KR100211755B1 - Antenna booster mixer circuit - Google Patents

Abstract

Even when the video tape recorder (VTR) is turned off and the booster amplifier is stopped, an antenna booster mixer circuit is provided which bypasses the received signal input to the antenna input terminal and outputs it to the antenna output terminal so that unnecessary power is not consumed.

A booster which is assembled to the VTR 1, connected between the antenna input terminal 14 and the antenna output terminal 15, and between the antenna input terminal 14 and the antenna output terminal 15, and shares the power supply with the VTR 1; The amplifiers 7 and 9 and a signal bypass circuit 12 connected in parallel to the booster amplifiers 7 and 9, and when the power supply of the VTR 1 is turned on at the time of recording or reproduction of the signal, the antenna The received signal supplied to the input terminal 14 is transmitted from the booster amplifier 7 to the antenna output terminal 15, and when the power of the VTR 1 is off, the received signal supplied to the antenna input terminal 14 is The signal is output from the antenna output terminal 15 via the signal bypass circuit 12.

Description

Antenna Booster Mixer Circuit

The present invention relates to an antenna booster mixer circuit that is assembled and used in a videotape recorder, and more particularly, to an antenna booster mixer circuit that can transmit an antenna received signal between antenna input and output terminals even when the power supply of the videotape recorder is turned off.

Currently, the European television broadcasting system broadcasts the broadcast signal of each channel using the UHF band. When receiving the broadcast signal connected to the video tape recorder, the television is normally connected to the antenna input terminal of the video tape recorder. An antenna is connected, and the antenna output terminal is coupled to an input terminal of a television receiver to receive a broadcast signal.

In this case, an antenna booster mixer circuit is incorporated into the videotape recorder, and the antenna booster mixer circuit includes a booster amplifier, an antenna input terminal, an antenna output terminal, and the like for amplifying a signal received by the antenna.

The antenna booster mixer circuit receives a television signal using an antenna connected to the antenna input terminal, and when the received television signal is displayed on a television receiver by award, the power supply of the video tape recorder is turned on to turn on the booster amplifier. In operation, the received television signal is amplified by a booster amplifier and supplied to the television receiver via an antenna output terminal. On the other hand, when receiving a television signal using an antenna and recording the received television signal with the videotape recorder, the power supply of the videotape recorder is turned on to turn on the booster amplifier and the received television signal is booster amplifier. After amplification, the signal is branched and supplied to the tuner of the videotape recorder, demodulated and extracted from the required image signal, and the like, and the obtained image signal is recorded. In addition, when a recorded signal or the like recorded in a videotape recorder is reproduced, and the reproduced signal is displayed on a television receiver in a water phase, the reproduced signal is applied to a mixer stage through high frequency modulation to form a signal equivalent to the television signal. This signal is supplied to a television receiver.

7 is a schematic configuration diagram showing a coupling relationship between a known receiver, that is, a video tape recorder and a television receiver, used when receiving a European television broadcast signal, and FIG. 8 is a video shown in FIG. FIG. 8A is a block diagram showing a layout connection relationship between an antenna booster mixer circuit, a video tape recorder and a television receiver, and FIG. 8B is a specific internal structure of the antenna booster mixer circuit. A circuit diagram is shown.

As shown in Figs. 7, 8A, and 8B, the video tape recorder (VTR) 41 includes an antenna input terminal 53, an antenna output terminal 54, an antenna booster mixer circuit 42, and recording. The regeneration circuit 43 is provided. An antenna 44 is connected to the antenna input terminal 53, and an antenna input terminal 55 of the television receiver 45 is connected to the antenna output terminal 54. The antenna booster mixer circuit 42 includes a first coupling capacitor 56, a first booster amplifier 46, a first inductor 57, a first divider 47, a second booster amplifier 48, and a second inductor. (58), a second divider (49), a second coupling capacitor (59), and a high frequency (RF) modulator 50, respectively, and the recording / playback circuit 43 includes a recording / playback section 51 and a tuner 52. Each is provided.

On the antenna booster mixer circuit 42 side, the first booster amplifier 46 has an input connected to the antenna input terminal 53 via a first coupling capacitor 56 and an output of the first divider 47. The first divider 47 is connected to the input of the second booster amplifier 48 and the other output to the input of the tuner 52 on the recording / reproducing circuit 43 side, respectively. . The second divider 49 has one input connected to the output of the second booster amplifier 48, the other input to the output of the high frequency modulator 50, and the output passed through the second coupling capacitor 59 to the antenna output terminal. And the input of the high frequency modulator 50 is connected to the output of the recording / reproducing section 51 on the recording / reproducing circuit 43 side. The power supply of the first booster amplifier 46 is supplied to the power supply terminal 60 via the first inductor 57, and the power supply of the second booster amplifier 48 is supplied to the power supply terminal 60 via the second inductor 58. Connected. On the recording / reproducing circuit 41 side, the input of the recording / reproducing section 51 is connected to the output of the tuner 52.

