JP2001053639A - Booster device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To secure stable amplifying operation by storing respective cables connected to an amplifying circuit board in a metallic antenna mast and preventing the amplifying circuit board from oscillating while holding ambient radio wave environment excellent. SOLUTION: Input terminals 8, 9, and 10 are arranged above the amplifying circuit board 12 arranged in an amplifying device 2 and an output terminal 11 is arranged below the amplifying circuit board 12; and the distances between the input terminals 8, 9, and 10 and output terminal 11 are made long, an upper mast 3 shields cables 13, 14, and 15 connected to the input terminals 8, 9, and 10 of the amplifying circuit board 12, and a lower mast 16 shields a cable 19 connected to the output terminal 11 of the amplifying circuit board 12.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a booster device for amplifying a received signal obtained by a receiving operation of a television antenna and supplying the amplified signal to a television receiver, and more particularly to an amplifying device in an antenna mast or in the middle of the antenna mast. The present invention relates to a booster device in which a device is arranged to prevent oscillation of an amplifier circuit due to a contact failure of an output cable or the like.

[Summary of the Invention] The present invention relates to an input cable for an amplifying device in which an amplifying device for amplifying a received signal obtained by a receiving operation of a television antenna and supplying the amplified signal to a television receiver is built in an antenna mast. In addition, the output cable is shielded, and the input terminal and the output terminal of the amplifying device are spatially separated from each other, so that the feedback operation causing the oscillation is reduced and the oscillation of the booster device is prevented.

[0003]

2. Description of the Related Art Among households nationwide, about 1,700
In many homes, when receiving a television broadcast signal, a received signal received by an antenna is amplified by a booster device, supplied to a television receiver provided in each home, and broadcast by a broadcast station. The displayed program contents are displayed.

FIG. 8 is a schematic configuration diagram showing an example of standard receiving equipment for general households using such a booster device.

[0005] A receiving facility 101 shown in FIG.
Roof horse 104 installed on the top of the second roof 103
A BS antenna 106 provided on a predetermined portion of the roof horse 104, for example, a pole stand 105; a mast 107 substantially vertically supported by a pillar standoff 105 of the roof horse 104; and an upper end portion of the mast 107 , A VHF antenna 109 provided slightly below the upper end of the mast 107, a mast branch line stopper 110 provided in the middle of the mast 107, the mast branch line stopper 110 and the eaves 111 of the roof 103. Mast 1 by connecting the questions with the parts
07 to prevent falling, and UHF
A plurality of coaxial cables 113, 114, and 115 for taking in the respective received signals obtained by the receiving operation of the antenna 108, the VHF antenna 109, and the BS antenna 106, and provided in the middle of the mast 107, and each of the coaxial cables 113 to
5, a booster device 116 for capturing each received signal and amplifying each received signal into one signal, and a booster device 116
The signal amplified by the
2 and one coaxial cable 117 leading to inside
And a separator 118 installed in the house 102 to separate a signal supplied via the coaxial cable 117 into received signals, and a receiver 118 installed in the house 102 to receive each received signal separated by the separator 118 and to transmit the UHF television broadcast. TV receiver 119 for displaying the contents of VHF television broadcast and BS television broadcast
And

The UHF antenna 108, the VHF antenna 109, and the BS antenna 106 use the UHF television broadcast signal, the VHF television broadcast signal, and the BS
While receiving the television broadcast signals, the booster device 116 uses the VHF antennas 109 and U
After amplifying each received signal output from the HF antenna 108 and the BS antenna 106 and combining them into one signal, the signal is supplied to a separator 118 via a coaxial cable 117, and the received signal is separated by the separator 118. Separately, the television receiver 119 displays the contents of UHF television broadcast, VHF television broadcast, and BS television broadcast.

