Abstract: Hybrid fiber/coaxial (coax) taps, and related methods and networks. The hybrid fiber/coax tap is configured to receive and convert downlink optical RF signals from a downlink distribution optical fiber to downlink electrical RF signals to be split and distributed to coax taps. Subscriber coax cables can be connected to the coax taps to “tap” the downlink electrical RF signals to subscribers. The hybrid fiber/coax tap is also configured to convert received uplink electrical RF signals on the coax taps into uplink optical RF signals to be distributed over an uplink distribution optical fiber connected to the output optical port. The hybrid fiber/coax tap also includes an input coax port configured to be connected to a coax distribution cable to receive a power signal from a coax network for powering fiber optic components. Electrical RF signals received on the coax port are passed on an output coax port to downstream taps.

Abstract: Supporting analog remote antenna units (RAUs) in digital distributed antenna systems (DASs) using analog RAU digital adaptors. In the digital DAS disclosed herein, a head-end equipment (HEE) is configured to exchange digital communications signals with a plurality of digital RAUs. The digital DAS is also configured to distribute digital communications signals to an analog RAU(s), which is not inherently capable of processing the digital communications signals. In this regard, an analog RAU digital adaptor(s) is provided in an analog remote unit to serve as a digital interface for the analog RAU(s). The analog RAU digital adaptor(s) is configured to provide conversions between the digital communications signals and analog RF communications signals. By providing the analog RAU digital adaptor as the digital interface for the analog RAU(s), the digital DAS can be configured to compatibly communicate with the analog RAU(s) and the digital RAU(s).

Abstract: Embodiments disclosed in the detailed description include supporting an add-on remote unit(s) (RU) in an optical fiber-based distributed antenna system (DAS) over existing optical fiber communications medium using radio frequency (RF) multiplexing. An existing DAS comprises at least one existing head end equipment (HEE) communicatively coupled to a plurality of existing RUs through an existing optical fiber communications medium. In aspects disclosed herein, an add-on RU is added to the existing DAS to support additional wireless communications. No new optical fibers are required to be deployed to support communications to the add-on RU in the existing DAS. Instead, the existing DAS is configured to support the add-on RU through the existing optical fiber communications medium using RF multiplexing. As a result, the add-on RU can be added to the existing optical fiber-based DAS without adding new optical fibers, thus leading to reduced service disruptions and deployment costs.

Abstract: Embodiments disclosed in the detailed description include supporting an add-on remote unit(s) (RU) in an optical fiber-based distributed antenna system (DAS) over existing optical fiber communications medium using radio frequency (RF) multiplexing. An existing DAS comprises at least one existing head end equipment (HEE) communicatively coupled to a plurality of existing RUs through an existing optical fiber communications medium. In aspects disclosed herein, an add-on RU is added to the existing DAS to support additional wireless communications. No new optical fibers are required to be deployed to support communications to the add-on RU in the existing DAS. Instead, the existing DAS is configured to support the add-on RU through the existing optical fiber communications medium using RF multiplexing. As a result, the add-on RU can be added to the existing optical fiber-based DAS without adding new optical fibers, thus leading to reduced service disruptions and deployment costs.

Abstract: Embodiments disclosed in the detailed description include supporting an add-on remote unit(s) (RU) in an optical fiber-based distributed antenna system (DAS) over existing optical fiber communications medium using radio frequency (RF) multiplexing. An existing DAS comprises at least one existing head end equipment (HEE) communicatively coupled to a plurality of existing RUs through an existing optical fiber communications medium. In aspects disclosed herein, an add-on RU is added to the existing DAS to support additional wireless communications. No new optical fibers are required to be deployed to support communications to the add-on RU in the existing DAS. Instead, the existing DAS is configured to support the add-on RU through the existing optical fiber communications medium using RF multiplexing. As a result, the add-on RU can be added to the existing optical fiber-based DAS without adding new optical fibers, thus leading to reduced service disruptions and deployment costs.

Abstract: Embodiments disclosed in the detailed description include supporting an add-on remote unit(s) (RU) in an optical fiber-based distributed antenna system (DAS) over existing optical fiber communications medium using radio frequency (RF) multiplexing. An existing DAS comprises at least one existing head end equipment (HEE) communicatively coupled to a plurality of existing RUs through an existing optical fiber communications medium. In aspects disclosed herein, an add-on RU is added to the existing DAS to support additional wireless communications. No new optical fibers are required to be deployed to support communications to the add-on RU in the existing DAS. Instead, the existing DAS is configured to support the add-on RU through the existing optical fiber communications medium using RF multiplexing. As a result, the add-on RU can be added to the existing optical fiber-based DAS without adding new optical fibers, thus leading to reduced service disruptions and deployment costs.

