Vpit: real-time embedded single object 3D tracking using voxel pseudo images

Illia Oleksiienko, Paraskevi Nousi, Nikolaos Passalis, Anastasios Tefas, Alexandros Iosifidis
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Abstract

In this paper, we propose a novel voxel-based 3D single object tracking (3D SOT) method called Voxel Pseudo Image Tracking (VPIT). VPIT is the first method that uses voxel pseudo images for 3D SOT. The input point cloud is structured by pillar-based voxelization, and the resulting pseudo image is used as an input to a 2D-like Siamese SOT method. The pseudo image is created in the Bird’s-eye View (BEV) coordinates; and therefore, the objects in it have constant size. Thus, only the object rotation can change in the new coordinate system and not the object scale. For this reason, we replace multi-scale search with a multi-rotation search, where differently rotated search regions are compared against a single target representation to predict both position and rotation of the object. Experiments on KITTI [1] Tracking dataset show that VPIT is the fastest 3D SOT method and maintains competitive Success and Precision values. Application of a SOT method in a real-world scenario meets with limitations such as lower computational capabilities of embedded devices and a latency-unforgiving environment, where the method is forced to skip certain data frames if the inference speed is not high enough. We implement a real-time evaluation protocol and show that other methods lose most of their performance on embedded devices; while, VPIT maintains its ability to track the object.

Abstract Image

Vpit:使用体素伪图像进行实时嵌入式单个物体 3D 跟踪
本文提出了一种新颖的基于体素的三维单个物体跟踪(3D SOT)方法,称为体素伪图像跟踪(VPIT)。VPIT 是第一种使用体素伪图像进行 3D SOT 的方法。输入点云通过基于柱的体素化进行结构化,生成的伪图像用作类似二维连体 SOT 方法的输入。伪图像以鸟瞰图(BEV)坐标创建,因此其中的物体大小不变。因此,在新的坐标系中,只有物体的旋转会发生变化,而物体的比例不会发生变化。因此,我们用多旋转搜索取代多尺度搜索,将不同旋转搜索区域与单一目标表示进行比较,以预测物体的位置和旋转。在 KITTI [1] 跟踪数据集上的实验表明,VPIT 是最快的 3D SOT 方法,并保持了具有竞争力的成功率和精确度值。在现实世界中应用 SOT 方法会遇到一些限制,例如嵌入式设备的计算能力较低,以及延迟环境不宽松,如果推理速度不够快,该方法就会被迫跳过某些数据帧。我们实施了一个实时评估协议,结果表明其他方法在嵌入式设备上的性能大打折扣,而 VPIT 却能保持跟踪物体的能力。
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