In this case, the booster device 116 is provided as shown in FIG.
, A booster main body 120 attached to the lower side of the mast 107 and a BS-IF input terminal 1 provided on the lower surface of the booster main body 120 and connected to one end of a coaxial cable 115 connected to the BS antenna 106.
21, a waterproof cap 122 for preventing rainwater or the like from entering the BS-IF input terminal 121, and one end of a coaxial cable 113 provided on the lower surface of the booster main body 120 and connected to the UHF antenna 108. UHF
An input terminal 123, a waterproof cap 124 for preventing rainwater or the like from entering the UHF input terminal 123, and a VHF antenna 10 provided on the lower surface of the booster body 120.
9, a VHF input terminal 125 to which one end of the coaxial cable 114 is connected, a waterproof cap 126 for preventing rainwater or the like from entering the VHF input terminal 125,
The separator 1 is provided on the lower surface of the booster body 120.
An output terminal 127 to which one end of the coaxial cable 117 connected to the output terminal 18 is connected, and a waterproof cap 128 for preventing rainwater or the like from entering the output terminal 127 are provided.

Then, the BS-IF input terminal 121, UH
The VHF antenna 109, the UHF antenna 108, the BS antenna 1 via the coaxial cables 113 to 115 connected to the F input terminal 123 and the VHF input terminal 125, respectively.
After receiving and amplifying each of the received signals output from the input terminal 06, the signals are combined into one signal while amplifying the signals, and then the one signal obtained by combining the received signals is separated into a separator 118 via a coaxial cable 117 connected to an output terminal 127. To supply.

[0009]

By the way, the conventional booster device 11 used in the receiving equipment 101 as described above.
6 is said to have a service life of approximately 7 to 10 years, but due to failure of the booster device 116 main body, poor wiring work, aging of the booster device 116, etc.,
Even before the end of the useful life, positive feedback is applied to the amplifier circuit provided in the booster main body 120, and the amplifier circuit oscillates, and the booster main body 120 itself or a coaxial cable connected to the booster main body 120 is used. Unnecessary electromagnetic waves (jamming waves) are radiated from 117, and there is a problem that a relatively wide area is obstructed around the place where the booster device 116 is installed.

[0010] Even if such a failure occurs and a complaint such as poor reception is received by the Japan Broadcasting Corporation, it is necessary to find out in which home the booster device 116 provided in the home emits jamming radio waves. In 1993, about 2,500 complaints were filed each year, and the national average was about 1 even when the reception environment such as the density of houses was considered.
It is estimated that 82,500 households are affected, but there is a problem that it is difficult to deal with the damage.

For this reason, although there is a strong demand for the development of a technique for solving such a problem, the booster device 11
6 is turned off once, and then turned on again, it is difficult to reproduce an interference phenomenon, such as unnecessary electromagnetic waves from the booster device 116 being eliminated. 107
Once installed, it is difficult to shield this booster device 116 from the surroundings,
There is a problem that it is difficult to determine which part of the booster device 116 is defective and unnecessary electromagnetic waves are radiated.

In view of the above circumstances, the present invention prevents unnecessary radio waves from entering the input side of an amplification circuit board from the outside,
A main object of the present invention is to provide a booster device capable of preventing oscillation of an amplifier circuit board and ensuring a stable amplification operation while maintaining a favorable surrounding radio wave environment.

[0013]

In order to achieve the above object, according to the present invention, there is provided an amplifier circuit board for amplifying a reception signal obtained by a receiving operation of a television antenna, and A conductive pipe having a function of shielding an input cable and an output cable to be connected and a function as an antenna mast is provided.

According to a second aspect of the present invention, in the booster device according to the first aspect, the conductive pipe is divided into an upper conductive pipe and a lower conductive pipe, and the booster device includes the booster circuit board. The upper conductive pipe is fixed to an upper side, and the lower conductive pipe is fixed to a lower side of the amplifying device.

According to a third aspect of the present invention, in the booster device according to the first aspect, the conductive pipe is constituted by one pipe that houses the amplifier circuit board, the input cable, and the output cable. And

According to a fourth aspect of the present invention, in the booster device according to any one of the first to third aspects, the input cable is disposed in an upper side of the mast or in the upper mast, and the output cable is connected to the mast. It is characterized by being arranged in the lower part of the mast or in the lower mast.

