JP2004048141A - Common reception system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a common reception system that requires no installation of a coaxial cable up to each receiver and can flexibly cope with a poor reception area with a complicated geography. <P>SOLUTION: A reception antenna for common reception installed on a rooftop or the like of a high rise building causing radio wave interference receives a broadcast wave outputted from a transmission station and a head end device amplifies the received broadcast wave. The amplified broadcast wave is transmitted to a relay transmitter placed on a transmission pole of an area shaded under the building via a coaxial cable. The relay transmitter has a relay amplifier and a distribution device and one distributed signal is sent to a post-stage relay transmitter via the coaxial cable. The other distributed signal is transmitted from a transmission antenna for retransmission connected to the relay transmitter as a very weak radio wave. Each home directs its reception antenna to the transmission antenna of the relay transmitter to be capable of receiving the broadcast wave. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
[0002]
The present invention relates to a joint receiving system for retransmitting radio waves received by a joint antenna to each receiver in a building shadow area where a terrestrial wave from a broadcasting station cannot be directly received.
[0003]
[Prior art]
[0004]
In the current terrestrial television broadcasting, in the shadowy areas such as high-rise buildings and expressways, the electric field received by the radio wave is low, and the reception is difficult. A receiving system is used.
[0005]
In a conventional joint reception system, a reception antenna and a transmission antenna are provided on the roof of a high-rise building, a radio wave from a broadcasting station is received by the reception antenna, amplified to a predetermined power, and transmitted from the transmission antenna to a difficult viewing area at the same frequency. Retransmission is performed. In addition, a CATV system that uses a coaxial cable instead of a transmission antenna and transmits a cable to each receiver in a difficult-to-view area is also used.
[0006]
[Problems to be solved by the invention]
[0007]
However, the conventional joint receiving system has the following problems.
[0008]
When retransmission is performed using a transmitting antenna, it has been difficult to cover a difficult-to-view area in an appropriate state using one antenna. For example, radio waves do not reach directly below a high-rise building equipped with a transmitting antenna, and cannot be received. In addition, in the vicinity of a high-rise building, the receiving antenna must be installed upward, but the normal receiving antenna can be installed horizontally, and it is difficult to fix it with an elevation angle. Was. Further, in a distant place, a radio wave from a broadcasting station and a radio wave from a transmitting antenna of the joint receiving system interfere with each other, which may cause a new reception obstacle.
[0009]
On the other hand, when a cable is transmitted to each receiver using a coaxial cable, there is a problem that a large amount of cost is required for construction of the cable and the relay amplifier.
[0010]
The present invention solves the problems of the prior art, and provides a joint receiving system that does not require the installation of a coaxial cable to each receiver and that can flexibly cope with difficult-to-view areas on complex terrain. is there.
[0011]
[Means for Solving the Problems]
[0012]
In order to solve the above-mentioned problem, the present invention provides a joint receiving system in a difficult viewing area, a receiving antenna for receiving a radio wave output from a broadcasting station, and a broadcast wave to be retransmitted from the radio wave received by the receiving antenna. And a main amplifier that amplifies an input signal given from the receiver to a predetermined level and outputs the amplified signal, and amplifies a signal input to an input terminal. A relay transmitter for branching and outputting to an output terminal and transmitting from a transmitting antenna, a first cable connecting between an output side of the main amplifier and an input terminal of the relay transmitter, and the relay transmitter , And a second cable connecting between the input terminal of the relay transmitter at the subsequent stage.
[0013]
According to the present invention, since the joint receiving system is configured as described above, the following operation is performed.
[0014]
The radio wave output from the broadcast station is received by a receiving antenna installed on the roof of a high-rise building or the like, and the broadcast wave to be retransmitted is selectively received by the receiver. The broadcast wave is adjusted in level by the receiver, amplified to a predetermined level by the main amplifier, and transmitted to the relay transmitter via the first cable. In a relay transmitter, a signal input to an input terminal is amplified and branched, one signal is output to an output terminal, and the other signal is transmitted from a transmission antenna.
[0015]
Further, the output terminal of the relay transmitter is connected to a relay transmitter at a subsequent stage via a second cable, so that a plurality of relay transmitters can be connected in series. Since each relay transmitter has a transmission antenna for outputting a broadcast wave for retransmission, the retransmitted broadcast wave is received by directing a reception antenna of a home in a difficult-to-view area to this transmission antenna. be able to.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
[0017]
(1st Embodiment)
[0018]
FIG. 1 is a conceptual diagram of a joint receiving system according to a first embodiment of the present invention.
