JP2008099128A - Power source separated booster - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power source separated booster capable of efficiently performing adjustment work. <P>SOLUTION: The power source separated booster comprises: a power source unit 12 which outputs a control signal generated according to operation for instructing an attenuation amount and a gain while superimposing the control signal on DC power source; and an amplification unit 11 which is operated by the DC power source supplied from the power source unit through a cable 3 and adjusts, at each frequency band, the attenuation amount and the gain of a signal received by an antenna in accordance with the control signal superimposed on the DC power source. Furthermore, the power source separated booster comprises: a remote control operating unit 13a which generates the control signal instructing the attenuation amount and the gain according to operation; the power source unit which generates and outputs DC power source; and the amplification unit which is operated by the DC power source from the power source unit through the cable and adjusts the attenuation amount and the gain of a signal received by the antenna in accordance with the control signal sent from the remote control operating unit through the other cable connected to the cable and the cable. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a power supply separation type booster in which an amplification unit that amplifies a signal received by an antenna and a power supply unit that supplies power to the amplification unit are separated, and in particular, the gain and attenuation in the amplification unit are adjusted. Regarding technology.

  FIG. 10 is a diagram illustrating a configuration of a receiving system to which a conventional power source separation type booster is applied. The power supply separation type booster applied to this receiving system is mainly composed of an amplifying unit 1 attached in the vicinity of an antenna installed on a roof and a power source unit 2 attached indoors. The part 2 is connected by a cable 3. For example, a coaxial cable is used as the cable 3 and each cable described below.

  The amplifying unit 1 amplifies a weak signal generated by receiving radio waves with the VHF antenna 4, the UHF antenna 5, and the BS · 110 ° CS antenna 6, and sends the amplified signal as a received signal to the power supply unit 2 via the cable 3. . Although details of the amplifying unit 1 are not shown, the gain of the gain controller included in the amplifying unit 1 is adjusted by, for example, operating a volume, and the attenuation amount of the attenuator is set by, for example, a changeover switch. It is performed by switching.

  The power supply unit 2 uses the cable 3 as a power transmission line to supply DC power to the amplification unit 1, relays the received signal sent from the amplification unit 1, and uses the cable 7 to the distributor 8. send. The distributor 8 uses a cable 9 to receive a reception signal sent from the amplifier 1 via the cable 3, the power supply unit 2, and the cable 7, and a plurality of television receivers provided in each of a plurality of rooms. Distribute to outlet 10 (hereinafter abbreviated as “TV”).

  FIG. 11 is a diagram showing a configuration of another receiving system to which a conventional power source separation type booster is applied. A power supply separation type booster applied to this receiving system is mainly composed of an amplifying unit 1 attached in the vicinity of an antenna installed on a roof and a power source unit 2 attached indoors. The power supply unit 2 is connected to the TV outlet 10 connected from the amplification unit 1 via the cable 3, the distributor 8 and the cable 9. In this case, as the distributor 8, a conductive distributor capable of passing a current between the input and output terminals is used.

  The amplifying unit 1 amplifies a weak signal generated by receiving radio waves with the VHF antenna 4, the UHF antenna 5, and the BS · 110 ° CS antenna 6, and sends the amplified signal as a received signal to the distributor 8 via the cable 3. . Although details of the amplifying unit 1 are not shown, the gain of the gain controller included in the amplifying unit 1 is adjusted by, for example, operating a volume, and the attenuation amount of the attenuator is set by, for example, a changeover switch. It is done by switching.

  The distributor 8 distributes the received signal sent from the amplifier 1 via the cable 3 to the plurality of TV outlets 10 via the cable 9. The power supply unit 2 supplies DC power to the amplification unit 1 by using the cable 9, the distributor 8, and the cable 3 as a power transmission line.

  As a technology related to a booster, for example, Patent Document 1 compensates for a voltage drop in a DC current passing path from a power supply device to a CS (communication satellite) antenna, and reliably switches the polarization of the CS antenna. A "satellite reception system, power supply device, and reception signal amplifier" that can be used is known. In the technique disclosed in Patent Document 1, a received signal from a CS antenna is amplified by a booster, mixed with a received signal from another antenna, further distributed by a four distributor, and transmitted to a terminal. In the receiving system, the distributor and the booster can transmit a voltage signal from the terminal side to the CS antenna side, and the booster can supply a voltage for supplying power to devices on the transmission path between itself and another antenna ( 15V) is generated from the voltage signal from the terminal side and output. Then, the power supply device on the terminal side of the distributor generates a voltage signal that is higher than the voltage (11V or 15V) of the polarization switching signal from the CS tuner by a predetermined voltage Vd and can supply power to the CS antenna and the device. Output to the CS antenna.

JP 2001-119314 A

  In the above-described conventional power source separation type booster, when adjusting the gain or attenuation for adjusting the signal input to the TV to an appropriate level, the gain control of the amplifying unit 1 installed on the roof or the like is performed. It is necessary to directly operate the volume switch and the attenuator changeover switch, and to check the signal level of the output terminal of the power supply unit 2 and the TV outlet 10 using a TV or measuring instrument installed indoors. Therefore, it is necessary to perform adjustment work while communicating with multiple people (one person is on the roof, the other person is indoors, etc.), or one person moves back and forth between the roof and the room. There is a problem of inefficiency.

  In addition, in a receiving system where a housing complex or a receiving point exists at a remote location, a plurality of boosters are used, and the installation location of each booster is often remote. Even in such a case, it is necessary to make adjustments such as gain and attenuation for each booster. However, there is a problem that work efficiency is poor because it is necessary to perform adjustment work by moving back and forth between the roof and the room.

  Therefore, the present invention has been made to solve the above-described problems, and an object of the present invention is to provide a power source separation type booster capable of efficiently performing adjustment work.

