Full scaled 3D visual odometry from a single wearable omnidirectional camera

Daniel Gutiérrez-Gómez, L. Puig, J. J. Guerrero
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引用次数: 24

Abstract

In the last years monocular SLAM has been widely used to obtain highly accurate maps and trajectory estimations of a moving camera. However, one of the issues of this approach is that, due to the impossibility of the depth being measured in a single image, global scale is not observable and scene and camera motion can only be recovered up to scale. This problem gets aggravated as we deal with larger scenes since it is more likely that scale drift arises between different map portions and their corresponding motion estimates. To compute the absolute scale we need to know some kind of dimension of the scene (e.g., actual size of an element of the scene, velocity of the camera or baseline between two frames) and somehow integrate it in the SLAM estimation. In this paper, we present a method to recover the scale of the scene using an omnidirectional camera mounted on a helmet. The high precision of visual SLAM allows the head vertical oscillation during walking to be perceived in the trajectory estimation. By performing a spectral analysis on the camera vertical displacement, we can measure the step frequency. We relate the step frequency to the speed of the camera by an empirical formula based on biomedical experiments on human walking. This speed measurement is integrated in a particle filter to estimate the current scale factor and the 3D motion estimation with its true scale. We evaluated our approach using image sequences acquired while a person walks. Our experiments show that the proposed approach is able to cope with scale drift.
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全尺寸3D视觉里程计从一个单一的可穿戴的全方位相机
在过去的几年里,单目SLAM被广泛用于获得运动相机的高精度地图和轨迹估计。然而,这种方法的一个问题是,由于无法在单个图像中测量深度,因此无法观察到全局尺度,并且只能恢复到按比例的场景和相机运动。当我们处理更大的场景时,这个问题会变得更严重,因为在不同的地图部分及其相应的运动估计之间更有可能出现比例漂移。为了计算绝对尺度,我们需要知道场景的某些维度(例如,场景元素的实际尺寸,相机的速度或两帧之间的基线),并以某种方式将其整合到SLAM估计中。在本文中,我们提出了一种使用安装在头盔上的全向相机来恢复场景尺度的方法。视觉SLAM的高精度使得在轨迹估计中可以感知行走过程中头部的垂直振荡。通过对相机垂直位移进行频谱分析,我们可以测量阶跃频率。基于人体行走的生物医学实验,我们用经验公式将步进频率与相机的速度联系起来。该速度测量集成在粒子滤波器中,以估计当前比例因子和三维运动估计其真实比例。我们使用一个人走路时获得的图像序列来评估我们的方法。实验结果表明,该方法能够有效地解决尺度漂移问题。
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