用积分法对透镜阵列采样的三维图像进行深度范围分析

2009 3DTV Conference: The True Vision - Capture, Transmission and Display of 3D Video Pub Date : 2009-05-04 DOI:10.1109/3DTV.2009.5069634

F. Okano, J. Arai, M. Kawakita

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引用次数: 0

摘要

对重建的三维图像中的光线进行几何分析，并利用透镜阵列的积分方法对图像进行采样。光线通过透镜阵列形成光学图像，其中一部分进入观察者的瞳孔并在视网膜上形成图像。假定瞳孔有一定的直径。导出了三维图像的深度范围(其在视网膜上的投影图像由透镜阵列采样)。即，所述深度范围限于所述透镜阵列的周围区域，并取决于构成所述透镜阵列的元素透镜的间距。当重建的三维图像位于深度范围内时，其视觉分辨率受到奈奎斯特频率的限制。另一方面，当三维图像位于深度范围之外时，可以通过单质透镜的衍射将视觉分辨率提高到频率的上限。

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Depth range of a 3D image sampled by a lens array with the integral method

Light rays from reconstructed 3D images were geometrically analyzed, and sampling of the images by using a lens array with the integral method was demonstrated. The light rays pass through the lens array and form an optical image, part of which enters the observer's pupil and forms an image on the retina. It was assumed that the pupil has a certain diameter. The depth range of the 3D image (whose projected image on the retina is sampled by the lens array) was derived. That is, the depth range is restricted to the surrounding area of the lens array and depends on the pitch of the elemental lenses constituting the lens array. When the reconstructed 3D image is located within the depth range, its visual resolution is limited by the Nyquist frequency. On the other hand, when the 3D image is located out of the depth range, the visual resolution can be increased to the upper limit of frequency by diffraction of the elemental lens.

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来源期刊

2009 3DTV Conference: The True Vision - Capture, Transmission and Display of 3D Video

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