JP2013183340A - Bs modem and antenna control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a BS modem and an antenna control system capable of selecting a power supply for transmitting a power signal in a coaxial interface mode.SOLUTION: A BS modem includes a power supply switching circuit 3 which is connected with a plurality of power supply line transmitting power supply signals having different voltages and switches a power supply signal from a desired power supply line to output it to a feeder line 12.

Description

  The present invention relates to a BS modem and an antenna control system used in an antenna control system that controls an antenna in accordance with an AISG (Antenna Interface Standards Group) standard.

  In mobile radio base stations, antenna tilt control can generally be performed by remote control. Initially, each manufacturer used a unique method as an antenna control method. However, in recent LTE (Long Term Evolution) radio base stations and the like, antenna control is often performed according to the AISG standard. The AISG standard is a standard standardized to ensure basic interoperability of antennas (see, for example, Patent Document 1).

  Usually, an AISG device (AISG terminal equipment) such as an antenna of a radio base station and a RET (Remote Electrical Tilt) unit that controls the antenna is arranged at a high position such as an upper part of a steel tower or a rooftop of a building. On the other hand, a radio that feeds power to an antenna and a control device (AISG control device) that controls an AISG device are generally arranged at a low position such as a lower part of a steel tower. Here, the control device transmits a control signal (RS485 standard signal) to the AISG device, controls the AISG device to control the antenna, and supplies power to the AISG device.

  The antenna and the radio are connected by a feed line (RF feed line) made of a coaxial cable, and the AISG device and the control device are connected by a control cable (AISG control cable) conforming to the AISG standard. For example, the antenna and the AISG are connected. When the device is arranged at the upper part of the steel tower and the radio device and the control device are arranged at the lower part of the steel tower, two cables of the feeder line and the control cable are laid from the upper part to the lower part of the steel tower.

  However, for example, in a steel tower as high as several tens of meters, it is very troublesome to lay cables from the upper part to the lower part of the steel tower, and the cost for the construction also increases. In order to solve this problem, the AISG standard defines a method called a coaxial interface or a modem option (hereinafter referred to as a coaxial interface method).

  As shown in FIG. 9, in the antenna control system 91 using the coaxial interface method, two modems called a BS modem 13 and an antenna modem 14 are provided in the middle of the feed line 12 that connects the antenna 10 and the radio 11. The BS modem 13 and the antenna modem 14 are used to transmit a control signal and a power signal for the AISG device 17 via the feeder line 12.

  The BS modem 13 is provided in the vicinity of the wireless device 11 (for example, the lower part of the steel tower), and a control device (AISG control device) 16 is connected via a control cable 15. The antenna modem 14 is provided in the vicinity of the antenna 10 (for example, at the top of the steel tower), and an AISG device 17 is connected via the control cable 15.

  As shown in FIG. 10, in the conventional BS modem 13, the control signal (RS485A, RS485B) input from the control device 16 via the input AISG connector 21 is modulated by the modem circuit 22 and modulated signal (AISG coaxial). An interface modulation signal and an on-off-keying signal having a carrier frequency of 2.176 MHz are generated, and the modulation signal and the power signal input from the control device 16 are combined by the combining circuit 23, and the combined signal (AISG) A coaxial interface signal (hereinafter simply referred to as an AISG signal) is output to a bias T circuit (Bias Tee) 24. The bias T circuit 24 is configured by combining a DC blocking capacitor (capacitance element) and an AC blocking inductor (inductive element). The bias T circuit 24 receives the AISG signal input from the synthesis circuit 23 from the wireless device 11 as an input side RF. The signal is superimposed on the power supply signal (RF signal) input via the connector 25 and output from the output side RF connector 26 to the power supply line 12 on the antenna 10 side.

