Albert Matveev, Ruslan Rakhimov, Alexey Artemov, G. Bobrovskikh, Vage Egiazarian, Emil Bogomolov, Daniele Panozzo, D. Zorin, Evgeny Burnaev
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引用次数: 0
摘要
我们提出了深度特征估计器(Deep Estimators of Features, DEFs),这是一个基于学习的框架,用于预测采样的3D形状中的尖锐几何特征。与现有的数据驱动方法将该问题简化为特征分类不同,我们提出回归一个标量场,表示点样本到局部补丁上最近的特征线的距离。我们的方法是第一个通过融合在单个斑块上获得的距离特征估计来扩展到大规模点云的方法。我们在新提出的合成和现实世界的3D CAD模型基准上广泛评估了我们针对相关最先进方法的方法。我们的方法不仅优于这些方法(在召回率和误报率方面有所改进),而且在合成数据上训练我们的模型并在扫描数据的小数据集上对其进行微调后,可以推广到现实世界的扫描。我们演示了一个下游应用程序,其中我们从距离扫描数据中重建直线和弯曲尖锐特征线的显式表示。我们在https://github.com/artonson/def上提供代码、预训练模型以及我们的训练和评估数据集。
We propose Deep Estimators of Features (DEFs), a learning-based framework for predicting sharp geometric features in sampled 3D shapes. Differently from existing data-driven methods, which reduce this problem to feature classification, we propose to regress a scalar field representing the distance from point samples to the closest feature line on local patches. Our approach is the first that scales to massive point clouds by fusing distance-to-feature estimates obtained on individual patches. We extensively evaluate our approach against related state-of-the-art methods on newly proposed synthetic and real-world 3D CAD model benchmarks. Our approach not only outperforms these (with improvements in Recall and False Positives Rates), but generalizes to real-world scans after training our model on synthetic data and fine-tuning it on a small dataset of scanned data. We demonstrate a downstream application, where we reconstruct an explicit representation of straight and curved sharp feature lines from range scan data. We make code, pre-trained models, and our training and evaluation datasets available at https://github.com/artonson/def.
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