  As a means for solving the above-mentioned problem, the power source separation type booster according to the first aspect of the present invention includes a power source unit that superimposes and outputs a control signal indicating an attenuation amount and a gain generated according to an operation on a DC power source, An amplifying unit that operates with a DC power source supplied via a cable from the power source unit and adjusts the attenuation and gain of the signal received by the antenna for each frequency band in accordance with a control signal superimposed on the DC power source, It is characterized by comprising.

  According to a second aspect of the present invention, the power source separation type booster includes a DC power source that generates a DC power source, an operation unit that indicates an attenuation amount and a gain by an operation, and an attenuation that is instructed from the operation unit. A transmission control unit that generates a control signal according to the amount and gain, and a modulation unit that performs pulse modulation according to the control signal from the transmission control unit and outputs the DC power source from the DC power source unit, The amplifying unit includes: an attenuator that controls an attenuation amount of a signal received by the antenna for each frequency band; a gain controller that adjusts a gain of the signal received by the antenna for each frequency band; and the power supply unit. A signal detector for detecting a control signal superimposed on a DC power source supplied via the cable; and attenuator control and gain control based on the control signal detected by the signal detector Reception control unit that performs the adjustment of the gain, characterized by comprising and.

  According to a third aspect of the present invention, there is provided a power source separation type booster, wherein a remote control operation unit that generates a control signal instructing attenuation and gain according to an operation, a power source unit that generates and outputs a DC power source, and the power source unit Of the signal received by the antenna according to the control signal sent via the other cable connected to the cable from the remote control operation unit and the cable. And an amplifying unit that adjusts the attenuation and gain for each frequency band.

  According to a fourth aspect of the present invention, the remote control operation unit is instructed by the high-frequency oscillation unit for generating a high-frequency signal, the operation unit for instructing the attenuation and gain by the operation, and the operation unit. A transmission control unit that generates a control signal according to an attenuation amount and a gain; and a modulation unit that performs pulse modulation according to a control signal from the transmission control unit on a high-frequency signal generated by the high-frequency oscillation unit and outputs the modulated signal. The amplifying unit controls an attenuation amount of a signal received by an antenna for each frequency band; a gain controller for adjusting a gain of the signal received by the antenna for each frequency band; and The other cable and a signal detector for detecting a control signal sent via the cable from a remote controller, and the reduction based on the control signal detected by the signal detector. Reception control unit for controlling and adjusting the gain of the gain controller of the vessels of attenuation, characterized by comprising and.

  According to a fifth aspect of the present invention, the remote control operation unit includes: a high-frequency oscillation unit that generates a high-frequency signal; an address setting unit that sets an address attached to an amplification unit to be adjusted; An operation unit for instructing an attenuation amount and a gain; a transmission control unit for generating a control signal according to an address set by the address setting unit and an attenuation amount and a gain instructed from the operation unit; and the high-frequency oscillation unit A modulation unit that outputs the signal by performing pulse modulation according to the control signal from the transmission control unit, and the amplification unit controls the attenuation amount of the signal received by the antenna for each frequency band. An attenuator, a gain controller for adjusting the gain of the signal received by the antenna for each frequency band, the other cable and the cable from the remote control operation unit A signal detector for detecting a control signal sent via the address, an address holding unit for holding an address given to itself, and a control signal sent from the modulation unit via the other cable and the cable When the address included in the address holding unit matches the address held in the address holding unit, based on the control signal detected by the signal detector, the attenuation control of the attenuator and the gain of the gain controller A reception control unit for performing adjustment.

  According to the power supply separation type booster of the present invention, for example, by operating a power supply unit installed indoors, it is possible to adjust attenuation and gain in an amplification unit installed on a roof, for example, by remote control. The attenuation and gain can be adjusted and checked indoors. As a result, work by a plurality of people and work such as going back and forth between the roof and the inside becomes unnecessary, and work efficiency is improved.

  In addition, for example, it is possible to adjust the amount of attenuation and gain in an amplifying unit installed on, for example, a roof by remote control by operating a remote control operating unit installed separately from the power supply unit indoors. Volume and gain adjustment and verification can be done indoors. As a result, work by a plurality of people and work such as going back and forth between the roof and the inside becomes unnecessary, and work efficiency is improved.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Note that the same components as those in the receiving system shown in the background art column are denoted by the same reference numerals as those used in the background art column.

Embodiment 1 FIG.
The power source separation type booster according to the first embodiment of the present invention is a home power source separation type booster with a remote control function that employs a power superimposed pulse modulation method. FIG. 1 shows a configuration of a receiving system to which a power supply separation type booster according to Embodiment 1 is applied.

  The power supply separation type booster applied to this receiving system is mainly composed of an amplifying unit 11 attached in the vicinity of an antenna installed on a roof, and a power source unit 12 attached indoors. The part 12 is connected by a cable 3. For example, a coaxial cable is used as the cable 3 and each cable described below.

  The amplifying unit 11 amplifies a weak signal generated by receiving radio waves with the VHF antenna 4, the UHF antenna 5, and the BS · 110 ° CS antenna 6, and sends the amplified signal as a received signal to the power supply unit 12 via the cable 3. . The setting of the attenuation amount and the adjustment of the gain in the amplifying unit 11 are performed by remote control from the power source unit 12 installed indoors. Details of the amplifying unit 11 will be described later.

  The power supply unit 12 supplies the DC power to the amplification unit 11 using the cable 3 as a power transmission line, relays the reception signal sent from the amplification unit 11, and uses the cable 7 to the distributor 8. send. The power supply unit 12 adjusts the attenuation amount and gain in the amplifying unit 11 by remote control by superimposing a control signal for adjusting the attenuation amount and gain in the amplifying unit 11 on the DC power supply to the amplifying unit 11. It can be done. Details of the power supply unit 12 will be described later.

  FIG. 2 is a block diagram showing a circuit configuration of the power source separation type booster according to the first embodiment. The power source separation type booster is roughly composed of an amplifier unit 11 and a power source unit 12. .