  As shown in FIG. 11, the antenna modem 14 inputs a power feeding signal (a power feeding signal on which an AISG signal is superimposed) input from the BS modem 13 via the input side RF connector 31 to the bias T circuit 32, and the bias T circuit. At 32, the AISG signal is separated from the feed signal. The separated feed signal is output from the output-side RF connector 33 to the feed line 12 on the antenna 10 side. The AISG signal separated by the bias T circuit 32 is further separated into a modulation signal and a power supply signal by the separation circuit 34, and the separated modulation signal is demodulated by the modem circuit 35 and returned to the control signal, which is demodulated. The control signal and the power signal separated by the separation circuit 34 are output to the AISG device 17 via the output AISG connector 36.

  In general, the modem circuit 22 of the BS modem 13 and the modem circuit 35 of the antenna modem 14 are of the same configuration. As in the configuration example shown in FIG. 12, the modem circuits 22 and 35 modulate the control signal (RS485 standard signal) input to the RS485 interface 111 by the modulation circuit 112 to generate a modulation signal, and the generated modulation signal Is output from the directional coupler 113 to the outside, and the modulation signal input to the directional coupler 113 is demodulated by the demodulation circuit 114 and returned to the control signal, and output from the RS485 interface 111 to the outside. Is configured to do. The power supply circuit 115 of the modem circuits 22 and 35 uses the power supplied from the control device 16 to convert the input power supply voltage to the voltage for the modem circuits 22 and 35, and the RS485 interface 111, the modulation circuit 112, It is configured to output to the demodulation circuit 114.

  By adopting such a coaxial interface method, it is only necessary to lay the feeder line 12 from the upper part to the lower part of the tower, and the total cost of the antenna control system including the construction cost can be greatly suppressed. Become.

Special table 2010-519844 gazette

  By the way, as shown in Table 1, in the AISG standard, three types of power supplies of +12 V (No. 1), -48 V (No. 2), and 10 to 30 V (No. 6) are prepared. Table 1 shows the connector terminal number (Pin Number) defined in the AISG standard, signals propagated at each terminal (Signal), mandatory connection (Mandatory) or optional connection (Optional). No. 8 NC means no connection.

  In the coaxial interface type antenna control system 91 described above, a power supply signal is transmitted via a feeder 12 made of a coaxial cable, and the coaxial cable has only two conductors, a center conductor and an outer conductor, so that there is one type. Can be transmitted only (for example, 10-30V power supply which is essential connection).

  The type of power supply (power supply voltage) transmitted through the feeder line 12 is determined by the BS modem 13, but since the power supply voltage that can be used in the antenna modem 14 is usually fixed, the power supply voltage supplied from the BS modem 13 is the antenna. If the power supply voltage is different from the power supply voltage that can be used by the modem 14, the antenna modem 14 may not operate normally and a problem may occur in the entire system.

  Since the 10-30V power supply is indispensable, at present, if the BS modem 13 is configured to supply the 10-30V power supply, the above-described problems can be substantially avoided. However, in the old antenna control system, the antenna modem 14 and the AISG device 17 may use only a + 12V power supply. If the absolute value of the voltage is increased, a large amount of power can be supplied even with a small current. Since it is possible to improve the power efficiency by suppressing the voltage drop at 15 etc., it is considered that the number of antenna control systems using -48V power supply will increase in the future. Therefore, in order to increase the flexibility and expandability of the antenna control system, a BS modem 13 that can select a power source to be transmitted by the coaxial interface method is desired.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a BS modem and an antenna control system capable of selecting a power source to be transmitted by a coaxial interface method.

  The present invention was devised to achieve the above object, and includes an AISG device that controls an antenna in accordance with the AISG standard, a control device that transmits a control signal and a power signal to the AISG device, and the antenna. The AISG device is connected to separate the modulation signal and the power supply signal from the input power supply signal, and the modulation signal is demodulated and returned to the control signal. An antenna modem that outputs a control signal and a power signal to the AISG device and a separated feed signal to the feed line on the antenna side. Is provided in the middle of the power supply line on the side, and the control device is connected to modulate a control signal input from the control device. A BS modem that generates a modulation signal, superimposes the modulation signal and the power signal input from the control device on the power supply signal input from the radio, and outputs the signal to the power supply line on the antenna side. A plurality of power supply lines that transmit power supply signals having different voltages, and a power supply switching circuit that switches a power supply signal from a desired power supply line to the power supply line among the plurality of power supply lines. It is a modem.

