JP4628390B2 - Power supply method in amplification device - Google Patents

Description

  The present invention relates to an amplifying apparatus for amplifying a TV signal, and more specifically, a TV signal such as a VHF signal or a UHF signal is amplified by an amplifying unit provided at a high place, and the TV signal is directed toward a television receiver installed on the ground. In addition, the present invention relates to an amplifying device and a power supply method in the amplifying device that transmit power from the ground toward an amplifying unit installed at a high place.

Conventionally, a TV signal such as a VHF signal and a UHF signal is amplified by an amplifying unit provided at a high place, and the TV signal is sent to a television set installed on the ground, and from the ground to a high place. An amplifying apparatus that sends power toward an installed amplifying unit is widely known. For example, this type of apparatus is disclosed in Patent Document 1.
In the amplifying device disclosed in Patent Document 1, the amplifying unit is disposed at a high place. The input side is connected to the VHF signal input terminal connected to the VHF antenna, the output side is connected to the output terminal, the input side is connected to the UHF signal input terminal connected to the UHF antenna, and the output side is the output terminal. An amplifying unit comprising: a UHF amplifier circuit connected to the base station; and a BS / CS amplifier circuit having an input side connected to a BS / CS signal input terminal connected to the BS / CS antenna and an output side connected to the output terminal. .

In addition, a signal from the amplifying unit disposed at the high position to the receiver placed on the ground is transmitted through a transmission line provided between the output terminal and the receiver. .
Further, on the ground, the power supply unit is provided, and the power of the AC power supply is changed to a predetermined low voltage power based on the common general technical knowledge and is transmitted to the amplification unit that is superposed on the transmission line and arranged at a high place. It is.
When the amplification unit is arranged at a high place as described above, the distance between the antenna and the amplification unit can be reduced, so that a weak TV signal input from the antenna is amplified at a close distance, and a high-quality TV signal is transmitted to the receiver. There are benefits that can be done.

JP 2004-201254 A

In the amplifying apparatus having such a configuration, even when VHF band TV broadcasting ends in the future and the VHF band TV signal is completely stopped, power will continue to be sent from the ground to the VHF amplifier circuit. There is a problem that wasteful power continues to be consumed in the VHF amplifier circuit.
In addition, when the TV signal in the VHF band is completely stopped, even if it is attempted to stop power supply to the VHF amplifier circuit, power must be continuously sent to the UHF amplifier circuit. There is a trouble that can not be stopped only.
As a last resort, it is conceivable to open the case of the amplifying unit arranged at a high place and cut the power supply point of the VHF amplifier circuit. Is dangerous for amateurs and impractical.

Further, in the future, for example, when the VHF band TV broadcast ends in 2011 and the VHF band TV signal is completely stopped, the frequency band used by the current terrestrial analog broadcast and digital terrestrial broadcast in the UHF band ( 470-770 MHz: see FIG. 2 (A)), terrestrial analog broadcasting is completely stopped, and due to that, 710-770 MHz shown in FIG. 2 (B) among 470-770 MHz in the currently used UHF band. When a frequency band of ˜770 MHz is allocated to another service, there is a problem that a new failure occurs in reception of the terrestrial digital broadcast.
There is a problem that an expert is required to remove the obstacle that occurs in the reception of such terrestrial digital broadcasting, and an extra expense is required.

The purpose of the present application is to provide an amplifying device that can stop sending unnecessary power to the VHF amplifier circuit when VHF band TV broadcasting ends in the future and the VHF band TV signal completely stops. It is what.
Another object of the present invention is to provide an amplifying apparatus that can perform an operation on the ground to stop sending unnecessary power to the VHF amplifier circuit.
Another purpose is to provide means on the ground that will not cause any new obstacles to reception of terrestrial digital broadcasting even if terrestrial analog broadcasting in the current UHF band is completely stopped and terrestrial digital broadcasting remains. It is an object of the present invention to provide an amplifying device that can also be used.
Other objects and advantages will be readily apparent from the drawings and the following description associated therewith.