  First, details of the amplifying unit 11 will be described. The amplifying unit 11 is a mixer (not shown) that mixes the signal from the CS / BS terminal 21 to which the BS / 110 ° CS antenna 6 is connected, the UHF antenna 5 or the UHF antenna 5 and the signal from the VHF antenna 4. A UHF / UHF / VHF terminal 22 to which a “UV mixer” is connected; a VHF terminal 23 to which the VHF antenna 4 is connected; and an input / output terminal 24 to be connected to the power supply unit 12.

  The DC power supplied from the power supply unit 12 to the input / output terminal 24 is supplied to all active elements constituting the amplifying unit 11 via a wiring (not shown), and the filter 25, the power transmission line 26 and the filter 27. Is supplied from the CS / BS terminal 21 to the BS / 110 ° CS antenna 6. An open / close switch 28 is provided in the middle of the power transmission line 26 so as to control whether or not the DC power is supplied to the BS · 110 ° CS antenna 6.

  The signal sent from the BS · 110 ° CS antenna 6 to the CS · BS terminal 21 is sent to the filter 31, where the BS · CS frequency band signal is extracted and sent to the attenuator (ATT) 32. It is done. The attenuator 32 attenuates the signal sent from the filter 31 in accordance with an attenuation amount set by a remote control control signal reception microcomputer (hereinafter abbreviated as “reception microcomputer”) 75, and an amplifier (AMP ) Send to 33. The reception microcomputer 75 corresponds to the reception control unit of the present invention. The amplifier 33 amplifies the signal sent from the attenuator 32 and sends it to a gain controller (GC) 34. The gain controller 34 adjusts the gain of the signal sent from the amplifier 33 according to the signal sent from the D / A converter 76, and sends it to the amplifier (AMP) 35. The amplifier 35 amplifies the signal sent from the gain controller 34 and sends it to the input / output terminal 24 via the filter 36. As a result, the signal received by the BS · 110 ° CS antenna 6 is amplified and sent from the input / output terminal 24 to the power supply unit 12 via the cable 3.

  A signal sent from the UHF antenna 5 to the UHF / UHF / VHF terminal 22 is sent to a filter 41, where a signal in the UHF frequency band is extracted and sent to an attenuator (ATT) 42. The attenuator 42 attenuates the signal sent from the filter 41 according to the attenuation set by the receiving microcomputer 75 and sends the signal to the amplifier (AMP) 43. The amplifier 43 amplifies the signal sent from the attenuator 42 and sends it to the gain controller (GC) 44. The gain controller 44 adjusts the gain of the signal sent from the amplifier 43 according to the signal sent from the D / A converter 76, and sends it to the amplifier (AMP) 45. The amplifier 45 amplifies the signal sent from the gain controller 44 and sends it to the input / output terminal 24 via the filter 46 and the filter 47. As a result, the signal received by the UHF antenna 5 is amplified and sent from the input / output terminal 24 to the power supply unit 12 via the cable 3.

  A signal sent from the VHF antenna 4 to the VHF terminal 23 is sent to the filter 51 and the filter 61 via the switch 50. The filter 51 extracts a signal in the VHF (High) frequency band sent from the VHF terminal 23 via the switch 50 and sends it to an attenuator (ATT) 52. The attenuator 52 attenuates the signal sent from the filter 51 according to the attenuation set by the receiving microcomputer 75 and sends the signal to the amplifier (AMP) 53. The amplifier 53 amplifies the signal sent from the attenuator 52 and sends it to the gain controller (GC) 54. The gain controller 54 adjusts the gain of the signal sent from the amplifier 53 according to the signal sent from the D / A converter 76, and sends it to the amplifier (AMP) 55. The amplifier 55 amplifies the signal sent from the gain controller 54 and sends it to the input / output terminal 24 via the filter 56, filter 57 and filter 47. As a result, the signal in the VHF (High) frequency band received by the VHF antenna 4 is amplified and sent from the input / output terminal 24 to the power supply unit 12 via the cable 3.

  The filter 61 extracts a VHF (Low) frequency band signal sent from the VHF terminal 23 via the switch 50 and sends the signal to the attenuator (ATT) 62. The attenuator 62 attenuates the signal sent from the filter 61 according to the attenuation set by the receiving microcomputer 75 and sends the signal to the amplifier (AMP) 63. The amplifier 63 amplifies the signal sent from the attenuator 62 and sends it to the gain controller (GC) 64. The gain controller 64 adjusts the gain of the signal sent from the amplifier 63 according to the signal sent from the D / A converter 76, and sends it to the amplifier (AMP) 65. The amplifier 65 amplifies the signal sent from the gain controller 64 and sends it to the input / output terminal 24 via the filter 66, the filter 57 and the filter 47. As a result, the signal in the VHF (Low) frequency band received by the VHF antenna 4 is amplified and sent from the input / output terminal 24 to the power supply unit 12 via the cable 3.

  When the UV mixer is connected to the UHF / UHF / VHF terminal 22, the switch 50 is connected to the filter 40 side. In this case, the signal sent from the VHF antenna 4 and the UHF antenna 5 to the UHF / UHF / VHF terminal 22 via the UV mixer is sent to the filter 40, and a signal in the VHF frequency band is extracted in the filter 40. To the filter 51 and the filter 61. Subsequent operations are as described above.

  The DC power supplied from the power supply unit 12 to the input / output terminal 24 is supplied to the regulator 71 and the signal detector 72 through the filter 25. The regulator 71 smoothes and constants the input DC power supply and sends it to the receiving microcomputer 75 as a power supply for the receiving microcomputer 75.

  The signal detector 72 extracts the control signal superimposed on the DC power source sent from the filter 25 and sends it to the amplifier 73. The amplifier 73 amplifies the control signal sent from the signal detector 72 and sends it to the waveform shaping circuit 74. The waveform shaping circuit 74 shapes the waveform of the control signal sent from the amplifier 73 and sends it to the receiving microcomputer 75.

