JP5148454B2 - High frequency amplifier - Google Patents

Description

  The present invention relates to a high-frequency amplifier, and more particularly to a device that amplifies high-frequency signals in different frequency bands by separate high-frequency amplification means.

  As a high-frequency amplifier that amplifies high-frequency signals in different frequency bands as described above by separate high-frequency amplification means, for example, there is a booster for television reception. For example, amplification means for amplifying the VHF band and television in the UHF band Some have provided amplification means for amplifying John broadcast signals. In recent years, terrestrial digital television broadcasting has been started in the UHF band, and in 2011, it has been decided that analog television broadcasting in the VHF band will be stopped. Currently, a commercially available booster is still provided with amplification means for the VHF band because broadcasting in the VHF band is still being performed. Even after the television broadcast in the VHF band is stopped, it is not desirable to operate the amplification means for the VHF band from the viewpoint of power consumption, and the VHF band for television broadcasting will be used in the future. There is also the possibility of disrupting the equipment. As a technique for improving this point, there is one disclosed in Patent Document 1.

  In the technology disclosed in Patent Document 1, the high frequency amplification unit includes a VHF amplification circuit and a UHF amplification circuit, and a power supply unit is provided separately from the high frequency amplification unit. The power supply unit can generate a voltage of 15V and a voltage of 7.5V. While broadcasting in the VHF band is being performed, the power supply unit supplies a voltage of 15 V to the high frequency amplification unit. When detecting that the voltage of 15V is supplied, the high-frequency amplifier supplies the voltage of 15V to the VHF amplifier circuit and the UHF amplifier circuit to operate them. When broadcasting in the VHF band is stopped, a voltage of 7.5 V is supplied from the power supply unit to the high frequency amplification unit. When the high frequency amplifier detects that a voltage of 7.5 V is supplied, it supplies a voltage of 7.5 V to the UHF amplifier circuit, operates only this, and stops the VHF amplifier circuit. As a result, the operation stop of the VHF amplifier circuit can be remotely controlled.

JP 2006-33364 A

  According to the technique of Patent Document 1, the UHF amplifier circuit is operated by a voltage of 7.5 V after the VHF band is stopped. In this case, since the voltage supplied to the semiconductor constituting the UHF amplifier circuit has decreased from 15 V to 7.5 V, the UHF amplifier circuit may not be able to fully exhibit its performance.

  An object of the present invention is to provide a high-frequency amplifier that can stop operation of at least one of a plurality of amplifying means by remote control and can continue to supply a normal voltage to the amplifying means that continues to operate. And

  The high frequency amplifier of one embodiment of the present invention includes high frequency amplification means. The high frequency amplification means includes first amplification means for amplifying a high frequency signal in a first frequency band, for example, VHF band, and second amplification means for amplifying a high frequency signal in a second frequency band, for example, UHF band. And. In addition to this, the high-frequency amplification means may include third amplification means, for example, third amplification means for amplifying satellite broadcast or satellite communication signals. A voltage is supplied from the outside, and the internal power supply means supplies the first and second amplification means with an operating voltage at which these normally operate. When the external voltage is a predetermined first value, the control means causes the internal power supply means to supply the operating voltage to the first and second amplifying means. When the external voltage changes from a first value voltage to a second value voltage different from the first value voltage, and returns to the first value voltage, the control means includes: The supply of the operating voltage from the internal power supply means to the first amplifying means is stopped, and the supply of the operating voltage to the second amplifying means is continued. Note that the voltage of the second value can be smaller than the voltage of the first value, or can be larger. However, a smaller value is desirable.

  In the high-frequency amplifier configured as described above, the operation of the first amplifying means can be stopped in accordance with the change in the value of the voltage supplied from the outside, and even when the first amplifying means is stopped, The amplifying means 2 is continuously supplied with an operating voltage necessary to operate it normally. Therefore, the second amplifying means can sufficiently exhibit its performance.

  The control means can stop the supply of the operating voltage when the voltage of the second value is maintained for a predetermined time and then changed to the voltage of the first value. By configuring in this way, it is possible to prevent the control means from malfunctioning due to a temporary voltage change and to stop the first amplifying means by mistake.

