A method and device for reversible story are provided. The method includes: when presenting a media stream of a current story, detecting a request performed by a user for generating an alternative story corresponding to the current story; in response to the request for generating the alternative story, determining a target path in a hyperstory, the hyperstory including multiple paths corresponding to multiple stories that describe different status change trends of one or more story characters, and the target path sharing a same initial segment with a path of the current story in the hyperstory and including a branch point where a story trend change occurs; determining a media stream of the alternative story according to the target path; and presenting the media stream of the alternative story.

According to a vehicle display system, a mobile terminal apparatus includes: a primary-screen-view display section that displays an output screen-view generated with execution of an application on the mobile terminal apparatus as a primary screen-view; a conversion section that converts the primary screen-view into a secondary screen-view complying with a vehicle apparatus; a manipulation layer generation section that generates a manipulation layer to manipulate the application; a state layer generation section that generates a state layer indicating a state of the mobile terminal apparatus; and a transmission section that transmits the secondary screen-view, the manipulation layer, and the state layer to the vehicle apparatus. The vehicle apparatus includes a secondary-screen-view display section that displays the manipulation layer and the state layer on the vehicle apparatus itself together with the secondary screen-view.

Reception-side processing performed in a case where transmission of standard dynamic range video data and transmission of high dynamic range video data coexist in a time sequence is simplified.

SDR transmission video data is converted into SDR transmission video data through dynamic range conversion. The SDR transmission video data is the one obtained by performing, on SDR video data, photoelectric conversion in accordance with an SDR photoelectric conversion characteristic. In this case, the conversion is performed on the basis of conversion information for converting a value of conversion data in accordance with the SDR photoelectric conversion characteristic into a value of conversion data in accordance with an HDR photoelectric conversion characteristic. A video stream is obtained by performing encoding processing on HDR transmission video data. A container having a predetermined format and including this video stream is transmitted.

Reception-side processing performed in a case where transmission of standard dynamic range video data and transmission of high dynamic range video data coexist in a time sequence is simplified.

SDR transmission video data is converted into SDR transmission video data through dynamic range conversion. The SDR transmission video data is the one obtained by performing, on SDR video data, photoelectric conversion in accordance with an SDR photoelectric conversion characteristic. In this case, the conversion is performed on the basis of conversion information for converting a value of conversion data in accordance with the SDR photoelectric conversion characteristic into a value of conversion data in accordance with an HDR photoelectric conversion characteristic. A video stream is obtained by performing encoding processing on HDR transmission video data. A container having a predetermined format and including this video stream is transmitted.

Embodiments of the present disclosure may provide a video file processing method, including: receiving a splitting instruction of a video file; determining splitting nodes corresponding to the splitting instruction; splitting the video file to multiple sub-video files using the splitting nodes; and storing the multiple sub-video files. Embodiments of the present disclosure may further provide a video file processing device. With the embodiments of the present disclosure, the video file may be segmentally displayed, which may optimize management of the video file.

Embodiments of the present disclosure may provide a video file processing method, including: receiving a splitting instruction of a video file; determining splitting nodes corresponding to the splitting instruction; splitting the video file to multiple sub-video files using the splitting nodes; and storing the multiple sub-video files. Embodiments of the present disclosure may further provide a video file processing device. With the embodiments of the present disclosure, the video file may be segmentally displayed, which may optimize management of the video file.

Disclosed is a system and method for reducing the total latency for transferring a frame from the low latency camera system mounted on an aerial vehicle to the display of the remote controller. The method includes reducing the latency through each of the modules of the system, i.e. through a camera module, an encoder module, a wireless interface transmission, wireless interface receiver module, a decoder module and a display module. To reduce the latency across the modules, methods such as overclocking the image processor, pipelining the frame, squashing the processed frame, using a fast hardware encoder that can perform slice based encoding, tuning the wireless medium using queue sizing, queue flushing, bitrate feedback, physical medium rate feedback, dynamic encoder parameter tuning and wireless radio parameter adjustment, using a fast hardware decoder that can perform slice based decoding and overclocking the display module are used.

A method includes capturing, using an Internet of Things (IoT) device, real-time video of a user performing an exercise associated with a first exercise class. Real-time video of the user is displayed, via a display, concurrently with video of an instructor, to provide a visual comparison of the user to the instructor. Image analysis of the real-time video of the user is performed to determine a performance of the user, and a representation thereof is displayed. Biometric data associated with the user is received at the IoT device from a wearable device at multiple points in time. Heart rates are identified based on the biometric data, and scores based on the heart rates are displayed via the display. A recommendation for a second exercise class different from the first exercise class is determined based on a profile of the user, and displayed via the display.

A broadcast signal transmission method comprises outputting an RoHC channel that includes one or more RoHC streams and a signaling table that includes information related to header compression by performing header compression for Internet Protocol (IP) packets, which include broadcast data, in accordance with an adaptation mode, a header of each IP packet including an IP header and a User Datagram Protocol (UDP) header, generating at least one first link layer packet that includes the RoHC channel and generating at least one second link layer packet that includes the signaling table, and physical layer processing the at least one first link layer packet and the at least one second link layer packet and transmitting through one or more Physical Layer Pipes (PLPs), wherein the signaling table includes adaptation mode information indicating the adaptation mode, and each RoHC stream in the RoHC channel includes RoHC packets.

Provided are a signal processing device and an image display apparatus including the same. The signal processing device and the image display apparatus including the same include: a signal processor 170a may include an OSC processor configured to upscale an OSC having a first resolution to a second resolution greater than the first resolution; and a synthesizer configured to synthesize at least a part of an image having the second resolution and the upscaled OSD having the second resolution, and the OSD processor outputs the OSD having the second resolution, in which luminance and transparency are adjusted.