  The receiving microcomputer 75 analyzes the control signal sent from the waveform shaping circuit 74, extracts the amount of attenuation included in this control signal, and sets it in the attenuators 32, 42, 52 and 62. The receiving microcomputer 75 analyzes the control signal sent from the waveform shaping circuit 74, extracts the gain adjustment amount included in this control signal, and sends it to the D / A converter 76. The D / A converter 76 converts the digital signal indicating the gain adjustment amount sent from the reception microcomputer 75 into an analog signal, and sends the analog signal to the gain controllers 34, 44, 54 and 64.

  Next, details of the power supply unit 12 will be described. The power supply unit 12 includes a DC power supply unit 82 that generates, for example, a DC15V DC power supply from a commercial AC power supply AC100V supplied from a power outlet 81. The DC power generated by the DC power supply unit 82 is supplied to the operation unit 13 via the setting switch (SW) 83 and also supplied to the modulation unit 85.

  The operation unit 13 includes a regulator 90, operating elements 91 to 94 for setting attenuation, operating elements 95 to 98 for controlling gain, and a transmission remote control control signal microcomputer (hereinafter abbreviated as "transmission microcomputer"). Yes). The transmission microcomputer 99 corresponds to the transmission control unit of the present invention. The regulator 90 smoothes and converts the DC power supplied from the DC power supply unit 82 through the setting switch 83 to a constant voltage and sends it to the operating elements 91 to 98. Send to 99.

  Each of the operating elements 91 to 94 for setting the attenuation amount is constituted by a changeover switch for switching the attenuation amount to 0 dB or −10 dB, for example, and the setting state of each changeover switch is the transmission microcomputer 99. Sent to. The operation element 91 is used to set the attenuation amount of the signal in the VHF (Low) frequency band, and the operation element 92 is used to set the attenuation amount of the signal in the VHF (High) frequency band. 93 is used to set the attenuation amount of the signal in the UHF frequency band, and the operator 94 is used to set the attenuation amount of the signal in the CS / BS frequency band.

  Each of the operators 95 to 98 for controlling the gain is composed of a volume for instructing a gain control amount, and the setting state of each volume is sent to the transmission microcomputer 99. The controller 95 is used to indicate a control amount of the gain of the signal in the VHF (Low) frequency band, and the controller 96 is used to indicate a control amount of the gain of the signal in the VHF (High) frequency band. The operation unit 97 is used to indicate the control amount of the gain of the signal in the UHF frequency band, and the operation unit 98 is used to indicate the control amount of the gain of the signal in the CS / BS frequency band. .

  The transmission microcomputer 99 is set in the attenuators 32, 42, 52 and 62 based on the setting state of the changeover switch sent from the operation elements 91 to 94 and the setting state of the volume sent from the operation elements 95 to 98. The amount of attenuation to be performed and the gain control amount of the gain controllers 34, 44, 54 and 64 are calculated to generate an asynchronous control signal (pulse), which is sent to the modulation unit 85. Note that communication between the amplifying unit 11 and the power supply unit 12 is performed by asynchronous serial communication.

  The modulation unit 85 superimposes the control signal on the DC power source by performing pulse modulation on the DC power source transmitted from the DC power source unit 82 according to the control signal transmitted from the transmission microcomputer 99 of the operation unit 13. Let The DC power source on which the control signal is superimposed in the modulation unit 85 is sent to the input / output terminal 87 through the filter 86, and is sent from the input / output terminal 87 to the input / output terminal 24 of the amplification unit 11 through the cable 3.

  The input / output terminal 87 receives a reception signal sent from the amplifying unit 11 via the cable 3. The reception signal received at the input / output terminal 87 is removed from the DC component by the capacitor C, and a reception signal including only the original high frequency component is output from the output terminal 88. As shown in FIG. 1, the received signal output from the output terminal 88 is sent to the distributor 8 via the cable 7, distributed by the distributor 8, and sent to the TV outlet 10 via the cable 9. It is done.

  The power supply separation type booster according to the first embodiment configured as described above operates as follows. First, when the setting switch 83 of the power supply unit 12 is turned on, the operation unit 13 becomes operable. In this state, when the operating elements 91 to 98 are operated, a signal indicating a setting state set by the operation is input to the transmission microcomputer 99. The transmission microcomputer 99 generates an asynchronous control signal (pulse) based on the input signal and sends it to the modulation unit 85. As a result, the control signal is superimposed on the DC power supply and sent from the input / output terminal 87 to the input / output terminal 24 of the amplifier 11 via the cable 3.

  In the amplifying unit 11, the direct-current power source on which the control signal is superimposed (pulse-modulated) input to the input / output terminal 24 is sent to the signal detector 72 via the filter 25. The control signal detected by the signal detector 72 is waveform-shaped by the waveform shaping circuit 74 and sent to the receiving microcomputer 75. The receiving microcomputer 75 receives the serialized pulse signal, and if the data representing the received signal is different from the data stored in the internal memory (not shown), the data stored in the internal memory is The signal corresponding to the rewritten data is output. Thus, since the data received from the power supply unit 12 is stored in the internal memory of the reception microcomputer 75, even if a failure such as a power failure occurs, it can be easily restored to the state before the failure.

  One signal output from the receiving microcomputer 75 is sent to the attenuators 32, 42, 52 and 62. Each of the attenuators 32, 42, 52 and 62 sets the attenuation amount to, for example, 0 dB or −10 dB depending on the level of the signal sent from the receiving microcomputer 75.

  The other signal output from the receiving microcomputer 75 is converted to an analog signal by the D / A converter 76 and then sent to the gain controllers 34, 44, 54 and 64. Each of the gain controllers 34, 44, 54 and 64 changes the gain control amount in accordance with the level of the signal sent from the D / A converter 76. More specifically, the amount of attenuation is adjusted by controlling the voltage and current applied to the PIN diode.

