JP4582873B2 - Bidirectional amplifier - Google Patents

Description

[0001]
[Technical field to which the invention belongs]
The present invention amplifies a downstream signal input from a bidirectional CATV system via a lead-in line and distributes it to a plurality of terminals, and amplifies an upstream signal input from the terminal side and outputs it to the lead-in line side The present invention relates to an amplifying apparatus.
[0002]
[Prior art]
In a two-way CATV system, when a signal is drawn from each protector to an output terminal (terminal terminal) of each room, in recent years, with the increase in the size of a house, generally 4 to 6 distributions are required. A 4-6 distributor is used. In order to compensate the distribution loss of the distributor, a bidirectional amplifier is generally used together. In this case, all output terminals are bidirectional terminals.
[0003]
[Problems to be solved by the invention]
In the conventional bidirectional CATV system as described above, since the output terminals are all bidirectional terminals as described above, noise in the same frequency band as the upstream signal band enters from the output terminal, and the bidirectional amplifier described above. And is transmitted to the CATV center apparatus through the CATV transmission path, disturbing other communications, and may not be able to communicate. In order to prevent this interference, most of the output that uses only the downstream signal can be taken by blocking the upstream signal from passing through the output terminal and interposing only a downstream signal (for example, a high-pass filter). The filter must be installed at the terminal, which deteriorates the appearance and causes a problem that the user or the CATV operator must bear the cost. Further, even when bidirectional communication is performed, if the entire upstream signal band is passed, there is a possibility that communication may not be possible particularly in a noisy 10 to 30 MHz band. In order to reduce this influence, it is possible to take measures by interposing a filter that passes only the upstream signal and downstream signal of 30 MHz to 55 MHz and blocks the upstream signal of 10 MHz to 30 MHz, for example. This is not preferable because it is necessary to install these filters in place, and to prepare two types of filters, and to increase the labor for managing inventory and the like.
[0004]
The present invention has been made in view of the above-described conventional problems. In a bidirectional amplifying apparatus capable of outputting upstream signals input from a plurality of output terminals connected to the terminal side from the input terminals to the CATV transmission line, The purpose is to limit the input of upstream signals from the network and to switch the transmission frequency band of upstream signals.
[0005]
[Means for Solving the Problems and Effects of the Invention]
The invention described in claim 1 made to achieve such an object,
An input terminal connected to the lead-in line of the bidirectional CATV system for inputting a downstream signal from the lead-in line;
A downstream amplifier circuit that amplifies the downstream signal input from the input terminal;
A distribution circuit for distributing the downlink signal amplified by the amplification circuit to a plurality of;
A plurality of output terminals for outputting the downstream signals distributed by the distribution circuit to the terminal side,
With
Among the plurality of output terminals, some output terminals are unidirectional output terminals that only output the downlink signal to the terminal side, and the remaining output terminals output the downlink signal to the terminal side and the terminal side Is set as a bi-directional output terminal for capturing upstream signals input from
A signal path for transmitting the upstream signal is provided between the bidirectional output terminal and the input terminal,
Moreover, the signal path for uplink signal transmission includes
An upstream amplification circuit for amplifying the upstream signal;
A band switching circuit for switching the transmission frequency band of the upstream signal that can pass through the signal path;
The gist of the present invention is a bidirectional amplifying device characterized in that is provided.
[0006]
Therefore, according to the bidirectional amplifier of the present invention, as a TV receiver Yachi Yuna, when connecting or device only transmits the downlink signal, these devices, by connecting to a unidirectional output terminal That's fine. Since the unidirectional output terminal is only connected to the downstream amplifier circuit via the distribution circuit, even if noise having the same frequency as the upstream signal frequency band is applied to this terminal, it is transmitted to the CATV center. Never happen.
[0007]
Further, uplink signal inputted to the bidirectional output terminal via the signal path for upstream signal transmission, but is transmitted to the input terminal, this signal path, the order to switch the transmission frequency band of the uplink signal A band switching circuit is provided.