According to the first aspect of the present invention, in a conductive pipe used as an antenna mast, an amplifier circuit board for amplifying an input received signal, an input cable connected to the amplifier circuit board, By storing the output cable and shielding the input cable and the output cable respectively, unnecessary radio waves are prevented from being radiated from the output side of the amplifier circuit board, and unnecessary radio waves are externally transmitted to the input side of the amplifier circuit board. To prevent the invasion of the amplifying circuit board and prevent oscillation of the amplifying circuit board while maintaining a favorable radio wave environment, thereby ensuring a stable amplifying operation.

According to the second aspect of the present invention, as the conductive pipe, a pipe divided into an upper conductive pipe and a lower conductive pipe is used. The input pipe and the output cable connected to the amplifier circuit board are housed in a metal antenna mast by fixing the characteristic pipes to the upper and lower sides of the amplifier that incorporates the amplifier circuit board. While preventing unnecessary radio waves from being radiated from the output side of the amplification circuit board and preventing unnecessary radio waves from entering the input side of the amplification circuit board from the outside, while maintaining a good surrounding radio wave environment, Oscillation of the amplification circuit board is prevented, and a stable amplification operation is ensured.

According to the third aspect of the present invention, the amplifier circuit board, the input cable, and the output cable are housed in one antenna mast, and the strength of the entire device is increased while the amplifier circuit board is increased. This prevents unwanted radio waves from being radiated from the output side of the amplifier circuit and prevents unwanted radio waves from entering the input side of the amplifier circuit from the outside. And a stable amplification operation is ensured.

According to the fourth aspect of the present invention, the input cable is arranged in the upper or upper mast of the mast, and the output cable is arranged in the lower or lower mast of the mast. The input cable connected to the amplifier circuit board and the output cable are separated from each other so that they do not come into contact with each other, and the electromagnetic coupling force is reduced, thereby causing the output side of the amplifier circuit board to cause oscillation. , The level of the signal that returns to the input side is reduced, thereby preventing oscillation of the amplifier circuit board and ensuring a stable amplification operation.

[0021]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS <Basic Description of the Invention> First, prior to a detailed description of a booster device according to the present invention, a basic description of a booster device according to the present invention will be given.

<< Verification of Oscillation Mechanism >> First, the present inventors verified the oscillation mechanism of the booster device in the following procedure in order to study a method for preventing the oscillation of the booster device.

<< Measurement of Feedback Level in Oscillation State >> First, as shown in FIG. 3, as an amplifier having an amplification characteristic equivalent to that of a general booster device, "DX ANTENNN" is used.
A BM-312A "made by A is selected, and a signal generator 132, a load device 133, and a variable attenuator (variable attenuator) 134 are connected to the amplifier 131, and the output of the signal generator 132 is output. With the output of the amplifier 131 set to “92 dB” and the output of the amplifier 131 set to “92 dB”, the attenuation factor of the variable attenuator device 134 is sequentially reduced, and the level of the signal that is fed back from the output side of the amplifier 131 to the input side of the amplifier 131 (feedback) When the feedback level exceeded "55 dB", the amplifier 131 oscillated.

From this, it is presumed that even a normal booster device oscillates when the feedback level exceeds "55 dB".

<< Measurement of Radiation Wave Level >> Next, the amplifier 13
BM-31 made by DX ANTENNA
2A ", as shown in FIG.
And the load device 133, and the amplifier 13
1, the output of the signal generator 132 is set to “72 dB”, and the output of the amplifier 131 is set.
Is set to “92 dB”, and the spectrum analyzer device 13 connected to the dipole antenna 135 is output.
6 was used to measure the level of the radio wave radiated from the amplifier 131 (radiation wave level), and the following results were obtained.