  When the above operation is completed, the setting switch 83 of the power supply unit 12 is turned off. Thereby, the operation of the operation unit 13 is completed, and thereafter, only the DC power is supplied from the power supply unit 12 to the amplification unit 11 via the cable 3.

  As described above, according to the power source separation type booster according to the first embodiment of the present invention, as shown in FIG. 1, the operation unit for controlling the attenuation and gain of the power source unit 12 installed indoors. 13 is configured to superimpose a control signal on a DC power supply supplied to the amplifying unit 11 and send the control signal to the amplifying unit 11 to adjust the attenuation and gain in the amplifying unit 11, so that the attenuation and gain can be controlled by remote control. Can be adjusted. Therefore, the attenuation amount and gain can be adjusted and confirmed indoors, so that work such as work by a plurality of people and going back and forth between the roof and the inside becomes unnecessary, and work efficiency is improved.

  In addition, although the power supply unit 12 of the power supply separation type booster according to the first embodiment described above is configured to be connected to the upstream side of the distributor 8, as shown in FIG. It can be configured to connect to a TV outlet 10. In this case, as the distributor 8, a Dentsu-type distributor is used, and the DC power source generated by the power supply unit 12 and superimposed with the control signal is connected to the TV outlet 10, the cable 9, the distributor 8, and the cable 3. Then, the signal is supplied to the amplifying unit 11.

Embodiment 2. FIG.
The power supply separation type booster according to the second embodiment of the present invention is a home power supply separation type booster with a remote control function that employs a radio frequency (RF) pulse modulation method. FIG. 4 shows the configuration of a receiving system to which the power supply separation type booster according to the second embodiment is applied.

  The power supply separation type booster applied to this receiving system is mainly composed of an amplifying unit 11a attached in the vicinity of an antenna installed on a roof, a power source unit 12a attached indoors, and a remote control operation unit 13a. The remote control operation unit 13a is connected to a position on the downstream side of the amplification unit 11a and through which a high frequency signal generated by the remote control operation unit 13a can pass, for example, the TV outlet 10 in the room. The amplifying unit 11a and the power supply unit 12a are connected by the cable 3, and the power supply unit 12a and the remote control operation unit 13a are connected through the cable 7, the distributor 8, the cable 9, and the TV outlet 10. .

  The amplifying unit 11a amplifies a weak signal generated by receiving radio waves with the VHF antenna 4, the UHF antenna 5, and the BS · 110 ° CS antenna 6, and sends the amplified signal to the power supply unit 12a via the cable 3 as a received signal. . The setting of the attenuation amount and the adjustment of the gain in the amplification unit 11a are performed by remote control from a remote control operation unit 13a attached indoors. Details of the amplifying unit 11a will be described later.

  The power supply unit 12a supplies the DC power to the amplification unit 11a using the cable 3 as a power transmission line, and also relays the reception signal sent from the amplification unit 11a to the distributor 8 via the cable 7. send. Details of the power supply unit 12a will be described later.

  The remote control operation unit 13a superimposes a control signal for adjusting the attenuation and gain in the amplification unit 11a on a high frequency signal (RF signal), and the TV outlet 10, the cable 9, the distributor 8, the cable 7, the power supply unit 12a, The data is sent to the amplifying unit 11a via the cable 3. As a result, the attenuation and gain in the amplifying section 11a can be adjusted by remote control from the remote control operating section 13a. Details of the remote controller 13a will be described later.

  FIG. 5 is a block diagram showing a circuit configuration of the power source separation type booster according to the second embodiment. This power source separation type booster is roughly divided into an amplifier unit 11a, a power source unit 12a, and a remote control operation unit 13a. It is configured.

  First, details of the amplifying unit 11a will be described. In the amplifying unit 11a, the signal detector 72, the amplifier 73, and the waveform shaping circuit 74 are removed from the amplifying unit 11 of the power source separation type booster according to the first embodiment. Instead of these, the filter 101, the AGC circuit 102, and the signal detection A device 103 and an amplifier (AMP) 104 are added. In the following, the same components as those of the amplifying unit 11 of the power supply separation type booster according to the first embodiment are denoted by the same reference numerals as those used in the first embodiment, and the description thereof is omitted. The explanation is centered.

  The filter 101 filters the high-frequency signal superimposed with the control signal sent from the input / output terminal 24 via the filter 47 and the filter 57 and sends the filtered high-frequency signal to the AGC circuit 102. The AGC circuit 102 adjusts the gain of the high-frequency signal sent from the filter 101 to a level that can be detected by the signal detector 103 at the next stage, and sends it to the signal detector 103. The signal detector 103 extracts only the control signal from the high frequency signal sent from the AGC circuit 102 and sends it to the amplifier 104. The amplifier 104 amplifies the control signal sent from the signal detector 103 and sends it to the receiving microcomputer 75.

  Next, details of the power supply unit 12a will be described. The power supply unit 12a is configured by removing the operation unit 13 and the modulation unit 85 from the power supply unit 12 of the power supply separation type booster according to the first embodiment. The DC power output from the DC power supply unit 82 is sent to the input / output terminal 87 through the filter 86, and is sent from the input / output terminal 87 to the amplifier 11 a through the cable 3.

  Next, details of the remote control operation unit 13a will be described. The remote control operation unit 13a includes a power source 111, a switch 112, a high frequency oscillation unit (RF oscillation unit) 113, a modulation unit 114, a filter 115, a transmission terminal 116, a filter 117, an output terminal 118, operating elements 91 to 98, and a transmission microcomputer 99. It has. Operators 91 to 98 and transmission microcomputer 99 are the same as those included in operation unit 13 of power supply unit 12 of the power supply separation type booster according to the first embodiment.

  The power source 111 generates a DC power source used in the remote control operation unit 13a and supplies it to the high frequency oscillation unit 113, the operating elements 91 to 98, the transmission microcomputer 99, and other active elements via the switch 112.