  The power supply device further includes an external power input connector to which a power supply device provided separately from the control device is connected, and the power signal input from the power supply device via the external power input connector is a voltage of the power signal. It may be configured to input to the power supply switching circuit via a power supply line according to the above.

  A DC / DC converter that generates and outputs a power supply signal having a voltage different from that of the power supply signal from the power supply signal input from the control device; and the power supply signal input from the control device and the DC / DC converter You may comprise so that the produced | generated power supply signal may be input into the said power supply switching circuit via the power supply line according to the voltage of a power supply signal.

  You may further provide the display means which displays the voltage of the power supply signal output to the said feeder from the said power supply switching circuit.

  Further, the present invention provides an AISG device that controls an antenna in accordance with the AISG standard, a control device that transmits a control signal and a power signal to the AISG device, and a feed line that connects the antenna and a radio. The control device is connected to generate a modulation signal by modulating the control signal input from the control device, and the modulation signal and the power signal input from the control device A BS modem that is superimposed on the power feeding signal input from the antenna and output to the power feeding line on the antenna side, and is provided in the middle of the power feeding line on the antenna side of the BS modem, and the AISG device is connected The modulation signal and the power supply signal are separated from the power supply signal input from the BS modem, and the modulation signal is demodulated by the modem circuit and returned to the control signal. An antenna control system comprising: an antenna modem that outputs a control signal and a power signal to the AISG device; and an antenna modem that outputs the separated power signal to the power supply line on the antenna side. The antenna control system includes a power supply switching circuit in which a plurality of power supply lines to be transmitted are connected, and a power supply signal from a desired power supply line among the plurality of power supply lines is switched to be output to the feeder line.

  ADVANTAGE OF THE INVENTION According to this invention, the BS modem and antenna control system which can select the power supply transmitted by a coaxial interface system can be provided.

(A) is a schematic block diagram of the antenna control system using the BS modem which concerns on one embodiment of this invention, (b) is a schematic block diagram of BS modem. (A), (b) is a figure which shows the modification of the power supply switching circuit used for BS modem of FIG.1 (b). (A), (b) is explanatory drawing which shows an example of the trigger of the power supply switching circuit used for BS modem of FIG.1 (b). It is a schematic block diagram of BS modem which concerns on other embodiment of this invention. (A) is a schematic block diagram of BS modem which concerns on other embodiment of this invention, (b) is a schematic block diagram of the antenna control system using BS modem of (a). It is a schematic block diagram of BS modem which concerns on other embodiment of this invention. It is a schematic block diagram of BS modem which concerns on other embodiment of this invention. It is a schematic block diagram of BS modem which concerns on other embodiment of this invention. It is a schematic block diagram of the conventional antenna control system. It is a schematic block diagram of the conventional BS modem used for the conventional antenna control system of FIG. It is a schematic block diagram of the antenna modem used for the conventional antenna control system of FIG. It is a schematic block diagram of the modem circuit used for BS modem of FIG. 10, and the antenna modem of FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

  1A is a schematic configuration diagram of an antenna control system using a BS modem according to an embodiment of the present invention, and FIG. 1B is a schematic configuration diagram of a BS modem.

  As shown in FIG. 1 (a), the antenna control system 1 controls the AISG device 17 by transmitting a control signal to the AISG device 17 that controls the antenna 10 according to the AISG standard, and the AISG device 17. A control device 16 that controls the antenna 10 and transmits a power signal of one voltage defined by the AISG standard to the AISG device 17 and a power supply 11 that connects the antenna 10 and the radio 11 that feeds power to the antenna 10. A BS modem 2 of the present invention provided in the middle of the electric wire 12 and an antenna modem 14 provided in the middle of the feeder line 12 closer to the antenna 10 than the BS modem 2 are provided.

