A multi-format digital video production system is capable of maintaining full-bandwidth resolution of subject material while providing professional quality editing and manipulation of images intended for digital television and other applications, including digital HDTV programs and specialized video monitoring applications. This allows emerging broadband video transmission media, including Internet broadcast schemes, to overcome existing technology limitations. The approach facilitates high-quality/large-screen video production and monitoring through the use of conventional broadband channels, including those which currently only exhibit bandwidths on the order of 4 Mbps. In formats utilizing substantially 24 fps progressive scan multi-format system, direct streaming is made possible from HDTV (16:9) high-quality data, thereby expanding market applications which require these higher levels of resolution, bits per pixel, and so forth.

Disclosed are a signal processing device and an image display apparatus including the same. The signal processing device of an embodiment of the present disclosure includes: a quality calculator configured to calculate an source quality of an image signal received from an external settop box or a network; an image quality setter configured to set an image quality of the image signal based on the calculated source quality; and an image quality processor configured to perform image quality processing on the image signal based on the set image quality, wherein in response to the source quality of the received image signal being changed at a first time point, the image quality setter changes an image quality setting sequentially from a first setting to a second setting; and based on the image quality setting, the image quality processor performs image quality processing. Accordingly, flicker may be reduced when an image quality is changed due to a change in the source quality of the received image signal.

A system and method to facilitating selecting or otherwise providing access to electronic content and services. Access to the content and services may be provided in such as a manner as to facilitate access to higher quality forms of the content. The higher quality forms of the content may be relate to any number of characteristics associated with displaying, transmitting, compressing, securing, and/or otherwise manipulating the content to more suitable forms relative to another form.

A system and method to facilitating selecting or otherwise providing access to electronic content and services. Access to the content and services may be provided in such as a manner as to facilitate access to higher quality forms of the content. The higher quality forms of the content may be relate to any number of characteristics associated with displaying, transmitting, compressing, securing, and/or otherwise manipulating the content to more suitable forms relative to another form.

A video signal conversion device includes a frontend interface circuit, a FPGA video processor and a backend interface circuit. The frontend interface circuit receives a HDR video input signal from a video transmitting device. The FPGA video processor outputs a SDR first video output signal. A video receiving device receives the first video output signal and a HDR second video output signal from the FPGA video processor through the video bridge controller of the backend interface circuit by PCI-E.

An electronic device includes a first interface configured to obtain a first media data of a first source device; a second interface configured to obtain a second media data of a second source device; a processing device configured to generate a third media data; and an output device configured to output media data. The media data may be the first media data, the second media data, or the third media data. The third media data affects the first media data or the second media data if the third media data and the first media data are simultaneously outputted, or the third media data and the second media data are simultaneously outputted. The processing device is configured to process the first media data and the second media data to obtain a processing result, the processing result being used to generate presentation data indicating correspondences between interfaces and the media data.

An electronic device includes a first interface configured to obtain a first media data of a first source device; a second interface configured to obtain a second media data of a second source device; a processing device configured to generate a third media data; and an output device configured to output media data. The media data may be the first media data, the second media data, or the third media data. The third media data affects the first media data or the second media data if the third media data and the first media data are simultaneously outputted, or the third media data and the second media data are simultaneously outputted. The processing device is configured to process the first media data and the second media data to obtain a processing result, the processing result being used to generate presentation data indicating correspondences between interfaces and the media data.

A graphics adjustment system detects the video resolution of digital video to be output by a receiving device and saves the graphics settings input by the user when the user adjusts the graphics settings on the receiving device such that the digital video being presented in the presentation device is not cut off due to overscanning. The system saves the graphics adjustment settings as the setting to use going forward for digital video of that same resolution for that particular presentation device. In this manner, the digital video output from the receiving device will not be cut off when presented on the presentation device, even when the receiving device is switching between receiving digital video programming of different resolutions from various program distributors and/or the content providers.

A graphics adjustment system detects the video resolution of digital video to be output by a receiving device and saves the graphics settings input by the user when the user adjusts the graphics settings on the receiving device such that the digital video being presented in the presentation device is not cut off due to overscanning. The system saves the graphics adjustment settings as the setting to use going forward for digital video of that same resolution for that particular presentation device. In this manner, the digital video output from the receiving device will not be cut off when presented on the presentation device, even when the receiving device is switching between receiving digital video programming of different resolutions from various program distributors and/or the content providers.

A graphics adjustment system detects the video resolution of digital video to be output by a receiving device and saves the graphics settings input by the user when the user adjusts the graphics settings on the receiving device such that the digital video being presented in the presentation device is not cut off due to overscanning. The system saves the graphics adjustment settings as the setting to use going forward for digital video of that same resolution for that particular presentation device. In this manner, the digital video output from the receiving device will not be cut off when presented on the presentation device, even when the receiving device is switching between receiving digital video programming of different resolutions from various program distributors and/or the content providers.