A 3D scene acquisition and reconstruction system via optical axial scanning

Jiaqing Dong, Zilong Li, Xuan Liu, Wenhua Zhong, Guijun Wang, Qiegen Liu, Xianlin Song
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Abstract

In recent years, three-dimensional (3D) display technology has developed rapidly, and it is widely used in education, medical, military and other fields. 3D holographic display is regarded as the ultimate solution of 3D display. However, the lack of 3D content is one of the challenges that has been faced by 3D holographic display. The traditional method uses light-field camera and RGB-D camera to obtain 3D information of real scene, which has the problems of high-system complexity and long-time consumption. Here, we proposed a 3D scene acquisition and reconstruction system based on optical axial scanning. First an electrically tunable lens (ETL) was used for high-speed focus shift (up to 2.5 ms). A CCD camera was synchronized with the ETL to acquire multi-focused image sequence of real scene. Then, Tenengrad operator was used to obtain the focusing area of each multi-focused image, and the 3D image were obtained. Finally, the Computer-generated Hologram (CGH) can be obtained by the layer-based diffraction algorithm. The CGH was loaded onto the space light modulator to reconstruct the 3D holographic image. The experimental results verify the feasibility of the system. This method will expand the application of 3D holographic display in the field of education, advertising, entertainment, and other fields.
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一种基于光轴扫描的三维场景采集与重建系统
近年来,三维(3D)显示技术发展迅速,广泛应用于教育、医疗、军事等领域。三维全息显示被认为是三维显示的终极解决方案。然而,缺乏3D内容是3D全息显示所面临的挑战之一。传统方法采用光场相机和RGB-D相机获取真实场景的三维信息,存在系统复杂度高、消耗时间长等问题。本文提出了一种基于光轴扫描的三维场景采集与重建系统。首先,电可调镜头(ETL)用于高速聚焦(高达2.5毫秒)。将CCD相机与ETL同步,获取真实场景的多聚焦图像序列。然后,利用Tenengrad算子求出各多聚焦图像的聚焦区域,得到三维图像;最后,利用基于层的衍射算法获得计算机生成全息图(CGH)。将CGH加载到空间光调制器上重建三维全息图像。实验结果验证了该系统的可行性。这种方法将扩大3D全息显示在教育、广告、娱乐等领域的应用。
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