The power supply method in the amplification device of the present invention is:
A VHF amplifier circuit having an input side connected to a VHF signal input terminal connected to the VHF antenna and an output side connected to an output terminal;
An amplifying unit having an input side connected to a UHF signal input terminal connected to a UHF antenna and an output side connected to the output terminal is disposed at a high place and is disposed on the ground from the amplifying unit. The signal toward the receiver is transmitted through a transmission line provided between the output terminal disposed at the above-mentioned high place and the receiver on the ground,
On the other hand, on the ground, a power supply unit is provided, and the supply of power required in the amplification unit provided at the high place is transmitted superimposed on the transmission line, and the VHF amplification circuit, UHF amplification circuit, In the power supply method in the amplifying apparatus that operates each of the
Between the UHF signal input terminal and the UHF amplifier circuit, a UHF bandpass circuit and a specific airband reduction circuit are interposed so as to be selectively usable,
In both of these circuits, the UHF band-pass circuit is selected when power is supplied to the VHF amplifier circuit, and the specific air band reduction circuit is selected when power is not supplied to the VHF amplifier circuit. So that
The power supply unit to be provided on the ground includes a voltage switching unit that can switch a DC voltage to be output between a predetermined voltage and a high predetermined voltage higher than the predetermined voltage,
For the VHF amplifier circuit, a predetermined voltage is output when the voltage from the power supply unit is a high predetermined voltage, and a predetermined voltage is not output when the voltage from the power supply unit is a predetermined voltage. Power is supplied via the voltage changing means, and power of a high predetermined voltage is normally supplied from the power supply unit to operate the VHF amplifier circuit and the UHF amplifier circuit, respectively.
In the power supply unit, when the operation of the UHF amplifier circuit arranged at the high place is continued and the VHF amplifier circuit at the high place is put into a resting state, the voltage switching means is switched. The UHF signal input terminal is configured to output the power of a predetermined voltage and keep the operation of the UHF amplifier circuit in a state of stopping the VHF amplifier circuit and not supplying power to the VHF amplifier circuit. What is necessary is that the specific air-band reduction circuit is interposed between the UHF amplifier circuit and the UHF amplifier circuit.

As described above, the present invention exists in a high place by simply switching the DC voltage output from the power supply unit provided on the ground from the high predetermined voltage higher than the predetermined voltage to the predetermined voltage slightly lower in voltage value. There is a feature that the power supply of the VHF amplifier circuit can be cut off, and there is a great effect in saving useless power to the VHF amplifier circuit without damaging the UHF amplifier circuit.
In addition, when the power supply of the VHF amplifier circuit present at a high place is shut off, the work can be performed on the ground, and the operation can be performed extremely safely.

  In addition, VHF band TV broadcasting will end in the future, and VHF band TV signals will be completely stopped. Even if the 710 to 770 MHz frequency band in the currently used UHF band is allocated to other services due to the wave, the new obstacle to the reception of the terrestrial digital broadcasting is due to the operation on the ground. Thus, there is an effect that can be removed in advance.

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a conceptual diagram of a house, a plurality of types of antennas arranged at a high place in the house, and a positional relationship between the antenna and the amplification unit. 2 is a comparison diagram of frequency bands used by terrestrial analog broadcasting and terrestrial digital broadcasting in the UHF band, and frequency bands used for receiving future terrestrial digital broadcasting. FIG. 3 is a diagram illustrating VHF band TV signals and UHF band. FIG. 4 shows a circuit diagram of the voltage changing means. FIG. 4 is a circuit diagram for explaining a TV signal receiving circuit and a power supply circuit for these circuits. FIG. 5 is a circuit diagram for explaining a VHF band TV signal, a UHF band TV signal, a BS / CS band receiving circuit, and a power supply circuit for these circuits. FIG. FIG. 7 is a perspective view for explaining the relationship between the case of the power supply unit and the voltage switching unit. FIG. 7 is a circuit diagram of the selection unit showing an example of a circuit configuration different from the selection unit shown.
In the technical matters shown in the above figure, new technical items (member configuration, combination, function, etc.) added in the following description of the configuration relating to the power supply unit 16, the selection unit 32, and the voltage changing unit 46 are shown. Matters relating to the explanation of the above are separately discussed, and other technical matters are widely known among those skilled in the art, for example, disclosed in Patent Document 1. Since they overlap, a part of the overlapping description is omitted in this specification.