  The high-frequency oscillator 113 generates a high-frequency signal used as a carrier and sends it to the modulator 114. The modulation unit 114 superimposes the control signal on the high-frequency signal by performing pulse modulation on the high-frequency signal transmitted from the high-frequency oscillation unit 113 in accordance with the control signal transmitted from the transmission microcomputer 99. The high frequency signal on which the control signal is superimposed in the modulation unit 114 is sent to the transmission terminal 116 through the filter 115, and from the transmission terminal 116, the TV outlet 10, the cable 9, the distributor 8, the cable 7, the power supply unit 12a, It is sent to the amplifying unit 11a via the cable 3. The signal that has passed through the filter 115 is blocked by the filter 117 and is not output from the output terminal 118. However, the reception signal input from the transmission terminal 116 is output from the output terminal 118 via the filter 117.

  The power supply separation type booster according to the second embodiment configured as described above operates as follows. First, when the switch 112 of the remote control operation unit 13a is turned on, the remote control operation unit 13a becomes operable. When the operating elements 91 to 98 are operated in this state, a signal indicating a setting state set by the operation is input to the transmission microcomputer 99. The transmission microcomputer 99 generates an asynchronous control signal (pulse) based on the input signal and sends it to the modulation unit 114.

  On the other hand, the high-frequency oscillator 113 starts oscillation when the switch 112 is turned on, generates a high-frequency signal, and sends it to the modulator 114. As a result, the modulation unit 114 superimposes the control signal on the high-frequency signal and transmits the signal from the transmission terminal 116 to the amplification unit 11a via the TV outlet 10, the cable 9, the distributor 8, the cable 7, the power supply unit 12a, and the cable 3. It is done.

  In the amplifying unit 11a, the high-frequency signal on which the control signal is superimposed (pulse-modulated) input to the input / output terminal 24 is sent to the AGC circuit 102 via the filter 47, the filter 57, and the filter 101. The gain is adjusted by the AGC circuit 102 and sent to the signal detector 103. The control signal detected by the signal detector 103 is amplified by the amplifier 104 and sent to the receiving microcomputer 75. The subsequent operation is the same as the operation of the power supply separation type booster according to the first embodiment described above. When the attenuation and gain settings are completed as described above, the remote control operation unit 13a is removed from the TV outlet 10.

  As described above, according to the power source separation type booster according to the second embodiment of the present invention, as shown in FIG. 4, a remote control operation unit that can be connected to an indoor TV outlet separately from the power source unit 12a. 13a is provided, and the control signal generated in response to the operation of the remote control operation unit 13a is superimposed on the high frequency signal and sent to the amplifying unit 11a to adjust the attenuation and gain in the amplifying unit 11a. The attenuation and gain can be adjusted by remote control from anywhere as long as a high frequency signal can pass downstream from the section 11a. Therefore, the attenuation amount and gain can be adjusted and confirmed indoors, so that work such as work by a plurality of people and going back and forth between the roof and the inside becomes unnecessary, and work efficiency is improved.

  In addition, although the power supply part 12a of the power source separation type booster according to the second embodiment described above is configured to be connected to the upstream side of the distributor 8, as shown in FIG. It can also be configured to connect to the TV outlet 10. In this case, a conductive type is used as the distributor 8. Further, the high frequency signal on which the control signal is superimposed generated by the remote control operation unit 13 a is supplied to the amplification unit 11 a via the TV outlet 10, the cable 9, the distributor 8, and the cable 3.

Embodiment 3 FIG.
The power source separation type booster according to the third embodiment of the present invention is a home power source separation type booster with a remote control function that employs the same RF pulse modulation method as the power source separation type booster according to the second embodiment described above. The attenuation and gain of a plurality of amplifying units can be adjusted. The present invention is applied to a receiving system when receiving points are separated as shown in FIG. 7 or when a plurality of boosters are used in an apartment house as shown in FIG.

  The power supply separation type booster applied to the reception system shown in FIG. 7 includes an amplification unit A attached in the vicinity of an antenna installed at a remote reception point, a power supply unit 12a for the amplification unit A installed indoors, The amplifier unit B is mounted between the power supply unit 12a and the distributor 8, and a remote control operation unit 13b. The remote control operation unit 13b is downstream from the amplification unit B and is operated by the remote controller. It is connected to a position where the high-frequency signal generated in the section 13b can pass, for example, the TV outlet 10 in the room. The amplifying unit A and the power supply unit 12a are connected by a cable 3, the power supply unit 12a and the amplifying unit B are connected by a cable 7a, and the amplifying unit B and the remote control operation unit 13b are connected by a cable 7b. , A distributor 8, a cable 9 and a TV outlet 10.

  The amplifying unit A amplifies a weak signal generated by receiving radio waves with the VHF antenna 4, the UHF antenna 5, and the BS · 110 ° CS antenna 6, and sends the amplified signal as a received signal to the power supply unit 12 a via the cable 3. .

  The amplifying unit B further amplifies the reception signal sent from the amplifying unit A through the power supply unit 12a and the cable 7a, and sends the amplified signal to the distributor 8 through the cable 7b. Attenuation amount setting and gain adjustment in the amplifying unit A and the amplifying unit B are performed by remote control from a remote control operation unit 13b installed indoors. Details of the amplifying unit A and the amplifying unit B will be described later.

  The power supply unit 12a supplies the DC power to the amplification unit A using the cable 3 as a power transmission line, and also relays the received signal sent from the amplification unit A to the amplification unit B using the cable 7a. send. Since this power supply unit 12a is the same as that of the power supply separation type booster according to the second embodiment, detailed description thereof is omitted.