[0008]
For this reason, for example, in an area where the inflow noise level is relatively large , there is a possibility of disturbing other communications. Therefore, the transmission frequency band of the upstream signal is changed to the normal frequency band (for example , via the band switching circuit). By switching to a frequency band (for example, 30 MHz to 55 MHz) narrower than 10 MHz to 55 MHz, other services communicating at 10 MHz to 30 MHz can be prevented from being affected .
When a bidirectional output terminal is not necessary, in other words, when only a general TV receiver that does not connect a bidirectional terminal device (STB, cable modem, etc.) is connected, the transmission frequency band of the upstream signal is zero. It may be possible to set to .
[0009]
Next, in the bidirectional amplifying device according to claim 2, a plurality of bidirectional output terminals are provided, and each bidirectional output terminal has a signal path for uplink signal transmission from the bidirectional output terminal. Is provided with an upstream signal blocking switch for switching whether or not the upstream signal is passed.
Therefore, according to the bidirectional amplifying device described in claim 2, each bidirectional output terminal can be caused to function as a unidirectional output terminal by operating the upstream signal blocking changeover switch. , Bidirectional output terminal bi-directional / unidirectional can be selected.
Further , for example, bidirectional (10 MHz to 55 MHz), bidirectional (30 MHz to 55 MHz), and unidirectional can be freely set by operating the band switching circuit and the upstream signal blocking switching switch. There is an excellent effect that it can cope with a change in the corresponding terminal device.
Further, in the bidirectional amplifying device according to claim 3, in addition to an input terminal for inputting a downstream signal from the lead-in line, an input terminal for inputting a satellite reception signal is provided. Mixing means for generating a downlink signal to be output from each output terminal to the terminal side by mixing the downlink signal input from the input terminal and the satellite reception signal is provided.
For this reason, according to the bidirectional amplifying device according to claim 3, in addition to the downlink signal transmitted from the CATV system, the satellite reception signal received by the BS antenna or the CS antenna is also transmitted to the terminal side. can do.
Further, in the bidirectional amplifying device according to claim 4, a filter for separating a polarization switching signal input from the terminal side is provided at each of the bidirectional output terminal and the unidirectional output terminal. The input terminal for inputting the satellite reception signal is provided with a filter for superimposing the polarization switching signal separated by the separation filter on the input terminal and outputting the signal from the input terminal. It has been.
For this reason, according to the bidirectional amplifying device described in claim 4, the user can receive a desired broadcast only by selecting a channel with the CS tuner without being aware of the polarization. Furthermore, among a plurality of output terminals, the CS tuner can be connected to any terminal. In other words, since any room can be connected, there is an excellent effect that the room in which the CS tuner is installed can be arbitrarily determined as necessary.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
First, FIG. 6 is a block diagram showing the configuration of a bidirectional CATV system.
In FIG. 6, reference numeral 1 denotes a house, which includes an apartment house and an individual house (detached house). 2 is a lead-in line from the CATV system, 3 is a CS antenna that receives a CS signal, 3a is a CS converter that converts the CS received signal to an IF band, 4 is a BS antenna that receives a BS signal, and 4a is an BS band that receives a BS signal BS converter for converting the, 5 bidirectional amplifier (corresponding to the bidirectional amplifier of the present invention. hereinafter, simply referred to as amplifier) 6 receives the BS-CS signal, and outputs the video and audio, etc. signals tuner , 56 is a TV receiver for outputting the video / audio output from the tuner 6 , 57 is a cable modem, 58 is an information terminal device, and 59 is a set top box (hereinafter referred to as STB).