[0019]
This joint receiving system re-transmits to a home in which a broadcast radio wave from a transmitting station cannot be directly received in a high-rise building shadow area or the like, using a weak radio wave. This joint reception system has a reception antenna for joint reception installed on the roof of a high-rise building or the like that can directly receive radio waves from a transmitting station. The receiving antenna is connected to a receiver for selecting and receiving a broadcast wave to be retransmitted and a head-end device including a main amplifier for amplifying the received broadcast wave.
[0020]
On the other hand, the difficult-to-view area behind the building is divided into a plurality of areas according to road divisions and the like, and a transmission pole is provided for each area. A relay transmitter that outputs a retransmission radio wave with weak power is attached to the transmission pole, and the headend device and these relay transmitters are connected in series or in parallel via a coaxial cable. The receiving antenna of each home is installed toward the nearest relay transmitter, and receives a broadcast wave retransmitted from the relay transmitter with weak power.
[0021]
FIG. 2 is a specific configuration diagram of the joint reception system of FIG.
[0022]
This joint reception system includes a reception antenna 11 for joint reception installed on the roof of a high-rise building or the like, and a head-end device including a receiver 12 and a main amplifier 20 is connected to the reception antenna 11. .
[0023]
The receiver 12 receives a broadcast wave, such as a television broadcast or an FM broadcast, to be retransmitted and received by the receiving antenna 11 for each channel, adjusts the broadcast wave to a predetermined level, and outputs a mixed wave thereof. . The output side of the receiver 12 is connected to the input terminal 21 of the main amplifier 20. The main amplifier 20 amplifies the broadcast wave for retransmission to a predetermined level, adds a pilot signal of a level corresponding to the input level to the amplified signal, and outputs the resulting signal.
[0024]
A splitter 22 is connected to an input terminal 21 of the main amplifier 20, and a broadband amplifier (AMP) 23 and a level detector 24 are connected to first and second output sides of the splitter 22, respectively. . The output side of the amplifier 23 is connected via a variable attenuator (ATT) 25 to an amplifier 26 for automatic gain adjustment. The output of the amplifier 26 is connected to a splitter 27, the first output of which is connected to the first input of a mixer 28.
[0025]
The second output side of the splitter 27 is connected to the input side of the gain controller 29, the output signal of the gain controller 29 controls the amount of attenuation of the variable attenuator 25, and the output level of the amplifier 26 is constant. They are kept at the level.
[0026]
The main amplifier 20 further has a pilot oscillator 30 for generating a pilot signal PIL of a specific frequency, and an output side of the pilot oscillator 30 is connected to an input side of a variable attenuator 31 controlled by an output signal of the level detector 24. It is connected to the. As a result, the pilot signal PIL having a level corresponding to the input level of the broadcast wave supplied to the input terminal 21 is output from the variable attenuator 31. The output side of the variable attenuator 31 is connected to the second input side of the mixer 28, and the output side of the mixer 28 is connected to the output terminal 32.
[0027]
The output terminal 32 of the main amplifier 20 is connected to the input terminal 51 of the relay transmitter 50 via the cable 40.
[0028]
A splitter 52 is connected to an input terminal 51 of the relay transmitter 50, and a broadband amplifier 53 and a band-pass filter (BPF) 54 are connected to first and second output sides of the splitter 52, respectively. . The band-pass filter 54 passes only the frequency component of the pilot signal PIL. The output side of the amplifier 53 is connected to an amplifier 56 via a variable attenuator 55, and the output side of the amplifier 56 is connected to a splitter 57. The first output of the splitter 57 is connected to the splitter 58, and the second output is connected to the output controller 59 and the squelch controller 60.
[0029]
The output controller 59 outputs a control signal to the variable attenuator 55 based on the signal level of the amplifier 56 provided via the splitter 57 and the level of the pilot signal PIL provided from the band-pass filter 54. . Thus, the signal level provided from variable attenuator 55 to amplifier 56 is controlled to a value corresponding to the level of pilot signal PIL.
[0030]
The squelch controller 60 detects the noise level in the signal output from the amplifier 56, and when this noise level exceeds a certain value, determines that the valid signal has been interrupted, and determines the amount of attenuation of the variable attenuator 55. Is set to the maximum value. This makes it possible to prevent the relay transmitter 50 from outputting a strong noise when the input signal is interrupted.
