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Main Authors: Lu, Weining, Bin, Deer, Ma, Lian, Ma, Ming, Ma, Zhihao, Chen, Xiangyang, Wang, Longfei, Feng, Yixiao, Jiang, Zhouxian, Shi, Yongliang, Liang, Bin
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.06749
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author Lu, Weining
Bin, Deer
Ma, Lian
Ma, Ming
Ma, Zhihao
Chen, Xiangyang
Wang, Longfei
Feng, Yixiao
Jiang, Zhouxian
Shi, Yongliang
Liang, Bin
author_facet Lu, Weining
Bin, Deer
Ma, Lian
Ma, Ming
Ma, Zhihao
Chen, Xiangyang
Wang, Longfei
Feng, Yixiao
Jiang, Zhouxian
Shi, Yongliang
Liang, Bin
contents Efficient, accurate, and flexible relative localization is crucial in air-ground collaborative tasks. However, current approaches for robot relative localization are primarily realized in the form of distributed multi-robot SLAM systems with the same sensor configuration, which are tightly coupled with the state estimation of all robots, limiting both flexibility and accuracy. To this end, we fully leverage the high capacity of Unmanned Ground Vehicle (UGV) to integrate multiple sensors, enabling a semi-distributed cross-modal air-ground relative localization framework. In this work, both the UGV and the Unmanned Aerial Vehicle (UAV) independently perform SLAM while extracting deep learning-based keypoints and global descriptors, which decouples the relative localization from the state estimation of all agents. The UGV employs a local Bundle Adjustment (BA) with LiDAR, camera, and an IMU to rapidly obtain accurate relative pose estimates. The BA process adopts sparse keypoint optimization and is divided into two stages: First, optimizing camera poses interpolated from LiDAR-Inertial Odometry (LIO), followed by estimating the relative camera poses between the UGV and UAV. Additionally, we implement an incremental loop closure detection algorithm using deep learning-based descriptors to maintain and retrieve keyframes efficiently. Experimental results demonstrate that our method achieves outstanding performance in both accuracy and efficiency. Unlike traditional multi-robot SLAM approaches that transmit images or point clouds, our method only transmits keypoint pixels and their descriptors, effectively constraining the communication bandwidth under 0.3 Mbps. Codes and data will be publicly available on https://github.com/Ascbpiac/cross-model-relative-localization.git.
format Preprint
id arxiv_https___arxiv_org_abs_2511_06749
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Semi-distributed Cross-modal Air-Ground Relative Localization
Lu, Weining
Bin, Deer
Ma, Lian
Ma, Ming
Ma, Zhihao
Chen, Xiangyang
Wang, Longfei
Feng, Yixiao
Jiang, Zhouxian
Shi, Yongliang
Liang, Bin
Robotics
Computer Vision and Pattern Recognition
Efficient, accurate, and flexible relative localization is crucial in air-ground collaborative tasks. However, current approaches for robot relative localization are primarily realized in the form of distributed multi-robot SLAM systems with the same sensor configuration, which are tightly coupled with the state estimation of all robots, limiting both flexibility and accuracy. To this end, we fully leverage the high capacity of Unmanned Ground Vehicle (UGV) to integrate multiple sensors, enabling a semi-distributed cross-modal air-ground relative localization framework. In this work, both the UGV and the Unmanned Aerial Vehicle (UAV) independently perform SLAM while extracting deep learning-based keypoints and global descriptors, which decouples the relative localization from the state estimation of all agents. The UGV employs a local Bundle Adjustment (BA) with LiDAR, camera, and an IMU to rapidly obtain accurate relative pose estimates. The BA process adopts sparse keypoint optimization and is divided into two stages: First, optimizing camera poses interpolated from LiDAR-Inertial Odometry (LIO), followed by estimating the relative camera poses between the UGV and UAV. Additionally, we implement an incremental loop closure detection algorithm using deep learning-based descriptors to maintain and retrieve keyframes efficiently. Experimental results demonstrate that our method achieves outstanding performance in both accuracy and efficiency. Unlike traditional multi-robot SLAM approaches that transmit images or point clouds, our method only transmits keypoint pixels and their descriptors, effectively constraining the communication bandwidth under 0.3 Mbps. Codes and data will be publicly available on https://github.com/Ascbpiac/cross-model-relative-localization.git.
title Semi-distributed Cross-modal Air-Ground Relative Localization
topic Robotics
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2511.06749