JP2013077906A - Apparatus for television reception - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent a voltage drop from occurring as much as possible when electrically transmitting DC power supply.SOLUTION: When the DC power supply is supplied from a downstream side to a second output terminal OUT2, the DC power supply is impressed through a choke coil CH3 and a resistor R to a relay coil and a relay RY is driven. Thus, the DC power supply from the second output terminal OUT2 is outputted from an input terminal IN through a route of CH3-c of RY-a of RY-CH1. Also, when the DC power supply is supplied from the downstream side only to a first output terminal OUT1, the DC power supply is outputted from the input terminal IN through a route of CH2-b of RY-a of RY-CH1. Since the relay is used in such a manner, the DC power supply is supplied to an antenna for satellite broadcasting connected to the upstream side of the input terminal IN without causing the voltage drop.

Description

  The present invention relates to a television receiving device provided between an antenna such as a distributor that distributes a television reception signal or a booster that amplifies the television reception signal and a reception device such as a television.

  In a television reception system including a satellite broadcast antenna and a terrestrial digital broadcast antenna, conventionally, a satellite broadcast antenna reception signal and a terrestrial digital broadcast antenna reception signal are mixed by a mixer, and then a booster. The received signal mixed by the above is amplified, and the amplified received signal is distributed by a distributor to be supplied to a receiving device such as a television, a recorder or a TV tuner. In this case, since the satellite broadcasting antenna requires a DC power source (generally, DC 15 V) for operating the converter, a DC power source is transmitted from a receiving device such as a television, a recorder or a TV tuner to transmit the received signal. It is superimposed on a coaxial cable and supplied to a satellite broadcasting antenna. Thus, in order to supply DC power to the satellite broadcasting antenna, in the distributor, booster and mixer provided between the satellite broadcasting antenna and the receiving device, the DC power supplied to the output terminal is used as the input terminal. It can be output from the Dentsu-type receiver equipment.

FIG. 4 shows a circuit configuration of a conventional Dentsu mixer. The mixer 100 can mix the reception signal of the satellite broadcasting antenna and the reception signal of the terrestrial digital broadcasting antenna.
In the mixer 100 illustrated in FIG. 4, a satellite broadcast antenna reception signal is input to the input terminal IN101, and a digital terrestrial broadcast antenna reception signal is input to the input terminal IN102. The reception signal input to the first input terminal IN101 is input to the mixing circuit 101 via the capacitor C101, and the reception signal input to the second input terminal IN102 is input to the mixing circuit 101 via the capacitor C102. The reception signal mixed by the mixing circuit 101 is output from the output terminal OUT via the capacitor C103.
The DC power supplied to the output terminal OUT via the downstream transmission line is output from the first input terminal IN101 via the choke coil CH101. As a result, DC power is supplied as converter power from the first input terminal IN101 to the satellite broadcasting antenna. Since the capacitors C101 to C103 function as a DC blocking function, there is no fear that a DC power source is applied to the mixing circuit 101, and the choke coil CH101 functions as a reception signal blocking function. There is no risk of leakage of received signals.

Next, FIG. 5 shows a circuit configuration of a conventional Dentsu type four distributor. The 4-distributor 110 can divide the received signal, which has been mixed, into four parts, and can output the DC power supplied to at least one of the four output terminals that respectively output the distribution outputs from the input terminal. .
In the four distributor 110 shown in FIG. 5, the received signal input to the input terminal IN is input to the four distribution circuit 111 via the DC blocking capacitor C111 and divided into four. The four divided first distribution outputs from the four distribution circuit 111 are output from the first output terminal OUT111 via the DC blocking capacitor C112, and the second distribution output from the four distribution circuit 111 is the DC blocking output. Output from the second output terminal OUT112 via the capacitor C113, and the third distribution output from the four distribution circuit 111 is output from the third output terminal OUT113 via the DC blocking capacitor C114 and output from the four distribution circuit 111. The fourth distribution output is output from the fourth output terminal OUT114 via the DC blocking capacitor C115.

