Towards Long-Tailed 3D Detection

Conference on Robot Learning Pub Date : 2022-11-16 DOI:10.48550/arXiv.2211.08691

Neehar Peri, Achal Dave, Deva Ramanan, Shu Kong

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引用次数: 4

Abstract

Contemporary autonomous vehicle (AV) benchmarks have advanced techniques for training 3D detectors, particularly on large-scale lidar data. Surprisingly, although semantic class labels naturally follow a long-tailed distribution, contemporary benchmarks focus on only a few common classes (e.g., pedestrian and car) and neglect many rare classes in-the-tail (e.g., debris and stroller). However, AVs must still detect rare classes to ensure safe operation. Moreover, semantic classes are often organized within a hierarchy, e.g., tail classes such as child and construction-worker are arguably subclasses of pedestrian. However, such hierarchical relationships are often ignored, which may lead to misleading estimates of performance and missed opportunities for algorithmic innovation. We address these challenges by formally studying the problem of Long-Tailed 3D Detection (LT3D), which evaluates on all classes, including those in-the-tail. We evaluate and innovate upon popular 3D detection codebases, such as CenterPoint and PointPillars, adapting them for LT3D. We develop hierarchical losses that promote feature sharing across common-vs-rare classes, as well as improved detection metrics that award partial credit to"reasonable"mistakes respecting the hierarchy (e.g., mistaking a child for an adult). Finally, we point out that fine-grained tail class accuracy is particularly improved via multimodal fusion of RGB images with LiDAR; simply put, small fine-grained classes are challenging to identify from sparse (lidar) geometry alone, suggesting that multimodal cues are crucial to long-tailed 3D detection. Our modifications improve accuracy by 5% AP on average for all classes, and dramatically improve AP for rare classes (e.g., stroller AP improves from 3.6 to 31.6)! Our code is available at https://github.com/neeharperi/LT3D

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走向长尾三维探测

现代自动驾驶汽车(AV)基准具有先进的3D探测器训练技术，特别是在大规模激光雷达数据上。令人惊讶的是，尽管语义类标签自然地遵循长尾分布，但当代基准测试只关注几个常见的类(例如，行人和汽车)，而忽略了许多罕见的尾部类(例如，碎片和婴儿车)。然而，自动驾驶汽车仍然必须检测稀有类别，以确保安全运行。此外，语义类通常在层次结构中组织，例如，尾类如child和construction-worker可以说是pedestrian的子类。然而，这种层次关系往往被忽视，这可能导致对性能的误导性估计，并错失算法创新的机会。我们通过正式研究长尾3D检测(LT3D)问题来解决这些挑战，LT3D对所有类别进行评估，包括那些在尾部的类别。我们对流行的3D检测代码库(如CenterPoint和PointPillars)进行评估和创新，使其适应LT3D。我们开发了层次损失，促进了常见类与罕见类之间的特征共享，并改进了检测指标，对尊重层次的“合理”错误(例如，将儿童误认为成人)给予部分信任。最后，我们指出，通过RGB图像与LiDAR的多模态融合，可以特别提高细粒度尾类的精度;简而言之，仅从稀疏(激光雷达)几何形状中识别小的细粒度类具有挑战性，这表明多模态线索对长尾3D检测至关重要。我们的修改使所有职业的准确率平均提高了5%，并且显著提高了稀有职业的准确率(例如，婴儿车的准确率从3.6提高到31.6)!我们的代码可在https://github.com/neeharperi/LT3D上获得

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Conference on Robot Learning

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