In FIG. 1, reference numeral 1 denotes an outline of a house exemplified as a building, and reference numeral 2 denotes a support column established on the roof of the house 1. Reference numerals 3, 4, 5, 8, and 9 denote a well-known VHF antenna, UHF antenna, BS / CS antenna, a case in which the amplifying unit 9 is built, an amplifying unit, and the like disposed at a high place. Reference numerals 3a, 4a, 5a, 11, and 12 denote a VHF input terminal, UHF input terminal, BS / CS input terminal, output terminal, transmission line (coaxial cable), and the like of the amplifying unit 9. In the house 1, 15, 16, 17, 20, and 21 indicate known distributors, power supply units (power supply devices), television receivers, TV terminals, and power output terminals, respectively, and 18 and 18a indicate coaxial cables. .
In addition, the coaxial cables 18 and 12 in the house 1 are used for superimposing and transmitting the electric power required in the amplifying unit 9 at a high place from the power source unit 16 as is apparent from FIG.

Next, the amplifying unit 9 will be described. As apparent from FIGS. 3 and 5, for example, the input side is connected to the VHF signal input terminal 3a connected to the VHF antenna 3, the output side is connected to the output terminal 11, and the input side is a UHF antenna. 4 is connected to a UHF signal input terminal 4 a connected to the UHF signal input terminal 4 a, and an output side is connected to the output terminal 11. Further, as shown in FIG. 5, a BS / CS amplifying circuit 42 whose input side is connected to the BS / CS signal input terminal 5a connected to the BS / CS antenna and whose output side is connected to the output terminal 11 is provided.
3 and 5 is disposed at a high place in the building, and the signal from the amplifying section 9 toward the receiver 17 disposed on the ground is disposed at the above-described high place. The signal is transmitted through a transmission line 12 provided between the output terminal 11 and the receiver 17 on the ground.
On the other hand, on the ground, the power required by the amplifying unit 9 provided with the power supply unit 16 and provided at the high place is transmitted while being superimposed on the transmission line 12, and connected as shown in the figure to the VHF amplification. The circuit 25, the UHF amplifier circuit 35, and the BS / CS amplifier circuit 42 are operated.

  A VHF amplifier circuit 25 connected between the VHF signal input terminal 3a and the output terminal 11, and a UHF amplifier circuit 35 connected between the UHF signal input terminal 4a and the output terminal 11, respectively. As is well known, the circuits arranged at the front and rear may be provided with favorite circuits corresponding to various requirements. 3 and 5 exemplify the following simple circuit. 3 and 5, 26, 27, and 28 indicate the existence of a known VHF band pass filter, VHF / UHF band pass filter, and power supply separation filter, and 31 and 36 indicate a high pass filter, UHF band pass filter, Showed existence. In addition to this, a circuit configuration including well-known circuit elements (not shown) may be performed as necessary.