  The BS modem 2 generates a modulation signal by modulating the control signal input from the control device 16 via the input AISG connector (male connector) 21, and generates the modulation signal and the power signal input from the control device 16. The synthesized signal (AISG signal) is superimposed on the power feeding signal input from the wireless device 11 via the input side RF connector 25 and output from the output side RF connector 26 to the power feeding line 12 on the antenna 10 side. is there. Details of the BS modem 2 will be described later. The input AISG connector 21 is a general connector (AISG connector) conforming to the AISG standard, and the RF connectors 25 and 26 are general coaxial cable connectors.

  The antenna modem 14 separates the AISG signal from the power feeding signal input from the BS modem 2 via the input-side RF connector 31, separates the AISG signal into a modulation signal and a power supply signal, and demodulates and controls the modulation signal. Returning to the signal, the control signal and the power signal are output from the output AISG connector 36 to the AISG device 17, and the separated power supply signal is output from the output side RF connector 33 to the power supply line 12 on the antenna 10 side. The antenna modem 14 is a general antenna modem conventionally used, and is the same as that described with reference to FIG. The output AISG connector 36 is a general connector (AISG connector) conforming to the AISG standard, and the RF connectors 31 and 33 are general coaxial cable connectors.

  The BS modem 2 is provided in the vicinity of the wireless device 11 (for example, the lower part of the steel tower), and a control device 16 is connected via a control cable 15. The antenna modem 14 is provided in the vicinity of the antenna 10 (for example, at the top of the steel tower), and an AISG device 17 is connected via the control cable 15.

  The control cable 15 includes a control signal line for transmitting a control signal and a power line for transmitting a power signal, and a male connector 15a and a female connector 15b are provided at both ends thereof. The control device 16 is provided with an output connector (female connector) 16a, and the AISG device 17 is provided with an input connector (male connector) 17a. These connectors 15a, 15b, 16a, and 17a are general connectors (AISG connectors) conforming to the AISG standard. Although not shown, the AISG device 17 is provided with an output connector (female connector) so that a plurality of AISG devices 17 can be connected in a daisy chain.

  By connecting the male connector 15a of the control cable 15 to the output connector 16a of the control device 16 and connecting the female connector 15b of the control cable 15 to the input AISG connector 21 of the BS modem 2, the control device 16 and the BS modem 2 are connected. Are connected via the control cable 15. The power supply line 12 extending from the wireless device 11 is connected to the input side RF connector 25 of the BS modem 2, whereby the wireless device 11 and the BS modem 2 are connected via the power supply line 12.

  Further, the male connector 15a of the control cable 15 is connected to the output AISG connector 36 of the antenna modem 14, and the female connector 15b of the control cable 15 is connected to the input connector 17a of the AISG device 17, whereby the antenna modem 14 and the AISG device are connected. 17 is connected through a control cable 15. In addition, the power supply line 12 extending to the antenna 10 is connected to the output-side RF connector 33 of the antenna modem 14, whereby the antenna modem 14 and the antenna 10 are connected via the power supply line 12.

  Furthermore, one end of the feed line 12 is connected to the output side RF connector 26 of the BS modem 2, and the other end of the feed line 12 is connected to the input side RF connector 31 of the antenna modem 14. A modem 14 is connected via the feeder line 12.

  Next, the BS modem 2 will be described.

  As described above, in the AISG standard, three types of power supplies (10 to 30 V, +12 V, and −48 V) having different voltages are prepared, but here, all three types of power supplies are supplied from the control device 16 to the BS modem 2. Suppose that

  As shown in FIG. 1B, the BS modem 2 includes a modem circuit 22 that modulates a control signal (RS485A, RS485B) input from the control device 16 via the input AISG connector 21, and generates a modulation signal; A synthesizing circuit 23 that synthesizes the modulation signal generated by the modem circuit 22 and the power supply signal input from the control device 16, and a signal (AISG signal) synthesized by the synthesizing circuit 23 are connected from the radio 11 to the input-side RF connector 25. And a bias T circuit 24 that superimposes the feed signal input via the output side RF connector 26 and outputs it to the feed line 12 on the antenna 10 side.

