Systems and methods facilitate autonomous image capture and/or picture production. A location unit is attached to each tracked object. An object tracking device receives location information from each location unit. A camera control device controls, based upon the location information, at least one motorized camera to capture image data of at least one tracked object.

Systems and methods facilitate autonomous image capture and/or picture production. A location unit is attached to each tracked object. An object tracking device receives location information from each location unit. A camera control device controls, based upon the location information, at least one motorized camera to capture image data of at least one tracked object.

Managing multiple devices, such as tracking beacons, is challenging, especially as the number of beacons increases. A beacon and a charging station are provided for managing the settings of the beacons. The beacon includes a display with a graphical user interface (GUI) for updating settings. The charging station includes charging ports and a display with a GUI for updating beacon settings.

The present invention is an information processing device that performs information processing to output (produce and distribute) video content using video from multiple video sources including network cameras, the information processing device comprising: a switching means for performing switching based on video signals transferred by the transfer method used to transfer data without confirming reception by the receiving node with the transmitting node at the video source; and an information processing means that outputs (produces and distributes) video content based on information indicating which video source was switched at what time by the switching means and based on video data outputted from the video sources.

An example system comprises a base with a bottom end and a top end opposite the bottom end, a motor within the base, the motor being coupled to a rotational component of the base and configured to turn the rotational component about an axis of rotation, the rotational component being at the top end of the base, the axis of rotation being perpendicular to the top end of the base, and an arm coupled to the rotational component, the arm configured to move a holding member above the top of the base, the holding member configurable to hold a digital device above the top end of the base, the arm being adjustable to position and tilt the holding member, the rotational component being capable of turning the arm and the holding member, the arm configured to tilt the holding member at a first angle relative to the arm.

An image-stream windowing method includes capturing, with a camera located at a fixed position and having a fixed field of view, a high-resolution image stream of an object that moves during said capturing. The high-resolution image stream includes a sequence of high-resolution frames. The method also includes determining, for each high-resolution frame of the sequence of high-resolution frames, a respective window, of a sequence of windows corresponding to the sequence of high-resolution frames, that encloses the object within said each high-resolution frame. The size and location of the respective window are determined based at least on the fixed position, the fixed field of view, and a position of the object. The method also includes generating a low-resolution image stream from the high-resolution image stream by cropping said each high-resolution frame with its respective window.

An image-stream windowing method includes capturing, with a camera located at a fixed position and having a fixed field of view, a high-resolution image stream of an object that moves during said capturing. The high-resolution image stream includes a sequence of high-resolution frames. The method also includes determining, for each high-resolution frame of the sequence of high-resolution frames, a respective window, of a sequence of windows corresponding to the sequence of high-resolution frames, that encloses the object within said each high-resolution frame. The size and location of the respective window are determined based at least on the fixed position, the fixed field of view, and a position of the object. The method also includes generating a low-resolution image stream from the high-resolution image stream by cropping said each high-resolution frame with its respective window.

The present invention provides a multi-viewpoint video image viewing system that allows a viewer to view a multi-viewpoint video content and removes in advance video images in which hands are hidden as a video image candidate. A first invention of the present application selects video images to be displayed on a video image display section in advance and presents the selected video images to a viewer by causing an information processing apparatus to perform hand-target image recognition on motion image (video image) data that includes image data captured with a plurality of video cameras and a frame string disposed in a time region to select video images showing a hand or not to select video images showing no hand.

An imaging system including an image sensor coupled to a controller to image an external scene is described. The controller includes logic storing instructions that when executed causes the imaging system to perform operations including capturing images, including a first image and a second image, of an external scene, and generating reduced representations of the images including a first reduced representation associated with the first image and a second reduced representation associated with the second image. The operations further include comparing the first reduced representation with the second reduced representation to determine a difference between the first image and the second image and identifying an occurrence of an occlusion affecting the image sensor imaging the external scene when the difference is greater than a threshold value.

Methods, systems, and devices for guiding a subject back within the recognizable visual range of a multimedia system are described. According to one of the described methods, when it is determined that the target has left the recognizable range of the multimedia system, sensor information is acquired from a portable electronic device (or controller) the user has been using to control the multimedia system, and the acquired sensor information is used to determine where the user is, relative to the recognizable range. In one example, the user is asked to make a gesture with the portable electronic device, and the sensor information concerning that gesture is used to determine the user's relative location. In another example, the sensor information recorded at the time the user left the recognizable range is used to determine the user's relative location.