English

A Deep Learning-Based GPR Forward Solver for Predicting B-Scans of Subsurface Objects

Image and Video Processing 2022-10-05 v1

Abstract

The forward full-wave modeling of ground-penetrating radar (GPR) facilitates the understanding and interpretation of GPR data. Traditional forward solvers require excessive computational resources, especially when their repetitive executions are needed in signal processing and/or machine learning algorithms for GPR data inversion. To alleviate the computational burden, a deep learning-based 2D GPR forward solver is proposed to predict the GPR B-scans of subsurface objects buried in the heterogeneous soil. The proposed solver is constructed as a bimodal encoder-decoder neural network. Two encoders followed by an adaptive feature fusion module are designed to extract informative features from the subsurface permittivity and conductivity maps. The decoder subsequently constructs the B-scans from the fused feature representations. To enhance the network's generalization capability, transfer learning is employed to fine-tune the network for new scenarios vastly different from those in training set. Numerical results show that the proposed solver achieves a mean relative error of 1.28%. For predicting the B-scan of one subsurface object, the proposed solver requires 12 milliseconds, which is 22,500x less than the time required by a classical physics-based solver.

Keywords

Cite

@article{arxiv.2207.06527,
  title  = {A Deep Learning-Based GPR Forward Solver for Predicting B-Scans of Subsurface Objects},
  author = {Qiqi Dai and Yee Hui Lee and Hai-Han Sun and Jiwei Qian and Genevieve Ow and Mohamed Lokman Mohd Yusof and Abdulkadir C. Yucel},
  journal= {arXiv preprint arXiv:2207.06527},
  year   = {2022}
}
R2 v1 2026-06-25T00:53:48.754Z