(1) When the input cable 137 and the output cable 138 are normally connected: 45 dB (2) When the outer conductor of the output cable 138 is not connected to the housing of the amplifier 131: 45 dB (3) Output cable When the center conductor 138 does not sufficiently contact the output terminal of the amplifier 131: 75 dB

From these results, when the output cable 138 has a poor contact, this output cable 138
From this, it was found that a radiation wave exceeding the allowable feedback level of the amplifier 131 was emitted.

<< Measurement of radiation wave level from mismatched point >>
Next, "DX ANTENNN" which is the amplifier 131
As shown in FIG. 5, a signal generator 132, a load device 133, and one of the receivers BM-312A "
After connecting the distribution device 139 and the cable 140 to each other, an inconsistent portion is created in any of the distribution device 139 and the cable 140, and “1.
With a dipole antenna (not shown) installed at a distance of 5 m, the output of the signal generator 132 is set to "72 dB", the output of the amplifier 131 is set to "92 dB", and radiated from the mismatched portion. When the level (radiation level) of the radio wave was measured, the following results were obtained.

(1) When the outer conductor of the cable 140 is not connected to the housing of the distribution device 139: 58 dB (2) When the outer conductor of the cable 140 is cut in the middle: 58 dB

From these results, when only the center conductor of the cable 140 is connected to the distribution device 139, or when the outer conductor of the cable 140 is cut off in the middle of the cable 140, for example, When there is a mismatch on the receiving system, the amplifier 131
It was found that the radiation wave exceeding the allowable feedback level was emitted.

<< Measurement of Relationship between Antenna and Unmatched Location >> Next, the "DX ANTENNA" which is the amplifier 131
As shown in FIG. 6, a television antenna 141, a load device 133, and a distribution device 13
9 and the cable 140, and then the distribution device 139
In a state where a mismatched portion is created in a portion and a dipole antenna (not shown) is installed in the vicinity of the mismatched portion, seven kinds of radio waves (average per wave, 70 dB per wave, in the VHF band) are provided by the television antenna 141. (Radio waves) were sequentially received, and the level (radiation level) of the radio waves radiated from the mismatched portion was measured. As a result, the cable length from the television antenna 141 to the amplifier 131 and the "X _1", the cable length from the amplifier 131 to the output terminal of the distributor 139 "X _2" and a total cable length obtained by adding the "X _3" is below Under the conditions shown, it was found that the amplifier 131 oscillated.

X ₃ <1 m (1)

<< Operating Prevention Measures by Ferrite Core >> Next, as shown in FIG. 7, in a state where a mismatching portion is created in the distributor 139, the cable length “X ₁ ” from the television antenna 141 to the amplifier 131 is determined. Amplifier 131
The cable length “X ₂ ” from the cable to the output terminal of the distributor 139 is set to “0.5 m”, and the amplifier 131 shown in the equation (1) oscillates.
The ferrite core 142 was attached to either the output terminal portion of the cable 131 or the cable 140, and it was checked whether the oscillation of the amplifier 131 stopped. It was not possible to stop the oscillation, and the oscillation could be stopped only when the ferrite core 142 was mounted immediately near the mismatched portion.

<< Verification Results >> Based on these measurement results and the verification results, when the output cable 138 connected to the output side of the amplifier 131 has a poor contact, or when there is a mismatch between the receiving device other than the amplifier 131 and the receiving device. When there is, the amplifier 131 oscillates. Therefore, it is estimated that the booster device oscillates when the same conditions are satisfied in the actual booster device.

Therefore, the present inventors consider the oscillation of the amplifier 131 caused by the poor contact of the output cable 138 connected to the output side of the amplifier 131 with respect to the input side of the amplifier 131 and the output side of the amplifier 131. The input side of the amplifier 131 and the output side of the amplifier 131 are shielded by a conductor tube or the like, so that radio waves (radiation waves) radiated from the output terminal of the amplifier 131 can be separated from the television antenna 141 or the input cable. 13
7, the feedback level when the signal is fed back to the input side of the amplifier 131 is reduced to an allowable feedback level or less.
31 is prevented from oscillating.