Further, 7, 8, 9 is an input terminal of the bidirectional amplifier 5, 7 is connected to the CATV drop cable 2, those containing a first signal (VHF and UHF signals from the CATV drop cable 2, the frequency is, for example, 69MHz～770MHz. hereinafter, type) that bidirectional downstream signal, the fourth signal (frequency is, for example, 10MHz～55MHz. hereinafter, an input for outputting a): bidirectional uplink signal terminal, 8, a third signal CS converter 3a for satellite communication receiver outputs (frequency is, for example, 1527MHz～2150MHz. hereinafter referred to CS-IF signal) input terminal for inputting, 9, second signal (frequency BS converter 4a for receiving satellite broadcasting is outputted is, for example, 1035MHz～1335MHz. hereinafter, the BS-IF signal U), which is an input terminal for inputting.
Note that the output signal of the mixer 55 may be connected to the input terminal 7 instead of the CATV lead-in line 2. A VHF reception antenna 53 and a UHF reception antenna 54 are connected to the mixer 55.
Further, 10 is a first output terminal of the bidirectional amplifier 5 (hereinafter, referred to as a bidirectional output terminal), and by operating the up signal blocking changeover switch 12 to be described later, whereas either bidirectional or unidirectional Can be selected. Further, 11 is a second output terminal of the bidirectional amplifier 5 (hereinafter, the single referred way output terminal), and from this output terminal 11 is outputted only downlink signal.
[0011]
Next, the configuration of the bidirectional amplifier 5 will be described in detail with reference to FIG.
The bi-directional amplifier 5, an input terminal 9 for inputting an input terminal 8, BS-IF signal for entering the input terminal 7, CS-IF signal to enter a bi-directional downstream signal, bidirectional and single A plurality of bidirectional output terminals 10 whose directions can be switched, a plurality of unidirectional output terminals 11, and a plug 39 for power supply input are provided. Further, lightning arresters are attached to the input terminal 7, the input terminal 8, the input terminal 9, the bidirectional output terminal 10 and the unidirectional output terminal 11, respectively.
In FIG. 1, when a user generates data for reservation of a pay program and TV shopping, etc. to an external interactive CATV system center device, the data is generated by an information terminal device such as a personal computer. Is converted into a bidirectional upstream signal that can be transmitted by an external bidirectional CATV system by the cable modem 57, and this bidirectional upstream signal is transmitted through a coaxial cable to the bidirectional output terminal 10 of the bidirectional amplifier 5. Entered. Similarly, by operating the operation button of the STB 59, the bidirectional upstream signal is input to the bidirectional output terminal 10.
A bidirectional upstream signal input to the bidirectional output terminal 10 is input to a power supply signal separation filter 41 described later, and is taken into the amplifier 5. The bidirectional upstream signal input to the power supply signal separation filter 41 is input to a bidirectional upstream signal blocking changeover switch 12 described later and a distribution mixing circuit 27 as a mixing circuit.
Bidirectional uplink signal mixed with bidirectional uplink signal other interactive output terminal 10 in distributive mixing circuit 27, two-way downstream signal, BS-IF signal, prevents the CS-IF signals, a bidirectional uplink signal A filter 18 (for example, a low-pass filter; hereinafter referred to as LPF) to be passed is limited to a predetermined bandwidth by a band switching circuit 17 to be described later, and is amplified or attenuated to a predetermined level by a gain adjusting circuit 16, an amplifier circuit 15, and an attenuation circuit 14. , through the filter 13 which passes through the two-way uplink signal blocks the bidirectional downlink signal is transmitted to the input terminal 7. Then, the transmitted bidirectional upstream signal is transmitted to the CATV center apparatus by a cable connected to the input terminal 7 and processed by the center apparatus.
[0012]
Next, the bidirectional downstream signal transmitted through the CATV lead-in line 2 is input to the input terminal 7 of the amplifier 5. The bidirectional downstream signal input to the input terminal 7 is input to the filter 19 that blocks the bidirectional upstream signal and passes only the bidirectional downstream signal (for example, a high-pass filter; hereinafter referred to as HPF) and is taken into the amplifier 5. .