  The internal power supply means may use a first value voltage as the operating voltage. If comprised in this way, the internal power supply means can be set as a very simple circuit structure, such as a circuit which makes the voltage of the first value constant, for example, and converts the voltage of the first value into the operating voltage. Such a complicated circuit is not required.

  A plurality of voltages having different values can be prepared as the second value of the externally supplied voltage. In this case, the control means changes to the voltage of the first value or the voltage of the other second value after the voltage of the second value determined in advance among the voltages of the second value is supplied. The supply of the operating voltage from the internal power supply means to the first amplifying means is stopped, the supply of the operating voltage to the second amplifying means is continued, and the voltage of the first value or the plurality of The voltage changes from one of the second value voltages to a second value voltage other than the predetermined second value voltage, and changes to the first value voltage or another second value voltage. Then, the means provided in the high frequency amplification means is controlled. Examples of the means included in the high-frequency amplification means include an AGC means, a variable filter, and a third amplification means included in the second amplification means.

  With this configuration, the first amplifying unit can be remotely stopped to operate the second amplifying unit with the voltage of the first value, and the other units included in the high frequency amplifying unit can be remotely controlled. You can also

  The external voltage may be superimposed on the transmission line for transmitting the output signals of the first and second amplifying means from the external power supply means. In this case, the external power supply means has voltage generation means for generating a voltage having the first value. The voltage conversion means converts the first value voltage from the voltage generation means into a second value voltage. After outputting the first value voltage from the voltage generation means, the selection means outputs the second value voltage from the voltage conversion means.

  As described above, according to the present invention, even after the first amplifying means is stopped by remote control, the second amplifying means can be supplied with an operating voltage necessary for operating it normally. The high-frequency signal in the second frequency band can be received well.

  A high-frequency amplifier according to an embodiment of the present invention is a booster for television broadcasting. As shown in FIG. 1, a high-frequency amplifier, for example, a main body 2 and an external power supply provided separately from the main body 2 are provided. For example, the power supply unit 4 is included. The main body 2 is attached to, for example, an outdoor television antenna column. The power supply unit 4 is disposed indoors, for example, on the television receiver side.

  The main body 2 has first amplification means, for example, an amplification stage 6 and amplification stages 8a and 8b, for amplifying television broadcast signals in a first frequency band, for example, a VHF band high band and a VHF band low band, respectively. doing. A pre-stage bandpass filter 10 is provided on the input side of the amplification stage 6. A television broadcast signal in the UHF band and the VHF band is supplied from an antenna (not shown) to the input terminal 12 provided in the main body 2, and these are supplied to the upstream band pass filter 10. The television broadcast signal in the VHF band low band is selected by the pre-stage band pass filter 10 and supplied to the amplification stage 6 where it is amplified. Unnecessary frequency components generated by the amplification are removed by the subsequent band-pass filter 14.

  Among the UHF band and VHF band television broadcast signals from the input terminal 12, the high-frequency VHF band television broadcast signal is selected by the pre-stage bandpass filter 16 and amplified by the amplification stages 8a and 8b. Unnecessary frequency components generated by this amplification are removed by the subsequent band-pass filter 18.

  Second amplifying means, for example, amplification stages 20a and 20b for amplifying a television broadcast signal in a second frequency band, for example, UHF band, are provided. Of the UHF band and VHF band television broadcast signals from the input terminal 12, the UHF band television broadcast signal is selected by the pre-stage band pass filter 22 and amplified by the amplification stages 20a and 20b. Unnecessary frequency components generated by this amplification are removed by the subsequent band-pass filter 24.

Third amplifying means, for example, amplifying stages 26a and 26b are provided for amplifying a third frequency band, for example, an intermediate frequency signal of a satellite broadcast signal or / and a satellite communication signal. A band-pass filter 28 that passes an intermediate frequency signal of a satellite broadcast signal or (and) a satellite communication signal is provided in front of the amplification stage 26a, and this is transmitted from an input terminal 30 provided in the main body 2 to the satellite broadcast. An intermediate frequency signal of a signal or (and) a satellite communication signal is provided. This intermediate frequency signal is supplied to the input terminal 30 from a satellite broadcast or / and satellite communication receiving converter (not shown) provided in the satellite broadcast / and / or satellite communication receiving antenna. The intermediate frequency signal of the satellite broadcast signal or / and the satellite communication signal is supplied to the amplification stage 26a via the band pass filter 28, amplified, and further amplified by the amplification stage 26b. Unnecessary frequency components generated by this amplification are removed by the subsequent band-pass filter 32.

