Full-waveform inversion of ground-penetrating radar data in frequency-dependent media involving permittivity attenuation

Tan, Qiaoyan; Bohlen, Thomas; Allroggen, Niklas

doi:10.1093/gji/ggac319

Cited by 10 publications

(3 citation statements)

References 50 publications

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“…Deep learning offers significant advantages in handling GPR data. Its automatic feature extraction capability eliminates the need for the manual extraction of complex underground signal features, thus enhancing processing efficiency [27]. The robust generalization ability of deep learning models enables them to adapt to data from different geological conditions, improving the versatility of data processing.…”

Section: Introductionmentioning

confidence: 99%

Rock Layer Classification and Identification in Ground-Penetrating Radar via Machine Learning

Xu,

Yan,

Feng

et al. 2024

Remote Sensing

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Ground-penetrating radar (GPR) faces complex challenges in identifying underground rock formations and lithological structures. The diversity, intricate shapes, and electromagnetic properties of subsurface rock formations make their accurate detection difficult. Additionally, the heterogeneity of subsurface media, signal scattering, and non-linear propagation effects contribute to the complexity of signal interpretation. To address these challenges, this study fully considers the unique advantages of convolutional neural networks (CNNs) in accurately identifying underground rock formations and lithological structures, particularly their powerful feature extraction capabilities. Deep learning models possess the ability to automatically extract complex signal features from radar data, while also demonstrating excellent generalization performance, enabling them to handle data from various geological conditions. Moreover, deep learning can efficiently process large-scale data, thereby improving the accuracy and efficiency of identification. In our research, we utilized deep neural networks to process GPR signals, using radar images as inputs and generating structure-related information associated with rock formations and lithological structures as outputs. Through training and learning, we successfully established an effective mapping relationship between radar images and lithological label signals. The results from synthetic data indicate a rock block identification success rate exceeding 88%, with a satisfactory continuity identification of lithological structures. Transferring the network to measured data, the trained model exhibits excellent performance in predicting data collected from the field, further enhancing the geological interpretation and analysis. Therefore, through the results obtained from synthetic and measured data, we can demonstrate the effectiveness and feasibility of this research method.

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Section: Introductionmentioning

confidence: 99%

Rock Layer Classification and Identification in Ground-Penetrating Radar via Machine Learning

Xu,

Yan,

Feng

et al. 2024

Remote Sensing

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“…Different scenarios of the radar applications involve the transmission of the noise signals through media with dielectric properties showing frequency-dependent behavior [7][8][9][10][11][12]. The impairments introduced in the transmitted signal due to frequency dispersion can lead the receiver structures to work under optimal performance, thus increasing the difficulty to accomplish accurate retrieval of the carried information-that may consist of bit streaming, amplitude or phase levels, or target presence detection-or just to restore the received signal.…”

Section: Introductionmentioning

confidence: 99%

Multipath Detection and Mitigation of Random Noise Signals Propagated through Naturally Lossy Dispersive Media for Radar Applications

Vazquez Alejos,

Dawood

2023

Sensors

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This paper describes a methodological analysis of the Brillouin precursor formation to understand the impairments undergone by like-noise and random noise waveforms propagating through naturally dispersive media commonly found in radar applications. By means of a frequency-domain methodology based on considering the frequency response of the medium under study, the effect of these dispersive media on the evolution of an input signal can be seen as frequency filtering. The simulations were performed at a center frequency of 1.5 GHz and for a signal bandwidth of 3 GHz. Four random noise signals were considered: Barker codes, PRBS codes, Frank codes, Costas codes and additive white Gaussian noise. The experienced impairments were assessed in terms of cross-correlation function (CCF) degradation. The differences in the behavior of each type of phase and frequency coded signal to face the dispersive propagation have been demonstrated in terms of parameters used for information retrieval: peak amplitude decay, CCF secondary sidelobe level and multipath detectability. Finally, a frequency filtering approach is proposed to mitigate the impairments due to dispersive propagation under multipath conditions.

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“…Similarly, moisture or the presence of certain contaminants can strongly attenuate the high frequencies, limiting the frequency range of the recorded signal [12,13]. Therefore, by analyzing the frequency Sensors 2022, 22, 9851 2 of 14 variations as a time function, some information regarding the electromagnetic properties of the materials under investigation can be obtained [14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Optimization of Dominant Frequency and Bandwidth Analysis in Multi-Frequency 3D GPR Signals to Identify Contaminated Areas

Paredes-Palacios

Mota-Toledo²,

Biosca

et al. 2022

Sensors

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Ground-penetrating radar (GPR) has been widely used in investigations of contaminated areas because of its sensitivity to variations associated with the nature of pore fluids. However, most of the studies were usually based on the visual interpretation of radargrams or on a time domain amplitude analysis. In this work, we propose a methodology that consists of analyzing the spectral content of the signal recorded in multi-frequency 3D GPR profiles. A remarkable advantage of this type of antenna is its step-frequency system, which provides a much wider emission spectrum than the one corresponding to conventional single-frequency antennas. From the data in the frequency domain, the dominant frequency and bandwidth were calculated as parameters whose variation could be related to the presence of light non-aqueous phase liquid (LNAPL) in the subsurface. By analyzing the variations of these two parameters simultaneously, we were able to delimit the contaminated zones in a case study, associating them with a significant shift of the frequency spectrum with respect to the average of the study area. Finally, as a validation method of the proposed methodology, the results of the frequency analysis were compared with resistivity data obtained with an electromagnetic conductivity meter, showing a very good correlation between the results.

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Full-waveform inversion of ground-penetrating radar data in frequency-dependent media involving permittivity attenuation

Cited by 10 publications

References 50 publications

Rock Layer Classification and Identification in Ground-Penetrating Radar via Machine Learning

Rock Layer Classification and Identification in Ground-Penetrating Radar via Machine Learning

Multipath Detection and Mitigation of Random Noise Signals Propagated through Naturally Lossy Dispersive Media for Radar Applications

Optimization of Dominant Frequency and Bandwidth Analysis in Multi-Frequency 3D GPR Signals to Identify Contaminated Areas

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