Abstract: An electronic apparatus includes first and second electronic devices, and first and second heat sinks for dissipating heat, wherein there is each of electrical conductivity between the first electronic device and the first heat sink, thermal conductivity between the first electronic device and the first heat sink, electrical conductivity between the second electronic device and the second heat sink, and thermal conductivity between the second electronic device and the second heat sink, wherein electrical conductivity is provided between the first and second heat sinks, and wherein thermal resistance is provided between the first and second heat sinks, so that the second heat sink remains cooler than the first heat, such as for protecting the second electrical device from the heat generated by the first electronic device.

Abstract: Supporting analog remote antenna units (RAUs) in digital distributed antenna systems (DASs) using analog RAU digital adaptors. In the digital DAS disclosed herein, a head-end equipment (HEE) is configured to exchange digital communications signals with a plurality of digital RAUs. The digital DAS is also configured to distribute digital communications signals to an analog RAU(s), which is not inherently capable of processing the digital communications signals. In this regard, an analog RAU digital adaptor(s) is provided in an analog remote unit to serve as a digital interface for the analog RAU(s). The analog RAU digital adaptor(s) is configured to provide conversions between the digital communications signals and analog RF communications signals. By providing the analog RAU digital adaptor as the digital interface for the analog RAU(s), the digital DAS can be configured to compatibly communicate with the analog RAU(s) and the digital RAU(s).

Abstract: Embodiments disclosed in the detailed description include supporting an add-on remote unit(s) (RU) in an optical fiber-based distributed antenna system (DAS) over existing optical fiber communication medium using wavelength division multiplexing (WDM). An existing DAS comprises at least one existing head end equipment (HEE) communicatively coupled to a plurality of existing RUs through an optical fiber communication medium. In aspects disclosed herein, an add-on RU is added to the existing DAS to support additional wireless communications. No new optical fibers are required to be deployed to support communications to the add-on RU in the DAS. Instead, the DAS is configured to support the add-on RU through the existing optical fiber communication medium using WDM. Thus, the add-on RU can be added to the existing DAS without adding new optical fibers, thus leading to reduced service disruptions and deployment costs.

Abstract: A connector for connecting a coaxial cable to a components box is disclosed, the connector is adapted to receive a central conductor of the coaxial cable and to firmly connect it to a central pin in the connector using a seizing force of a springy element, without needing to use a fastening screw or the like and without needing to open the component box. The connector of the invention is further adapted to allow releasing the central conductor from the central pin without needing to unfasten a screw or opening the component box. The connector is further adapted to facilitate the connection of the coaxial cable to the connector in another orientation similarly, without needing to use a fastening screw or the like and without needing to open the component box.

Abstract: A face plate for cable-TV networks, the face plate adapted to operate in frequencies as high as 1.8 GHz. The face plate comprising terminals, electronic circuitry, impedance matching units and a disturbances suppressor. The disturbances suppressor is designed to suppress the parasitic resonance of the transmission line that appears inside the extended operational frequency band of 1000 to 1800 MHz. The impedance matching units are adapted to match the impedance of the terminal with that of electronic circuitry.

Abstract: A wideband power coupler and method for taping part of a RF signal from a combined RF and AC signal with relatively simple structure and relatively low number of needed parts. The power coupler may include a BALUN, the BALUN constructed of a central conductor, an outer conductor and a ferrite element. Combined downstream AC and RF signal may flow through the central conductor of the BALUN. A part of the RF signal is reflected on the outer conductor of the BALUN with 180 degrees phase shift with respect to the RF signal, to create a reversed signal. Another part of the RF signal is sampled by a high pass filter. An autotransformer sums the reversed signal with the RF signal to create an output RF signal for an output tap port.

Abstract: A face plate for cable-TV networks, the face plate adapted to operate in frequencies as high as 1.8 GHz. The face plate comprising terminals, electronic circuitry, impedance matching units and a disturbances suppressor. The disturbances suppressor is designed to suppress the parasitic resonance of the transmission line that appears inside the extended operational frequency band of 1000 to 1800 MHz. The impedance matching units are adapted to match the impedance of the terminal with that of electronic circuitry.

Abstract: A connector for connecting a coaxial cable to a components box is disclosed, the connector is adapted to receive a central conductor of the coaxial cable and to firmly connect it to a central pin in the connector using a seizing force of a springy element, without needing to use a fastening screw or the like and without needing to open the component box. The connector of the invention is further adapted to allow releasing the central conductor from the central pin without needing to unfasten a screw or opening the component box. The connector is further adapted to facilitate the connection of the coaxial cable to the connector in another orientation similarly, without needing to use a fastening screw or the like and without needing to open the component box.

Abstract: A wideband power coupler and method for taping part of a RF signal from a combined RF and AC signal with relatively simple structure and relatively low number of needed parts. The power coupler may include a BALUN, the BALUN constructed of a central conductor, an outer conductor and a ferrite element. Combined downstream AC and RF signal may flow through the central conductor of the BALUN. A part of the RF signal is reflected on the outer conductor of the BALUN with 180 degrees phase shift with respect to the RF signal, to create a reversed signal. Another part of the RF signal is sampled by a high pass filter. An autotransformer sums the reversed signal with the RF signal to create an output RF signal for an output tap port.