The antenna booster mixer circuit 42 according to the above configuration operates as follows.

First, the power supply of the video tape recorder 41 is turned on to supply power supply voltages of the first and second booster amplifiers 46 and 48 to the power supply terminal 60. Here, when the received television signal is received by the television receiver 45, the received signal received by the antenna 44 in the antenna booster mixer circuit 42 is transmitted from the antenna input terminal 53 to the first coupling capacitor 56. The first booster amplifier 46 is supplied to the first booster amplifier 46, and then the received signal is amplified by the first booster amplifier 46 and then supplied to the first divider 47 and divided into two parts. One of the divided received signals is supplied to the second booster amplifier 48, and amplified therein and then supplied to the second coupling capacitor 59 through the second divider 49, and then to the antenna of the television receiver 45. It is supplied to the input terminal 55 and is received by the television receiver 45. At this time, the reception signal is received by the video tape recorder 41 in parallel with the reception of the reception signal in the television receiver 45, or the reception signal is received regardless of the reception of the reception signal in the television receiver 45. When the signal is recorded by the videotape recorder 41, when the tuner 52 receives the other received signal distributed to the first divider 47 in the recording / playback circuit 43, the received signal is frequencyd. After conversion and demodulation, the image signal is converted to an image signal suitable for recording, and supplied to the recording and playback section 51, so that the recording and playback section 51 records the recording signal. Subsequently, when the image signal already recorded in the recording and playback section 51 is reproduced, and the reproduced recording signal is received by the television receiver 45, the recording and playback section 51 in the recording and playback circuit 43 When the image signal is reproduced, in the antenna booster mixer circuit 42, the high frequency modulator 50 modulates and frequency converts the reproduced signal into a reception signal suitable for a television signal, and the converted received signal is divided into the second divider 49 The second coupling capacitor 59 is supplied to the second coupling capacitor 59, and then to the antenna connection terminal 55 of the television receiver 45 so as to be received in the television receiver 45.

In this manner, the known antenna booster mixer circuit 42 according to the above configuration supplies the television receiver signal to the television receiver 45 to receive the television receiver 45, and the television receiver signal to the video tape recorder 41. And the reproduction signal of the videotape recorder 41 can be supplied to the television receiver 45 to perform three functions of awarding the television receiver 45.

In the known antenna booster mixer circuit 42, the power supply of the first and second booster amplifiers 46 and 48 is shared with the power supply of the video tape recorder 41. That is, if the video tape recorder 41 is not turned on, the first and second booster amplifiers 46 and 48 are not turned on, and the television receiver 45 is used to display the image of the received signal. There is a problem that cannot be done.

The reason is that the video tape recorder 41 has a built-in divider for distributing the received signal, and the received signal is greatly attenuated by the divider, and furthermore, the electric field strength of the received broadcast signal of the UHF band is not so large. This is to improve the image quality of the display image by compensating for large attenuation of the received signal by interposing the first and second booster amplifiers 46 and 48 in the mixer circuit 42.

On the other hand, since the known antenna booster mixer circuit 42 needs to turn on the video tape recorder 41 even when only the television receiver 45 is operated as described above, the video tape recorder At 41, unnecessary power is consumed and there is a problem that it is never desirable from the viewpoint of energy saving.

SUMMARY OF THE INVENTION The present invention solves this problem, and an object thereof is to transmit an antenna booster mixer without attenuating a large amount of the received signal even when the video tape recorder is not used, without attenuating the received signal. To provide a circuit.

1 is a block diagram showing a layout connection relationship between an antenna booster mixer circuit of the present invention, a video tape recorder and a television receiver;

Fig. 2 is a circuit diagram showing a first embodiment of the antenna booster mixer circuit according to the present invention.

3 is a circuit diagram showing a second embodiment of the antenna booster mixer circuit according to the present invention;

4 is a circuit diagram showing a third embodiment of the antenna booster mixer circuit according to the present invention;

In the first and second embodiments shown in Figs. 5A and 5, an explanatory diagram in which the states of the respective components are shown in a list at the time of reception, recording, and playback;

Fig. 6 is a characteristic diagram showing drain voltage / current characteristics corresponding to the gate and source voltages of the N-channel FETs used for the first switch and the second switch, respectively.