Regarding the oscillation of the amplifier 131 caused by the occurrence of the mismatch in the receiving device other than the amplifier 131, it is possible to stop the oscillation of the amplifier 131 by mounting the ferrite core 142 immediately near the mismatching point. Although it is possible, when such an inconsistency occurs, it is more practical to perform the repair to eliminate the inconsistent portion. Therefore, in such a case, it is decided to repair the inconsistency.

<Detailed Description of the Invention> FIG. 1 shows an embodiment of a booster device according to the first, second and fourth aspects of the present invention using the above-described basic principle. It is a perspective view.

The booster device 1 shown in FIG. 1 includes an amplifying device 2 formed in a rectangular shape, an upper mast 3 having a hollow metal pipe or the like, and a lower end fixed to an upper portion of the amplifying device 2. A waterproof cap 4 provided at the upper end of the upper mast 3 to prevent rainwater or the like from entering the upper mast 3 and a plug attached to the waterproof cap 4 portion, for example, easy to connect and stable for a long time. One end of a cable connected to a VHF antenna, one end of a cable connected to a UHF antenna, and one end of a cable connected to a BS antenna (or CS antenna), each of which is configured by a connectable F-type plug or the like. And a plurality of input terminals 5, 6 and 7 to be provided.

The booster device 1 is arranged in the amplifying device 2 and has respective input terminals 8 formed on the upper side.
Each received signal input via 9, 10 is designated by a designated gain, for example, "25 dB", "30 dB" or "35 dB".
B ", and amplifies the signal into one signal, and outputs the signal from an output terminal 11 formed on the lower side.
2 and an upper mast 3, one end of each of which is connected to each of the input terminals 5, 6 and 7, and the other end of which is connected to the amplifier circuit board 12.
And a plurality of cables 13, 14, 15 respectively connected to the input terminals 8, 9, 10.

Further, the booster device 1 is composed of a hollow metal pipe or the like, and has a lower mast 16 whose upper end is fixed to a lower portion of the amplifier 2, and is provided in the middle of the lower mast 16. A waterproof cap 17 for preventing rainwater or the like from entering the side mast 16 and a plug attached to the waterproof cap 17, for example, an F-type plug for easy connection and stable connection for a long time. An output terminal 18 to which one end of a coaxial cable connected to the separator is connected, and which is arranged in the lower mast 16, one end is connected to the output terminal 11 of the amplifier circuit board 12, and the other end is an output terminal. Cable 1 connected to 18
9 is provided.

When using the booster device 1,
First, a VHF antenna, UHF antenna,
BS antenna (or CS antenna) is attached,
The ends of the coaxial cables connected to the VHF antenna, UHF antenna, BS antenna (or CS antenna) are connected to the input terminals 5, 6, 7 respectively, and the lower end of the lower mast 16 is attached to the roof of the house. After being inserted into the roof horse attached to and fixed to the roof at each branch line,
One end of a coaxial cable extending from a separator provided in the house is connected to the output terminal 18.

Then, UHF antenna, VHF antenna, BS antenna (or CS antenna)
When an HF television broadcast signal, a VHF television broadcast signal, and a BS television broadcast signal (or a CS television broadcast signal) are received, the amplification device 2 uses the VHF antenna, the UHF antenna, and the BS.
After each received signal output from the antenna (or CS antenna) is amplified and combined into one signal, the signal is supplied to a separator via a coaxial cable, and each received signal is separated by the separator. The contents of UHF television broadcast, VHF television broadcast, BS television broadcast (or CS television broadcast) are displayed on the television receiver.