One end of the choke coil CH111 is connected to the input terminal IN, and the other end of the choke coil CH111 is connected to the cathodes of four diodes D112, D113, D114, and D115. The anode of the diode D112 is connected to the first output terminal OUT111 via the choke coil CH112 via the path AA, and the anode of the diode D113 is connected to the second output terminal OUT112 via the choke coil CH113 via the path BB. The anode of the diode D114 is connected to the third output terminal OUT113 via the choke coil CH114 via the path CC, and the anode of the diode D115 is connected to the fourth output terminal OUT114 via the choke coil CH115 via the path DD. Is done.
Thereby, the DC power supplied from the downstream transmission line to at least one of the first output terminal OUT111 to the fourth output terminal OUT114 is the path of the CH112-D112, the path of the CH113-D113, the path of the CH114-D114, The signal is output from the input terminal IN via at least one of the paths D115 and further via the choke coil CH111. As a result, it is possible to supply a DC power source as a converter power source to the satellite broadcasting antenna connected to the upstream side of the input terminal IN. Note that the choke coils CH111 to CH115 function as blocking received signals, so that there is no possibility that the received signals leak through the choke coils CH111 to CH115.

Next, FIG. 6 shows a circuit configuration of a Dentsu booster 200 having a conventional two distributor. This Density booster 200 can amplify the received signal distributed by the distributor to a predetermined level and distribute and output it to at least one of the two output terminals that respectively amplify and output each signal. DC power can be output from the input terminal.
The Dentsu booster 200 shown in FIG. 6 includes a booster unit 200 a and a two distribution circuit 206. A received signal input to the input terminal IN is supplied to a booster unit 200a via a DC blocking capacitor C201, and a low-pass filter (hereinafter referred to as “LPF”) 201 for extracting a digital terrestrial broadcasting band, and an IF of satellite broadcasting This is supplied to a high-pass filter (hereinafter referred to as “HPF”) 207 that extracts the band.

The reception signal of digital terrestrial broadcasting extracted by the LPF 201 is supplied to an amplifier (hereinafter referred to as “AMP”) 202 and amplified to a predetermined level, and unnecessary components are removed by the LPF 203. The LPF 203 outputs a terrestrial digital broadcast reception signal amplified to a predetermined level.
The satellite broadcast reception signal extracted by the HPF 207 is amplified to a predetermined level by the AMP 208 and unnecessary components are removed by the HPF 209 before being output. The output signals of the LPF 203 and the HPF 209 are mixed and output from the booster unit 200a, supplied to the 2-distribution circuit 206, and divided into two. The first distribution output distributed by the two distribution circuit 206 is output from the first output terminal OUT201 via the DC blocking capacitor C204, and the second distribution output is output from the second output terminal OUT202 via the DC blocking capacitor C205. Is output from.
Note that power is supplied from the power supply unit 210 to the AMP 202 and the AMP 208.

One end of a choke coil CH201 is connected to the input terminal IN, and the other end of the choke coil CH201 is connected to the cathodes of two diodes D202 and D203. The anode of the diode D202 is connected to the first output terminal OUT201 via the choke coil CH202, and the anode of the diode D203 is connected to the second output terminal OUT202 via the choke coil CH203.
As a result, the DC power supplied from the downstream transmission line to at least one of the first output terminal OUT201 and the second output terminal OUT202 passes through at least one of the CH202-D202 path and the CH203-D203 path. Further, it is output from the input terminal IN via the choke coil CH201. As a result, it is possible to supply a DC power source as a converter power source to the satellite broadcasting antenna connected to the upstream side of the input terminal IN. In addition, since the choke coils CH201 to CH203 function as a reception signal blocking function, there is no possibility that the reception signal leaks through the choke coils CH201 to CH203.

