耦合光学分辨深度

Junjie Luo, Yuxuan Liu, Emma Alexander, Qi Guo
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引用次数: 0

摘要

我们提出了一种低计算量的被动照明三维传感机制--耦合光学微分深度。它基于我们的发现,即使用简单的闭合式关系,可以通过离焦图像的一对耦合光学导数严格确定每像素物体的距离。与以往利用图像的空间导数来估计场景深度的离焦深度(DfD)方法不同,所提出的机制仅使用光学导数,因此对噪声的鲁棒性大大提高。此外,与之前许多对光圈编码有要求的 DfD 算法不同,这种关系被证明适用于多种光圈编码。我们建立了第一个基于耦合光学差分深度的三维传感器。它的光学组件包括一个可变形透镜和电动光圈,可对光学功率和光圈半径进行动态调整。传感器捕捉两对图像:一对是光学功率的差异变化,另一对是光圈尺度的差异变化。从这四幅图像中,只需对每个输出像素进行 36 次浮点运算(FLOPOP)即可生成深度图和置信度图,比我们所知的之前最低的被动照明深度感应解决方案低十倍以上。此外,该传感器生成的深度图的工作范围是之前 DfD 方法的两倍多,而计算量却大大降低。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Depth from Coupled Optical Differentiation
We propose depth from coupled optical differentiation, a low-computation passive-lighting 3D sensing mechanism. It is based on our discovery that per-pixel object distance can be rigorously determined by a coupled pair of optical derivatives of a defocused image using a simple, closed-form relationship. Unlike previous depth-from-defocus (DfD) methods that leverage spatial derivatives of the image to estimate scene depths, the proposed mechanism's use of only optical derivatives makes it significantly more robust to noise. Furthermore, unlike many previous DfD algorithms with requirements on aperture code, this relationship is proved to be universal to a broad range of aperture codes. We build the first 3D sensor based on depth from coupled optical differentiation. Its optical assembly includes a deformable lens and a motorized iris, which enables dynamic adjustments to the optical power and aperture radius. The sensor captures two pairs of images: one pair with a differential change of optical power and the other with a differential change of aperture scale. From the four images, a depth and confidence map can be generated with only 36 floating point operations per output pixel (FLOPOP), more than ten times lower than the previous lowest passive-lighting depth sensing solution to our knowledge. Additionally, the depth map generated by the proposed sensor demonstrates more than twice the working range of previous DfD methods while using significantly lower computation.
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