The bidirectional downstream signal input to the filter 19 is filtered by a filter 20 (for example, LPF) for removing an 800 MHz band interference wave, an attenuation circuit 21, a gain adjustment circuit 22, an amplification circuit 23, a tilt circuit 24, and an amplification circuit 23. Amplified to a predetermined level, the CATV upstream signal passes and is transmitted to a filter 25 (for example, LPF) for blocking the passage of the BS · CS-IF signal, and BS · B from the input terminal 8 and the input terminal 9 described later. It is combined with the CS-IF signal and input to the distribution circuit 36.
One of the downlink signals equally distributed by the distribution circuit 36 (specifically, a bidirectional downlink signal and a signal obtained by combining a BS / CS-IF signal) blocks the bidirectional uplink signal, and the bidirectional downlink signal and the BS The signal is input to a filter 26 (for example, LPF) that passes the -IF signal and the CS-IF signal. The signal that has passed through the filter 26 is input to the distribution / mixing circuit 27 and divided into four, and then to the bidirectional output terminal 10 via the upstream signal blocking switch circuit 12 and the power signal separation filter 41, respectively. The signal is output, transmitted through a coaxial cable connected to the bidirectional output terminal 10, and received by the BS / CS tuner 6 and the TV receiver 56.
Also, other distributed downlink signal equally in the distribution circuit 36 via the filter 37 of the same characteristics as the filter 26, is inputted to the distribution circuit 38, Ru is 4 distributed by the distributor circuit 38. Then, the 4 distributed downlink signals are respectively output to the unidirectional output terminal 11 via a power signal separation filter 41, it is transmitted through the coaxial cable connected to the unidirectional output terminal 11, BS · CS Received by the tuner 6 and the TV receiver 56. If the performance can be satisfied without the filter 37, the filter 37 may be omitted.
[0013]
Next, the CS signal is received by the CS antenna 3 and the CS converter 3a, and the CS-IF signal is output from the CS converter 3a. The CS-IF signal is transmitted through the coaxial cable between the CS converter 3 a and the input terminal 8 of the amplifier 5 and input to the input terminal 8. The CS-IF signal input to the input terminal 8 is input to a power signal separation filter 49 described later, and is taken into the amplifier 5. The CS-IF signal input to the power supply signal separation filter 49 is transmitted through the attenuation circuit 28, the gain adjustment circuit 29, and the filter 30 (for example, HPF) that passes the CS-IF signal and blocks the BS-IF signal. The signal is combined with a BS-IF signal transmitted from an input terminal 9 to be described later, amplified to a predetermined level by an amplifier circuit 34, transmitted to a filter 35 that blocks the CATV downstream signal and passes only the CS / BS-IF signal. . The CS / BS-IF signal that has passed through the filter 35 is combined with the bidirectional downlink signal and transmitted to the distribution circuit 36. The process of transmission from the distribution circuit 36 to the bidirectional output terminal 10 and the unidirectional output terminal 11 is the same as the transmission of the bidirectional downlink signal, and will not be described because it is redundantly described.
[0014]
Similarly, the BS signal is received by the BS antenna 4 and the BS converter 4a, and the BS-IF signal is output from the BS converter 4a. The BS-IF signal is transmitted between the BS converter 4 a and the input terminal 9 of the amplifier 5 through a coaxial cable and input to the input terminal 9. The BS-IF signal input to the input terminal 9 is input to the power supply signal separation filter 49 and taken into the amplifier 5. The BS-IF signal input to the power supply signal separation filter 49 is transmitted through an attenuation circuit 31, a gain adjustment circuit 32, and a filter 33 (for example, LPF) that passes the BS-IF signal and blocks the CS-IF signal. Are combined with the CS-IF signal and input to the amplifier circuit 34. The process of transmission from the amplifier circuit 34 to the bidirectional output terminal 10 and the unidirectional output terminal 11 is the same as the transmission of the CS-IF signal, and a description thereof is omitted because it is redundant.
