Abstract: The present application includes a computer implemented method including at least two modes for analyzing a stereoscopic image corresponding to a two dimensional image. The method includes analyzing one or more layers of the two dimensional image to determine a depth pixel offset for every pixel in the two dimensional image and creating by the processing element a depth map, such as a gray scale map, by coloring every pixel a color shade based on the respective depth pixel offset for the pixel. The method further includes displaying on a display an output image corresponding to the stereoscopic image, receiving a first user selection corresponding a first depth pixel offset, determining a plurality of pixels of the output image corresponding to the first depth pixel offset, and applying a first identifier to the plurality of pixels on the output image corresponding to the first depth pixel offset.

Abstract: Implementations of the present invention involve methods and systems for converting a 2-D multimedia image to a 3-D multimedia image by utilizing a plurality of layers of the 2-D image. The layers may comprise one or more portions of the 2-D image and may be digitized and stored in a computer-readable database. The layers may be reproduced as a corresponding left eye and right eye version of the layer, including a pixel offset corresponding to a desired 3-D effect for each layer of the image. The combined left eye layers and right eye layers may form the composite right eye and composite left eye images for a single 3-D multimedia image. Further, this process may be applied to each frame of a animated feature film to convert the film from 2-D to 3-D.

Abstract: The present application includes a computer implemented method including at least two modes for analyzing a stereoscopic image corresponding to a two dimensional image. The method includes analyzing one or more layers of the two dimensional image to determine a depth pixel offset for every pixel in the two dimensional image and creating by the processing element a depth map, such as a gray scale map, by coloring every pixel a color shade based on the respective depth pixel offset for the pixel. The method further includes displaying on a display an output image corresponding to the stereoscopic image, receiving a first user selection corresponding a first depth pixel offset, determining a plurality of pixels of the output image corresponding to the first depth pixel offset, and applying a first identifier to the plurality of pixels on the output image corresponding to the first depth pixel offset.

Abstract: Implementations of the present invention involve methods and systems for converting a 2-D image to a stereoscopic 3-D image and displaying the depth of one or more pixels of the 3-D image through an output image of a user interface. The pixels of the output image display the perceived depth of the corresponding 3-D image such that the user may determine the relative depth of the pixels of the image. In addition, one or more x-offset values or z-axis positions may be individually selected such that any pixel of the output image that correspond to the selected values is indicated in the output image. By providing the user with a visualization tool to quickly determine the perceived position of any pixel of a stereoscopic image, the user may confirm the proper alignment of the objects of the image in relation to the image as a whole.

Abstract: A method for performing stereo composition using multiple camera pairs. The method includes positioning first and second pairs of virtual cameras for imaging an animated scene. The method includes, with the first and second pairs of the cameras, obtaining 3D data for each camera for the animated scene. Then, a blending region is selected by defining a first boundary surface for the first pair of the cameras and a second boundary surface, spaced a distance apart from the first boundary surface, for the second pair of the cameras, with the blending region being the space between the first and second boundary surfaces. The method includes, with a blending module or function, combining the 3D data from a number of consequent cameras. The blending module monotonically increases the stereoscopic disparity function in a viewing direction and combines the 3D data in a continuous manner, e.g., to insure C1 continuity.

Abstract: Implementations of the present invention involve methods and systems for creating depth and volume in a 2-D planar image to create an associated 3-D image by utilizing a plurality of layers of the 2-D image, where each layer comprises one or more portions of the 2-D image. Each layer may be reproduced into a corresponding left eye and right eye layers, with one or both layers including a pixel offset corresponding to a perceived depth. Further, a depth model may be created for one or more objects of the 2-D image to provide a template upon which the pixel offset for one or more pixels of the 2-D image may be adjusted to provide the 2-D image with a more nuanced 3-D effect. In this manner, the 2-D image may be converted to a corresponding 3-D image with a perceived depth.

Abstract: Implementations of the present disclosure involve methods and systems for creating depth and volume in a 2-D image by utilizing a plurality of layers of the 2-D image, where each layer comprises one or more portions of the 2-D image. Each layer may be reproduced into a corresponding left eye and right eye layers that include a depth pixel offset corresponding to a perceived depth. Further, a volume effect may also be applied to one or more objects of the 2-D image by associating a volume pixel offset to one or more pixels of the image. Thus, any pixel of the 2-D image may have a depth pixel offset to provide a perceived depth as well as a volume pixel offset to provide a stereoscopic 3-D volume effect. In this manner, the 2-D image may be converted to a corresponding stereoscopic 3-D image with perceived depth and volume effects applied.

Abstract: A method for performing stereo composition using multiple camera pairs. The method includes positioning first and second pairs of virtual cameras for imaging an animated scene. The method includes, with the first and second pairs of the cameras, obtaining 3D data for each camera for the animated scene. Then, a blending region is selected by defining a first boundary surface for the first pair of the cameras and a second boundary surface, spaced a distance apart from the first boundary surface, for the second pair of the cameras, with the blending region being the space between the first and second boundary surfaces. The method includes, with a blending module or function, combining the 3D data from a number of consequent cameras. The blending module monotonically increases the stereoscopic disparity function in a viewing direction and combines the 3D data in a continuous manner, e.g., to insure C1 continuity.