Reference numeral 46 denotes voltage changing means, which includes a voltage detection unit 46a and a voltage control unit 46b (see FIG. 4). Under normal conditions, the DC 20 V voltage input from the terminal 71 is output to the terminal 72 via the transistor 30. In this case, a Zener diode 48a having a Zener voltage of 3V in the voltage detection unit 46a and a Zener diode 48b having a Zener voltage of 15V in the voltage control unit 46b are connected as shown in FIG. The output voltage is a predetermined voltage dropped to DC15V.
Therefore, according to the above configuration, as is apparent from the circuit diagrams of FIGS. 3 and 5, the VHF amplifier circuit 25 and the UHF amplifier circuit 35 operate properly by receiving power of a predetermined voltage, so that the VHF connected to the VHF antenna 3 An appropriate VHF signal can be output from the signal input terminal 3 a to the output terminal 11, and an appropriate UHF signal can be output from the UHF signal input terminal 4 a connected to the UHF antenna 4 to the output terminal 11. Can be delivered.

Next, when the voltage inputted from the terminal 71 drops by switching the circuit switch 56 on the ground and becomes a predetermined voltage of DC15V, the zener voltage of the voltage detector 46a is 3V. Due to the presence of the Zener diode 48b whose Zener voltage of the voltage control unit 46b is 15V, the summed Zener voltage becomes 18V, and this Zener voltage becomes higher than the DC 15V (predetermined voltage) of the voltage inputted from the terminal 71. Therefore, the voltage of the collector 30c of the transistor 30 is low, and the function of the transistor 30 exhibits a switching effect, and the circuit is cut off here.
Accordingly, there is no voltage at the terminal 72, power supply to the VHF amplifier circuit 25 and power to the relay 37a in the selection means 32 are cut off, the VHF amplifier circuit 25 is stopped, and the specific airband reduction circuit 39 is selectively used. become.

  Further, since various circuits are known as a circuit disposed before and after the BS / CS amplifying circuit 42 connected between the BS / CS signal input terminal 5a and the output terminal 11, various circuits are known. What is necessary is just to provide a favorite circuit according to a request | requirement. In FIG. 5, a power source separation filter 40 for supplying power toward the BS antenna, constant voltage circuits 45 and 47, an intermediate frequency band pass filter (1032 to 2602 MHz) 41, a high pass filter (for BS / CS signal passage). 43 etc. were illustrated as shown. As shown in FIG. 5, a television signal received by the BS / CS antenna by further adding a known circuit element is input from the terminal 5a, is amplified and reaches the output terminal 11, and is received on the ground receiver. An appropriate signal can be delivered to the terminal 17.

Next, between the UHF signal input terminal 4a and the UHF amplifier circuit 35, as is apparent from FIGS. 3, 5, and 6, a UHF band pass circuit 38, a specific air band reduction circuit 39, and both of these circuits are provided. The selection means 32 provided with the switching means 37 for switching so that selection can be used is interposed.
The switching means 37 selects the UHF band-pass circuit 38 so that it can be used when power is supplied to the VHF amplifier circuit 25, and the specific air band reduction circuit when power is not supplied to the VHF amplifier circuit 25. 39 is selectively used.
The UHF band-pass circuit 38 is interposed between the input terminal 33 connected to the UHF signal input terminal 4a and the output terminal 34 connected to the UHF amplifier circuit 35, and is used in a state where the changeover switch 37b is closed (solid line). Is.

The specific air band reduction circuit 39 is a band displayed on the right side of the terrestrial digital broadcasting band (470 to 710 MHz) shown in FIG. 2B, and becomes empty as terrestrial analog television broadcasting ends. For this frequency band (in this case, “the frequency band (710 to 770 MHz) that will be vacated as the terrestrial analog television broadcast ends” is called “specific air band”), It shows the presence of a filter-band-stop for that reduce the disturbance to be expected that after the termination of analog broadcasting this "specific air-band" is incoming by being diverted in FIG 2 (a). As this filter, for example, an arbitrary circuit such as a band eliminator filter or a trap circuit is used.
This specific airband reduction circuit 39 is interposed between an input end 33 connected to the UHF signal input terminal 4a and an output end 34 connected to the UHF amplifier circuit 35, and the side where the changeover switch 37b is indicated by a broken line (FIG. 3). 5 is used in the closed state. Then, as a matter of course, the interference wave input to the UHF amplifier circuit 35 is reduced, and the UHF amplifier circuit 35 enters a desirable operation state.

