Techniques pertaining to the transmission of digital data via a conventional transmission medium (e.g., a coaxial cable for TV) specifically for analog composite video signals are disclosed. To retrofit in an existing system not designed for transmitting digital signals or data, the techniques are provided to convert the data into an analog signal that is transmitted over a coaxial cable, where the analog signal, when received, is decomposed to recover the data. According to one aspect of the present invention, videos in high quality (e.g. high definition or HD format) from HD cameras are used in the conventional surveillance system, where the transmission medium for the analogy videos is already installed.

A system for communicating wireless signals over a cable network includes a wireless over cable (WoC) amplifier configured to communicate wireless frequency band signals with a modem. The system may also include a WoC splitter configured to communicate the wireless frequency band signals with the WoC amplifier directly or via one or more cables, and a WoC adapter configured to receive the wireless frequency band signals from the WoC splitter via one or more cables, and transmit the wireless frequency band signals wirelessly to one or more wireless communication devices.

Methods for hosting low-latency streaming interactive audio/video (A/V) include executing one or more video games or applications on a server communicatively coupled to a data network. Packet streams are received from a plurality of users and routed to the one or more video games. The packet streams include user control input that are used to compute A/V data in response. The A/V data are received from the video games or applications. Portions of the A/V data are compressed in parallel using processing units resulting in low-latency streaming compressed A/V data. The low-latency streaming compressed A/V data are routed to each of the users over a corresponding data network communication channel. The executing of video games, receiving of packet streams and A/V data, compressing portions of the A/V data and routing the compressed A/V data are performed with a latency such that at least one user has the perception that the controlled video game is responding instantly.

The present invention is directed to a CATV & MoCA® device, such as a RF signal amplifier. The RF signal amplifier includes a RF input port to receive signals from, and transmit signals to, a service provider. The RF input port is connected to an active communication path with a downstream signal amplifier leading to an input of a resistive splitter network. The resistive splitter network has plural interconnected resistors, which split the amplified signal received at the input of the resistive splitter network and provide the signal to plural “CATV & MoCA®” output ports. Upstream CATV signals received by the “CATV & MoCA®” output ports are combined by the resistive splitter network and sent to the RF input port to be transmitted to the service provider. MoCA® signals received by any one of the “CATV & MoCA®” output ports are carried by the resistive splitter network to the other “CATV & MoCA®” output ports, and potentially to other “MoCA® only” ports of the RF signal amplifier.

Methods and systems are disclosed for using a common frequency spectrum for simultaneous upstream and downstream communications in a network by implementing directional diversity techniques. Non-reciprocal coupling devices, such as circulators, may be configured in the network to provide unidirectional transmission of each signal to prevent interference. In some embodiments, feed-forward interference cancellation is utilized to increase signal isolation of upstream and downstream signals.

A distribution element for a self-calibrating RF network and system and method for use of the same are disclosed. In one embodiment of the distribution element, the distribution element is located between a headend layer and an endpoint layer. An upstream directional control circuit and a downstream directional control circuit are positioned in a spaced opposing relationship such that respective upstream line and the downstream line are separated into a forward line and reverse line therebetween while being combined at the respective upstream directional control circuit and the downstream directional control circuit. A pair of amplifier circuits positioned between the upstream and downstream control circuits are under the control of a controller to amplify and shape the signal of the forward line and the reverse line. The controller monitor and analyzes signals through the distribution element.

Systems, methods, and computer-readable media for porting locally processed media data with low latency to a remote client device via various wireless links are provided. In one example embodiment, a transceiver module may include a local network interface and a controller that may receive a client control signal from a client device over a wireless local area network via the local network interface, transmit a media control signal based on the client control signal to a media device, receive media data based on the media control signal from the media device, and transmit to the client device over the wireless local area network via the local network interface client data based on the media data and a low-latency compression technique. The receipt of the media data and transmission of the client data may be accomplished with substantially no detectable latency. Additional embodiments are also provided.

A method for transmitting digital subscriber connection signals to an interface of an end user via a coaxial cable includes: supplying, by a distribution point unit (DPU), first balanced subscriber connection signals to the coaxial cable by a first transformation; coupling unbalanced subscriber connection signals into the coaxial cable into a lower frequency range of an overall frequency range; attenuating, by means of a filtering device, a reflection of the unbalanced subscriber connection signals in the coaxial cable; a second transformation of the unbalanced subscriber connection signals into second balanced subscriber connection signals by means of a balun device assigned to the interface, wherein the input impedance of the filtering device is adjusted with respect to reflections from the direction of the customer terminal output; and separately making the second balanced subscriber connection signals available at the customer terminal output.

An entry adapter configured to communicate cable television (CATV) signals from a CATV network to one or more network devices and to communicate Multi-Media over Coaxial Alliance (MoCA) signals with a MoCA server, the entry adapter including one or more MoCA ports, and a signal combination device configured to direct the CATV signals toward one or more access ports without substantial attenuation, to substantially attenuate the CATV signals directed toward the one or more MoCA ports, to pass the MoCA signals from the one or more MoCA ports to the one or more access ports, and to pass the MoCA signals from the one or more access ports to the one or more MoCA ports.

Example methods, apparatus and articles of manufacture (i.e., physical storage media) to perform media source detection based on frequency band selection and processing are disclosed. Example meters disclosed herein are to compare a first audio signal from a monitored media device with a second audio signal from a first one of a plurality of media sources in communication with the monitored media device to determine a sequence of match results, the first audio signal associated with media presented by the media device. Disclosed example meters are also to compute a standard deviation of time delays associated with respective ones of the match results. Disclosed example meters are further to determine whether the first one of the media sources is a source of the media presented by the monitored media device based on the standard deviation.