[0031]
The first and second output sides of the splitter 58 are connected to output terminals 61 and 62, respectively. The output terminal 61 is connected to a relay transmitter at the next stage via a cable 70, and the output terminal 62 is connected to a transmission antenna 80 for retransmission.
[0032]
Next, the operation of FIG. 2 will be described.
[0033]
Broadcast waves such as television broadcasts and FM broadcasts are received by a reception antenna 11 for joint reception installed on the roof of a high-rise building or the like, and provided to a receiver 12. In the receiver 12, a broadcast wave to be retransmitted is selected from the broadcast waves received by the receiving antenna 11, adjusted to a predetermined level for each channel, and the mixed wave is output. The mixed wave output from the receiver 12 is input from the input terminal 21 as an input signal of the main amplifier 20. The input signal is split into two by a splitter 22, most of which is provided to an amplifier 23 and amplified, and a part is provided to a level detector 24.
[0034]
The output signal of the amplifier 23 is input to a gain control amplifier 26 via a variable attenuator 25, amplified by the amplifier 26, branched by a splitter 27, and a part of the output signal is given to a gain controller 29. Can be In the gain controller 29, a control signal is generated such that the output level of the amplifier 26 becomes constant, and the amount of attenuation of the variable attenuator 25 is controlled. By the feedback operation of the gain controller 29 and the variable attenuator 25, the output level of the amplifier 26 is maintained at a predetermined level.
[0035]
The level of a part of the input signal split by the splitter 22 is detected by the level detector 24, and a voltage corresponding to the average level is supplied to the variable attenuator 31 as a control voltage. On the other hand, to the input side of the variable attenuator 31, a pilot signal PIL of a predetermined level at a predetermined frequency is given from the pilot oscillator 30. As a result, a pilot signal PIL having a level corresponding to the average level of the input signal of the main amplifier 20 is output from the output side of the variable attenuator 31.
[0036]
Most of the output signal of the amplifier 26 split by the splitter 27 and the pilot signal PIL set to a level corresponding to the average level of the input signal by the variable attenuator 31 are mixed by the mixer 28 and output to the output terminal 32. To the cable 40.
[0037]
The output signal of the main amplifier 20 sent to the cable 40 is sent to the relay transmitter 50 and split into two by the splitter 52. Most of the output signal is given to the amplifier 53 and amplified. It is provided to a band pass filter 54. In band pass filter 54, pilot signal PIL is extracted and provided to output controller 59. The output signal of the amplifier 53 is input to a gain control amplifier 56 via a variable attenuator 55, amplified by the amplifier 56, then branched by a splitter 57, and part of the output controller 59. Is given to the squelch controller 60.
[0038]
The output controller 59 compares the signal level output from the amplifier 56 and branched by the splitter 57 with the level of the pilot signal PIL extracted by the band-pass filter 54, and the output level of the amplifier 56 is set to the level of the pilot signal PIL. A control signal having a value corresponding to the level is generated, and the amount of attenuation of the variable attenuator 55 is controlled. By the feedback operation of the output controller 59 and the variable attenuator 55, the output level of the amplifier 56 is maintained at a level corresponding to the level of the pilot signal PIL applied to the relay transmitter 50.
[0039]
The noise level of a part of the signal split by the splitter 57 is detected by the squelch controller 60. When the noise level exceeds a certain value, the squelch controller 60 outputs a control signal for maximizing the attenuation of the variable attenuator 55. This prevents noise output from the relay transmitter 50 when the input signal is interrupted. Most of the signals split by the splitter 57 are further split by the splitter 58 and output from the output terminals 61 and 62.
[0040]
A transmission antenna 80 for retransmission is connected to the output terminal 62, and a weak radio wave is transmitted from the transmission antenna 80 to the area of the hard-to-view area.
[0041]
On the other hand, a cable 70 is connected to the output terminal 61, and a similar relay transmitter is further connected to the cable 70. Thus, the plurality of relay transmitters 50 are connected in series to the respective areas via the cable 70, and the same weak radio wave is output from the transmission antenna 80 for each of these areas.
[0042]
Therefore, each home can receive the retransmitted broadcast wave by directing the receiving antenna to the nearest transmitting antenna 80.
[0043]
As described above, the joint receiving system according to the first embodiment has the following advantages.
[0044]
(1) Since the broadcast wave is retransmitted using weak radio waves between the relay transmitter 50 and the receiver in each home, it is not necessary to lay a coaxial cable to each receiver.