7 is a configuration diagram showing a connection relationship between a video tape recorder, a television receiver, and an antenna in a European television broadcasting receiver;

8A and 8B are circuit diagrams showing an example of an antenna booster mixer circuit in the video tape recorder shown in FIG.

* Explanation of symbols for main parts of the drawings

1: Video Tape Recorder (VTR) 2: Antenna Booster Mixer Circuit

3: recording and reproducing circuit 4: television signal receiving antenna

5: TV receiver 6: first changeover switch

6 (1): first switching FET 6 (2): first switching diode

6 (3): 1st resistor 6 (4): 2nd resistor

6 (5): 3rd switching diode 6 (6): 4th switching diode

7: first booster amplifier 8: first divider

8 (1): first divider 9: second booster amplifier

10: second divider 10 (1): second divider

11: 2nd switch 11 (1): 2nd switching FET

11 (2): Second switching diode 11 (3): Third resistor

11 (4): 4th resistor 11 (5): 5th switching diode

11 (6): 6th switching diode 12: signal bypass circuit

12 (1): first high resistance 12 (2): second high resistance

12 (3): Fifth coupling capacitor 12 (4): Fifth coupling capacitor

12 (5): fifth resistor 12 (6): bypass diode

12 (7): 7th coupling capacitor 12 (8): 6th resistor

12 (9): Second bypass diode 12 (10): Third bypass diode

12 (11): 7th resistor 12 (12): smoothing capacitor

12 (13): Eighth Resistor 13: High Frequency (RF) Modulator

14: antenna input terminal 15: antenna output terminal

16: recording and playback unit 17: tuner

18: antenna input terminal 19: first coupling capacitor

20: second coupling capacitor 21: first buffer resistor

22: first inductor 23: second inductor

24: third coupling capacitor 25: second buffer resistor

26: fourth coupling capacitor 27: power supply terminal

28: 9th resistance 29: 10th resistance

30: switching power supply terminal

In order to achieve the above object, the present invention provides a booster amplifier, which is assembled to a video tape recorder, is connected between an antenna input terminal and an antenna output terminal, and is connected between the antenna input terminal and the antenna output terminal, and the power supply is shared with the video tape recorder. And a signal bypass circuit connected to the booster amplifier in parallel, and when the video tape recorder is powered on, an antenna received signal supplied to the antenna input terminal is transmitted from the booster amplifier to the antenna output terminal. And the antenna received signal supplied to the antenna input terminal when the video tape recorder is powered off is output from the antenna output terminal via the signal bypass circuit.

According to the above means, the antenna booster mixer circuit includes a booster amplifier whose power is turned on / off in correspondence with the on / off of the video tape recorder power supply, and a signal bypass circuit connected to the booster amplifier in parallel. When the video tape recorder is turned on when the signal is recorded or reproduced, the signal transmission path of the antenna booster mixer circuit is switched to the booster amplifier side. At this time, the received signal supplied to the antenna input terminal is amplified by a booster amplifier and converted into a video signal by processing the received signal into a required signal. After reproducing or reproducing the image signal recorded in the recording / reproducing circuit, the image signal is converted into a received signal by processing the required signal of the image signal, and the received signal is supplied from the antenna output terminal to the television receiver to reproduce the image on a television receiver. Or On the other hand, when only the signal is received and the power supply of the videotape recorder is turned off, the signal transmission path of the antenna booster mixer circuit is switched to the signal bypass circuit side. At this time, the received signal supplied to the antenna input terminal is transmitted directly to the antenna output terminal through the signal bypass circuit, and is then supplied from the antenna output terminal to the television receiver and reproduced by the television receiver.

In this manner, according to the above means, when the video tape recorder does not record or reproduce a signal, that is, when only the signal is received, the antenna is not supplied with the power supply of the antenna booster mixer circuit. The booster mixer circuit can be supplied to a television receiver, whereby an antenna booster mixer circuit is obtained which does not cause unnecessary power consumption.

Example

EMBODIMENT OF THE INVENTION Hereinafter, the Example of this invention is described in detail based on drawing.

Fig. 1 is a block diagram showing the arrangement connection relationship between an antenna booster mixer circuit of the present invention, a video tape recorder and a television receiver, and Fig. 2 is a circuit diagram showing a first embodiment of the antenna booster mixer circuit according to the present invention. .