Japanese Patent No. 3577676

In the conventional television receiving system, each antenna and the mixer 100, the mixer 100 and the four distributors 110, and the four distributor 110 and the electric communication type booster 200 are connected by transmission lines such as coaxial cables. When a DC power supply is superimposed on the transmission line, a slight voltage drop occurs due to the resistance of the transmission line. Further, in the 4-distributor 110 and the continuity type booster 200, a DC power supply is prevented from flowing backward using a diode, and the DC power supply drops by the forward voltage of the diode. In the silicon diode generally used as such a rectifying diode, the forward voltage is set to about 0.7 V, so that the DC power source passes through the 4-distributor 110 and the conductive booster 200. Every voltage drop is about 0.7V.
In this way, in the television receiving system, a plurality of television receiving devices are interposed between the antenna and the television, so that the voltage drop becomes large and sufficient power cannot be supplied to the satellite broadcasting antenna. There is a problem that there is a risk that reception by the antenna for use may be affected.

  Accordingly, an object of the present invention is to provide a television receiving device that does not generate as much as possible when a voltage drop of a DC power supply is conducted.

  A television receiving device of the present invention is a television receiving device provided between an antenna and a receiving device, and an input terminal to which a reception signal received by the antenna is input, and an input to the input terminal A functional unit to which the received signal is input via a DC blocking capacitor, a plurality of output terminals from which output signals from the functional unit are output via a DC blocking capacitor, DC power supplied to the output terminal from the downstream side of the output terminal is supplied to the relay coil and the normally open contact via the first choke coil, and another DC power supplied to the other output terminal And a relay that is supplied to the normally closed contact via the second choke coil and the movable contact is connected to the input terminal via the third choke coil. There.

  According to the present invention, the DC power supplied to the output terminal from the downstream side of the one output terminal is supplied to the relay coil and the normally open contact via the first choke coil, and the other output terminal And a relay having a movable contact connected to the input terminal via a third choke coil. The other DC power source is supplied to the normally closed contact via the second choke coil. Thus, since the DC power supplied to the output terminal is output from the input terminal via the relay contact, the DC power can be output from the input terminal without causing a voltage drop. It is possible to prevent as much as possible the risk of affecting the reception.

It is a block diagram which shows the structure of the receiving system for televisions using the apparatus for television reception of this invention. It is a circuit diagram which shows the structure of the electric conduction type 4 divider | distributor made into the Example of this invention. It is a circuit diagram which shows the structure of the Dentsu-type booster made into the Example of this invention. It is a circuit diagram which shows the structure of the electric connection type mixer used for the receiving system of the conventional television. It is a circuit diagram which shows the structure of the Dentsu type 4 divider | distributor used for the receiving system of the conventional television. It is a circuit diagram which shows the structure of the Dentsu type booster used for the receiving system of the conventional television.

FIG. 1 is a block diagram showing a configuration of a television receiving system using the television receiving device of the present invention.
In the receiving system 1 shown in FIG. 1, a satellite broadcast antenna 10 is an antenna for receiving BS broadcast and CS broadcast, and a BS-IF signal and a CS-IF signal converted to an intermediate frequency by a built-in converter are received signals. Output. The frequency band of this received signal is 1032 MHz to 2602 MHz. The FM antenna 11a is an antenna that receives FM radio broadcasting, and outputs a reception signal in a frequency band of 76 MHz to 90 MHz. The UHF antenna 11b is an antenna that receives terrestrial digital broadcasting, and outputs a received signal in a frequency band of 470 MHz to 710 MHz. The reception signal from the FM antenna 11a and the reception signal from the UHF antenna 11b are input to the mixer 12b and mixed. The reception signal from the satellite broadcasting antenna 10 and the reception signals from the FM antenna 11a and the UHF antenna 11b output from the mixer 12b are input to the mixer 12a and mixed. The input terminal of the mixer 12a to which the received signal from the satellite broadcasting antenna 10 is input is of a conductive type, and has a circuit configuration similar to that of the mixer 100 having the circuit configuration shown in FIG. The mixed reception signal output from the mixer 12a is supplied to the four distributor 13 and divided into four. One distributed output signal is guided to a TV outlet 14 provided on a building wall or the like. The output paths of the remaining three output signals divided into four are not shown.

