Directional wireless drop systems are provided. These systems include a tap unit that is connected to a communications line of the broadband network; a cable modem unit connected to the tap unit; a plurality of wireless routers connected to the cable modem unit; and a directional antenna unit that is connected to at least a first of the wireless routers. Each wireless router is associated with a respective one of a plurality of subscriber premises that are served by the directional wireless drop system and is configured to communicate with at least one device that is located at the respective one of plurality of subscriber premises.

A satellite television antenna apparatus is connectable to a remotely-located set top box (STB). The satellite television antenna apparatus can include a motorized reflector dish movable in at least one of an azimuth orientation and an elevation orientation, and an antenna control system. The antenna control system can be configured to conduct two-way communication through a physical connection or a wireless connection between the satellite television antenna apparatus and the STB.

A transmission method includes: generating one or more transfer frames that each store one or more streams used for content transfer; and transmitting the one or more generated frames through broadcast, each of the one or more streams storing one or more second transfer units, each of the one or more second transfer units storing one or more first transfer units, and each of the one or more first transfer units storing one or more Internet Protocol (IP) packets. In at least one stream among the one or more streams, each of the first transfer units positioned at a head contains reference clock information indicating time used for reproduction of the content.

Methods, apparatus, systems, and articles of manufacture are disclosed to enable Digital Satellite Equipment Control (DiSEqC) communication between an antenna and a processor. An example apparatus includes a receiver to be coupled to an antenna by a cable and configured to bidirectionally communicate with the antenna via a communication signal having a periodic waveform, wherein the receiver further includes a low dropout regulator (LDO) pass transistor to be coupled to the cable and configured to generate a current signal based on the periodic waveform of the communication signal, a current envelope detector circuit coupled to the LDO pass transistor configured to generate a voltage signal based on the current signal, and a processor. The processor is coupled to the current envelope detector circuit and configured to process the voltage signal generated by the current envelope detector.

Methods, apparatus, systems, and articles of manufacture are disclosed to enable Digital Satellite Equipment Control (DiSEqC) communication between an antenna and a processor. An example apparatus includes a receiver to be coupled to an antenna by a cable and configured to bidirectionally communicate with the antenna via a communication signal having a periodic waveform, wherein the receiver further includes a low dropout regulator (LDO) pass transistor to be coupled to the cable and configured to generate a current signal based on the periodic waveform of the communication signal, a current envelope detector circuit coupled to the LDO pass transistor configured to generate a voltage signal based on the current signal, and a processor. The processor is coupled to the current envelope detector circuit and configured to process the voltage signal generated by the current envelope detector.

Small wave communications between a base station and user equipment are facilitated by transmitting a movement request to a movable element to change a position when the movable element is in a beam path for an RF communications beam of more than 6 GHz between a first user equipment and a base station. The movable element may be a reflector that reflects the small wave to the user equipment, or an object whose movement improves a communication path.

A satellite television antenna system can include a self-pointing satellite antenna and a power inserter coupled to the self-pointing satellite antenna. The power inserter can include an enclosure body and a circuit board disposed inside of the enclosure body. The circuit board includes a microprocessor. The microprocessor can be configured via software code to determine whether a first type of communication protocol is being received from a set top box (STB) coupled to the power inserter, determine a configuration for a first constellation of spacecraft if the first type of communication protocol is being received from the STB, and determine a configuration for a second constellation of spacecraft if the first type of communication protocol is not being received from the STB. The first constellation of spacecraft is different than the second constellation of spacecraft.

A system and method are provided that, among other things, can reduce the burden on receiving computers, increase data throughput, reduce system failure, and provide components of a scalable and flexible network architecture. Specifically, the system and method provide a multichannel-multicast network environment for use in dynamically assigning data to channels. This configuration is particularly useful in a trading network environment, as it effectively performs channel reassignments in a way not to disturb the receipt of the underlying data. While the example embodiments described herein pertain to electronic trading, the principles of the present invention may be equally applied in other environments where the advantages presented herein are beneficial.

A system and method are provided that, among other things, can reduce the burden on receiving computers, increase data throughput, reduce system failure, and provide components of a scalable and flexible network architecture. Specifically, the system and method provide a multichannel-multicast network environment for use in dynamically assigning data to channels. This configuration is particularly useful in a trading network environment, as it effectively performs channel reassignments in a way not to disturb the receipt of the underlying data. While the example embodiments described herein pertain to electronic trading, the principles of the present invention may be equally applied in other environments where the advantages presented herein are beneficial.

An electronic device may be operable to sample a signal during an analog-to-digital conversion using an analog-to-digital converter in the electronic device, and the signal may comprise a wide bandwidth and a plurality of channels. The electronic device may adaptively change a sample rate of the sampling to move aliasing out of a region of one or more desired channels of the plurality of channels. The electronic device may change the sample rate using a variable oscillator in the electronic device. The change of the sample rate may comprise, for example, increasing or decreasing the sample rate by a particular percentage. In response to the change of the sample rate, the electronic device may perform, using a variable rate interpolator in the electronic device, variable rate interpolation. The variable rate interpolator may comprise, for example, a finite impulse response filter.