  The output signals of the post-stage bandpass filters 14, 18, 24, 32 are supplied to the output terminal 42 provided in the main body 2 via the DC blocking capacitors 34, 36, 38, 40. The output terminal 42 is connected to the input terminal 46 of the power supply unit 4 via a transmission line, for example, a coaxial cable 44.

  In the power supply unit 4, the output signals of the post-stage bandpass filters 14, 18, 24, and 32 supplied to the input terminal 46 are supplied to the output terminal 50 via the power supply inserter 48, and a television (not shown) from here. Supplied to John receiver. The power supply unit 4 includes voltage generation means, for example, a power supply circuit 52. The power supply circuit 52 generates a first value DC voltage, for example, a DC voltage of 15 V, from the commercial AC voltage supplied via the outlet 54. This 15V DC voltage is also supplied to voltage conversion means, for example, the voltage changing circuit 56, where it is converted into a second value voltage, eg, a 7.5V voltage, which is different from the first value voltage. . The voltage of 15V and the voltage of 7.5V are supplied to the selection means, for example, the changeover switch 58, and the one selected by the changeover switch 58 is connected to the main body 2 through the power supply inserter 48, the input terminal 46, and the coaxial cable 44. The output terminal 42 is supplied.

  The changeover switch 58 is performed by selection means control means, for example, a changeover switch control unit 60. The changeover switch control unit 60 is operated when a manual operation unit provided in the power supply unit 4, for example, a manual operation switch 62 is operated. 58 is controlled. That is, when the manual operation switch 62 is not operated, the changeover switch 58 selects a voltage of 15V as shown in FIG. When the manual operation switch 62 is operated, the changeover switch controller 60 selects a voltage of 7.5 V and maintains 7.5 V for a predetermined time T, for example, a time that is not mistaken for a power failure. Thereafter, the voltage is immediately changed to return to a voltage of 15 V, for example.

  The voltage DV from the changeover switch 58 is supplied to the output terminal 42 of the main body 2 via the power supply inserter 48, the input terminal 46, and the coaxial cable 44 as described above. A high frequency blocking coil 64 is connected to the output terminal 42, and the voltage from the power supply unit 4 is supplied to the voltage detection circuit 66 through this.

The voltage detection circuit 66 includes internal power supply means for making the supplied voltage DV constant, for example, to +15 V, and outputting it, and this voltage DV is directly supplied to the amplification stages 20a, 20b, 26a, 26b. The voltage DV is supplied to the input terminal 30 via the high frequency blocking coil 72, and is also supplied from the input terminal 30 to the satellite broadcast or / and satellite communication receiving converter. These amplifying stages 20a, 20b, 26a, 26b, satellite broadcast and / or satellite communication receiving converters are configured such that the operating voltage at which they normally operate is + 15V. Reference numeral 70 denotes a DC blocking capacitor. Further, a voltage of +15 V is supplied to the amplification stages 6, 8a, 8b via a switching means, for example, a switch 68. When the switch 68 is on, a voltage of +15 V is supplied to the amplification stages 6, 8a, 8b, and when the switch 68 is off, no voltage is supplied to the amplification stages 6, 8a, 8b. 6, 8a and 8b do not operate. Amplifying stages 6, 8a and 8b are also configured to have an operating voltage of + 15V at which they normally operate.

The voltage detection circuit 66 also includes a CPU, for example, and the CPU determines whether or not the supplied voltage DV is 7.5 V or less as shown in FIG. 3 (step S2). If the answer to this determination is no, the switch 68 is turned on (step S4), and the process returns to step S2. Therefore, even if the voltage DV does not maintain + 15V due to a voltage drop during transmission of the coaxial cable 44, for example, the switch 68 is turned on as long as it does not drop to + 7.5V or less, and the amplification stages 6, 8a , 8b, 20a, 20b, 26a, 26b are all supplied with an operating voltage, and all operate normally, such as a VHF band high band, VHF band low band, UHF band television broadcast signal, satellite broadcast signal or ( And) The intermediate frequency signal of the satellite communication signal is amplified.

