Automated AI-Based Annotation Framework for 3D Object Detection from LIDAR Data in Industrial Areas-Reference-Cited by-同舟云学术

Automated AI-Based Annotation Framework for 3D Object Detection from LIDAR Data in Industrial Areas

Published:2024-07-02 Issue: Volume: Page:
ISSN:0148-7191
Container-title:SAE Technical Paper Series
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Author:

Abdelhalim Gina¹,Simon Kevin¹,Bensch Robert²,Parimi Sai²,Qureshi Bilal Ahmed²

Affiliation:

1. Karlsruhe Institute of Technology

2. ANavS GmbH

Abstract

<div class="section abstract"><div class="htmlview paragraph">Autonomous Driving is used in various settings, including indoor areas such as industrial halls and warehouses. For perception in these environments, LIDAR is currently very popular due to its high accuracy compared to RADAR and its robustness to varying lighting conditions compared to cameras. However, there is a notable lack of freely available labeled LIDAR data in these settings, and most public datasets, such as KITTI and Waymo, focus on public road scenarios. As a result, specialized publicly available annotation frameworks are rare as well. This work tackles these shortcomings by developing an automated AI-based labeling tool to generate a LIDAR dataset with 3D ground truth annotations for industrial warehouse scenarios. The base pipeline for the annotation framework first upsamples the incoming 16-channel data into dense 64-channel data. The upsampled data is then manually annotated for the defined classes and this annotated 64-channel dataset is used to fine-tune the Part-A<sup>2</sup>-Net that has been pretrained on the KITTI dataset. This fine-tuned network shows promising results for the defined classes. To overcome some shortcomings with this pipeline, which mainly involves artefacts from upsampling and manual labeling, we extend the pipeline to make use of SLAM to generate the dense point cloud and use the generated poses to speed up the labeling process. The progression, therefore shows the three generations of the framework which started with manual upsampling and labeling. This then was extended to a semi-automated approach with automatic generation of dense map using SLAM and automatic annotation propagation to all the scans for all static classes and then the complete automatic pipeline that generates ground truth using the Part-A<sup>2</sup>-Net which was trained using the dataset generated from the manual and semi-automated pipelines. The dataset generated for this warehouse environment will continuously be extended and is publicly available at <a href="" target="_blank">https://github.com/anavsgmbh/lidar-warehouse-dataset</a>.</div></div>

Publisher

SAE International

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