Systems and methods are disclosed including a moving platform system suitable for mounting and use on a moving platform for communicating in real-time, comprising: a position system monitoring location of the moving platform and generating a sequence of time-based position data; a non-line of sight communication system; a high-speed line of sight communication system; and a computer system monitoring an availability of the non-line of sight communication system and the high-speed line of sight communication system and initiating connections when the non-line of sight communication system and the high-speed line of sight communication system are available, and receiving the sequence of time-based position data and transmitting the sequence of time-based position data via the at least one of the currently available non-line of sight communication system and the high-speed line of sight communication system.

The present technology ensures that electrooptical conversion processing for transmission video data obtained using an HDR optoelectrical conversion characteristic is favorably carried out at a receiving side. The transmission video data is obtained by performing high dynamic range optoelectrical conversion on high dynamic range video data. A video stream is obtained by applying encoding processing to this transmission video data. A container in a predetermined format including this video stream is transmitted. Meta information indicating an electrooptical conversion characteristic corresponding to a high dynamic range optoelectrical conversion characteristic is inserted into a parameter set field in the video stream.

The present disclosure relates to a health monitoring television, comprising: a physiological parameter acquisition device for acquiring a physiological parameter of a monitored object; a central processor for generating health monitoring information based on the acquired physiological parameter; and an information exhibition device for outputting the health monitoring information to a user. The health monitoring television according to the present disclosure endows the commonly used television in ordinary families with the health monitoring function, i.e., adding the central processor and the physiological parameter acquisition device, so as to enable the monitored object, particularly the old people, to learn their own physical status easily through direct visual and/or audible information.

The present disclosure describes a method for creating data products in real-time with the aid of a ground station system. The method includes the steps of monitoring one or more communication links for newly captured sensor data and positional data of oblique images, saving the sensor data and positional data to one or more directories of one or more computer readable media, monitoring the one or more directories of one or more computer readable media for sensor data and positional data, processing the sensor data and positional data to create one or more data products for use by one or more mapping and exploitation systems responsive to the sensor data and positional data being saved in the one or more directories, and storing the one or more data products to one or more directories of one or more computer readable media.

The present technology ensures that electrooptical conversion processing for transmission video data obtained using an HDR optoelectrical conversion characteristic is favorably carried out at a receiving side. The transmission video data is obtained by performing high dynamic range optoelectrical conversion on high dynamic range video data. A video stream is obtained by applying encoding processing to this transmission video data. A container in a predetermined format including this video stream is transmitted. Meta information indicating an electrooptical conversion characteristic corresponding to a high dynamic range optoelectrical conversion characteristic is inserted into a parameter set field in the video stream.

A transmission apparatus includes a video obtainer configured to obtain a video signal, a first converter configured to convert the video signal into an electrical signal complying with a high definition multimedia interface (HDMI (registered trademark)) standard, a second converter configured to convert the video signal into an optical signal, and a signal processor configured to perform at least one of the conversion using the first converter and the conversion using the second converter with respect to the obtained video signal.

An active optical fiber HDMI connecting device, having a transmitting terminal, a receiving terminal, optical fibers, and a power source module; the power source module provides power to the transmitting terminal and the receiving terminal; the transmitting terminal includes a signal input module and an electro/optical (E/O) conversion module; the receiving module comprises an optical/electro (O/E) conversion module and a signal receiving module; the signal input module inputs digital electro signals to the E/O conversion module; the E/O conversion module converts the digital electro signals to optical signals; the optical fibers transmit the optical signals to the O/E conversion module; the O/E conversion module converts the optical signals to digital electro signals; the signal receiving module receives the digital electro signals converted by the O/E conversion module.

The present technology ensures that electrooptical conversion processing for transmission video data obtained using an HDR optoelectrical conversion characteristic is favorably carried out at a receiving side. The transmission video data is obtained by performing high dynamic range optoelectrical conversion on high dynamic range video data. A video stream is obtained by applying encoding processing to this transmission video data. A container in a predetermined format including this video stream is transmitted. Meta information indicating an electrooptical conversion characteristic corresponding to a high dynamic range optoelectrical conversion characteristic is inserted into a parameter set field in the video stream.

A method for generating high dynamic range (HDR) image data is provided. The method includes: performing image enhancement on first image data represented in a first color space, and accordingly generating second image data, in which the first image data is produced using a first opto-electronic transfer function for standard dynamic range (SDR) content; converting the second image data into third image data represented in a second color space, in which a color gamut of the second color space is wider than a color gamut of the first color space; performing dynamic range adjustment on the third image data to generate fourth image data, in which the bit depth of the fourth image data is greater than the bit depth of the third image data; and converting the fourth image data into the HDR image data based on a second opto-electronic transfer function for HDR content.

The present technology ensures that electrooptical conversion processing for transmission video data obtained using an HDR optoelectrical conversion characteristic is favorably carried out at a receiving side. The transmission video data is obtained by performing high dynamic range optoelectrical conversion on high dynamic range video data. A video stream is obtained by applying encoding processing to this transmission video data. A container in a predetermined format including this video stream is transmitted. Meta information indicating an electrooptical conversion characteristic corresponding to a high dynamic range optoelectrical conversion characteristic is inserted into a parameter set field in the video stream.