If the answer to the determination in step S2 is yes, the timer t is reset in advance (step S6), and it is determined whether the voltage DV is +15 V or more (step S8). If the answer to this determination is no, the process is executed again from step S6. If the answer to the determination in step S8 is yes, it is determined whether the count value of the timer t is a predetermined time T (step S10). If the answer is yes, a voltage of + 7.5V is applied for the time T. Since the operation is continued, it is determined that the operation is instructed to stop the operation of the amplification stages 6, 8a, and 8b, and the switch 68 is turned off (step S12). As a result, no operating voltage is supplied to the amplification stages 6, 8a, 8b, and these do not operate. When the switch 68 is turned off, the switch 68 is maintained in an off state until a next on instruction is given. Following step S12, the process is executed again from step S2. If the answer to the question in Step S 10 is NO, it is determined that not the stop command, and resets the timer t (step S14), and executes again the step S2.

  The CPU and the switch 68 constitute a control means.

  Thus, according to this embodiment, by temporarily changing the value of the voltage supplied from the power supply unit 4, the switch 68 is switched to operate the amplification stages 6, 8a, 8b for VHF band amplification. The amplifier stages 20a and 20b for UHF band amplification, the amplifier stages 26a and 26b for satellite broadcast or / and satellite communication intermediate frequency signals, the satellite broadcast or / and satellite communication reception converter have + 15V Since the voltage is continuously supplied, these can be operated normally. Even if the voltage DV changes to +7.5 V, the voltage detection circuit 66 makes the voltage constant, and amplifies the amplification stages 20a and 20b for UHF band amplification, satellite broadcasting and / or satellite communication intermediate frequency signals. Since the time T supplied to the stages 26a, 26b and the converter for receiving satellite broadcasting or / and satellite communication and changing to + 7.5V is a short time that is not mistaken for a power failure, the voltage DV is +7. Even when the voltage is changed to .5V, the voltage detection circuit 66 makes the voltage constant, and the amplification stages 20a and 20b for UHF band amplification, the amplification stages 26a and 26b for satellite broadcasting or satellite communication intermediate frequency signals, and satellite broadcasting or ( And) since they are supplied to the satellite communication receiving converter, these operations are not affected.

  In the above embodiment, using a satellite broadcast or (and) satellite communication intermediate frequency signal amplification stage 26a, 26b, a satellite broadcast or (and) satellite communication receiving converter that is normally designed to operate at + 15V. Therefore, the voltage of the first value is set to + 15V. However, when only the amplification stages for the VHF band and the UHF band are used without using the amplification stages 26a and 26b, the voltage of the first value is Other voltages such as + 10V or + 5V can be used. In addition, since + 15V is used as the first value voltage, + 7.5V is used as the second value voltage in order to prevent misunderstanding as the second value voltage even if there is a voltage fluctuation. Although used, other voltage values, for example, the first voltage value is + 15V, may be + 10V or + 5V. In addition, the voltage of the second value is set to a value smaller than the voltage of the first value. However, although the configuration of the power supply unit 4 is somewhat complicated, a voltage having a value higher than the first value is It can also be used as a voltage of value 2.

  In the above embodiment, only + 7.5V is used as the second value voltage. However, the second value voltage is provided in addition to + 7.5V, for example, a plurality of + 10V and + 5V are provided, and from + 15V When the voltage changes to + 7.5V, the switch 68 is controlled as described above. As shown in FIG. 4A, when the voltage changes from + 15V to + 5V and returns to + 15V, or changes from + 15V to + 10V, the voltage changes to + 15V. When changed, another device in the main body 2 can be controlled. For example, when the amplification stages 6, 8a, 8b, 20a, 20b, 26a and 26b are provided with AGC means, the AGC means of the amplification stages 6, 8a and 8b are turned off when + 5V, and the amplification stage 20a when + 10V. , 20b, 26a, and 26b can be turned off. In addition, if a switch similar to the switch 68 is provided for the amplification stages 26a and 26b and it is found that satellite broadcasting or (and) satellite communication intermediate frequency signals are not input, a voltage of +5 V is supplied. When this switch is turned off, or according to the frequency of digital terrestrial broadcasting in the region where this high frequency amplifier is used, the cutoff frequency of the front and rear band pass filters 22 and 24 of the UHF band is variable. The filter 22 and 24 may be used to change the cutoff frequency.

