Patent application number | Description | Published |
20090185801 | Methods and Apparatus for Full-Resolution Light-Field Capture and Rendering - Method and apparatus for full-resolution light-field capture and rendering. A radiance camera is described in which the microlenses in a microlens array are focused on the image plane of the main lens instead of on the main lens, as in conventional plenoptic cameras. The microlens array may be located at distances greater than f from the photosensor, where f is the focal length of the microlenses. Radiance cameras in which the distance of the microlens array from the photosensor is adjustable, and in which other characteristics of the camera are adjustable, are described. Digital and film embodiments of the radiance camera are described. A full-resolution light-field rendering method may be applied to light-fields captured by a radiance camera to render higher-resolution output images than are possible with conventional plenoptic cameras and rendering methods. | 07-23-2009 |
20110211824 | Methods and Apparatus for Full-Resolution Light-Field Capture and Rendering - Method and apparatus for full-resolution light-field capture and rendering. A radiance camera is described in which the microlenses in a microlens array are focused on the image plane of the main lens instead of on the main lens, as in conventional plenoptic cameras. The microlens array may be located at distances greater than f from the photosensor, where f is the focal length of the microlenses. Radiance cameras in which the distance of the microlens array from the photosensor is adjustable, and in which other characteristics of the camera are adjustable, are described. Digital and film embodiments of the radiance camera are described. A full-resolution light-field rendering method may be applied to light-fields captured by a radiance camera to render higher-resolution output images than are possible with conventional plenoptic cameras and rendering methods. | 09-01-2011 |
20120177356 | Methods and Apparatus for Full-Resolution Light-Field Capture and Rendering - Method and apparatus for full-resolution light-field capture and rendering. A radiance camera is described in which the microlenses in a microlens array are focused on the image plane of the main lens instead of on the main lens, as in conventional plenoptic cameras. The microlens array may be located at distances greater than ƒ from the photosensor, where ƒ is the focal length of the microlenses. Radiance cameras in which the distance of the microlens array from the photosensor is adjustable, and in which other characteristics of the camera are adjustable, are described. Digital and film embodiments of the radiance camera are described. A full-resolution light-field rendering method may be applied to light-fields captured by a radiance camera to render higher-resolution output images than are possible with conventional plenoptic cameras and rendering methods. | 07-12-2012 |
20120229679 | Methods and Apparatus for Full-Resolution Light-Field Capture and Rendering - Method and apparatus for full-resolution light-field capture and rendering. A radiance camera is described in which the microlenses in a microlens array are focused on the image plane of the main lens instead of on the main lens, as in conventional plenoptic cameras. The microlens array may be located at distances greater than f from the photosensor, where f is the focal length of the microlenses. Radiance cameras in which the distance of the microlens array from the photosensor is adjustable, and in which other characteristics of the camera are adjustable, are described. Digital and film embodiments of the radiance camera are described. A full-resolution light-field rendering method may be applied to flats captured by a radiance camera to render higher-resolution output images than are possible with conventional plenoptic cameras and rendering methods. | 09-13-2012 |
20120281072 | Focused Plenoptic Camera Employing Different Apertures or Filtering at Different Microlenses - Methods and apparatus for capturing and rendering images with focused plenoptic cameras employing different filtering at different microlenses. In a focused plenoptic camera, the main lens creates an image at the focal plane. That image is re-imaged on the sensor multiple times by an array of microlenses. Different filters that provide different levels and/or types of filtering may be combined with different ones of the microlenses. A flat captured with the camera includes multiple microimages captured according to the different filters. Multiple images may be assembled from the microimages, with each image assembled from microimages captured using a different filter. A final image may be generated by appropriately combining the images assembled from the microimages. Alternatively, a final image, or multiple images, may be assembled from the microimages by first combining the microimages and then assembling the combined microimages to produce one or more output images. | 11-08-2012 |
20130120356 | Methods, Apparatus, and Computer-Readable Storage Media for Depth-Based Rendering of Focused Plenoptic Camera Data - Methods, apparatus, and computer-readable storage media for rendering focused plenoptic camera data. A depth-based rendering technique is described that estimates depth at each microimage and then applies that depth to determine a position in the input flat from which to read a value to be assigned to a given point in the output image. The techniques may be implemented according to parallel processing technology that renders multiple points of the output image in parallel. In at least some embodiments, the parallel processing technology is graphical processing unit (GPU) technology. | 05-16-2013 |
20130120605 | Methods, Apparatus, and Computer-Readable Storage Media for Blended Rendering of Focused Plenoptic Camera Data - Methods, apparatus, and computer-readable storage media for rendering focused plenoptic camera data. A rendering with blending technique is described that blends values from positions in multiple microimages and assigns the blended value to a given point in the output image. A rendering technique that combines depth-based rendering and rendering with blending is also described. Depth-based rendering estimates depth at each microimage and then applies that depth to determine a position in the input flat from which to read a value to be assigned to a given point in the output image. The techniques may be implemented according to parallel processing technology that renders multiple points of the output image in parallel. In at least some embodiments, the parallel processing technology is graphical processing unit (GPU) technology. | 05-16-2013 |
20130128081 | Methods and Apparatus for Reducing Plenoptic Camera Artifacts - Methods and apparatus for reducing plenoptic camera artifacts. A first method is based on careful design of the optical system of the focused plenoptic camera to reduce artifacts that result in differences in depth in the microimages. A second method is computational; a focused plenoptic camera rendering algorithm is provided that corrects for artifacts resulting from differences in depth in the microimages. While both the artifact-reducing focused plenoptic camera design and the artifact-reducing rendering algorithm work by themselves to reduce artifacts, the two approaches may be combined. | 05-23-2013 |
20130128087 | Methods and Apparatus for Super-Resolution in Integral Photography - Methods and apparatus for super-resolution in integral photography are described. Several techniques are described that, alone or in combination, may improve the super-resolution process and/or the quality of super-resolved images that may be generated from flats captured with a focused plenoptic camera using a super-resolution algorithm. At least some of these techniques involve modifications to the focused plenoptic camera design. In addition, at least some of these techniques involve modifications to the super-resolution rendering algorithm. The techniques may include techniques for reducing the size of pixels, techniques for shifting pixels relative to each other so that super-resolution is achievable at more or all depths of focus, and techniques for sampling using an appropriate filter or kernel. These techniques may, for example, reduce or eliminate the need to perform deconvolution on a super-resolved image, and may improve super-resolution results and/or increase performance. | 05-23-2013 |
20140347352 | APPARATUSES, METHODS, AND SYSTEMS FOR 2-DIMENSIONAL AND 3-DIMENSIONAL RENDERING AND DISPLAY OF PLENOPTIC IMAGES - Apparatuses, methods and systems for processing, rendering and displaying plenoptic images are disclosed. One exemplary embodiment is a method comprising storing a plenoptic image in a non-transitory computer readable memory associated with a processor, receiving at the processor a viewing position information, processing the plenoptic image and the viewing position information to render a visual output based upon information of the plenoptic image and the viewing position information, performing a blending or smoothing function on information of the plenoptic image including weighting each of a plurality of pixels of the plenoptic image based upon a first color value associated with each pixel and a set of second color values associated with a plurality of neighboring pixels, and displaying the visual output on a display device. The visual output displayed on the display device varies as a function of the viewing position information. | 11-27-2014 |