1 and 2, the video tape recorder (VTR) 1 includes an antenna booster mixer circuit 2, a recording / playback circuit 3, an antenna input terminal 14, and an antenna output terminal ( 15). An antenna 4 is connected to the antenna input terminal 14, and an antenna input terminal 18 of the television receiver 5 is connected to the antenna output terminal 15. The antenna booster mixer circuit 2 includes a first coupling capacitor 19, a first changeover switch 6, a first buffer resistor 21, a second coupling capacitor 20, a first booster amplifier 7, and a first coupling capacitor 19. The first inductor 22, the first divider 8, the second booster amplifier 9, the second inductor 23, the second divider 10, the third coupling capacitor 24 and the second buffer resistor 25 And a second switching switch 11, a fourth coupling capacitor 26, a signal bypass circuit 12, and a high frequency (RF) modulator 13, respectively. The recording and reproducing circuit 3 includes a recording and reproducing unit 16 and a tuner 17. The first changeover switch 6 is provided with a first switching N-channel FET6 (1), a first switch diode 6 (2), and a first resistor 6 (3), respectively, and the second changeover switch 11 Has a second switching N-channel FET 11 (1), a second switching diode 11 (2), and a third resistor 11 (3), respectively. The 1st divider 8 is equipped with the 1st divider 8 (1), and the 2nd divider 10 is equipped with the 2nd divider 10 (1). The signal bypass circuit 12 includes a first high resistance 12 (1), a second high resistance 12 (2), a fifth coupling capacitor 12 (3), a sixth coupling capacitor 12 (4), and a fifth resistance 12 (5). ) And bypass diode 12 (6), respectively.

On the antenna booster mixer circuit 2 side, the first changeover switch 6 has an input via the first coupling capacitor 19 to the antenna input terminal 14 and a first output on the second coupling capacitor 20. A second output is connected to the power supply terminal 27 via an input of the first booster amplifier 7 and a first buffer resistor 21 via a second output to an input of the signal bypass circuit 12, respectively. The first booster amplifier 7 has an output connected to the input of the first divider 8 and a power source connected to the power supply terminal 27 via the first inductor 22. The first divider 8 has one output connected to the input of the second booster amplifier 9 and the other output connected to the input of the tuner 17 on the recording / reproducing circuit 3 side. The second booster amplifier 9 has an output connected to one input of the second divider 10 and a power source connected to the power supply terminal 27 via the second inductor 23, respectively. The second divider 10 is connected with the other input to the output of the high frequency modulator 13 and the output via the third coupling capacitor 24 to the input of the second changeover switch 11, respectively. The second changeover switch 11 has a first input to the power supply terminal 27 via a second buffer resistor 25, a second input to an output of the signal bypass circuit 12, and an output of a fourth coupling capacitor ( It is connected to the antenna output terminal 15 via 26 respectively. The high frequency modulator 13 has an input connected to the output of the recording / playback section 16 on the recording / reproducing circuit 3 side.

In the first switching switch 6, the first switching FET 6 (1) has a source of a cathode of the first coupling capacitor 19 and the first switching diode 6 (2) and the first resistor 6 (3). At one end, the gate is connected to the other end of the first resistor 6 (3) and the ground point, and the drain D is connected to the input of the signal bypass circuit 12, respectively. The first switching diode 6 (2) has an anode connected to the second coupling capacitor 20. In the second switch 11, the second switch FET 11 (1) has a source of a cathode of the fourth coupling capacitor 26 and the second switch diode 11 (2) and a third resistor 11 (3). At one end of the gate, the gate is connected to the other end of the third resistor 11 (3) and the ground point, and the drain is connected to the output of the signal bypass circuit 12, respectively. The second switching diode 11 (2) has an anode connected to the third coupling capacitor 24. In the signal bypass circuit 12, the first high resistance 12 (1) has one end of the bypass diode 12 (6) passing through the input of the signal bypass circuit 12 and the fifth coupling capacitor 12 (3). At the anode, the other end is respectively connected to the ground point. The bypass diode 12 (6) has a positive pole at one end of the second high resistance 12 (2) via the fifth resistor 12 (5) via the power supply terminal 27 and the sixth coupling capacitor 12 (4), and the negative pole is the ground point. Are connected to each. One end of the second high resistance 12 (2) is connected to the output of the signal bypass circuit 12 and the other end thereof to the ground point. In this case, the first switching N-channel FET 6 (1) used for the first switching switch 6 and the second switching N-channel FET 11 (1) used for the second switching switch 11 are shown in Fig. 6. It has the characteristics as shown in the figure, and while the drain voltage V _D is all small, when the drain voltage V _D gradually increases, the drain current I _D increases in proportion to it, and the drain voltage (V _D) is greater than it, according to the value of the gate-source voltage (V _GS) to be the value of the drain current (I _D) constant, the value of the gate-source voltage (V _GS) 0 In this case, the constant value of the drain current I _D becomes maximum, and the constant value of the drain current I _D decreases sequentially as the value of the gate-source voltage V _GS becomes negative.