[0015]
Next, when AC 100 V is applied to the plug 39, DC 15 V is output by the power supply circuit 40. DC 15 V is supplied to the amplifier circuits 15, 23 and 34. DC 15 V is also supplied to the power signal separation filter 49 connected to the input terminal 9. As shown in FIG. 5, the power signal separation filter 49 allows the BS-IF signal to pass between the BS-IF signal input / power output terminal 49a and the BS-IF signal output terminal 49b and blocks a DC or low frequency signal. The capacitor 51 to be connected is connected, and a DC- or low-frequency signal used as a power source for the operation of the converter and for switching the polarization is passed between the power output terminal 49a and the power input terminal 49c. A choke coil 52 for blocking signals is connected. The power supply separation filter 49 connected to the input terminal 8 has the same configuration, but the choke coil 52 connected between the CS-IF signal input / power supply output terminal 49a and the power supply input terminal 49c includes a CS converter. The direct current used for the operation of 3a and for switching polarization and a low-frequency signal or pulse signal for switching polarization are passed. The BS-IF signal input / power output terminal 49 a is connected to the input terminal 9, and the BS-IF signal output terminal 49 b is connected to the attenuation circuit 31. A power input terminal 49 c is connected to the power circuit 40.
[0016]
Next, when a user selects a channel in the CS tuner 6 or STB 59 that is receiving the CS-IF signal connected to the bidirectional output terminal 10 and the unidirectional output terminal 11, the polarization switching signal corresponding to the selected channel is described above. It is output to the reception input terminal of the CS tuner 6 and STB 59 (DC 11 V or 15 V in this embodiment). The polarization switching signal is transmitted to the bidirectional output terminal 10 or the unidirectional output terminal 11 through the coaxial cable connected to the CS tuner 6 and the STB 59. The polarization switching signal input to the bidirectional output terminal 10 and the unidirectional output terminal 11 is input to the CS-IF signal output / polarization switching signal input terminal 41b. As shown in FIG. 4, the power supply signal separation filter 41 passes the CS-IF signal between the CS-IF signal input terminal 41a and the CS-IF signal output / polarization switching signal input terminal 41b, and allows direct current or low frequency. A capacitor 46 for blocking the signal is connected, and a DC- or low-frequency signal is passed between the CS-IF signal output / polarization switching signal input terminal 41b and the polarization switching signal output terminal 41c to block the CS-IF signal. A choke coil 47 and a diode 48 are connected in series. The CS-IF signal input terminal 41 a is connected to the upstream signal blocking switch 12, and the CS-IF signal output / polarization switching signal input terminal 41 b is connected to the bidirectional output terminal 10 or the unidirectional output terminal 11. ing. A polarization switching signal output terminal 41 c is connected to the power input terminal 49 c connected to the input terminal 8. The diode 48 is used to prevent the BS / CS tuner 6 and the STB 59 from failing when the polarization switching signal of the CS reception signal is simultaneously input from the plurality of bidirectional output terminals 10 and the unidirectional output terminal 11. This is a backflow prevention diode. Also, the BS / CS tuner 6 and the STB 59 can be connected to either the bidirectional output terminal 10 or the unidirectional output terminal 11 by OR connection of the diode 48. Next, as shown in FIG. 2, the upstream signal blocking switch 12 is a two-circuit two-contact switch 50, a filter 42 that blocks a bidirectional upstream signal and passes a bidirectional downstream signal, a BS-IF signal, and a CS-IF signal. (For example, HPF) are connected as shown in the figure. By operating the two-circuit two-contact switch 50, bidirectional transmission and unidirectional transmission can be selected. When the switch 50 is selected to the 50a side, bidirectional transmission is possible through which all CATV upstream signals, CATV downstream signals, CS-IF signals, and BS-IF signals can pass. On the other hand, when the switch 50 is selected to the 50b side, a filter 42 (for example, HPF) that blocks the bidirectional upstream signal and passes the downstream signal is interposed in series, thereby blocking the CATV upstream signal and the CATV. This is unidirectional transmission that allows only so-called downlink signals of downlink signals, CS-IF signals, and BS-IF signals to pass.