  In the BS modem 2 according to the present embodiment, a plurality of power supply lines for transmitting power supply signals having different voltages are connected, and a power supply signal from a desired power supply line among the plurality of power supply lines is output to the feeder line 12. A power supply switching circuit 3 for switching to is further provided. The synthesis circuit 23 is configured to synthesize the modulation signal generated by the modem circuit 22 and the power supply signal input from the power supply switching circuit 3 and output the resultant signal to the bias T circuit 24.

  The terminals of No. 1 (+ 12V), No. 2 (−48V), No. 6 (10 to 30V) of the input AISG connector 21 serving as a power supply line are electrically connected to the input of the power supply switching circuit 3 by internal wiring. The output of the switching circuit 3 is electrically connected to the power supply signal input of the synthesis circuit 23. One of the three power lines (for example, a power line of 10 to 30 V that is an essential connection) is electrically connected to the power circuit of the modem circuit 22 so that power is supplied to the modem circuit 22. It has become. The modem circuit 22 is the same as that described with reference to FIG.

  The pin terminals of Nos. 3 and 5 (RS485A and RS485B) of the input AISG connector 21 are electrically connected to the input / output unit (RS485 interface) of the control signal of the modem circuit 22 by internal wiring, and the modulation signal of the modem circuit 22 The input / output unit (directional coupler) is electrically connected to the input of the modulation signal of the synthesis circuit 23 by internal wiring.

  In the present embodiment, a three-contact switch is used as the power supply switching circuit 3. The output terminal serving as the common terminal is electrically connected to the input of the power signal of the synthesis circuit 23, and the three input terminals serving as the contacts are connected to each power line (the first, second and sixth terminals of the input AISG connector 21). Are electrically connected to each other. The switch used for the power supply switching circuit 3 may be either mechanical (such as a relay) or electronic. When a power supply switching circuit 3 that requires a power supply is used, power may be supplied to the power supply switching circuit 3 from an arbitrary power supply line.

  In the present embodiment, a three-contact switch is used as the power supply switching circuit 3, but two two-contact switches 41 are used as shown in FIG. By connecting the output terminal (common terminal) to one input terminal (terminal to be a contact) of the switch 41 in the second stage, it is also possible to configure the same operation as that of the three-contact switch. is there. Further, as shown in FIG. 2B, a switch 42 with one contact (on / off operation type) is provided in each power supply line, and only the switch 42 of the power supply line to be output is closed and the other switches 42 are opened. Thus, the power supply switching circuit 3 may be configured to switch so that a power supply signal from a desired power supply line is output to the feeder line 12.

  As a trigger for switching the power supply switching circuit 3, as shown in FIG. 3A, a switching control signal input from the outside via the switching control signal input terminal 43 may be used. As shown in (b), an operation switch 44 for manual operation may be provided on the surface of the housing, and switching may be performed using the operation of the operation switch 44 as a trigger.

  The operation of the present embodiment will be described.

  In the BS modem 2 according to the present embodiment, a plurality of power supply lines for transmitting power supply signals having different voltages are connected, and a power supply signal from a desired power supply line among the plurality of power supply lines is output to the feeder line 12. A power supply switching circuit 3 for switching to is provided.

  By providing the power supply switching circuit 3, it is possible to select a power source to be transmitted by the coaxial interface method, and it is possible to select a power source used by the antenna modem 14 and the AISG device 17 and to supply power.

  In other words, according to the present invention, it is possible to supply a desired power source according to the power source used in the antenna modem 14 or the AISG device 17. As a result, it is possible to easily incorporate the BS modem 2 into an old antenna control system that uses only a specific power source, and also when the power source used by the antenna modem 14 or the AISG device 17 is changed. It is possible to easily cope with the problem by simply switching the circuit 3, and the flexibility and expandability of the antenna control system 1 can be improved.

  Next, another embodiment of the present invention will be described.

  A BS modem 41 shown in FIG. 4 is configured such that in the BS modem 2 of FIG. 1B, the power supply switching circuit 3 is configured by one two-contact switch so that two power supply lines can be switched. In this way, the power supply switching circuit 3 can be configured so that it can be selected which of the two types of power supplies is used without configuring all the three types of power supplies. Note that the two types of power sources that can be selected may be appropriately determined according to the system configuration. According to the BS modem 41, since the power supply switching circuit 3 can be configured by one two-contact switch, the circuit configuration is simplified and the cost can be reduced.

