2020
DOI: 10.3390/rs12213655
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Wavelet Scattering Network-Based Machine Learning for Ground Penetrating Radar Imaging: Application in Pipeline Identification

Abstract: Automatic and efficient ground penetrating radar (GPR) data analysis remains a bottleneck, especially restricting applications in real-time monitoring systems. Deep learning approaches have good practice in automatic object identification, but their intensive data requirement has reduced their applicability. This paper developed a machine learning framework based on wavelet scattering networks to analyze GPR data for subsurface pipeline identification. Wavelet scattering network is functionally equivalent to c… Show more

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Cited by 24 publications
(27 citation statements)
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“…The main goal is to detect the features corresponding to buried pipelines in GPR datasets. Results presented in [10] yield a classification accuracy greater than 95% in the presented examples.…”
Section: Gpr Data Processing Enhancementmentioning
confidence: 76%
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“…The main goal is to detect the features corresponding to buried pipelines in GPR datasets. Results presented in [10] yield a classification accuracy greater than 95% in the presented examples.…”
Section: Gpr Data Processing Enhancementmentioning
confidence: 76%
“…Ref. [10] introduces a machine learning framework based on wavelet scattering networks, which are functionally equivalent to CNN. The main goal is to detect the features corresponding to buried pipelines in GPR datasets.…”
Section: Gpr Data Processing Enhancementmentioning
confidence: 99%
See 1 more Smart Citation
“…Scenario 1: identifying sparse rock cracks Since visibly obtaining the actual fissure distribution inside the surrounding rocks is difficult, the numerically generated radargram is analyzed to compare the reconstructed profile with the preset geometric model. The open-source software, 'gprMax' [51], can simulate electromagnetic wave propagation inside the subterranean sections and have been extensively applied in evaluating GPR signal processing approaches (e.g., [52,53]). We assume that the signal reflections are all generated by rock fissures, not strata interfaces, since the underground caverns are built inside the single layer of granite.…”
Section: Simulated Signal Analysismentioning
confidence: 99%
“…Since all operators have been predefined, the WSN contains no parameters, and thus, the dataset requirement decreases. In [ 30 ], only 40 radargrams were required for training and validation to achieve a learning accuracy over 95%. The learning frameworks based on WSNs also outperformed CNNs in multiple applications, achieving a learning accuracy up to 99.7% (e.g., [ 31 , 32 ]).…”
Section: Introductionmentioning
confidence: 99%