On the recording / reproducing circuit 3 side, the input of the recording / reproducing section 16 is connected to the output of the tuner 17.

In the above configuration, the antenna booster mixer circuit 2 of the present embodiment operates as follows.

First, when the received signal received by the antenna 4 with the power of the video tape recorder 1 turned off is transmitted to the television receiver 5 via the antenna booster mixer circuit 2 (hereinafter, this is received). Since the first and second switching switches 6 and 11 are not supplied with a power supply voltage to the power supply terminal 27, the first and second switching diodes 6 (2) and 11 (2) Is off. When the first and second switching diodes 6 (2) and 11 (2) are turned off, the gate-source voltage V _{GS of} the first and second switching FETs 6 (1) and 11 (1) is respectively _reduced . 0 bias. At this time, the first and second switching diodes 6 (2) and 11 (2) are drained when the gate-source voltage V _GS is 0 bias, for example, as shown in FIG. The value of the current I _D is maximized, i.e., the first and second switching FETs 6 (1) and 11 (1) are turned on, and the first and second switching switches 6 and 11 are connected by a signal. It is switched to the pass circuit 12 side. Here, when the received signal received by the television signal receiving antenna 4 is supplied to the antenna input terminal 14 of the antenna booster mixer circuit 2, the first and second switching switches 6, 11 are connected to the signal bypass circuit. Since it is switched to the (12) side, the received signal is supplied to the antenna output terminal 15 via the first switch 6, the signal bypass circuit 12, and the second switch 11, and then the television receiver ( It is supplied to the antenna input terminal 18 of 5), and the image reproduction of the received signal is performed by the television receiver 5. In this case, in the signal bypass circuit 12, since the power supply voltage is not supplied to the power supply terminal 27 and the bypass diode 12 6 is turned off, the input of the signal bypass circuit 12 is performed. The received signal supplied to is transmitted to the output of the signal bypass circuit 12 through the fifth coupling capacitor 12 (3) and the sixth coupling capacitor 12 (4) in a state of having a small signal loss.

Next, in the videotape recorder 1, when the recording / reproducing circuit 3 is used to record the received signal received by the antenna 4 as the recording signal by the recording / reproducing circuit 3 (hereinafter, this is recorded. When the video signal recorded in the recording / reproducing circuit 3 is reproduced and supplied to the television receiver 5 as an image signal (hereinafter referred to as playback), the video tape recorder 1 The power is turned on, and a power supply voltage is supplied to the power supply terminal 27 of the antenna booster mixer circuit 2. At this time, the first and second switching switches 6 and 11 are supplied with a power supply voltage to the power supply terminal 27 so that the first and second switching diodes 6 (2) and 11 (2) are connected between the anode and the cathode. A forward bias voltage (constant voltage) is applied as the voltage V _AK . Therefore, the first and second switching diodes 6 (2) and 11 (2) are turned on, and the first and second switching FETs 6 (1) and 11 (1) are, for example, in accordance with the characteristics shown in FIG. As shown, as the negative bias value of the gate-source voltage V _GS increases, the value of the drain current I _D becomes very small. Since the gate-source voltage V _GS changes depending on the selection of the resistance values of the first buffer resistor 21 and the first resistor 6 (3), the gate-source voltage V _GS is as negative as possible. The resistance values of the first buffer resistor 21 and the first resistor 6 (3) are selected to increase by. When the resistance value is selected, the first and second switching FETs 6 (1) and 11 (1) are turned off, and the first and second switching switches 6 and 11 are connected to the first and second booster amplifiers ( 7, 9) is switched to the side.

Here, when the received signal received by the antenna 4 at the time of recording is supplied to the antenna input terminal 14 of the antenna booster mixer circuit 2, the first and second changeover switches 6, 11 are first and second. Since the two booster amplifiers 7 and 9 are switched to the side, the received signal is supplied from the first changeover switch 6 to the first booster amplifier 7 and the first divider 8, and at the first divider 8, Are distributed to dogs. One of the received signals distributed by the first divider 8 is supplied to the antenna output terminal 15 via the second booster amplifier 9, the second divider 10, and the second changeover switch 11. Subsequently, it is supplied to the antenna input terminal 18 of the television receiver 5, and image reproduction of the received signal is performed by the television receiver 5. At the same time, the other received signal distributed by the first divider 8 is supplied to the tuner 17 on the recording / reproducing circuit 3 side, where the received signal is frequency converted and demodulated and suitable for recording. After conversion to, it is supplied to the recording / playback section 16 and the video signal is recorded by the recording-playback section 16.