[0045]
(2) Since the difficult-to-view area is divided into a plurality of areas, and the relay transmitter 50 and the transmission antenna 80 are provided for each area, it is possible to flexibly cope with the difficult-to-view area with complicated terrain.
[0046]
(3) The main amplifier 20 outputs a pilot signal PIL corresponding to the level of the input signal together with the broadcast wave, and each relay transmitter 50 adjusts the output of the amplifier 56 so as to match the level of the received pilot signal PIL. It is configured to adjust. Thereby, the broadcast wave can be retransmitted from the transmission antenna 80 of each relay transmitter 50 with substantially the same strength as the reception electric field of the reception antenna 11.
[0047]
(4) Since a plurality of transmitting antennas 80 are arranged in the hard-to-view area, by directing the receiving antenna of each home to an appropriate transmitting antenna 80, it is possible to avoid radio wave interference with the original broadcast wave.
[0048]
(Second embodiment)
[0049]
FIG. 3 is a configuration diagram of a main amplifier showing a second embodiment of the present invention. This main amplifier 20A is provided in place of the main amplifier 20 in FIG. 2, and the same elements as those in FIG. 2 are denoted by the same reference numerals.
[0050]
In the main amplifier 20A, the level detector 24A is provided in place of the level detector 24 while the level detector 24 in FIG. 2 is deleted, and the second output side of the leveler 27 is connected to the input side of the level detector 24A. Connected to. The output signal of the level detector 24A is provided as a control signal of the variable attenuator 31. Other configurations are the same as those of the main amplifier 20 in FIG.
[0051]
In the main amplifier 20A, the level of the pilot signal PIL mixed with the output signal is controlled by the level of the amplified input signal, that is, the level of the output signal. Since the input and output levels of main amplifier 20A are always in a fixed relationship by automatic gain control, a pilot signal PIL having a level corresponding to the level of the input signal can be output, similarly to main amplifier 20 in FIG. .
[0052]
The second embodiment has the following advantages in addition to the advantages (1) to (4).
[0053]
(5) Since the input level of the level detector 24A is high, the configuration is simplified, and the branching device 22 is not required, so that the circuit can be simplified and more stable operation can be performed.
[0054]
(Third embodiment)
[0055]
FIG. 4 is a configuration diagram of a joint receiving system according to a third embodiment of the present invention, wherein components common to those in FIG. 2 are denoted by common reference numerals.
[0056]
In this joint receiving system, a measured value of the input signal level is transmitted as digital data instead of an analog pilot signal indicating the level of the input signal. For this reason, in FIG. 4, a digitally controlled main amplifier 20B and a relay transmitter 50B are provided instead of the main amplifier 20 and the relay transmitter 50 in FIG.
[0057]
The main amplifier 20B includes an analog / digital converter (hereinafter, referred to as “ADC”) 33, a processor (CPU) 34, and a modulator 35 instead of the pilot oscillator 30 and the variable attenuator 51 of the main amplifier 20 in FIG. Is provided.
[0058]
The ADC 33 converts an analog signal of the input level detected by the level detector 24 into a digital value. The processor 34 generates data DAT for setting the output level of the relay transmitter 50B based on the digital value converted by the ADC 33. The modulator 35 modulates the data DAT generated by the processor 34 and sends it out to the cable 40. The output of the modulator 35 is connected to the second input of the mixer 28.
[0059]
On the other hand, the relay transmitter 50B includes a demodulator 63, an ADC 64, a processor 65, and a digital-to-analog converter (hereinafter, “Digital-to-analog converter”) instead of the band-pass filter 54 and the output controller 59 of the relay transmitter 50 in FIG. DAC ”66).
[0060]
The demodulator 63 extracts a modulation signal from the signals branched by the splitter 52 and restores the original data DAT. The data DAT restored by the demodulator 63 is provided to the processor 65. The ADC 64 converts the level of the output signal of the relay transmitter 50B split by the splitter 57 into a digital value. The digital value obtained by the ADC 64 is supplied to the processor 65.
[0061]
The processor 65 generates a control signal for controlling the variable attenuator 55 based on the data DAT provided from the demodulator 63 and the digital value provided from the ADC 64. The control signal generated by the processor 65 is supplied to a DAC 66, converted into an analog control signal by the DAC 66, and supplied as a control signal for the variable attenuator 55. Other configurations are the same as those in FIG.
