A video recording system for a head safety device includes a microcontroller and an accelerometer mounted in the head safety device. The accelerometer is coupled to the microcontroller. A plurality of camera modules are mounted on the head safety device and coupled to the microcontroller. The camera modules are positioned facing outward to obtain images at different angles of an environment surrounding the head safety device. The microcontroller receives data from the accelerometer and automatically initiates video recording with the camera modules when movement of the head safety device, as sensed using the accelerometer, reaches or exceeds a selected movement threshold.

The present technology relates to a reproduction device, a reproduction method, and a recording medium capable of displaying graphics with a broader dynamic range of luminance and appropriate brightness. The reproduction device reads a Tone_map stream and a graphics stream of an extended graphics from a recording device, wherein the recording device records the Tone_map stream including HDR information indicating a luminance feature of the extended graphics which are first graphics with a first luminance range different from and broader than a second luminance range, and a luminance conversion definition information used in luminance conversion from the extended graphics to standard graphics. The standard graphics are graphics with the second luminance range. The reproduction device converts the extended graphics into the standard graphics based on the luminance conversion definition information of the extended graphics included in the Tone map stream.

A display apparatus connected to an external apparatus that executes a recording process for image data. A display panel displays an image based on received image data. A memory storing a program executed by the processor causes the display apparatus to set an image-quality adjusting parameter for the received image data, to execute an image-quality adjusting process on the received image data using the image-quality adjusting parameter set for the received image data, to detect a start of the recording process for the image data executed by the external apparatus, and to perform control in which, in response to the detection of the start of the recording process for the image data executed by the external apparatus, the image-quality adjusting parameter that has been set for the received image data is automatically recorded in a storage as an image-quality adjusting parameter corresponding to the data recorded by the external apparatus.

A billiard table top lighting apparatus provides substantially uniform lighting across the surface of a billiard table surface. The frame may support one or more cameras, one or more motion sensors, one or more microphones, and/or one or more computing devices to enable any of a variety of innovative features. Such features could include automatic game play recording from one or more perspectives, merged video track storage for replay, review, and analysis, automatic lighting and dimming control, control of the apparatus from any mobile device, automatic provision of a shot clock, and the like.

A method for processing image information has accessing position information associated with images, identifying a position sequence that provides a series of locations along a pathway corresponding to a subject, and displaying the images in an order of the position sequence. The position sequence is adjusted based on movement of the subject.

A verification system includes: a code generation server publicizing time stamped codes; a proving device, including a video camera, that acquires a published time stamped code from the code generation server, and, while recording a video, incorporates the acquired time stamped code into the video; and a verifying device that receives the video, extracts the time stamped code from the content of the video, compares the time stamped code to published time stamped codes, and displays a verification of the published time stamped code.

Aspects of the present invention are drawn to a server device for use with a stream of encoded A/V data and an n×m array of client devices. The server device includes a memory and a processor. The memory causes the server device to decode the A/V data to gain access to decoded video data and decoded audio data, as well as determining the configuration of the n×m array of client devices. The memory causes the server device to separate the decoded video data into n times m distinct video data payloads and encode n times m converted streams of encoded A/V data. The memory additionally causes the server device to transmit the n times m encoded subdivided streams to the n×m array of client devices, respectively, based on the determined configuration of the n×m array of client devices.

A system includes a recorder configured to record audio and/or video of a subject of interest and output a recording of the subject of interest and a non-contact sensor associated with the recorder. The non-contact sensor is constructed and arranged to measure movement and/or vibration of the subject of interest from substantially the same perspective and at the same time as the recorder. The system includes a controller configured to transform the measured movement and/or vibration of the subject of interest measured by the non-contact sensor into a tactile data stream for sending to a haptic display device for playback with the recording of the subject of interest by the recorder and providing haptic effects corresponding to the measured movement and/or vibration to a user of the haptic display device in synchronization with the recording.

Methods and systems are disclosed including a computing device configured to allow a user to view a multi-stream video from a selected angle/direction with respect to the contents of the multi-stream video, under the user's control. The multi-stream video is generated using multiple Image Acquisition Devices (IAD), such as cameras, simultaneously, consecutively, or independently filming a scene, each IAD having a different position with respect to each of the other IADs. Each image data stream obtained from each IAD may be uniquely identified to allow selective real-time playback of image data streams under user control. Each image data stream represents a corresponding viewing angle to the user. The user may dynamically change the selection of an image stream, and thus the viewing angle, while viewing a recorded scene. Multiple image streams of the same scene may be selected and viewed simultaneously to provide 3D or other visual effects.

Various embodiments of the present invention relate generally to systems and processes for transforming a style of video data. In one embodiment, a neural network is used to interpolate native video data received from a camera system on a mobile device in real-time. The interpolation converts the live native video data into a particular style. For example, the style can be associated with a particular artist or a particular theme. The stylized video data can viewed on a display of the mobile device in a manner similar to which native live video data is output to the display. Thus, the stylized video data, which is viewed on the display, is consistent with a current position and orientation of the camera system on the display.