When the recording signal is reproduced by the recording / reproducing section 16 in the recording / reproducing circuit 3 at the time of reproduction, this image signal is modulated and frequency-converted by the high frequency modulator 13 of the antenna booster mixer circuit 2. The received signal is converted into a reception signal suitable for the signal, and the converted reception signal is supplied from the second divider 10 to the antenna output terminal 15 through the second switch 11, and then the antenna input terminal of the television receiver 5. Supplied to (18), water image reproduction of the received signal is performed by the television receiver 5. FIG.

As described above, according to the antenna booster mixer circuit 2 of the first embodiment, even when the power supply of the video tape recorder 1 is turned off and the power supply to the antenna booster mixer circuit 2 is not performed, a large transmission of the received signal is performed. The antenna booster mixer circuit 2 can be obtained by supplying to the television receiver 5 via the signal bypass circuit 12 without causing any loss, thereby avoiding unnecessary power consumption.

Further, according to the antenna booster mixer circuit 2 of the first embodiment, the intermodulation distortion can be improved as compared with the conventional antenna booster mixer circuit shown in Fig. 8B.

Next, Fig. 3 is a circuit diagram showing the second embodiment of the antenna booster mixer circuit 2 according to the present invention, and the first and second switching switch circuits 6 and 11 with respect to the first embodiment. The circuit configuration is partially changed.

In addition, in FIG. 3, the same code | symbol is attached | subjected about the component same as the component shown in FIG. 2, and the description is abbreviate | omitted.

As shown in Fig. 3, in the first switchover circuit 6, the first switching FET6 (1) is grounded via the second resistor 6 (4) instead of the gate is directly connected, and the second In the switching switch circuit 11, the second switching FET 11 (1) is grounded via a fourth resistor 11 (4) instead of the gate connected directly to ground, similarly to the first switching FET 6 (1). It is connected.

Since the operation of the second embodiment with the above configuration is almost the same as the operation of the first embodiment described above in any case of reception, recording, and reproduction, the detailed description of the second embodiment is omitted.

In this case, according to the antenna booster mixer circuit 2 of the second embodiment, not only the same operational effects as in the first embodiment are obtained, but also the improvement of the intermodulation distortion is compared with the conventional antenna booster mixer circuit shown in Fig. 8B. It is possible to improve about 11 to 22 db, and the degree of improvement is larger than that of the first embodiment.

Next, Fig. 4 is a circuit diagram showing the third embodiment of the antenna booster mixer circuit 2 according to the present invention. The first and second switching switch circuits 6, 11 and the first embodiment will be described. The circuit configuration of the part related to the signal bypass circuit 12 is changed, respectively.

4, the same code | symbol is attached | subjected about the component same as the component shown in FIG. 2, and the description is abbreviate | omitted.

As shown in FIG. 4, the first switchover circuit 6 comprises a third switching diode 6 (5) and a fourth switching diode 6 (6), the input of which is via a first coupling capacitor 19. The first output is connected to the input of the first booster amplifier 7 and the second output is connected to the input of the signal bypass circuit 12 through the antenna input terminal 14 and the ninth resistor 28, respectively. . The second switching switch circuit 11 is composed of a fifth switching diode 11 (5) and a sixth switching diode 11 (6), and a first input is input to an output of the second distributor 10. To the output of the signal bypass circuit 12, the output is connected to the ground point via the fourth coupling capacitor 26 via the antenna output terminal 15 and the tenth resistor 29, respectively. The signal bypass circuit 12 includes a seventh coupling capacitor 12 (7), a sixth resistor 12 (8), second and third bypass diodes 12 (9), 12 (10), and a seventh resistor. 12 (11), the smoothing capacitor 12 (12), and the eighth resistor 12 (13). In the first switching switch circuit 6, the third switching diode 6 (5) has a positive pole at the first booster amplifier 7 and a negative pole at the first coupling capacitor 19 and the fourth switching diode. It is connected to the cathode of 6 (6), respectively. The fourth switching diode 6 (6) has an anode connected to the input of the signal bypass circuit 12. In the second switching switch circuit 11, the fifth switching diode 11 (5) has a positive pole at the second divider 10 and a negative pole at the fourth coupling capacitor 26 and the sixth switching diode 11 (6). It is connected to the cathode of respectively. In the sixth switching diode 11 (6), an anode is connected to the output of the signal bypass circuit 12. In the signal bypass circuit 12, one end and the other end of the seventh coupling capacitor 12 (7) are connected to the input and the output of the signal bypass circuit 12, respectively, and the sixth resistor 12 (8) is made of one end. One end of the seven coupling capacitor 12 (7) is connected to the other end of the switching power supply terminal 30 for supplying the switching voltage. The second and third bypass diodes 12 (9) and 12 (10) have an anode connected to each one end of the seventh resistor 12 (11) and the smoothing capacitor 12 (12), and the cathode of the seventh coupling capacitor 12 ( Connected to the other end of 7). The other end of the seventh resistor 12 (11) is connected to the power supply terminal 27, and the other end of the smoothing capacitor 12 (12) is connected to the ground point. One end and the other end of the eighth resistor 12 (13) are connected to an input and an output of the signal bypass circuit 12, respectively. The switching power supply terminal 30 is supplied with a switching voltage of positive polarity at the time of reception, and a switching voltage of ground potential at the time of recording and reproduction.

