Addressing the Gaps of IoU Loss in 3D Object Detection with IIoU

IF 2.8 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS Future Internet Pub Date : 2023-12-11 DOI:10.3390/fi15120399

N. Ravi, Mohamed El-Sharkawy

引用次数: 0

Abstract

Three-dimensional object detection involves estimating the dimensions, orientations, and locations of 3D bounding boxes. Intersection of Union (IoU) loss measures the overlap between predicted 3D box and ground truth 3D bounding boxes. The localization task uses smooth-L1 loss with IoU to estimate the object’s location, and the classification task identifies the object/class category inside each 3D bounding box. Localization suffers a performance gap in cases where the predicted and ground truth boxes overlap significantly less or do not overlap, indicating the boxes are far away, and in scenarios where the boxes are inclusive. Existing axis-aligned IoU losses suffer performance drop in cases of rotated 3D bounding boxes. This research addresses the shortcomings in bounding box regression problems of 3D object detection by introducing an Improved Intersection Over Union (IIoU) loss. The proposed loss function’s performance is experimented on LiDAR-based and Camera-LiDAR-based fusion methods using the KITTI dataset.

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利用 IIoU 解决 3D 物体检测中 IoU 丢失的问题

三维物体检测包括估计三维边界框的尺寸、方向和位置。联合交叉（IoU）损失测量预测的三维边界框与地面实况三维边界框之间的重叠程度。定位任务使用平滑-L1 损失和 IoU 来估计物体的位置，分类任务则识别每个三维边界框内的物体/类别。在预测方框和地面实况方框重叠较少或不重叠的情况下（表明方框距离较远），以及在方框具有包容性的情况下，定位会出现性能差距。在旋转三维边界框的情况下，现有的轴对齐 IoU 损失会导致性能下降。针对三维物体检测中边界框回归问题的不足，本研究引入了改进的 "交集大于联合"（IIoU）损失。利用 KITTI 数据集，在基于激光雷达和基于相机-激光雷达的融合方法上对所提出的损失函数的性能进行了实验。

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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来源期刊

Future Internet Computer Science-Computer Networks and Communications

CiteScore

7.10

自引率

5.90%

发文量

303

审稿时长

11 weeks

期刊介绍： Future Internet is a scholarly open access journal which provides an advanced forum for science and research concerned with evolution of Internet technologies and related smart systems for “Net-Living” development. The general reference subject is therefore the evolution towards the future internet ecosystem, which is feeding a continuous, intensive, artificial transformation of the lived environment, for a widespread and significant improvement of well-being in all spheres of human life (private, public, professional). Included topics are: • advanced communications network infrastructures • evolution of internet basic services • internet of things • netted peripheral sensors • industrial internet • centralized and distributed data centers • embedded computing • cloud computing • software defined network functions and network virtualization • cloud-let and fog-computing • big data, open data and analytical tools • cyber-physical systems • network and distributed operating systems • web services • semantic structures and related software tools • artificial and augmented intelligence • augmented reality • system interoperability and flexible service composition • smart mission-critical system architectures • smart terminals and applications • pro-sumer tools for application design and development • cyber security compliance • privacy compliance • reliability compliance • dependability compliance • accountability compliance • trust compliance • technical quality of basic services.