  One end of a coaxial cable serving as a transmission line is attached to the terminal of the TV outlet 14 via the coaxial terminal, and the other end of the coaxial cable is connected to the electric booster 15. The Dentsu booster 15 separates the received signal into FM radio broadcast and terrestrial digital broadcast frequency band reception signals and BS / CS-IF signal frequency band reception signals to receive FM radio broadcasts. Except for the signal, each is amplified to a predetermined level. Then, the reception signal of the FM radio broadcast, the amplified digital terrestrial broadcast, and the reception signal of the BS / CS-IF signal are mixed, and the mixed reception signal is divided into two and output. The first reception signal amplified and distributed by the Dentsu booster 15 is supplied to the first television (TV 1) 16, and the second reception signal is supplied to the second television (TV 2) 17. Is done. The reception signal output from the Dentsu booster 15 may be supplied to a receiving device such as a recorder or a TV tuner.

  In a receiving device such as TV1 (16) or TV2 (17) to which a reception signal output from the Dentsu booster 15 is supplied, a DC power source for operating the converter of the satellite broadcasting antenna 10 is connected to the antenna terminal of the receiving device. It can be supplied to the satellite broadcasting antenna 10 by being superimposed on the connected coaxial cable. In this case, the converter power supply superimposed on the coaxial cable is supplied to the output terminal of the continuity booster 15 and is output from the input terminal because it is of the continuity type. It is supplied to the outlet 14. The converter power is supplied to the output terminal of the four distributor 13 through a coaxial cable connected to the TV outlet 14, but the four distributor 13 is also of a conductive type, so that the converter is connected from the input terminal to the converter. Power is output. Further, the converter power output from the input terminal of the 4-distributor 13 is supplied to the output terminal of the conductive mixer 12a and output from the input terminal to which the received signal from the satellite broadcasting antenna 10 is input. Next, the converter power is supplied to the output terminal of the satellite broadcasting antenna 10 via the coaxial cable connected to the input terminal of the mixer 12a, so that the converter power is built in the satellite broadcasting antenna 10. It will be supplied to the converter.

Next, FIG. 2 shows a circuit diagram showing the configuration of the four distributor 13 which is an embodiment of the television receiving device of the present invention. The 4-distributor 13 can distribute the mixed received signals into four, and can output the DC power supplied to at least one of the four output terminals that respectively output the distribution outputs from the input terminals. .
In the four distributor 13 according to the embodiment of the present invention shown in FIG. 2, the received signal input to the input terminal IN is input to the four distribution circuit 30 via the DC blocking capacitor C31 and divided into four. The four divided first distribution outputs from the four distribution circuit 30 are output from the first output terminal OUT1 through the DC blocking capacitor C32, and the second distribution output from the four distribution circuit 30 is the DC blocking output. Output from the second output terminal OUT2 via the capacitor C33 and the third distribution output from the four distribution circuit 30 are output from the third output terminal OUT3 via the DC blocking capacitor C34 and output from the four distribution circuit 30. The fourth distribution output is output from the fourth output terminal OUT4 via the DC blocking capacitor C35.
In the four distributor 13 according to the embodiment of the present invention, a relay is used. In the relay, the contact to which the movable contact is connected in a state where the relay coil is not driven is a normally closed contact. The contact to which the movable contact is connected in a state where is driven is a normally open contact.

  One end of the choke coil CH31 is connected to the input terminal IN, and the other end of the choke coil CH31 is connected to the movable contact a1 of the first relay RY1. The normally closed contact b1 of the first relay RY1 is connected to the movable contact a2 of the second relay RY2, and the normally open contact c1 of the first relay RY1 is connected to the movable contact a3 of the third relay RY3. . Further, the other end of the relay coil whose one end is grounded is connected to the normally open contact c1 of the first relay RY1 and the movable contact a3 of the third relay RY3 via the resistor R1. Further, the normally closed contact b2 of the second relay RY2 is connected to the first output terminal OUT1 through the choke coil CH32 via the path AA, and the normally open contact c2 of the second relay RY2 is connected via the choke coil CH33. And connected to the second output terminal OUT2 by a path BB. Further, the other end of the relay coil whose one end of the second relay RY2 is grounded is connected to the normally open contact c2 of the second relay RY2 via the resistor R2. Furthermore, the normally closed contact b3 of the third relay RY3 is connected to the third output terminal OUT3 via the choke coil CH34 via the path CC, and the normally open contact c3 of the third relay RY3 is connected to the choke coil CH35. Through the path DD to the fourth output terminal OUT4. The other end of the relay coil whose one end is grounded is connected to a normally open contact c3 of the third relay RY3 via a resistor R3.