[0017]
Next, as shown in FIG. 3, the band switching circuit 17 includes a two-circuit three-contact switch 43, a filter 44 (for example, HPF) that can pass a signal in a part of the band (for example, 30 MHz to 55 MHz) of the bidirectional upstream signal, and Two termination resistors 45 are connected as shown in the figure. By operating the two-circuit, three-contact switch 43, whether to pass the entire band of the bidirectional upstream signal (for example, 10 MHz to 55 MHz) or to pass only the partial band of the bidirectional upstream signal (for example, 30 MHz to 55 MHz) In addition, it is possible to select one of blocking the passage of the bidirectional upstream signal. Specifically, when the 43a side is selected by the two-circuit, three-contact switch 43, the bidirectional output signal can pass from the bidirectional output terminal 10 to the input terminal 7 in all bands. Further, when the 43b side is selected by the two-circuit three-contact switch 43, only signals in a part of the band of the bidirectional upstream signal can pass from the bidirectional output terminal 10 to the input terminal 7. When the 43 c side is selected by the two-circuit three-contact switch 43, the bidirectional upstream signal input from the bidirectional output terminal 10 is terminated by the termination resistor 45. Further, since one end of the gain adjustment circuit 16 is also terminated by the termination resistor 45, a bidirectional upstream signal can be prevented without disturbing the circuit impedance. Therefore, there is an effect that the isolation between the input and the output becomes higher than when the unidirectional direction is selected by the upstream signal blocking switch 12.
[0018]
Note that the downlink is the input terminal 7, filter 19, filter 20, attenuation circuit 21, gain adjustment circuit 22, amplification circuit 23, filter 24, amplification circuit 23, filter 25, distribution circuit 36, filter 26, distribution mixing circuit 27, It corresponds to the upstream signal blocking switch 12, the power signal separation filter 41, the filter 37, the distribution circuit 38, the power signal separation filter 41, the bidirectional output terminal 10, the unidirectional output terminal 11, the satellite reception line is the input terminal 8, the power Signal separation filter 49, attenuation circuit 28, gain adjustment circuit 29, filter 30, amplification circuit 34, filter 35, distribution circuit 36, filter 26 distribution mixing circuit 27, upstream signal blocking switch 12, power supply signal separation filter 41, bidirectional Output terminal 10, filter 37, distribution circuit 38, power supply signal separation filter 41, unidirectional output terminal 11, This corresponds to the power terminal 9, the power supply signal separation filter 49, the attenuation circuit 31, the gain adjustment circuit 32, and the filter 33. The upstream line is the bidirectional output terminal 10, the power supply signal separation filter 41, the upstream signal blocking changeover switch 12, and the distribution mixing circuit. 27, a filter 18, a band switching circuit 17, a gain adjustment circuit 16, an amplifier circuit 15, an attenuation circuit 14, a filter 13, and an input terminal 7, the distribution means corresponds to the distribution circuit 36, and the band switching means corresponds to the band switching circuit. The bidirectional / unidirectional switching means corresponds to the upstream signal blocking switch 12. Since the amplifier 5 body is made of aluminum die casting, it has good shielding properties and is not affected by external noise. In FIG. 7, an input terminal 7, an input terminal 8, an input terminal 9, and a plug 39 project from the bottom surface, and a plurality of bidirectional output terminals 10 and a unidirectional output terminal 11 project from the top surface. . As shown in FIG. 9, the unidirectional output terminal 11 has a level difference of L at the front and rear. This is because the F-type plug C can be easily attached and detached when the amplifier 5 is installed on the wall W. Thereby, work can be prepared even in a small place such as a distribution board. Further, since the upstream signal blocking changeover switch 12 is provided near each bidirectional output terminal 10, an operation error can be prevented as compared with the case where the upstream signal blocking switching switch 12 is provided intensively. A band switching circuit 17 and a filter 24 are provided on the front, and gain adjustment circuits 16, 22, 29, and 32, and attenuation circuits 14, 21, 28, and 31 are provided as shown in the figure. A pilot lamp PL indicating an operating state is provided at the upper right of the front. The pilot lamp PL is lit during operation. Although the above embodiment has been described for the case where the amplifier 5 is used indoors, the amplifier 5 can be easily changed depending on the situation, such as being used outdoors by being housed in a waterproof case.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing a configuration of a bidirectional amplifier.
