Methods for encoding and decoding high-dynamic range signals are presented. The signals are encoded in a high frame rate and are accompanied by frame-rate conversion metadata defining a preferred set of frame-rate down-conversion parameters, which are determined according to the maximum luminance of a target display, display playback priority modes, or judder control modes. A decoder uses the frame-rate conversion metadata to apply frame-rate down-conversion to the input high-frame-rate signal according to at least the maximum luminance of the target display and/or the characteristics of the signal itself. Frame-based and pixel-based frame-rate conversions, and judder models for judder control via metadata are also discussed.

A transmission method in the present disclosure includes; obtaining an image and image signal characteristics information indicating one of an opto-electrical transfer function (OETF) or an electro-optical transfer function (EOTF) as image signal characteristics of the image; and transmitting a signal including the image and the image signal characteristics information. According to the transmission method in the present disclosure, a receiving device that received a high dynamic range (HDR) image and a standard dynamic range (SDR) image transmitted through broadcasting or the like can display these images appropriately.

A conversion method for converting luminance of a video, including a luminance value in a first luminance range, to be displayed on a display apparatus includes: acquiring a first luminance signal indicating a code value obtained by quantization of the luminance value of the video; and converting the code value indicated by the acquired first luminance signal into a second luminance value determined based on a luminance range of the display apparatus, the second luminance value being compatible with a second luminance range with a maximum value smaller than a maximum value of the first luminance range and larger than 100 nit. This provides the conversion method capable of achieving further improvement.

An HDMI source conversion device according to one aspect of the disclosure includes an HDMI interface, an IP interface, and a converter. The HDMI interface receives a first signal based on the HDMI communication protocol. The IP interface receives address information from a control device via a network based on the Internet protocol, the control device being connected to the network, and the address information indicating the address on the network of an HDMI sink conversion device that is a device different from the control device. The converter converts the first signal based on the HDMI communication protocol into a second signal based on the Internet protocol by adding at least the address information to the first signal received by the HDMI interface. The IP interface transmits the second signal to the HDMI sink conversion device via the network.

Method and device of transmitting and receiving ultra high video are provided. The method of transmitting ultra high definition video includes: acquiring ultra high definition video; compressing data, by a compression algorithm to obtain compressed data, of the ultra high definition video; packing the compressed data into user datagram protocol (UDP) data packets; transmitting the UDP data packets to a first 10-gigabit network module according to a UDP protocol. The compressed data is packaged into the UDP data packets and the UDP data packets are transmitted by the 10-gigabit network module, thereby realizing the high-efficiency transmission of video data based on the 10-gigabit network and UDP protocol stack. A transmission system is also provided.

A semiconductor device which performs upconversion without a large amount of learning data is provided. The semiconductor device increasing the resolution of a first image data to generate a high-resolution image data. It includes the first step of generating a second image data by decreasing the resolution of the first image data, the second step of generating a third image data having a higher resolution than the second image data by inputting the second image data to a neural network, the third step of calculating an error for the third image data relative to the first image data by their comparison, and the fourth step of modifying a weight coefficient of the neural network on the basis of the error; and then the high resolution image data is generated by inputting the first image data into the neural network after a prescribed number of the second to fourth steps.

There is a problem that video data cannot be relayed from a transmission device having an HDMI connector to a receiving device having a USB Type-C connector. In order to solve the above problem, each of a receiving device having an HDMI reception function unit and a relay device, such as a conversion cable for relaying video data from a transmission device, is made to have a function of determining the other devices. By performing switching of a terminator or a protection element between valid and invalid or performing signal connection switching based on the determination result of the function unit, the above problem can be solved. In addition, it is also possible to realize reverse insertion connection for reversing the video data transmission direction of the relay device.

According to one implementation, a system for differentially transforming video content includes a computing platform having a hardware processor and a system memory storing a video reformatting software code. The hardware processor executes the video reformatting software code to receive an input video file including video content formatted for a first set of coordinates, and to detect one or more principle features depicted in the video content based on a predetermined principle feature identification data corresponding to the video content. The hardware processor further executes the video reformatting software code to differentially map the video content to a second set of coordinates to produce a reformatted video content. The resolution of the one or more principle features is enhanced relative to other features depicted in the reformatted video content.

A low-resolution image is displayed at high resolution and power consumption is reduced. Resolution is made higher by super-resolution processing. Then, display is performed with the luminance of a backlight controlled by local dimming after the super-resolution processing. By controlling the luminance of the backlight, power consumption can be reduced. Further, by performing the local dimming after the super-resolution processing, accurate display can be performed.

A video processing system includes a main chip and a processing chip. The main chip receives first data. The processing chip is coupled to the main chip, and receives second data and to perform a video processing on at least one of the first data transmitted from the main chip and the second data, in order to drive a display panel. First video carried on the first data or second video on the second data has a first resolution, and the first resolution is at least 8K ultra high definition.