  Thus, when DC power (converter power) is supplied from the downstream transmission line to the fourth output terminal OUT4, transmission downstream to the first output terminal OUT1, the second output terminal OUT2, and the third output terminal OUT3. Regardless of whether or not DC power (converter power) is supplied from the wire, DC power supplied to the fourth output terminal OUT4 is applied to the relay coil of the third relay RY3 via the choke coil CH35 and the resistor R3. Therefore, the third relay RY3 is driven and the movable contact a3 is switched to the normally open contact c3 side. Next, the DC power is applied to the relay coil of the first relay RY1 via the resistor R1 via the path a3 of c3-RY3 of CH35-RY3, and the first relay RY1 is driven to drive the normally open contact c1. The movable contact a1 is switched to the side. As a result, the DC power supplied to the fourth output terminal OUT4 is routed from the input terminal IN via the choke coil CH31 via the path c1 of the c1-RY1 of the a3-RY1 of the c3-RY3 of the CH35-RY3 and further. Is output. As a result, DC power (converter power) can be supplied to the satellite broadcasting antenna 10 connected to the upstream side of the input terminal IN.

  Further, when the DC power supply (converter power supply) is supplied from the downstream transmission line to the third output terminal OUT3 and the DC power supply (converter power supply) is not supplied from the downstream transmission line to the fourth output terminal OUT4, the first output Regardless of whether or not DC power (converter power) is supplied from the downstream transmission line to the output terminal OUT1 and the second output terminal OUT2, the DC power supplied to the third output terminal OUT3 is connected to the CH34-RY3. Since it is applied to the relay coil of the first relay RY1 via the path a3-R1 of b3-RY3, the first relay RY1 is driven and the movable contact a1 is switched to the normally open contact c1 side. As a result, the signal is output from the input terminal IN via the choke coil CH31 through the path a1 of c1-RY1 of c3-RY1 of b3-RY3 of b3-RY3 of CH34-RY3. As a result, DC power (converter power) can be supplied to the satellite broadcasting antenna 10 connected to the upstream side of the input terminal IN.

Furthermore, no DC power (converter power) is supplied from the downstream transmission line to the third output terminal OUT3 and the fourth output terminal OUT4, and DC power (converter power) from the downstream transmission line to the second output terminal OUT2. Is supplied to the first output terminal OUT1, regardless of whether or not DC power (converter power) is supplied from the downstream transmission line to the first output terminal OUT1. Applied to the relay coil of the second relay RY2 through CH33 and the resistor R2, the second relay RY2 is driven, and the movable contact a2 is switched to the normally open contact c2 side. As a result, the signal is output from the input terminal IN via the choke coil CH31 via the path a1 of b1-RY1 of a2-RY1 of c2-RY2 of c2-RY2 of CH33-RY2. Thereby, it becomes possible to supply DC power (converter power) to the satellite broadcasting antenna 10 connected to the upstream side of the input terminal IN.
Furthermore, no DC power (converter power) is supplied from the downstream transmission line to the second output terminal OUT2, the third output terminal OUT3, and the fourth output terminal OUT4, and from the downstream transmission line to the first output terminal OUT1. When a DC power supply (converter power supply) is supplied, the DC power supplied to the first output terminal OUT1 passes through the path a1 of b2-RY1 of b2-RY1 of b2-RY2 of CH32-RY2, It is output from the input terminal IN via the choke coil CH31. Thereby, it becomes possible to supply DC power (converter power) to the satellite broadcasting antenna 10 connected to the upstream side of the input terminal IN.