Since the operation of the third embodiment with the above configuration is substantially the same as the operation of the first embodiment described above in any case at the time of reception, recording, and playback, a detailed description of the operation of the third embodiment is omitted. .

However, when the power supply of the video tape recorder 1 is in the OFF state, the first changeover switch 6 is driven by the positive changeover voltage of the changeover power supply terminal 30 supplied through the sixth resistor 12 (8). Since the third switching diode 6 (5) is reversely biased to the off state and the fourth switching diode 6 (6) is forward biased to the on state, the first switching switch 6 is moved to the signal bypass circuit 12 side. Is switched. The second switching switch 11 is connected to the fifth switching diode 11 by the positive switching voltage of the switching power supply terminal 30 supplied through the sixth resistor 12 (8) and the eighth resistor 12 (13). (5) is reversely biased to the off state, and since the sixth switching diode 11 (6) is forward biased to the on state, the second changeover switch 11 is also switched to the signal bypass circuit 12 side. In addition, the signal bypass circuit 12 is driven by the voltage of the power supply terminal 27 supplied through the fifth resistor 12 (8) and the seventh resistor 12 (13). Since 12 (10) are reverse biased and turned off, respectively, the received signal supplied to the input is transmitted to the output with little signal loss through the seventh coupling capacitor 12 (7).

In addition, when the power supply of the video tape recorder 1 is turned on, the first changeover switch 6 causes the voltage of the changeover power supply terminal 30 supplied through the sixth resistor 12 (8) to become the ground potential, The third switching diode 6 (5) is forward biased on by the power supply voltage of the power supply terminal 27 supplied from the input of the first booster amplifier 7, so that the fourth switching diode 6 (6) is turned on. Since it is reverse biased and turned off, the first changeover switch 6 is switched to the first and second booster amplifiers 7 and 9 side. In the second switching switch 11, the voltage of the switching power supply terminal 30 supplied through the sixth resistor 12 (8) and the eighth resistor 12 (13) is a ground unit, and the second booster amplifier 9 Since the power supply voltage of the power supply terminal 27 is supplied from the output of the power supply terminal 27 through the second divider 10, the fifth switching diode 11 (5) is forward biased and turned on. It is reverse biased and turned off, and the second changeover switch 11 is also switched to the first and second booster amplifiers 7 and 9 side.

Thus, according to the third embodiment, as in the first embodiment, even if the power supply of the video tape recorder 1 is off and no power is supplied to the antenna booster mixer circuit 2, a large transmission loss is caused to the received signal. The antenna booster mixer circuit 2 can be supplied to the television receiver via the signal bypass circuit 12 without causing unnecessary power consumption.

Here, FIG. 5 is an explanatory diagram showing a state in each component part at the time of reception, recording, reproduction, and the like in the first to third embodiments, and FIG. 5A shows the first and second embodiments, 5B relates to the third embodiment.