The switching means 37 shown in FIGS. 3 and 5 shows an example in which a relay circuit is used, for example, for ease of explanation. The coil 37a is connected between the ground 37c and the power supply terminal 37e. The power supply terminal 37e is connected to the same power as that supplied to the VHF amplifier circuit 25. Therefore, in a state where power is supplied to the VHF amplifier circuit 25, the changeover switch 37b is closed at the position of the solid line, and the UHF band-pass circuit 38 is selected to be usable. In the state where the power, for example, the power having a voltage of 15v is not supplied, the changeover switch 37b is closed at the position of the broken line, and the specific air band reduction circuit 39 is selectively used.

Next, the power supply unit 16 shown in FIGS. 3, 5 and 7 is provided on the ground. The power supply unit 16 is provided with a rectifier circuit 54 for converting the power of the AC power supply (commercial frequency) received through the AC plug 50 into DC power.
3, 5, and 7, the individual members of the power supply unit 16 are widely known. 16 a is a case body formed of an arbitrary hard material such as a plastic material, and 16 b is formed in a concave shape. A lid of the case that can be freely opened and closed to cover the terminal accommodating chamber 16c of the case, 21 is a power output terminal (television signal receiving terminal), 22 is a power source separation filter, 23 is a television terminal, and 51 is a voltage drop transformer. Show. Reference numerals 51a and 51b denote transformer taps (intermediate outlet points), 51a for sending DC 15V to the power output terminal 21, and 51b for sending DC 20V to the power output terminal 21. Reference numeral 55 denotes voltage switching means for switching these voltages.

  Next, in the power supply unit 16, a circuit switch 56 is provided for the circuit supplied to the power supply output terminal 21 as shown in FIGS. Since the circuit switch 56 only needs to cut off the current at a necessary time, for example, as shown in FIGS. 3, 5, and 7, a general on / off switch may be used in combination. You may comprise using this changeover switch.

The operation of the above configuration will be described.
The commercial power source coming from the AC plug 50 becomes a low voltage by the transformer 51 as is well known, rectified by the rectifier 54, and the electric power is output from the terminal 21. In this case, when the switch 56 is selected to the DC20V side, the voltage at the terminal 21 is “high predetermined voltage (DC20V)”, as is apparent from the connection state of the circuits shown in FIGS. Go to the amplifying unit 9. In this case, since the low voltage circuit 47 exists in the middle, the voltage drops to the “predetermined voltage (DC15V)” and is fed to the corresponding UHF amplifier circuit 35, BS / CS amplifier circuit 42, etc. as is well known.
Even if the voltage at the terminal 21 is a high predetermined voltage (DC20V), the voltage is lowered to the predetermined voltage (DC15V) as is well known because the voltage changing means 46 exists in the middle, and the corresponding power is As shown in FIGS. 3 and 5, the VHF amplifier circuit 25 is supplied to the power supply terminal 37e of the selection means 32, and the VHF amplification circuit 25 is operated and the relay 37a and the changeover switch 37b in the selection means 32 are operated. A UHF band-pass circuit 38 is interposed between the signal input terminal 4a and the UHF amplifier circuit 35.

  In this state, corresponding TV signals are input from the VHF antenna 3, the UHF antenna 4, and the BS / CS antenna 5 to the input terminals 3a, 4a, and 5a related to the antennas of the amplifying unit 9. Since the amplifying unit 9 has a configuration as shown in FIGS. 3 and 4, the television signal from the input terminal 3a is amplified by the VHF amplifier circuit 25 and the output terminal 11, and the television signal from the input terminal 4a is UHF amplified. The output signal is amplified by the circuit 35 and the television signal from the input terminal 5a is amplified by the BS amplification circuit 42 and sent to the television receiver 17 via the output terminal 11 respectively.