As described above, in the four distributor 13 according to the present invention, the DC power supply (converter power supply) is supplied from the downstream transmission line to at least one of the first output terminal OUT1 to the fourth output terminal OUT4. , The supplied DC power is output from the input terminal IN. In this case, since no voltage drop occurs in the relays RY1 to RY3, a DC power supply (converter power supply) that does not cause a voltage drop is supplied to the satellite broadcasting antenna 10 connected to the upstream side of the input terminal IN. become.
In addition, since the choke coils CH31 to CH35 function as blocking received signals, there is no possibility that the received signals leak through the choke coils CH31 to CH35.

Next, FIG. 3 shows a circuit diagram showing the configuration of the Dentsu booster 15 which is an embodiment of the television receiving device of the present invention. The Dentsu booster 15 can amplify the received signal distributed by the upstream distributor to a predetermined level and distribute and output the signal, and amplifies and outputs at least one of the two output terminals that respectively output the amplified signal. The DC power supplied to can be output from the input terminal.
3 includes a booster unit 15a and a two-distribution circuit 25. As shown in FIG. The received signal input to the input terminal IN is supplied to the booster unit 15a via the DC blocking capacitor C1 and extracts a frequency band between the FM radio broadcast and the terrestrial digital broadcast (hereinafter referred to as “LPF”). 20 and a high-pass filter (hereinafter referred to as “HPF”) 26 that extracts a BS / CS-IF band of satellite broadcasting. The FM radio broadcast reception signal extracted by the LPF 20 is input to the LPF 24 after being extracted by a two-stage cascaded T-type LPF. The T-type LPF includes three coils L1, L2, and L3 connected in series, and capacitors C2 and C3 connected between these coils and the ground.

  The reception signal of the terrestrial digital broadcast extracted from the output of the LPF 20 by the HPF 21 is supplied to an amplifier (hereinafter referred to as “AMP”) 22 to be amplified to a predetermined level, and to the LPF 24 via the HPF 23 that removes unnecessary components. Supplied. The LPF 24 is a filter that removes unnecessary components, and a FM radio broadcast reception signal and a terrestrial digital broadcast reception signal amplified to a predetermined level are mixed and output. Further, the satellite broadcast reception signal extracted by the HPF 26 is output to the HPF 28 which is amplified to a predetermined level by the AMP 27 and removes unnecessary components. The output signals of the LPF 24 and the HPF 28 are mixed and output from the booster unit 15a, supplied to the 2-distribution circuit 25, and divided into two. The first distribution output distributed by the two distribution circuit 25 is output from the first output terminal OUT1 through the DC blocking capacitor C4, and the second distribution output is output from the second output terminal OUT2 through the DC blocking capacitor C5. Is output from. Power is supplied from the power supply unit 29 to the AMP 22 and the AMP 27.

One end of the choke coil CH1 is connected to the input terminal IN, and the other end of the choke coil CH1 is connected to the movable contact a of the relay RY. The normally closed contact b of the relay RY is connected to the first output terminal OUT1 via the choke coil CH2, and the normally open contact c of the relay RY is connected to the second output terminal OUT2 via the choke coil CH3.
As a result, when DC power (converter power) is supplied from the downstream transmission line to the second output terminal OUT2, whether or not DC power is supplied from the downstream transmission line to the first output terminal OUT1. Regardless, since the DC power supplied to the second output terminal OUT2 is applied to the relay coil of the relay RY via the choke coil CH3 and the resistor R, the relay RY is driven to move the movable contact to the normally open contact c side. a switches. Accordingly, the DC power supplied to the second output terminal OUT2 is output from the input terminal IN via the CH3-RY c-RY a path and further via the choke coil CH1. As a result, DC power (converter power) can be supplied to the satellite broadcasting antenna 10 connected to the upstream side of the input terminal IN.

