 2: S.V.Evangelin Sonia He analysis the datazset and conceptualization in the study. Author 3: C.P.Shirley He Performed the Analysis of overall concept, writing and editing. Author 4: I.Titus He analysis the paper and supervisor of this paper.

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Correspondence to I. Titus.

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Raja, I.J., Sonia, S.V.E., Shirley, C.P. et al. Automatic visualization of gas leakage in the domestic sector using spacial and temporal models with image processing techniques. SIViP 18, 8859–8867 (2024). https://doi.org/10.1007/s11760-024-03513-6

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