  In FIG. 4 (a), it is shown that it returns to + 15V after changing to + 7.5V, + 5V, + 10V, but as shown in FIG. 4 (b), it can be changed from + 7.5V to + 5V, As shown in FIG. 5C, it can be changed from + 5V to + 10V. Even in these cases, the control assigned to these voltages is performed by changing to each voltage. In any case, the change in voltage other than + 15V is continued for a predetermined time T.

  In the above embodiment, the separate amplification stages 6, 8a, 8b are provided for the VHF band high band and the VHF band low band, but the entire VHF band can be amplified by one amplification stage. In addition, although the band pass filters 22 and 28 are provided in front of the amplification stages 20a and 26a, a high pass filter can be used instead. Further, although the amplification stages 26a and 26b are provided for amplifying the satellite broadcast or satellite communication intermediate frequency signal, they can be removed.

It is a block diagram of the high frequency amplifier of one Embodiment of this invention. It is a wave form diagram which shows the state of the voltage change of the power supply part of the high frequency amplifier of FIG. It is a flowchart which shows operation | movement of the voltage detection circuit of the high frequency amplifier of FIG. It is a wave form diagram which shows the state of the voltage change of the power supply part in the modification of the high frequency amplifier of FIG.

Explanation of symbols

2 Main body (high frequency amplification means)
4 Power supply (external power supply means)
6 8a 8b Amplification stage (first high frequency amplification means)
20a 20b amplification stage (second high frequency amplification means)
66 Voltage detection circuit (control means, internal power supply means)
68 switches (control means)

Claims (5)

High-frequency amplification means including first amplification means for amplifying a high-frequency signal in a first frequency band; and second amplification means for amplifying a high-frequency signal in a second frequency band;
An internal power supply means for supplying an operating voltage to which the voltage is supplied from the outside and normally operating to the first and second amplifying means;
When the external voltage is a voltage having a predetermined first value, the internal power supply means supplies the operating voltage to the first and second amplifying means, and the external voltage is When the voltage of the first value changes to the voltage of the second value different from the voltage of the first value and returns to the voltage of the first value, the internal power supply means to the first amplification means Control means for stopping the supply of the operating voltage and continuing the supply of the operating voltage to the second amplifying means;
A high-frequency amplifier provided.   2. The high frequency amplifier according to claim 1, wherein the control means stops the supply of the operating voltage when the voltage of the second value changes to the voltage of the first value after being maintained for a predetermined time. amplifier.   3. The high frequency amplifier according to claim 1, wherein the internal power supply means outputs a voltage having a first value as the operating voltage.   4. The high-frequency amplifier according to claim 1, wherein a plurality of voltages having different values are prepared as the second value of the voltage supplied from the outside. Among these, when the voltage of the first value or the voltage of the other second value is changed after the predetermined second value voltage is supplied, the internal power supply means to the first amplification means The supply of the operating voltage is stopped, the supply of the operating voltage to the second amplifying means is continued, and the other second value is determined from the first value voltage or the predetermined second value voltage. A high-frequency amplifier that controls the means included in the high-frequency amplification means when the voltage changes to a voltage of a first value or a voltage of another second value. The high-frequency amplifier according to any one of claims 1 to 3, wherein the external voltage is superimposed from an external power supply means on a transmission line for transmitting the output signals of the first and second amplification means.
The external power supply means includes a voltage generation means for generating a first value voltage, a voltage conversion means for converting the first value voltage into a second value voltage, and a first value from the voltage generation means. A high-frequency amplifier comprising: selection means for outputting a voltage having a second value from the voltage conversion means after outputting a voltage having a value.

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