First, as shown in Fig. 5A, in the first and second embodiments, the power supply of the video tape recorder 1 and the antenna booster mixer circuit 2 is turned on at the time of recording and reproduction, and thereby the first switching switch ( 6) and the second changeover switch 11 are switched to the first and second booster amplifiers 7 and 9, so that a part of the received signal is recorded and reproduced by the videotape recorder 1 during recording. Supplied to the video receiver, and a portion of the remaining received signals are supplied to the television receiver 5 to reproduce the image, and at the time of reproduction, all of the signals reproduced by the recording / reproducing circuit 3 are supplied to the television receiver 5 to reproduce the image. will be. Also, the power supply of the video tape recorder 1 and the antenna booster mixer circuit 2 is not turned on at the time of reception, so that both the first switch 6 and the second switch 11 are signal bypass circuits. By switching to the (12) side, all of the received signals are supplied to the television receiver 5 via the signal bypass circuit 12, whereby the water is reproduced.

Next, as shown in FIG. 5B, in the third embodiment, the power supply of the video tape recorder 1 and the antenna booster mixer circuit 2 is turned on during recording and playback, and the ground potential is supplied to the switching power supply terminal 30. FIG. By supplying a switching voltage of, since both the first switching switch 6 and the second switching switch 11 are switched to the first and second booster amplifiers 7 and 9, part of the received signal is recorded on the video tape during recording. The recording and reproducing circuit 3 of the recorder 1 is supplied and recorded, and a part of the remaining received signals are supplied to the television receiver 5 to reproduce the image. All of the signals reproduced by the recording and reproducing circuit 3 are reproduced. It is supplied to the television receiver 5 to reproduce water phase. In addition, the power supply of the video tape recorder 1 and the antenna booster mixer circuit 2 is not turned on at the time of reception, and the positive switching voltage is supplied to the switching power supply terminal 30, thereby providing the first switching switch 6 and Both of the two switching switches 11 are switched to the signal bypass circuit 12 side, and all of the received signals are supplied to the television receiver 5 via the signal bypass circuit 12, whereby the water is reproduced.

As described in detail above, according to the present invention, even when the power supply of the videotape recorder is turned off and no power is supplied to the antenna booster mixer circuit, the signal bypass circuit of the antenna booster mixer circuit can be provided without giving a large transmission loss to the received signal. It can be supplied to a television receiver via the antenna booster mixer circuit that does not cause unnecessary power consumption.

In addition, according to the present invention, the intermodulation distortion can be improved as compared with the conventional antenna booster mixer circuit.

Claims (6)

A booster amplifier which is assembled to a video tape recorder and is connected between an antenna input terminal, an antenna output terminal, the antenna input terminal and the antenna output terminal, and a power supply shared with the video tape recorder in parallel with the booster amplifier; When the video tape recorder is powered on, the antenna reception signal supplied to the antenna input terminal is transmitted from the booster amplifier to the antenna output terminal, and the power supply of the video tape recorder is And the antenna boost signal supplied to the antenna input terminal is output from the antenna output terminal via the signal bypass circuit. 2. The mixer of claim 1, wherein a mixer stage is connected between the booster amplifier and the antenna output terminal, wherein the mixer stage performs high frequency modulation on one output of the booster amplifier and the other of the booster amplifier. And an output of the mixer stage is connected to the antenna output terminal, respectively. The switching switch according to claim 1 or 2, wherein a switching switch for switching to the booster amplifier side or the signal bypass circuit side is connected to at least one of the antenna input terminal and the antenna output terminal. And an antenna booster mixer circuit that is switched corresponding to on / off of the booster amplifier power supply. 4. The switching switch according to claim 3, wherein the changeover switch comprises one N-channel FET, a bias resistor connected between a gate and a source of the FET, and a switching diode connected to a cathode of a source of the FET. A source is connected to the antenna input terminal or the antenna output terminal, the anode of the diode is connected to the booster amplifier power supply through the input or output of the booster amplifier and the buffer resistor, and the drain of the FET is connected to the signal bypass circuit, respectively. When the booster amplifier power is on, the diode is on, the FET is off, and is switched to the booster amplifier side; when the power of the booster amplifier is off, the diode is off, the FET is on and the signal by An antenna booster mixer circuit, which is switched to the pass circuit side. 5. The antenna booster mixer circuit according to claim 4, wherein the N-channel FET has a gate connected to ground via a gate resistor. 4. The switching switch of claim 3, wherein the changeover switch comprises two switching diodes on one side and the other on which the cathodes are commonly connected, and the common connected cathodes of the two diodes are connected to the antenna input terminal or the antenna output terminal. The one diode of the one diode is connected to the power supply of the booster amplification via the input or output of the booster amplifier, the anode of the other diode is respectively connected to the signal bypass circuit, and the one of the booster amplifier power source is on. A diode of on, the other diode is turned off and switched to the booster amplifier side, and when the power of the booster amplifier is turned off, the other diode is turned on and switched to the signal bypass circuit side. Booster mixer circuit.