A transmission system including a transmission device capable of transmitting a video signal, and a reception device capable of receiving the video signal transmitted by the transmission device, the transmission system includes: a processor connected to a memory; a video transmission circuit and a video reception circuit that transmit the video signal between the transmission device and the reception device; a transmission-side data transceiving circuit and a reception-side data transceiving circuit that transmit a data signal between the transmission device and the reception device, wherein the processor is configured to selectively execute a video signal transmission mode in which transmission of the video signal is performed and transmission of the data signal superimposed on the video signal is performed, and a data signal transmission exclusive mode in which transmission of the video signal is stopped and transmission of the data signal is performed.

Conventionally, in a transparent display area, a gradation value of each color component is assigned to transparent gradation. Hence, when video is displayed in a video display area, each color component can only be represented in gradations with a gradation value of 0 to 1022, and it becomes necessary to assign pixel values to the transparent gradation. Accordingly, a color represented by those pixel values cannot be displayed. In view of this, by adding transparent area information to a vertical blanking period of a video signal, the pixel values can also be used to display video. By this, each of the color components can be represented in gradations with a gradation value of 0 to 1023, and thus, video can be displayed in full-range color even when a transparent display area is provided.

A transmitting device for communicating via a multimedia communication link includes a compression circuitry that receives blanking period data corresponding to blanking states of video blanking periods. The compression circuitry compresses the blanking period data into compressed blanking period data. The transmitting device also includes an interface that transmits signals corresponding to the compressed blanking period data via one or more multimedia channels of the multimedia communication link.

A transmitting device for communicating via a multimedia communication link includes a compression circuitry that receives blanking period data corresponding to blanking states of video blanking periods. The compression circuitry compresses the blanking period data into compressed blanking period data. The transmitting device also includes an interface that transmits signals corresponding to the compressed blanking period data via one or more multimedia channels of the multimedia communication link.

A transmitting device for communicating via a multimedia communication link includes a compression circuitry that receives blanking period data corresponding to blanking states of video blanking periods. The compression circuitry compresses the blanking period data into compressed blanking period data. The transmitting device also includes an interface that transmits signals corresponding to the compressed blanking period data via one or more multimedia channels of the multimedia communication link.

Conventionally, in a transparent display area, a gradation value of each color component is assigned to transparent gradation. Hence, when video is displayed in a video display area, each color component can only be represented in gradations with a gradation value of 0 to 1022, and it becomes necessary to assign pixel values to the transparent gradation. Accordingly, a color represented by those pixel values cannot be displayed. In view of this, by adding transparent area information to a vertical blanking period of a video signal, the pixel values can also be used to display video. By this, each of the color components can be represented in gradations with a gradation value of 0 to 1023, and thus, video can be displayed in full-range color even when a transparent display area is provided.

An analog video signal received through a cable may be distorted due to the cable and noise during its transmission. Provided is a method and apparatus for determining a level of transmission distortion and compensating for an analog video signal. A video signal reception method and apparatus may determine a distortion level of an analog video signal using an equalizing pattern signal included in a video signal, and may compensate for the analog video signal based on the distortion level.

An HDMI source determines whether or not an HDMI sink can receive a sub-signal based on VSDB of E-EDID. When the HDMI sink can receive the sub-signal, the HDMI source adds a sub-signal to pixel data of a main image composed of pixel data whose number of bits is smaller than that of transmission pixel data transmitted by a transmitter, thereby constructing transmission pixel data. This data is transmitted by the transmitter through TMDS channels #0 to #2. Furthermore, the HDMI source transmits a general control packet containing sub-signal information indicating whether or not the sub-signal is contained in the transmission pixel data in the control period of a vertical blanking period. The present invention can be applied to, for example, HDMI.

An HDMI source determines whether or not an HDMI sink can receive a sub-signal based on VSDB of E-EDID. When the HDMI sink can receive the sub-signal, the HDMI source adds a sub-signal to pixel data of a main image composed of pixel data whose number of bits is smaller than that of transmission pixel data transmitted by a transmitter, thereby constructing transmission pixel data. This data is transmitted by the transmitter through TMDS channels #0 to #2. Furthermore, the HDMI source transmits a general control packet containing sub-signal information indicating whether or not the sub-signal is contained in the transmission pixel data in the control period of a vertical blanking period. The present invention can be applied to, for example, HDMI.

A transmission system including a transmission device capable of transmitting a video signal, and a reception device capable of receiving the video signal transmitted by the transmission device, the transmission system includes: a processor connected to a memory; a video transmission circuit and a video reception circuit that transmit the video signal between the transmission device and the reception device; a transmission-side data transceiving circuit and a reception-side data transceiving circuit that transmit a data signal between the transmission device and the reception device, wherein the processor is configured to selectively execute a video signal transmission mode in which transmission of the video signal is performed and transmission of the data signal superimposed on the video signal is performed, and a data signal transmission exclusive mode in which transmission of the video signal is stopped and transmission of the data signal is performed.