As described above, in this embodiment, the input terminals 8, 9, and 10 are arranged on the upper side of the amplifier circuit board 12 disposed in the amplifier 2, and the amplifier circuit board 1
By arranging the output terminal 11 on the lower side of 2, the distance between each of the input terminals 8, 9, 10 and the output terminal 11 can be increased. Also, each of the cables 13, 14, 15 connected to the input terminals 8, 9, 10 of the amplifier circuit board 12
Can be stored in the upper mast 3,
By storing the cable 19 connected to the amplifier circuit board 12 in the lower mast 16, the cables 13, 14, 15 connected to the input terminals 8, 9, 10 of the amplifier circuit board 12 by the upper mast 3. And an output terminal 1 of the amplifier circuit board 12 by the lower mast 16.
1 can be shielded.

As a result, the outer conductor (or the center conductor) of the cable 19 and the output terminal 11 of the amplifier circuit board 12 have poor contact, and even if unnecessary radio waves are radiated from the cable 19 or the like, the surroundings are adversely affected. And prevents the radiated wave from the cable 19 from returning to the UHF antenna, VHF antenna, BS antenna (or CS antenna), each of the cables 13, 14, 15 and the like. Unnecessary radio waves can be prevented from entering the input side of the circuit board 12, and the amplification operation of the amplifier circuit board 12 can be stabilized.

Also, in this embodiment, the amplifier circuit board 12 is made vertically long, the input terminals 8, 9, 10 and the output terminal 11 are separated from each other as much as possible, and the input terminals 8, 9, 10 are connected to each other. Cables 13, 14, 15
And the cable 19 connected to the output terminal 11 are separated from each other.
And the cable 11 can be prevented from contacting with each other, and the electromagnetic coupling force between the cables 13, 14, and 15 and the cable 11 can be reduced, and the amplifying circuit board 12 causing oscillation can be reduced. The level of the signal that is fed back from the output side to the input side is reduced, thereby preventing oscillation of the amplifier circuit board 12 and ensuring a stable amplification operation.

FIG. 2 is a perspective view showing an embodiment of the booster device according to the first, third and fourth aspects of the booster device according to the present invention.

The booster device 21 shown in this figure has a mast 22 composed of a hollow metal pipe or the like having a length substantially equal to that of a general mast,
2, a waterproof cap 23 for preventing rainwater or the like from entering the mast 22 and a waterproof cap 23.
One end of a cable connected to the VHF antenna, which is constituted by a plug attached to the portion, for example, an F-type plug that is easy to connect and that can be connected stably for a long period of time, etc.
It has a plurality of input terminals 24, 25, 26 to which one end of a cable connected to the HF antenna and one end of a cable connected to the BS antenna (or CS antenna) are connected.

The booster device 21 is disposed at a central portion in the mast 22 and receives received signals input through the input terminals 27, 28, 29 formed on the upper side, and receives a specified gain, For example, “25 dB”, “30 dB
B "or" 35 dB ", amplifying the signal into one signal, and amplifying circuit board 31 which is output from output terminal 30 formed on the lower side, and disposed on the upper side in mast 22, one end of each Are connected to the input terminals 24, 25 and 26, respectively, and the other ends are connected to the input terminals 27 and 2 of the amplifier circuit board 31, respectively.
A plurality of cables 32, 33,
34.

Further, the booster device 21 is provided below the mast 22 and has a waterproof cap 35 for preventing rainwater or the like from entering the mast 22, and a plug attached to the waterproof cap 35, for example, Easy connection,
An output terminal 36 to which one end of a coaxial cable connected to the separator is connected, which is constituted by an F-type connector capable of stable connection for a long time, and which is arranged below the mast 22 and one end of which is amplified A cable 37 connected to the output terminal 30 of the circuit board 31 and the other end connected to the output terminal 36
And

When using the booster device 21, first, a VHF antenna, a UHF antenna, and a BS antenna (or CS antenna) are attached to the mast 22, and the VHF antenna, the UHF antenna, and the BS antenna (or CS antenna) are attached to the mast 22. The ends of the connected coaxial cables are connected to the input terminals 24, 25, and 26, respectively, and the lower end of the mast 22 is inserted into a roof horse attached to the roof of the house, and is fixed to the roof at each branch line. After that, one end of the coaxial cable extending from the separator provided in the house is connected to the output terminal 36.