  The remote control operation unit 13b superimposes a control signal for adjusting the attenuation and gain in the amplification unit A and the amplification unit B on a high frequency signal (RF signal), and connects the TV outlet 10, the cable 9, the distributor 8, and the cable 7b. And sent to the amplifying unit B, and further sent to the amplifying unit A via the cable 7a, the power supply unit 12a and the cable 3. Thereby, the attenuation amount and gain in the amplification part A and the amplification part B can be adjusted by remote control from the remote control operation part 13b. Details of the remote control operation unit 13b will be described later.

  FIG. 9 is a block diagram showing a circuit configuration of the power supply separation type booster according to the third embodiment. The power supply separation type booster is roughly divided into an amplification unit A, an amplification unit B, a power supply unit 12a, and a remote controller. It is comprised from the operation part 13b.

  First, details of the amplification unit A will be described. The amplifying unit A is configured by adding an address setting unit 121 to the amplifying unit 11a of the power source separation type booster according to the second embodiment. In the following, the same components as those of the amplifying unit 11a of the power source separation type booster according to the second embodiment are denoted by the same reference numerals as those used in the second embodiment, and the description thereof is omitted. The explanation will be centered.

  The address setting unit 121 corresponds to the address holding unit of the present invention, and stores an address given to itself. The address stored in the address setting unit 121 is read by the receiving microcomputer 75.

  Next, details of the amplification unit B will be described. The amplifying unit B is configured by removing the filter 25 from the amplifying unit A and adding a power supply 124, a filter 125, a switch 126, and a filter 127. Also, a terminal 128 for inputting a signal in the CS / BS frequency band sent from the amplifier A, or a signal in which each signal in the CS / BS frequency band, UHF frequency band and VHF frequency band is mixed, and UHF A terminal 129 for inputting a signal in which a signal in the frequency band and a signal in the VHF frequency band are mixed is provided.

  The amplifying unit B is operated by a DC power source supplied from a power source 124 held therein. In the case of a reception system in which a signal obtained by mixing signals in the CS / BS frequency band, the UHF frequency band, and the VHF frequency band is input to the terminal 128, the switch 126 is connected to the filter 125 side. The filter 125 extracts a signal in the UHF frequency band and a signal in the VHF frequency band from the signal input from the terminal 128 and sends the signal to the filter 41 and the filter 127. The filter 127 extracts only the signal in the VHF frequency band from the signal sent from the filter 125 via the switch 126 and sends it to the filter 51 and the filter 61.

  In the case of a reception system in which a signal obtained by mixing a signal in the UHF frequency band and a signal in the VHF frequency band is input to the terminal 129, the switch 126 is connected to the terminal 129 side. The filter 127 extracts only the signal in the VHF frequency band from the signal sent from the terminal 129 via the switch 126 and sends it to the filter 51 and the filter 61.

  Next, details of the remote control operation unit 13b will be described. The remote control operation unit 13b is configured by adding an address setting unit 131 to the remote control operation unit 13a of the power source separation type booster according to the second embodiment. The address setting unit 131 is used to set the address of the amplification unit (amplification unit A or amplification unit B) to be adjusted. The address set by the address setting unit 131 is sent to the transmission microcomputer 99.

  The sending microcomputer 99 is based on the address sent from the address setting unit 131, the state of the changeover switch sent from the operation elements 91 to 94, and the volume setting state sent from the operation elements 95 to 98. Asynchronous control signals (pulses) are generated and sent to the modulator 114.

  The power supply separation type booster according to the third embodiment configured as described above operates as follows. First, an address (for example, “1”) is set in the address setting unit 121 of the amplification unit A. Similarly, an address (for example, “2”) is set in the address setting unit 121 of the amplification unit B. Thereafter, the address setting unit 131 of the remote control operation unit 13b is operated to set the address of the amplification unit to be adjusted.

  When the above setting operation is completed and the switch 112 of the remote control operation unit 13b is turned on, the remote control operation unit 13b becomes operable. When the operating elements 91 to 98 are operated in this state, a signal indicating a setting state set by the operation is input to the transmission microcomputer 99. The transmission microcomputer 99 generates an asynchronous control signal (pulse) based on the address input from the address setting unit 131 and the signals input from the operating elements 91 to 98 and sends the generated asynchronous control signal to the modulation unit 114.

  On the other hand, the high-frequency oscillator 113 starts oscillation when the switch 112 is turned on, generates a high-frequency signal, and sends it to the modulator 114. As a result, the modulation unit 114 superimposes the control signal on the high-frequency signal, and sends the control signal from the transmission terminal 116 to the amplification unit B via the TV outlet 10, the cable 9, the distributor 8, and the cable 7b. The signal is sent to the amplification unit A through the power supply unit 12a and the cable 3.

  In the amplifying unit A and the amplifying unit B, the high-frequency signal on which the control signal is superimposed (pulse-modulated) input to the terminal 24 is sent to the AGC circuit 102 via the filter 47, the filter 57, and the filter 101. The gain is adjusted by the AGC circuit 102 and sent to the signal detector 103. The control signal extracted by the signal detector 103 is amplified by the amplifier 104 and sent to the receiving microcomputer 75.

  When the address included in the control signal sent from the amplifier 104 matches the address set in the address setting unit 121, the receiving microcomputer 75 thereafter performs power supply separation according to the above-described first embodiment. It operates in the same way as the receiving microcomputer 75 of the type booster. Accordingly, the receiving microcomputer 75 of either the amplification unit A or the amplification unit B operates, and the attenuation amount and gain are set. When the attenuation and gain settings are completed as described above, the remote control operation unit 13b is removed from the TV outlet 10.

  As described above, according to the power source separation type booster according to the third embodiment of the present invention, as shown in FIG. 7, the remote control operation unit can be connected to the indoor TV outlet separately from the power source unit 12a. 13b is provided, and the control signal generated in response to the operation of the remote control operation unit 13b is superimposed on the high frequency signal and sent to the amplification unit A and the amplification unit B, and the attenuation amount and gain in the amplification unit A or the amplification unit B are adjusted. Since it is configured as described above, it is possible to adjust the attenuation amount and gain of an arbitrary amplification unit by remote control from anywhere where a high frequency signal can pass downstream from the amplification unit B. Therefore, the attenuation amount and gain can be adjusted and confirmed indoors, so that work such as work by a plurality of people and going back and forth between the roof and the inside becomes unnecessary, and work efficiency is improved.