Abstract: Implementations of the present invention involve methods and systems for converting a 2-D multimedia image to a 3-D multimedia image by utilizing a plurality of layers of the 2-D image. The layers may comprise one or more portions of the 2-D image and may be digitized and stored in a computer-readable database. The layers may be reproduced as a corresponding left eye and right eye version of the layer, including a pixel offset corresponding to a desired 3-D effect for each layer of the image. The combined left eye layers and right eye layers may form the composite right eye and composite left eye images for a single 3-D multimedia image. Further, this process may be applied to each frame of a animated feature film to convert the film from 2-D to 3-D.

Abstract: Implementations of the present invention involve methods and systems for converting a 2-D multimedia image to a 3-D multimedia image by utilizing a plurality of layers of the 2-D image. The layers may comprise one or more portions of the 2-D image and may be digitized and stored in a computer-readable database. The layers may be reproduced as a corresponding left eye and right eye version of the layer, including a pixel offset corresponding to a desired 3-D effect for each layer of the image. The combined left eye layers and right eye layers may form the composite right eye and composite left eye images for a single 3-D multimedia image. Further, this process may be applied to each frame of a animated feature film to convert the film from 2-D to 3-D.

Abstract: Implementations of the present invention involve methods and systems for converting a 2-D image to a stereoscopic 3-D image by segmenting one or more portions of the 2-D image based on one or more pixel color ranges. Further, a matte may be created that takes the shape of the segmented region such that several stereoscopic effects may be applied to the segmented region. In addition, ink lines that are contained within the segmented region may be removed to further define the corresponding matte. Implementations of the present disclosure also include a interface that provides the above functionality to a user for ease of segmentation and region selection. By utilizing the segmentation process, a 2-D image may be converted to a corresponding stereoscopic 3-D image with a perceived depth. Further, this process may be applied to each image of an animated feature film to convert the film from 2-D to 3-D.

Abstract: Implementations of the present invention involve methods and systems for converting a 2-D image to a stereoscopic 3-D image and displaying the depth of one or more pixels of the 3-D image through an output image of a user interface. The pixels of the output image display the perceived depth of the corresponding 3-D image such that the user may determine the relative depth of the pixels of the image. In addition, one or more x-offset values or z-axis positions may be individually selected such that any pixel of the output image that correspond to the selected values is indicated in the output image. By providing the user with a visualization tool to quickly determine the perceived position of any pixel of a stereoscopic image, the user may confirm the proper alignment of the objects of the image in relation to the image as a whole.

Abstract: Implementations of the present disclosure include an interface that provides display and management of depth and volume information for a stereoscopic 3-D image. More particularly, the interface provides information for the one or more layers that comprise the stereoscopic 3-D image. Depth information for the one or more layers of the stereoscopic image may include aspects of a pixel offset, z-axis position and virtual camera positions. The adjustment of one aspect of the depth information may affect the values for the other aspects of depth information for the layers. This information may be used by an animator to confirm the proper alignment of the objects and layers of the image in relation to the image as a whole. In addition, the interface may maintain such depth information for several stereoscopic 3-D images such that the information and adjustment to any number of 3-D images may be obtained through the interface.

Abstract: Implementations of the present invention involve methods and systems for creating depth and volume in a 2-D planar image to create an associated 3-D image by utilizing a plurality of layers of the 2-D image, where each layer comprises one or more portions of the 2-D image. Each layer may be reproduced into a corresponding left eye and right eye layers, with one or both layers including a pixel offset corresponding to a perceived depth. Further, a depth model may be created for one or more objects of the 2-D image to provide a template upon which the pixel offset for one or more pixels of the 2-D image may be adjusted to provide the 2-D image with a more nuanced 3-D effect. In this manner, the 2-D image may be converted to a corresponding 3-D image with a perceived depth.

Abstract: Implementations of the present invention involve methods and systems for converting a 2-D multimedia image to a 3-D multimedia image by utilizing a plurality of layers of the 2-D image. The layers may comprise one or more portions of the 2-D image and may be digitized and stored in a computer-readable database. The layers may be reproduced as a corresponding left eye and right eye version of the layer, including a pixel offset corresponding to a desired 3-D effect for each layer of the image. The combined left eye layers and right eye layers may form the composite right eye and composite left eye images for a single 3-D multimedia image. Further, this process may be applied to each frame of a animated feature film to convert the film from 2-D to 3-D.

Abstract: Implementations of the present disclosure involve methods and systems for creating depth and volume in a 2-D image by utilizing a plurality of layers of the 2-D image, where each layer comprises one or more portions of the 2-D image. Each layer may be reproduced into a corresponding left eye and right eye layers that include a depth pixel offset corresponding to a perceived depth. Further, a volume effect may also be applied to one or more objects of the 2-D image by associating a volume pixel offset to one or more pixels of the image. Thus, any pixel of the 2-D image may have a depth pixel offset to provide a perceived depth as well as a volume pixel offset to provide a stereoscopic 3-D volume effect. In this manner, the 2-D image may be converted to a corresponding stereoscopic 3-D image with perceived depth and volume effects applied.

Abstract: Implementations of the present invention involve methods and systems for converting a 2-D image to a stereoscopic 3-D image by segmenting one or more portions of the 2-D image based on one or more pixel color ranges. Further, a matte may be created that takes the shape of the segmented region such that several stereoscopic effects may be applied to the segmented region. In addition, ink lines that are contained within the segmented region may be removed to further define the corresponding matte. Implementations of the present disclosure also include a interface that provides the above functionality to a user for ease of segmentation and region selection. By utilizing the segmentation process, a 2-D image may be converted to a corresponding stereoscopic 3-D image with a perceived depth. Further, this process may be applied to each image of an animated feature film to convert the film from 2-D to 3-D.