The UHF antenna, VHF antenna, BS antenna (or CS antenna)
When the HF television broadcast signal, the VHF television broadcast signal, and the BS television broadcast signal (or the CS television broadcast signal) are received, the VHF antenna, the UHF antenna, and the B
After each received signal output from the S antenna (or CS antenna) is amplified and combined into one signal,
A signal is supplied to a separator via a coaxial cable, and the received signal is separated by the separator into a UHF television broadcast, a VHF television broadcast, a BS television broadcast (or a CS television). John Broadcast) is displayed.

As described above, in this embodiment, the input terminals 24, 25, and 26 are arranged on the upper side of the amplifier circuit board 31 disposed in the mast 22, and the output terminals are arranged on the lower side of the amplifier circuit board 31. By arranging the terminal 30,
The distance between each of the input terminals 24, 25, 26 and the output terminal 30 can be increased. The mast 22 shields the cables 32, 33, and 34 connected to the input terminals 24, 25, and 26 of the amplifier circuit board 31, and the cable 37 connected to the output terminal 30 of the amplifier circuit board 31. be able to. That is, by using the mast 22 having no joint, the strength of the entire booster device 21 is increased and the input terminals 27, 2
Each cable 32, 33, 34 connected to 8, 29;
The cable 37 connected to the amplifier circuit board 31 can be housed in the mast 22.

As a result, the outer conductor (or the center conductor) of the cable 37 and the output terminal 30 of the amplifier circuit board 31 have poor contact, and even if unnecessary radio waves are radiated from the cable 37 or the like, the surroundings are adversely affected. And a radio wave (radiation wave) radiated from the cable 37 is transmitted from the UHF antenna, the VHF antenna,
S antenna (or CS antenna), each cable 3
2, 33, 34, etc., it is possible to prevent unnecessary radio waves from entering the input side of the amplifier circuit board 31, and the amplification operation of the amplifier circuit board 31 can be stabilized.

Also, in this embodiment, the amplifier circuit board 31 is made vertically long so that the input terminals 27, 28, 29 and the output terminal 30 are separated as much as possible and connected to the input terminals 27, 28, 29. Cables 32, 3
3 and 34 are separated from the cable 37 connected to the output terminal 30, so that each cable 32, 3
3, 34 and the cable 37 can be prevented from contacting each other, and the cables 32, 33, 3
4 to reduce the electromagnetic coupling force between the cable 37 and
The level of the signal that returns from the output side to the input side of the amplifier circuit board 31 that causes oscillation is reduced, thereby preventing oscillation of the amplifier circuit board 31 and ensuring a stable amplification operation.

As described above, in each of the above-described embodiments, the VHF input terminals 4, 24, the UHF input terminals 5, 25, and the BS (or CS) input terminals are provided above the upper mast 3 or above the mast 22. Although input terminals 7 and 26 are provided, input terminals for VHF and UHF band amplification or UH bands are used instead of these input terminals 4 to 6 and 24 to 26.
An input terminal according to the content of the broadcast to be received, such as an input terminal for F-band amplification or an input terminal for VHF band amplification, may be provided.

Further, using an existing VU mixer, 1
One input terminal may receive a VHF band radio wave and a UHF band radio wave.

[0057]

As described above, in the booster device according to the first aspect, the input cable and the output cable connected to the amplifier circuit board are housed in the metal antenna mast, and the output side of the amplifier circuit board is provided. Prevents unwanted radio waves from radiating from the outside and prevents unwanted radio waves from entering the input side of the amplifier circuit board from the outside, preventing the oscillation of the amplifier circuit board while maintaining a good surrounding radio wave environment. do it,
A stable amplification operation can be ensured.