In such a reception state, for example, when the VHF band TV broadcast ends in 2011 and the terrestrial analog broadcast in the UHF band is completely stopped, the circuit switch 56 in the power supply unit 16 is switched. Then, the voltage output from the terminal 21 drops to a “predetermined voltage (DC15V)”, and the electric power generated by this voltage passes through the constant voltage circuit 47 and the UHF amplification circuit 35 and BS amplification as is apparent from FIGS. This is supplied to the circuit 42. On the other hand, since no voltage is generated from the terminal 72 in the voltage changing means 46 as described above, the VHF amplifier circuit 25 at a high place is in a resting state, and the supply of power to this is terminated. Therefore, subsequent power consumption does not occur.
At the same time, the power supply to the relay 37a in the selection means 32 is also terminated, and the changeover switch 37b is operated, so that the UHF signal input terminal 4a and the UHF amplifier circuit 35 are connected as shown by broken lines in FIGS. A specific airband reduction circuit 39 is interposed. This reduces (removes) a band that may become an interference wave among the signals coming from the UHF signal input terminal 4a as described above.

Next, the selection means 32 in FIGS. 3 and 5 shows an example in which the configuration relating to the relay 37 is used in the switching means for the sake of simplicity. The same function can be exhibited using For example, even if it is what is shown by FIG. 6, the completely same function can be exhibited.
Therefore, FIG. 6 showing an example different in that the switching means 37 is configured using the diodes (switches) 37g and 37h and the transistor 30 will be described.
The selection means 32 shown in FIG. 6 continues the operation in the ground power supply unit 16 with the UHF band-pass circuit 38 interposed before the UHF amplifier circuit 35 disposed at the high place, In this state, when the VHF amplifier circuit 25 in the high place is put into a dormant state, the power supplied to the VHF amplifier circuit is not sent to the amplifying unit disposed in the high place, so that the UHF amplification is performed. While the operation of the circuit is continued, the VHF amplifier circuit is put into a pause state and power is not supplied to the VHF amplifier circuit, so that a specific space is provided between the UHF signal input terminal 4a and the UHF amplifier circuit 35. The band reduction circuit 39 can be selectively interposed.
In the description, in FIG. 6, the parts considered to have the same or equivalent configuration in function, property, feature, etc. as those in FIGS. 1 to 5 and 7 are the same as those in FIGS. 1 to 5 and 7. The same reference numerals are assigned and duplicate explanations are omitted.

The switching means 37 includes a UHF band pass circuit 38 and a specific air band reduction circuit 39 as in the case shown in FIG.
The switching means 37 selects the UHF band-pass circuit 38 to be usable when the power is supplied to the VHF amplifier circuit 25, and the specific air band reduction circuit 39 is selectively used when the power is not supplied. It is comprised so that.
In FIG. 6, 37f indicates a power supply terminal connected to the constant voltage circuit 47, and 37c indicates ground. Reference numerals 60, 61, 62, and 63 denote known circuit elements, which respectively indicate a high-frequency passage / DC blocking type capacitor, a high-frequency blocking / DC passing type coil, a bias resistor, and an interference prevention resistor.

37g indicates a PIN diode (switch) having a property of allowing high frequency to pass when a voltage is applied to the power supply terminal 37e and being energized, and not allowing high frequency to pass when no voltage is applied.
37h, when a voltage (+ 15V) is applied to the power supply terminal 37f and the transistor 30 having a switch function is in an energized state, a high frequency is allowed to pass, and when the switch function of the transistor 30 is cut off. A PIN diode (switch) having a property of not allowing high frequency to pass therethrough is shown.

  The transistor 30 shown in FIG. 6 may have any known switch function. For example, the one shown in the figure is composed of an NPN type silicon transistor, and the voltage between the base 30b and the emitter 30e rises to around 0.6V to 0.7V or falls to around 0.6V to 0.7V. Depending on whether or not the current flows through the collector 30c (ON), it does not flow (OFF) switch function is used.