  A BS modem 51 shown in FIGS. 5A and 5B is an external power input connector 52 to which a power feeding device 53 provided separately from the control device 16 is connected in the BS modem 2 of FIG. Is further provided.

  As shown in FIG. 5B, the power feeding device 53 generates and outputs a power signal of voltages (10 to 30 V, +12 V, −48 V) defined by the AISG standard. To the external power input connector 52. Here, a case will be described in which a power supply device 53 that generates and outputs all three types of power supplies is described. In this case, as the power supply cable 54, it is necessary to use a cable having four electric wires corresponding to three power supply lines and a DC return line. What is necessary is just to comprise so that a power supply may be supplied to the electric power feeder 53 from a commercial power supply or another DC power supply device. The power feeding device 53 may be installed anywhere.

  In FIG. 5A, the external power input connector 52 has three power line terminals corresponding to three types of power supplies and a DC return line terminal, and the power line switching is performed for each power line terminal. The terminal is electrically connected to the corresponding input terminal of the circuit 3 and the terminal for the DC return line is electrically connected to the DC return line in the BS modem 2. That is, the BS modem 51 is configured such that the power signal input from the power supply device 53 via the external power input connector 52 is input to the power switching circuit 3 via the power line corresponding to the voltage of the power signal. Has been.

  Here, a case has been described in which a power supply device 53 that can supply all three types of power supplies is used. However, the power supply device 53 is not limited to this, and a power supply device 53 that supplies only one or two types of power supplies is used. May be. In this case, the power supply cable 54 may be one having two or three electric wires depending on the number of power supplies fed by the power supply device 53, and the external power input connector 52 may be a power supply device. What has only the terminal for power supply lines corresponding to the power supply which 53 supplies may be used.

  According to the BS modem 51, the power supply signal can be stably transmitted by the power supply from the power supply device 53, so that the control device 16 can be disposed at a position away from the BS modem 2. In addition, it is possible to supply power to the power source that is not supplied with power by the control device 16 using the power supply device 53.

  The BS modem 61 shown in FIG. 6 is identical to the BS modem 51 of FIG. 5 in that the internal wiring for connecting the terminals 1, 2 and 6 of the input AISG connector 21 and the power supply switching circuit 3 and the external power input connector 52 A diode 62 for preventing a backflow of current is provided in each of the internal wirings connecting the power supply line terminals and the power supply switching circuit 3.

  The diodes 62 provided in the 10-30 V power supply line and the +12 V power supply line are provided such that the input AISG connector 21 or the external power supply input connector 52 side is an anode and the power supply switching circuit 3 side is a cathode. The diode 72 provided in the −48V power supply line is provided such that the input AISG connector 21 or the external power supply input connector 52 side is the cathode and the power supply switching circuit 3 side is the anode.

  The input AISG connector 21 is a male connector, and a male connector is normally used as the external power input connector 52 which is a power input connector. However, in the male connector, terminals are exposed to the outside. Therefore, for example, when the power supply device 53 is connected to the external power input connector 52 and power is being supplied, if the input AISG connector 21 is not connected, the exposed terminal of the unconnected input AISG connector 21 is exposed. There is a risk that a short circuit will occur due to the contact of metal or the like, or an electric shock may occur due to a finger or the like coming into contact with the exposed terminal. According to the BS modem 61, by providing the diode 62, it becomes possible to prevent the reverse flow of current and prevent the voltage from appearing in the unconnected connectors 21 and 52, thereby eliminating the possibility of short circuit or electric shock. Can do.

  The BS modem 71 shown in FIG. 7 is a DC / DC converter that generates and outputs a power supply signal having a voltage different from that of the power supply signal from the power supply signal input from the control device 16 in the BS modem 1 of FIG. 72, and the power supply signal input from the control device 16 and the power supply signal generated by the DC / DC converter 72 are input to the power supply switching circuit 3 via the power supply line corresponding to the voltage of the power supply signal. It is a thing. According to the BS modem 71, it is possible to select a power source other than the power source to be fed by the control device 16 and output it to the feed line 12.

