TSVR-Net: An End-to-End Ground-Penetrating Radar Images Registration and Location Network

Remote. Sens. Pub Date : 2023-07-06 DOI:10.3390/rs15133428
Beizhen Bi, Liang Shen, Pengyu Zhang, Xiaotao Huang, Qin Xin, Tian Jin
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Abstract

Stable and reliable autonomous localization technology is fundamental for realizing autonomous driving. Localization systems based on global positioning system (GPS), cameras, LIDAR, etc., can be affected by building occlusion or drastic changes in the environment. These effects can degrade the localization accuracy and even cause the problem of localization failure. Localizing ground-penetrating radar (LGPR) as a new type of localization can rely only on robust subsurface information for autonomous localization. LGPR is mostly a 2D-2D registration process. This paper describes the LGPR as a slice-to-volume registration (SVR) problem and proposes an end-to-end TSVR-Net-based regression localization method. Firstly, the information of different dimensions in 3D data is used to ensure the high discriminative power of the data. Then the attention module is added to the design to make the network pay attention to important information and high discriminative regions while balancing the information weights of different dimensions. Eventually, it can directly regress to predict the current data location on the map. We designed several sets of experiments to verify the method’s effectiveness by a step-by-step analysis. The superiority of the proposed method over the current state-of-the-art LGPR method is also verified on five datasets. The experimental results show that both the deep learning method and the increase in dimensional information can improve the stability of the localization system. The proposed method exhibits excellent localization accuracy and better stability, providing a new concept to realize the stable and reliable real-time localization of ground-penetrating radar images.
TSVR-Net:端到端探地雷达图像配准与定位网络
稳定可靠的自主定位技术是实现自动驾驶的基础。基于全球定位系统(GPS)、摄像头、激光雷达等的定位系统可能会受到建筑物遮挡或环境剧烈变化的影响。这些影响会降低定位精度,甚至导致定位失败的问题。定位探地雷达作为一种新型的定位方式,只能依靠鲁棒的地下信息进行自主定位。LGPR主要是一个2D-2D注册过程。本文将LGPR描述为一个切片到体积的配准(SVR)问题,提出了一种基于tsvr - net的端到端回归定位方法。首先,利用三维数据中不同维度的信息,保证数据的高分辨能力;然后在设计中加入关注模块,使网络在平衡不同维度的信息权重的同时,关注重要信息和高判别区域。最终,它可以直接回归到预测当前数据在地图上的位置。我们设计了几组实验,通过一步一步的分析来验证该方法的有效性。在五个数据集上验证了所提出方法优于当前最先进的LGPR方法的优越性。实验结果表明,深度学习方法和维度信息的增加都能提高定位系统的稳定性。该方法具有良好的定位精度和较好的稳定性,为实现探地雷达图像稳定可靠的实时定位提供了新的思路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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