FIG. 2 is a circuit diagram of an upstream switch 12;
FIG. 3 is a circuit diagram of a band switcher 17;
4 is a circuit diagram of a power supply signal separation filter 41. FIG.
5 is a circuit diagram of a power supply signal separation filter 49. FIG.
FIG. 6 is a configuration diagram showing a configuration of a bidirectional CATV system.
FIG. 7 is a perspective view of a bidirectional amplifier.
FIG. 8 is a plan view of a bidirectional amplifier.
FIG. 9 is a side view of a bidirectional amplifier.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Housing 2 ... Lead wire from CATV system, 3a ... CS converter, 4a ... BS converter, 5 ... Amplifier, 6 ... BS / CS tuner, 7 ... Input terminal, 8 ... Input terminal, 9 ... Input terminal, 10 ... Bidirectional output terminal, 11 ... Unidirectional output terminal, 12 ... Upstream signal blocking switch, 14 ... Attenuating circuit, 15 ... Amplifying circuit, 17 ... Band switching circuit, 41 ... Power supply signal separation filter, 49 ... Power supply signal separation filter, 56 ... Television or BS / CS tuner built-in television, 57 ... Cable modem

Claims (4)

An input terminal connected to the lead-in line of the bidirectional CATV system for inputting a downstream signal from the lead-in line;
  A downstream amplifier circuit that amplifies the downstream signal input from the input terminal;
  A distribution circuit for distributing the downlink signal amplified by the amplification circuit to a plurality of;
  A plurality of output terminals for outputting the downstream signals distributed by the distribution circuit to the terminal side,
  With
  Among the plurality of output terminals, some output terminals are unidirectional output terminals that only output the downlink signal to the terminal side, and the remaining output terminals output the downlink signal to the terminal side and the terminal side Is set as a bi-directional output terminal for capturing upstream signals input from
  A signal path for transmitting the upstream signal is provided between the bidirectional output terminal and the input terminal,
  Moreover, the signal path for uplink signal transmission includes
  An upstream amplification circuit for amplifying the upstream signal;
  A band switching circuit for switching the transmission frequency band of the upstream signal that can pass through the signal path;
  A bidirectional amplifying apparatus characterized by comprising: A plurality of the bidirectional output terminals are provided,
  Each bidirectional output terminal is provided with an upstream signal blocking switch for switching whether or not the upstream signal is passed from the bidirectional output terminal toward the upstream signal transmission signal path. The bidirectional amplifying device according to claim 1, wherein: In addition to an input terminal for inputting a downlink signal from the lead-in line, an input terminal for inputting a satellite reception signal is provided, and the downlink signal and the satellite reception signal input from each of these input terminals are mixed. The bidirectional amplifying apparatus according to claim 1, further comprising a mixing unit that generates a downlink signal to be output from each of the output terminals to the terminal side. Each of the bidirectional output terminal and the unidirectional output terminal is provided with a filter for separating the polarization switching signal input from the terminal side,
  The input terminal for inputting the satellite reception signal is provided with a filter for superimposing the polarization switching signal separated by the separation filter on the input terminal and outputting the signal from the input terminal. The bidirectional amplifying device according to claim 3.

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