Next, the case where the UHF band pass circuit 38 is selectively used in the selection means 32 of FIG. 6 will be described.
When a voltage is applied to the power supply terminal 37e and supplied to the VHF amplifier circuit 25, a current flows between the ground 37c and the power supply terminal 37e. Therefore,
The UHF high frequency signal from the input terminal 33 passes through the capacitor 60, the diode 37g, and the capacitor 60, that is, passes through the UHF band-pass circuit 38 and reaches the UHF amplifier circuit 35.
In this case, a voltage of 15V is applied to the power supply terminal 37f, and a voltage of 15V is applied to the power supply terminal 37e. By selecting corresponding values for the interference preventing resistor 63 and the bias resistor 62 connected to the base 30b of the transistor 30, no substantial voltage is generated between the interference preventing resistor 63 and the bias resistor 62 ( At least the voltage between the base 30b and the emitter 30e can be reduced to around 0.6V or less). Accordingly, the transistor 30 is turned off, and no current flows through the diodes (switches) 37h and 37h, and the UHF high-frequency signal from the input terminal 33 does not flow into the specific airband reduction circuit 39.

Next, a case where the specific air band reduction circuit 39 is selectively used in the selection means 32 of FIG. 6 will be described.
When the voltage supplied to the VHF amplifier circuit 25 is cut off at the power supply terminal 37e, no current flows through the diode 37g between the ground 37c and the power supply terminal 37e. Therefore, the UHF high-frequency signal from the input terminal 33 is blocked by the diode 37g.

On the other hand, when the power (voltage) supplied to the VHF amplifier circuit 25 is lost, the power supply terminal 37e has no voltage. Accordingly, as described above, the voltage between the interference preventing resistor 63 and the bias resistor 62 is set by selecting the values of the interference preventing resistor 63 and the bias resistor 62 corresponding to the base 30b of the transistor 30 in advance. Can be substantially increased. Since at least the voltage between the base 30b and the emitter 30e can be increased to about 0.7V or more, the transistor 30 is turned on, and between the terminal 37f and the ground 37c, that is, the coil 61, the diode 37h, and the coil 61 The transistor 30, the coil 61, the diode 37h, and the coil 61 are turned on.
As a result, the UHF high frequency signal from the input terminal 33 passes through the capacitor 60, the diode 37h, the capacitor 60, the specific air band reduction circuit 39, the capacitor 60, the diode 37h, and the capacitor 60, that is, the specific air band reduction circuit. 39 and reaches the UHF amplifier circuit 35.

FIG. 2 is a conceptual diagram of a house, a plurality of types of antennas arranged at a high place in the house, and a positional relationship between the antenna and the amplification unit. Is a comparison diagram of the frequency band used for terrestrial analog broadcasting and terrestrial digital broadcasting in the UHF band and the frequency band used for receiving future terrestrial digital broadcasting, Is a circuit diagram for explaining a receiving circuit for a TV signal in the VHF band and a TV signal in the UHF band and a power supply circuit for these circuits, Shows a circuit diagram of the voltage changing means. Is a circuit diagram for explaining a TV signal in the VHF band, a TV signal in the UHF band, a receiving circuit in the BS / CS band, and a power supply circuit for these circuits, FIG. 4 is a circuit diagram of a selection unit showing an example of a circuit configuration different from the selection unit shown in FIG. 3. FIG. 3 is a perspective view for explaining the relationship between a case of a power supply unit and voltage switching means.

