Abstract: In various embodiments, the present invention provides a system and associated methods of calibration and use for an interactive imaging environment based on the optimization of parameters used in various segmentation algorithm techniques. These methods address the challenge of automatically calibrating an interactive imaging system, so that it is capable of aligning human body motion, or the like, to a visual display. As such the present invention provides a system and method of automatically and rapidly aligning the motion of an object to a visual display.

Abstract: In various embodiments, the present invention provides a system and associated methods of calibration and use for an interactive imaging environment based on the optimization of parameters used in various segmentation algorithm techniques. These methods address the challenge of automatically calibrating an interactive imaging system, so that it is capable of aligning human body motion, or the like, to a visual display. As such the present invention provides a system and method of automatically and rapidly aligning the motion of an object to a visual display.

Abstract: A computer-implemented method, a system, and software includes providing output from a touch-based device to an external display; detecting gestures from a user located away from and not physically touching the touch-based device; and translating the detected gestures into appropriate commands for the touch-based device. The systems and methods provide alternative control of touch-based devices such as mobile devices. The systems and methods can include a mobile device coupled to an external display device and controlled via user gestures monitored by a collocated sensor. Accordingly, the systems and methods allow users to operate applications (“apps”) on the mobile device displayed on the external display device and controlled without touching the mobile device using gestures monitored by the collocated sensor. This enables the wide variety of rich apps to be operated in a new manner.

Abstract: Systems and methods for simulating accessory display on a subject are described herein. At least one digital image of a subject is obtained. At least one target contour in an accessory target zone is identified. An accessory image and an accessory foreground matte, and a plurality of accessory control points associated with at least one contour contact zone are obtained. At least one accessory scaling factor is determined. At least one accessory registration angle is determined based on the at least one digital image. At least one simulated image is generated by registering a foreground portion of the accessory image with the at least one digital image based on the at least one accessory scaling factor, the at least one accessory registration angle, the accessory foreground matte, the at least one target contour, and the plurality of accessory control points, where registering includes applying a transformation.

Abstract: A method for simulating accessory display on a subject. An accessory is coupled with a mount with at least one contact portion configured to contact the accessory. The mount is positioned in at least one orientation with respect to an imaging device. At least one accessory image is captured of the accessory coupled with the mount in the at least one orientation using the imaging device. At least one accessory matte image is captured. At least one accessory foreground matte is generated for the at least one accessory. An accessory background matte is generated for the at least one accessory.

Abstract: The present disclosure provides a system and method for enabling meaningful body-to-body interaction with virtual video-based characters or objects in an interactive imaging environment including: capturing a corpus of video-based interaction data, processing the captured video using a segmentation process that corresponds to the capture setup in order to generate binary video data, labeling the corpus by assigning a description to clips of silhouette video, processing the labeled corpus of silhouette motion data to extract horizontal and vertical projection histograms for each frame of silhouette data, and estimating the motion state automatically from each frame of segmentation data using the processed model. Virtual characters or objects are represented using video captured from video-based motion, thereby creating the illusion of real characters or objects in an interactive imaging experience.

Abstract: The present disclosure provides a system and method for enabling meaningful body-to-body interaction with virtual video-based characters or objects in an interactive imaging environment including: capturing a corpus of video-based interaction data, processing the captured video using a segmentation process that corresponds to the capture setup in order to generate binary video data, labeling the corpus by assigning a description to clips of silhouette video, processing the labeled corpus of silhouette motion data to extract horizontal and vertical projection histograms for each frame of silhouette data, and estimating the motion state automatically from each frame of segmentation data using the processed model. Virtual characters or objects are represented using video captured from video-based motion, thereby creating the illusion of real characters or objects in an interactive imaging experience.

Abstract: The present invention provides a light-emitting apparatus and a method by which a crowd-based display is created wherein each light-emitting apparatus represents one of many independently moving pixels in the crowd-based display. This invention also provides methods, both internal and external to the light-emitting apparatus, by which the visual display sequence is controlled to provide various forms of colorful illumination. This invention discloses a shock wave method, a time-synchronized playback method, and a laser-based actuation method for creating the visual displays of illumination.

Abstract: In various embodiments, the present invention provides a system and associated methods of calibration and use for an interactive imaging environment based on the optimization of parameters used in various segmentation algorithm techniques. These methods address the challenge of automatically calibrating an interactive imaging system, so that it is capable of aligning human body motion, or the like, to a visual display. As such the present invention provides a system and method of automatically and rapidly aligning the motion of an object to a visual display.

Abstract: In various embodiments, the present invention provides a system and associated methods of calibration and use for an interactive imaging environment based on the optimization of parameters used in various segmentation algorithm techniques. These methods address the challenge of automatically calibrating an interactive imaging system, so that it is capable of aligning human body motion, or the like, to a visual display. As such the present invention provides a system and method of automatically and rapidly aligning the motion of an object to a visual display.

Abstract: The present invention provides a system and method for enabling meaningful body-to-body interaction with virtual video-based characters or objects in an interactive imaging environment including: capturing a corpus of video-based interaction data, processing the captured video using a segmentation process that corresponds to the capture setup in order to generate binary video data, labeling the corpus by assigning a description to clips of silhouette video, processing the labeled corpus of silhouette motion data to extract horizontal and vertical projection histograms for each frame of silhouette data, and estimating the motion state automatically from each frame of segmentation data using the processed model. Virtual characters or objects are represented using video captured from video-based motion, thereby creating the illusion of real characters or objects in an interactive imaging experience.

Abstract: The present invention provides a light-emitting apparatus and a method by which a crowd-based display is created wherein each light-emitting apparatus represents one of many independently moving pixels in the crowd-based display. This invention also provides methods, both internal and external to the light-emitting apparatus, by which the visual display sequence is controlled to provide various forms of colorful illumination. This invention discloses a shock wave method, a time-synchronized playback method, and a laser-based actuation method for creating the visual displays of illumination.

Abstract: The present invention provides a light-emitting apparatus and a method by which a crowd-based display is created wherein each light-emitting apparatus represents one of many independently moving pixels in the crowd-based display. This invention also provides methods, both internal and external to the light-emitting apparatus, by which the visual display sequence is controlled to provide various forms of colorful illumination. This invention discloses a shock wave method, a time-synchronized playback method, and a laser-based actuation method for creating the visual displays of illumination.