Digital video signals are transmitted from a transmitter to a receiver via a digital video interface including shielded twisted pair cables that are surrounded by an over-braid shield. The over-braid shield is connected to a chassis ground at a transmitting end and the receiving end. An interface conveys the received signals to receiver processing circuitry. The interface is connected to an isolated ground, isolating the receiver processing circuitry. The twisted pairs are also connected to the isolated ground, such that a return current is forced back through the twisted pair cable shields rather than the over-braid shield. This reduces electromagnetic emissions and confines transients primarily to the over-braid shield.

The video signal transmission and reception system performs transmission of a video signal and a control signal between the video signal transmitting device and the video signal receiving device via a common transmission line. The video signal transmitting device includes a video signal transmitter, a control signal transmitter and receiver, a filter circuit, a controller, and a camera. The video signal receiving device includes a video signal receiver, a control signal transmitter and receiver, a filter circuit, and a controller. By performing time management control performed by the controller or the controller such that the period of the transient state of transmission of the video signal is within the non-communication period of the control signal, interference between the video signal and the control signal in the period of the transient state of transmission of the video signal is suppressed.

The present invention provides a digital video broadcasting-terrestrial (DVB-T) system and modulation method thereof. The system comprises a transmission module and a receiving module. The transmission module modulates a video signal to a DVB-T signal. The receiving module receives the DVB-T signal via a transmission line and demodulates the DVB-T signal to the video signal, and at the same time, monitoring the signal-to-noise ratio (SNR) or bit error rate (BER), and quantizes them to a reference data. The receiving module transmits the reference data to the transmission module through the same transmission line. The system can determine a control parameter according to the reference data to set the modulation parameter of the DVB-T signal.

A passive cable adaptor for connecting a data source device with a display device is described. The adaptor has a packet-based interface connector at one end, the connector having a positive main link pin, a negative main link pin, a positive auxiliary channel pin, and a negative auxiliary channel pin. At the other end is a micro serial interface connector, wherein multimedia content is transmitted over the cable adaptor and electrical power is supplied over the cable adaptor simultaneously. The cable adaptor has an auxiliary and hot plug detect (HPD) controller utilized to map the auxiliary channel and HPD signals of the packet-based digital display to the micro serial interface ID signal.

A method for a source device transmitting data by using HDMI (High Definition Media Interface) to transmit and receive data is disclosed. A method for an HDMI source device to transmit and receive data comprises transmitting, to a sink device, a request for reading out EDID (Extended Display Identification Data) if the sink device is connected; receiving, from the sink device, EDID including port information of the sink device; transmitting operation parameter information determined based on the EDID; and transmitting data through HDMI.

An electronic device comprised of an HDMI Matrix/Switcher IC and IP Extension Processor. The invention will carry out this process by utilizing an HDMI matrix/switcher IC to control the flow of the HDMI signals to and from the IP processor. This allows one or more sources to be selected as the input to the IP processor or received content from the IP processor to be routed through the input of the HDMI matrix/switcher to an HDMI output of the HDMI matrix/switcher. This topology when configured as a transmitter can send the HDMI source over IP and can select which input is to be sent to the local HDMI output(s) of the unit. When configured as a receiver the IP content being received can be sent to the HDMI output(s) of the unit or same unit can select from one of the other HDMI input(s). The main intent of the invention would be to eliminate the need for 2 different products to achieve the end to end results and it allows for local switching and loop-out capabilities of the HDMI sources.

A streaming device may broadcast multimedia content, such as television signals, to electronic devices in a customer premises. The device may include a tuner to receive a signal, corresponding to a number of television channels, and to extract a second signal corresponding to a selected channel. The device may include a media processor to transcode the extracted signal to a second encoded format. The device may further authenticate a destination device as a destination device that is authorized to receive at least some of the television channels, and receive, from the destination device, channel selection information that identifies the selected channel. The device may further include a communication interface to transmit the signal, in the second encoded format, to the destination device.

Systems, methods, devices, and non-transitory media of the various embodiments facilitate real time playback of a digital broadcast by enabling reduction of the amount of time a receiver device's low power mode interface with a separate computing device operates in an operational/high power mode. The receiver device may associate a stream of media packets of a digital broadcast with system time clock timestamps indicating when the media packets were received, and store the media packets in a temporary packet buffer. Periodically, a media packet burst stored in the temporary packet buffer may be sent to the separate computing device via a low power mode interface operating in an operational/high-power mode different than a low power mode. The low power mode interface may be returned to the low-power mode until the next burst of packets is sent to the separate computing device.

An enhanced multimedia over coax alliance (MoCA) implementation having a single Receive (Rx) physical (Phy) module that is arranged to receive data via one of at least two Rx radio frequency (RF) modules, which are arranged to be in communication with a coaxial cable, and at least two transmit (Tx) Phy modules respectively arranged to be in communication with two Tx RF modules, which are also arranged to be in communication with the coaxial cable.

Transmission of stereo image data may be performed between devices, where a source device receives E-EDID from a sink device via DDC of an HDMI cable. This E-EDID contains information on 3D image data transmission modes supportable by the sink device. Based on information on 3D image data transmission modes from the sink device, the source device selects a predetermined transmission mode from among the 3D image data transmission modes supportable by the sink device. The source device transmits 3D image data in the selected transmission mode to the sink device. The source device transmits information on the transmission mode for the 3D image data, to the sink device by using an AVI InfoFrame packet or the like. The sink device processes the 3D image data received from the source device in accordance with its transmission mode, thereby obtaining left and right eye image data.