DESCRIPTION OF SYMBOLS 1 ... Construction, 2 ... Prop, 3 ... VHF antenna, 3a ... VHF input terminal, 4 ... UHF antenna, 4a ... UHF input terminal, 5 ... BS / CS antenna 5a ... BS / CS input terminal, 8 ... case, 9 ... amplifier, 11 ... output terminal, 12 ... transmission line (coaxial cable), 15 ... distributor, 16 ... Power supply unit (power supply device), 16a is the case body, 16b is the case lid, 16c is the terminal housing of the case, 17 ... TV receiver, 18, 18a, ... Coaxial cable, ..TV terminal, 21 ... power output terminal, 22 ... power source separation filter, 23 ... TV terminal, 25 ... VHF amplifier circuit, 26 ... VHF band pass filter, 27 ... VHF / UHF band pass filter, 28... Power supply separation filter, 30... Transistor, 31 ... High-pass filter,
32 ... selecting means, 33 ... input end, 34 ... output end, 35 ... UHF amplifier circuit, 36 ... UHF band pass filter, 37 ... switching means (relay), 37a ... Coil, 37b ... Changeover switch (solid line), 37c ... Ground, 37d ... Switch after changeover (dashed line), 37e ... Power supply terminal, 37f ... Power supply terminal (positive electrode), 37g ... Diode (switch), 37h ... Diode (switch), 38 ... UHF bandpass circuit, 39 ... Specific airband reduction circuit, 40 ... Power supply separation filter, 41 ... Middle Frequency band pass filter (1032 to 2602 MHz) 42... BS / CS amplifier circuit 43... High pass filter 45... Constant voltage circuit 46. 50 ... AC plug, 51 ... Transformer, 54 ...・ Rectifier, 55 ... Voltage switching means, 56 ... Circuit switch, 60 ... High frequency passing / DC blocking capacitor, 61 ... High frequency blocking / DC passing coil, 62 ... Bias resistor 63 ... Resistance for preventing interference.

Claims (1)

A VHF amplifier circuit having an input side connected to a VHF signal input terminal connected to the VHF antenna and an output side connected to an output terminal;
An amplifying unit having an input side connected to a UHF signal input terminal connected to a UHF antenna and an output side connected to the output terminal is disposed at a high place and is disposed on the ground from the amplifying unit. The signal toward the receiver is transmitted through a transmission line provided between the output terminal disposed at the above-mentioned high place and the receiver on the ground,
On the other hand, on the ground, a power supply unit is provided, and the supply of power required in the amplification unit provided at the high place is transmitted superimposed on the transmission line, and the VHF amplification circuit, UHF amplification circuit, In the power supply method in the amplifying apparatus that operates each of the
Between the UHF signal input terminal and the UHF amplifier circuit, a UHF bandpass circuit and a specific airband reduction circuit are interposed so as to be selectively usable,
In both of these circuits, the UHF band-pass circuit is selected when power is supplied to the VHF amplifier circuit, and the specific air band reduction circuit is selected when power is not supplied to the VHF amplifier circuit. So that
The power supply unit to be provided on the ground includes a voltage switching unit that can switch a DC voltage to be output between a predetermined voltage and a high predetermined voltage higher than the predetermined voltage,
For the VHF amplifier circuit, a predetermined voltage is output when the voltage from the power supply unit is a high predetermined voltage, and a predetermined voltage is not output when the voltage from the power supply unit is a predetermined voltage. Power is supplied via the voltage changing means, and power of a high predetermined voltage is normally supplied from the power supply unit to operate the VHF amplifier circuit and the UHF amplifier circuit, respectively.
In the power supply unit, when the operation of the UHF amplifier circuit arranged at the high place is continued and the VHF amplifier circuit at the high place is put into a resting state, the voltage switching means is switched. The UHF signal input terminal is configured to output the power of a predetermined voltage and keep the operation of the UHF amplifier circuit in a state of stopping the VHF amplifier circuit and not supplying power to the VHF amplifier circuit. A method of supplying power in an amplifying apparatus, wherein the specific airband reduction circuit is interposed between a UHF amplifier circuit and a UHF amplifier circuit.

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