[0062]
In this joint receiving system, an input signal provided from the receiver 12 to the main amplifier 20A is branched by a branching device 22, a part of which is provided to a level detector 24, and an average level is detected. It is converted to a digital value corresponding to the level of the input signal. The digital value is provided to the processor 34, and data DAT for setting the output level of the relay transmitter 50B is generated. The data DAT is modulated by the modulator 35, mixed with a retransmission broadcast wave output from the amplifier 26 by the mixer 28, and transmitted to the relay transmitter 50 B via the cable 40.
[0063]
In the relay transmitter 50B, the input signal is split by the splitter 52, a part of which is provided to the demodulator 63 to restore the data DAT and to the processor 65. On the other hand, the output signal of relay transmitter 50B output from amplifier 56 is split by splitter 57, and a part thereof is provided to ADC 64. The ADC 64 generates a digital value indicating the average level of the output signal and supplies the digital value to the processor 65.
[0064]
In the processor 65, a control signal for the variable attenuator 55 is generated based on the data DAT provided from the demodulator 63 and the digital value provided from the ADC 64, and provided to the DAC 66. In the DAC 66, the control signal supplied from the processor 65 is converted into an analog control signal, and supplied to the variable attenuator 55. As a result, the output level of the relay transmitter 50B becomes the value specified by the data DAT, and is transmitted from the transmission antenna 80 and output to the next relay transmitter 50B via the cable 70.
[0065]
As described above, the joint receiving system according to the third embodiment has the following advantages in addition to the advantages (1), (2), and (4).
[0066]
(6) The main amplifier 20B outputs the data DAT corresponding to the level of the input signal together with the broadcast wave, and each relay transmitter 50B adjusts the output of the amplifier 56 to match the value of the received data DAT. It is composed. Thus, the broadcast wave can be retransmitted from the transmission antenna 80 of each relay transmitter 50B with almost the same strength as the reception electric field of the reception antenna 11 without being affected by the fluctuation of the transmission loss of the cables 40 and 70.
[0067]
Note that the present invention is not limited to the above embodiment, and various modifications are possible. For example, there are the following modifications.
[0068]
(A) In a small and simple system in which the number of relay transmitters connected in cascade is small, an automatic gain control amplifier may be used without using the pilot signal PIL or the data DAT of the input signal level.
[0069]
(B) Although the main amplifiers 20, 20A, and 20B have one output terminal 32, a plurality of output terminals 32 may be provided to connect a plurality of relay transmitters 50 and the like. Similarly, the relay transmitters 50 and 50B may be provided with a plurality of output terminals 61 so that the plurality of relay transmitters 50 and 50B can be connected.
[0070]
(C) Although the automatic gain amplifier circuit is configured by combining the variable attenuator 25 and the fixed amplifier 26, a variable gain amplifier may be used.
[0071]
(D) As a method of determining that the input signal has been interrupted in the squelch controller 60, the level of the pilot signal PIL input to the relay transmitter 50 is monitored, and this is effective when this pilot signal PIL is not detected. It may be determined that the signal is interrupted, and the attenuation of the variable attenuator 50 may be set to the maximum value.
[0072]
【The invention's effect】
[0073]
As described above in detail, according to the first aspect, the relay transmitter that amplifies and splits the signal given from the main amplifier, outputs the amplified signal to an output terminal to a subsequent stage, and transmits the signal from a transmission antenna is provided. are doing. As a result, there is no need to lay a coaxial cable to the receivers in each home, and a joint receiving system that can flexibly cope with difficult-to-view areas with complicated terrain can be obtained.
[0074]
According to the second aspect, the main amplifier includes the level detector that detects the level of the input signal, and the pilot oscillator that generates a pilot signal having a level corresponding to the input signal. In addition, the relay transmitter includes an amplifier that amplifies a signal according to the received pilot signal. Thereby, the level of the retransmitted broadcast wave transmitted from the transmission antenna can be set to an appropriate value.
[0075]
According to the third aspect, the main amplifier includes the level detector that detects the level of the output signal, and the pilot oscillator that generates a pilot signal having a level corresponding to the output signal. Further, the relay transmitter includes an amplifier that amplifies a signal according to the received pilot signal. Thereby, the level of the retransmitted broadcast wave transmitted from the transmission antenna can be set to an appropriate value.
[0076]
According to the fourth aspect, the main amplifier includes a level detector that detects a level of the input signal, an ADC that converts the detected level into a digital value, a processor that generates control data based on the digital value, A modulator is provided for modulating the control data to generate a transmission data signal. The relay transmitter includes an amplifier that amplifies a signal according to the received control data. Thereby, the level of the retransmitted broadcast wave transmitted from the transmission antenna can be set to an appropriate value without being affected by the transmission loss of the cable and the like.