Further, when DC power (converter power) is not supplied from the downstream transmission line to the second output terminal OUT2, and DC power is supplied from the downstream transmission line to the first output terminal OUT1, the first output terminal The DC power supplied to OUT1 is applied to the normally closed contact b of the relay RY via the choke coil CH2, and the DC power is output from the movable contact a of the relay RY. As a result, the DC power supplied to the first output terminal OUT1 is output from the input terminal IN via the CH2-RY b-RY a path and further via the choke coil CH1. As a result, DC power (converter power) can be supplied to the satellite broadcasting antenna 10 connected to the upstream side of the input terminal IN.
As described above, in the conductive booster 15 according to the present invention, the DC power supply (converter power supply) is supplied from the downstream transmission line to at least one of the first output terminal OUT1 and the second output terminal OUT2. DC power is output from the input terminal IN. In this case, since no voltage drop occurs in the relay RY, a DC power supply (converter power supply) that does not cause a voltage drop is supplied to the satellite broadcasting antenna 10 connected to the upstream side of the input terminal IN. . In addition, since the choke coils CH1 to CH3 function as blocking received signals, there is no possibility that the received signals leak through the choke coils CH1 to CH3.

The television receiving device of the present invention described above can be applied not only to a distributor or a booster but also to a receiving device provided between an antenna and a receiving device.
Note that, in the Dentsu booster 15 according to the embodiment of the present invention, power is supplied to the AMP 22 and AMP 27 from the power supply unit 29, but a DC power output from the input terminal IN is used as an operating power supply for the AMP 22 and AMP 27. You may do it.

1 receiving system, 10 satellite broadcasting antenna, 11a FM antenna, 11b UHF antenna, 12a, 12b mixer, 134 distributor, 14 TV outlet, 15 Dentsu booster, 15a booster unit, 15a booster unit, 20 LPF, 21 HPF, 22 AMP, 23 HPF, 24 LPF, 25 2 distribution circuit, 26 HPF, 27 AMP, 28 HPF, 29 power supply unit, 304 distribution circuit, 100 mixer, 101 mixing circuit, 1104 distributor, 111 4 distribution Circuit, 200 Dentsu booster, 200a Booster part, 206 Two distribution circuit, 210 Power supply part, RY, RY1-RY3 relay

Claims (3)

A television receiving device provided between an antenna and a receiving device,
An input terminal to which a reception signal received by the antenna is input;
A functional unit in which the received signal input to the input terminal is input via a DC blocking capacitor;
A plurality of output terminals from which output signals from the functional units are output via a DC blocking capacitor;
The DC power supplied to the output terminal from the downstream side of the one output terminal is supplied to the relay coil and the normally open contact through the first choke coil, and the other power supplied to the other output terminal A relay in which a DC power source is supplied to the normally closed contact via a second choke coil, and a movable contact is connected to the input terminal via a third choke coil;
A television receiving device comprising: A television receiving device provided between an antenna and a receiving device,
An input terminal to which a reception signal received by the antenna is input;
A four-distribution circuit unit in which the received signal input to the input terminal is input via a DC blocking capacitor;
The four distribution circuit units divide the reception signal into four parts, and output four output terminals via DC blocking capacitors,
The first DC power supplied to the output terminal from the downstream side of the first output terminal is supplied to the first relay coil and the first normally open contact through the first choke coil, and A first relay in which a second DC power source supplied to the two output terminals is supplied to a first normally closed contact via a second choke coil;
A third DC power supplied from the downstream side of the third output terminal to the output terminal is supplied to the second relay coil and the second normally open contact via the third choke coil, and A second relay in which a fourth DC power source supplied to the four output terminals is supplied to a second normally closed contact via a second choke coil;
The first movable contact of the first relay is connected to a third normally closed contact, and the second movable contact of the second relay is a third relay coil and a third normally open contact. A third relay in which a third movable contact is connected to the input terminal via a fifth choke coil;
A television receiving device comprising: A television receiving device provided between an antenna and a receiving device,
An input terminal to which a reception signal received by the antenna is input;
The received signal input to the input terminal is input via a DC blocking capacitor, and the booster unit amplifies the input received signal to a predetermined level;
Two output terminals from which output signals from the booster unit are output via a DC blocking capacitor;
The first DC power supplied to the output terminal from the downstream side of the first output terminal is supplied to the relay coil and the normally open contact via the first choke coil, and to the second output terminal. A relay in which the supplied second DC power is supplied to the normally closed contact via the second choke coil, and the movable contact is connected to the input terminal via the third choke coil;
A television receiving device comprising:

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