  The BS modem 81 shown in FIG. 8 further includes display means 82 for displaying the voltage of the power signal output from the power supply switching circuit 3 to the power supply line 12 in the BS modem 1 of FIG. In FIG. 8, the display means 82 is composed of a voltage detection circuit 83 that detects the voltage of the power supply signal output from the power supply switching circuit 3 and a display 84 that displays the voltage detected by the voltage detection circuit 83. Shows the case. The indicator 84 is provided in the casing of the BS modem 81 and is provided at a position where it can be visually recognized from the outside. Note that the display means 82 is not limited to this, and may be, for example, a display that is switched in conjunction with the switching of the power supply switching circuit 3. According to the BS modem 81, the voltage of the power source transmitted by the coaxial interface method can be easily discriminated visually from the outside of the casing of the BS modem 81.

  The present invention is not limited to the above-described embodiment, and it is needless to say that various modifications can be made without departing from the spirit of the present invention.

DESCRIPTION OF SYMBOLS 1 Antenna control system 2 BS modem 3 Power supply switching circuit 10 Antenna 11 Radio | wireless machine 12 Feed line 14 Antenna modem 15 Control cable 16 Control apparatus 17 AISG device

Claims (5)

An AISG device that controls the antenna in accordance with the AISG standard;
A control device for transmitting a control signal and a power signal to the AISG device;
Provided in the middle of the feeder line connecting the antenna and the radio, and connected to the AISG device, separates the modulation signal and the power supply signal from the inputted feeding signal, and demodulates the modulation signal to control signal And an antenna modem that outputs a control signal and a power supply signal to the AISG device, and a separated feeding signal to the feeding line on the antenna side, and is used in an antenna control system,
Provided in the middle of the feeder line on the radio side of the antenna modem, and connected to the control device, modulates a control signal input from the control device to generate a modulation signal, A BS modem that superimposes a power supply signal input from the control device on a power supply signal input from the wireless device and outputs the power signal to the power supply line on the antenna side,
A plurality of power supply lines that transmit power supply signals having different voltages are connected, and a power supply switching circuit is provided that switches among the plurality of power supply lines so that a power supply signal from a desired power supply line is output to the power supply line. BS modem. An external power input connector to which a power feeding device provided separately from the control device is connected;
The BS according to claim 1, wherein a power supply signal input from the power supply device via the external power supply input connector is input to the power supply switching circuit via a power supply line corresponding to a voltage of the power supply signal. modem. A DC / DC converter that generates and outputs a power supply signal having a voltage different from that of the power supply signal from the power supply signal input from the control device;
The power supply signal input from the control device and the power supply signal generated by the DC / DC converter are configured to be input to the power supply switching circuit via a power supply line corresponding to the voltage of the power supply signal. 2. BS modem according to 2. The BS modem according to claim 1, further comprising display means for displaying a voltage of a power signal output from the power switching circuit to the power supply line. An AISG device that controls the antenna in accordance with the AISG standard;
A control device for transmitting a control signal and a power signal to the AISG device;
Provided in the middle of a feeder line connecting the antenna and the radio, and connected to the control device, modulates a control signal input from the control device to generate a modulated signal, and the modulated signal and the control A BS modem that superimposes a power supply signal input from the device on a power supply signal input from the wireless device and outputs the power signal to the power supply line on the antenna side;
Provided in the middle of the power supply line on the antenna side of the BS modem, and connected to the AISG device, separates a modulation signal and a power supply signal from a power supply signal input from the BS modem, and provides a modem circuit. An antenna modem that demodulates the modulation signal and returns it to the control signal, outputs the control signal and the power signal to the AISG device, and outputs the separated feeding signal to the feeding line on the antenna side;
In an antenna control system with
The BS modem is
A plurality of power supply lines that transmit power supply signals having different voltages are connected, and a power supply switching circuit is provided that switches among the plurality of power supply lines so that a power supply signal from a desired power supply line is output to the power supply line. And antenna control system.