[0077]
According to the fifth aspect, the relay transmitter includes the squelch controller that stops the output of the amplifier when the noise level exceeds a certain value. This eliminates the possibility that strong noise is output when the input signal is interrupted for some reason.
[0078]
According to the sixth aspect, the relay transmitter includes the squelch controller that stops the output of the amplifier when the pilot signal is not detected. This has the same effect as the fifth invention.
[Brief description of the drawings]
FIG. 1 is a conceptual diagram of a joint receiving system according to a first embodiment of the present invention.
FIG. 2 is a specific configuration diagram of the joint reception system of FIG. 1;
FIG. 3 is a configuration diagram of a main amplifier according to a second embodiment of the present invention.
FIG. 4 is a configuration diagram of a joint receiving system according to a third embodiment of the present invention.
[Explanation of symbols]
11 Receiving antenna 12 Receiver 20, 20A, 20B Main amplifier 23, 26, 53, 56 Amplifier 24 Level detector 25, 31, 55 Variable attenuator 30 Pilot oscillator 33, 64 ADC (analog-to-digital converter)
34, 65 Processor 35 Modulator 40, 70 Cable 50, 50B Relay transmitter 54 Band-pass filter 59 Output controller 60 Squelch controller 63 Demodulator 66 DAC (Digital-to-Analog Converter)
80 transmitting antenna

Claims (6)

A receiving antenna for receiving radio waves output from a broadcasting station,
A receiver that selectively receives a broadcast wave to be retransmitted from radio waves received by the receiving antenna, adjusts its level, and outputs the adjusted broadcast wave,
A main amplifier that amplifies an input signal given from the receiver to a predetermined level and outputs the amplified signal;
A relay transmitter that amplifies and branches a signal input to an input terminal, outputs the signal to an output terminal, and transmits the signal from a transmission antenna;
A first cable connecting between an output side of the main amplifier and an input terminal of the relay transmitter;
A second cable connecting between the output terminal of the relay transmitter and the input terminal of the subsequent relay transmitter,
A joint receiving system comprising: The main amplifier is
An amplifier for amplifying an input signal given from the receiver to a predetermined level;
A level detector for detecting a level of an input signal given from the receiver;
A pilot oscillator that generates a pilot signal having a level corresponding to the level of the input signal detected by the level detector;
A mixer for mixing and outputting the pilot signal to the output signal of the amplifier,
The relay transmitter,
A filter for extracting the pilot signal from a signal input to the input terminal,
An amplifier for amplifying a signal input to the input terminal so that an output level according to the level of the pilot signal extracted by the filter is provided.
The joint receiving system according to claim 1, wherein: The main amplifier is
An amplifier for amplifying an input signal given from the receiver to a predetermined level;
A level detector for detecting an output level of the amplifier;
A pilot oscillator that generates a pilot signal having a level corresponding to the output level detected by the level detector;
A mixer for mixing and outputting the pilot signal to the output signal of the amplifier,
The relay transmitter,
A filter for extracting the pilot signal from a signal input to the input terminal,
An amplifier for amplifying a signal input to the input terminal so that an output level according to the level of the pilot signal extracted by the filter is provided.
The joint receiving system according to claim 1, wherein: The main amplifier is
An amplifier for amplifying an input signal given from the receiver to a predetermined level;
A level detector for detecting a level of an input signal given from the receiver;
An analog-to-digital converter for converting an input level detected by the level detector into a digital value;
A processor that generates control data based on the digital value;
A modulator that modulates the control data to generate a transmission data signal;
A mixer that mixes and outputs the transmission data signal with the output signal of the amplifier,
The relay transmitter,
A demodulator that extracts the transmission data signal from the signal input to the input terminal and demodulates the control data.
An amplifier that amplifies a signal input to the input terminal so that the output level is in accordance with the control data demodulated by the demodulator.
The joint receiving system according to claim 1, wherein: The relay transmitter monitors a noise level in an output signal of an amplifier that amplifies a signal input to the input terminal, and stops an output of the amplifier when the noise level exceeds a certain value. The joint receiving system according to claim 2, further comprising a squelch controller. The relay transmitter monitors a pilot signal in an output signal of an amplifier that amplifies a signal input to the input terminal, and includes a squelch controller for stopping output of the amplifier when the pilot signal is not detected. The joint receiving system according to claim 2, 3, or 4, further comprising:

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