Aspects of the present disclosure are directed to a method for focusing a camera. In one embodiment, the method includes: dividing the field of view of the camera in to at least two segments: assigning, in each case, at least one operating element or at least one position of an operating element to the at least two segments; recognizing and tracking at least one object in at least two segments; automatically assigning the recognized at least two objects to the respective operating element or position of the operating element depending on which segment the objects are assigned to; and focusing the camera on the object assigned to the operating element or the position of the operating element in response to the operating element being actuated or the operating element being brought into the corresponding position.

A background display system for a virtual image recording studio comprises a background display device which is configured to display, behind or above a real subject, a representation of a virtual background for a recording by means of an associated camera, and a control device which is configured to control the background display device. The control device comprises a data input for receiving lens data from the associated camera and is configured to adjust the representation of the virtual background in dependence of the received lens data.

The present disclosure provides a camera signal monitoring apparatus and method, the camera signal monitoring apparatus including a processor, which includes a vehicle information input unit for receiving a vehicle speed and a yaw rate signal of a vehicle; a camera information input unit for receiving a camera signal including a vehicle speed and a yaw rate signal from a vehicle front camera; and a monitoring unit for calculating a vehicle driving trajectory using the vehicle speed and the yaw rate signal of the vehicle input from the vehicle information input unit, calculating a reference curvature value based on the calculated vehicle driving trajectory, and determining a reliability by comparing the calculated reference curvature value with a curvature value calculated by the camera signal input from the camera information input unit.

A system and method that recognizes and highlights objects in a video frame for augmented video production workflow. Ae video production camera is provided to capture a video frame and generate frame data and object data relating to objects within the video frame that are in focus. Moreover, a display device is included that is wearable by the camera operator and includes a camera that captures field of view data that corresponds to a field of view of the camera operator. Furthermore, the display device can compare the video frame data with the field of view data captured by the camera to generate visual indicators for the video frame and the in focus objects. As a result, the display device can provide the camera operator with a field of view having visual indicators of the video frame and the objects that appears as overlays over the operator's field of view.

Devices, systems and methods are disclosed for improving facial recognition and/or speaker recognition models by using results obtained from one model to assist in generating results from the other model. For example, a device may perform facial recognition for image data to identify users and may use the results of the facial recognition to assist in speaker recognition for corresponding audio data. Alternatively or additionally, the device may perform speaker recognition for audio data to identify users and may use the results of the speaker recognition to assist in facial recognition for corresponding image data. As a result, the device may identify users in video data that are not included in the facial recognition model and may identify users in audio data that are not included in the speaker recognition model. The facial recognition and/or speaker recognition models may be updated during run-time and/or offline using post-processed data.

Disclosed herein are systems and methods for controlling luminance during video production and broadcast. An exemplary system includes a camera to capture video content in a first imaging range, a histogram calculator to evaluate luminance in each pixel in the captured video content, and to generate a luminance histogram for the captured video content, a user interface generator that generates a user interface displaying the video content overlaid with the luminance histogram and generates a user interface displaying a light intensity curve and adjustable parameters for converting the first range into a second range, a luminance controller to convert luminance of the video content into the second imaging range based on the light intensity curve, and a broadcast controller to encode the video content with the second imaging range into broadcast range for transmitting to one or more endpoint devices.

A content production management system within a distributed studio environment includes a command interface module and a command queue management module. The command interface module is configured to render a user interface for a set of content production entities associated with a set of content production volumes within the distributed studio environment. The command queue management module, upon execution of software instructions, is configured to perform the operations of receiving, from the command interface module, a command targeting a target content production entity, assigning a synchronized execution time to the command, enqueueing the command into a command queue associated with the target content production entity according to the synchronized execution time, and enabling the target content production entity to execute the command from the command queue according to the synchronized execution time.

An image capturing apparatus includes an image capturing unit configured to capture an image of an object, a driving unit configured to change an image capturing direction of the image capturing unit, a control unit configured to control the driving unit, and, a reception unit configured to receive first tally information from another apparatus, wherein the control unit is configured to control, in a case where the reception unit does not receive the first tally information, the driving unit to set a maximum speed of the driving unit at a first driving speed, and control, in a case where the reception unit receives the first tally information, the driving unit to set the maximum speed at a second driving speed lower than the first driving speed.

A system includes an image capture device including a plurality of image sensors that are each configured to capture a mutually distinct visual of a scene. Further, a spatial data device is included that is configured to generate and transmit a signal, and to receive reflections of the signal from a plurality of objects within the scene, and to convey information corresponding to respective positions of the plurality of objects. At least one processor is configured to generate an image using at least one captured visual of the scene by at least one of the plurality of image sensors and using a measurement associated with the information conveyed by the spatial data device.

A production slate device may include a first arm having a first distal end, and a second arm having a second distal end. A hinge may movably couple the arms together so that the first distal end and second distal end form the portions of the arms that are distal to the hinge, and the hinge may enable the device to be moved into and between a closed position, in which the distal ends are proximate to or in contact with each other, and an open position, in which the distal ends are moved apart from each other. A board plate may be coupled to the second arm. The board plate may have a board length dimension (BL), and the second arm may have a total length dimension (TL). Preferably, the BL is less than 80 percent of the TL.