  In the above-described third embodiment, the case where the power source separation type booster including a plurality of amplifying units is applied to a reception system where reception points are separated as shown in FIG. 7 is described. The present invention can also be applied to an apartment reception system as shown in FIG.

It is a figure which shows the structure of the receiving system to which the power supply isolation | separation type booster which concerns on Embodiment 1 of this invention was applied. It is a block diagram which shows the circuit structure of the power supply isolation | separation type booster which concerns on Embodiment 1 of this invention. It is a figure which shows the structure of the other receiving system to which the power supply isolation | separation type booster which concerns on Embodiment 1 of this invention was applied. It is a figure which shows the structure of the receiving system to which the power supply isolation | separation type booster which concerns on Embodiment 2 of this invention was applied. It is a block diagram which shows the circuit structure of the power supply isolation | separation type booster which concerns on Embodiment 2 of this invention. It is a figure which shows the structure of the other receiving system to which the power supply isolation | separation type booster which concerns on Embodiment 2 of this invention was applied. It is a figure which shows the structure of the receiving system to which the power supply isolation | separation type booster which concerns on Embodiment 3 of this invention was applied. It is a figure which shows the structure of the receiving system to which the power supply isolation | separation type booster which concerns on Embodiment 3 of this invention was applied. It is a block diagram which shows the circuit structure of the power supply isolation | separation type booster which concerns on Embodiment 3 of this invention. It is a figure which shows the structure of the receiving system to which the conventional power supply isolation | separation type booster was applied. It is a figure which shows the structure of the other receiving system to which the conventional power supply isolation | separation type booster was applied.

Explanation of symbols

11, 11a Amplifying unit 12, 12a Power supply unit 13 Operation unit 13a Remote control operation unit 3 Cable 32, 42, 52, 62 Attenuator 35, 45, 55, 65 Gain controller 72, 103 Signal detector 75 Receiving microcomputer (Reception Control part)
82 DC power supply unit 85 Modulating unit 91 to 98 Operating element 99 Transmitting microcomputer (transmission control unit)
113 High-frequency oscillators 121 and 131 Address setting unit

Claims (5)

A power supply unit that superimposes and outputs a control signal indicating the attenuation and gain generated according to the operation on a DC power supply;
An amplifying unit that operates with a DC power source supplied via a cable from the power source unit and adjusts the attenuation and gain of the signal received by the antenna for each frequency band in accordance with a control signal superimposed on the DC power source,
And a power supply separation type booster. The power supply unit is
A DC power supply unit for generating a DC power supply;
An operation unit for instructing the attenuation and gain by operation,
A transmission control unit that generates a control signal according to the attenuation and gain instructed from the operation unit;
The DC power supply from the DC power supply unit includes a modulation unit that performs pulse modulation according to a control signal from the transmission control unit and outputs the modulated signal,
The amplification unit is
An attenuator for controlling the attenuation of the signal received by the antenna for each frequency band;
A gain controller for adjusting the gain of the signal received by the antenna for each frequency band;
A signal detector for detecting a control signal superimposed on a DC power supply supplied from the power supply unit via the cable;
A reception control unit that controls the attenuation of the attenuator and adjusts the gain of the gain controller based on the control signal detected by the signal detector;
The power supply separation type booster according to claim 1, comprising: A remote control operation unit for generating a control signal indicating an attenuation amount and a gain according to an operation;
A power supply unit that generates and outputs a DC power supply;
Operated by a DC power supply supplied from the power supply unit via a cable, and received by an antenna in response to another cable connected to the cable from the remote control operation unit and a control signal transmitted via the cable An amplifying unit for adjusting the attenuation and gain of the received signal for each frequency band;
And a power supply separation type booster. The remote control operation unit is
A high-frequency oscillation unit for generating a high-frequency signal;
An operation unit for instructing an attenuation amount and a gain by an operation, and
A transmission control unit that generates a control signal in accordance with the attenuation and gain instructed by the operator;
A high-frequency signal generated by the high-frequency oscillation unit, and a modulation unit that performs pulse modulation according to a control signal from the transmission control unit and outputs the modulation signal,
The amplification unit is
An attenuator for controlling the attenuation of the signal received by the antenna for each frequency band;
A gain controller for adjusting the gain of the signal received by the antenna for each frequency band;
A signal detector for detecting a control signal sent from the remote control operation unit via the other cable and the cable;
A reception control unit that controls the attenuation of the attenuator and adjusts the gain of the gain controller based on the control signal detected by the signal detector;
The power supply separation type booster according to claim 3, comprising: The remote control operation unit is
A high-frequency oscillation unit for generating a high-frequency signal;
An address setting unit for setting an address attached to the amplification unit to be adjusted;
An operation unit for instructing the attenuation and gain by operation,
A transmission control unit that generates a control signal according to the address set by the address setting unit and the attenuation amount and gain instructed from the operation unit;
A high-frequency signal from the high-frequency oscillation unit, and a modulation unit that performs pulse modulation according to a control signal from the transmission control unit and outputs the modulation signal,
The amplification unit is
An attenuator for controlling the attenuation of the signal received by the antenna for each frequency band;
A gain controller for adjusting the gain of the signal received by the antenna for each frequency band;
A signal detector for detecting a control signal sent from the remote control operation unit via the other cable and the cable;
An address holding unit for holding an address assigned to the self;
The control detected by the signal detector when the address included in the control signal sent from the modulation unit via the other cable and the cable matches the address held in the address holding unit. A reception control unit for controlling the attenuation amount of the attenuator and adjusting the gain of the gain controller based on a signal;
The power supply separation type booster according to claim 3, comprising:

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