In the booster device according to the second aspect, the input cable and the output cable connected to the amplifier circuit board are housed in a metal antenna mast, and unnecessary radio waves are radiated from the output side of the amplifier circuit board. To prevent
Prevents unwanted radio waves from entering the input side of the amplifier circuit board from the outside and prevents oscillation of the amplifier circuit board while maintaining a favorable surrounding radio wave environment, thereby ensuring stable amplification operation. .

In the booster device according to the third aspect, the amplifier circuit board, the input cable, and the output cable are housed in one antenna mast, and the strength of the entire device is increased while the output side of the amplifier circuit board is increased. To prevent unwanted radio waves from radiating from the outside, prevent unnecessary radio waves from entering the input side of the amplifier circuit from the outside, and prevent oscillation of the amplifier circuit board while maintaining a good surrounding radio wave environment. As a result, a stable amplification operation can be ensured.

In the booster device according to the fourth aspect, the input cable and the output cable connected to the amplifier circuit board are separated from each other so that they do not come into contact with each other, and the electromagnetic coupling force is reduced to reduce the oscillation. The level of a signal that is fed back from the output side to the input side of the amplifier circuit board, which causes the above, is reduced, thereby preventing oscillation of the amplifier circuit board and ensuring a stable amplification operation.

[Brief description of the drawings]

FIG. 1 is a perspective view showing an embodiment of a booster device according to claims 1, 2, and 4 of the booster device according to the present invention.

FIG. 2 is a perspective view showing an embodiment of a booster device according to the first, third and fourth aspects of the booster device according to the present invention.

FIG. 3 is a circuit diagram of a device used for measuring a relationship between an oscillation operation of a general booster device and a feedback level.

FIG. 4 is a circuit diagram of a device used for measuring a relationship between an input cable and an output cable connected to a general booster device and a radio wave level radiated from the booster device.

FIG. 5 is a circuit diagram of a device used for measuring a radio wave level radiated from a mismatched point when a mismatched point is present on a receiving system using a general booster device.

FIG. 6 is a circuit diagram of a device used for measuring the relationship between the length of each cable constituting a receiving system using a general booster device and the level of a radio wave radiated from a mismatched portion.

FIG. 7 is a circuit diagram of a device used for measuring a relationship between a ferrite core mounting position of a receiving system using a general booster device and a radio wave level radiated from the booster device.

FIG. 8 is a schematic configuration diagram showing an example of a receiving facility necessary for receiving a television broadcast in a general home.

9 is a partially cut front view showing a detailed configuration example of the booster device shown in FIG.

[Explanation of symbols]

1, 21: booster device 2: amplification device 3: upper mast (conductive pipe) 4, 17, 23, 35: waterproof cap 5, 6, 7, 8, 9, 10: input terminal 11, 18, 30, 36 : Output terminal 12, 31: Amplifier circuit board 13, 14, 15, 32, 33, 34: Cable (input cable 16: lower mast (conductive pipe) 19, 37: Cable (output cable) 22: Mast (conductive) 24, 25, 26, 27, 28, 29: input terminal

Claims (4)

[Claims] 1. An amplification circuit board for amplifying a reception signal obtained by a reception operation of a television antenna, a function of shielding an input cable and an output cable connected to the amplification circuit board, and a function as an antenna mast. A booster device comprising: a conductive pipe having; 2. The booster device according to claim 1, wherein the conductive pipe is divided into an upper conductive pipe and a lower conductive pipe, and the conductive pipe is provided on an upper side of an amplifier including the amplifier circuit board. An upper conductive pipe is fixed, and the lower conductive pipe is fixed to a lower side of the amplifying device. 3. The booster device according to claim 1, wherein the conductive pipe is constituted by a single pipe that houses the amplifier circuit board, the input cable, and the output cable. Booster device. 4. The booster device according to claim 1, wherein the input cable is disposed in an upper part of the mast or in the upper mast, and the output cable is disposed in the mast. A booster device arranged on a lower side or in the lower mast.