JP3996811B2 - Microwave / millimeter wave transmitter - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a microwave / millimeter wave transmission apparatus that wirelessly transmits a broadcast wave such as a terrestrial broadcast or a satellite broadcast of a television indoors using a microwave or a millimeter wave.
[0002]
[Prior art]
A system for wirelessly transmitting television terrestrial and satellite broadcast waves indoors using millimeter waves is disclosed in "Specified Low-Power Radio Station Millimeter-Wave Image Transmission Radio Equipment (ARIB STD-T69 1.0 Version)" Has been. The configuration is shown in FIG. In FIG. 8, 1 is a BS (broadcast satellite) receiving antenna, 2 is a CS (communication satellite) receiving antenna, 3 is a terrestrial receiving antenna, 4 is a CATV (cable television) cable, 5 is a transmitter, and 6 is a transmitter. A receiver 7 is a TV receiver.
[0003]
Broadcast wave IF (intermediate frequency) signals and the like received by the BS receiving antenna 1 and the CS receiving antenna 2 are sent to the transmitter 5 by cables drawn indoors from the outdoors. In the transmitter 5, these signals are up-converted into millimeter wave signals, then emitted into space and received by the receiver 6. In the receiver 6, the millimeter wave signal is down-converted to the original IF signal or the like and sent to the TV receiver 7 or a tuner (not shown).
[0004]
With the above configuration, since it is not necessary to directly connect the outdoor antenna and the receiver such as the TV receiver 7 or the tuner with a cable, the TV receiver 7 or the tuner is within the line-of-sight between the transmitter 5 and the receiver 6. It can be installed freely.
[0005]
[Problems to be solved by the invention]
However, in the above-mentioned conventional “radio equipment for specific low power radio station millimeter wave image transmission (ARIB STD-T69 version 1.0)”, a broadcast wave is transmitted indoors using millimeter waves. There are the following problems. That is, nothing is disclosed about a DC power supply method for operating the millimeter wave transmitter 5 and the BS receiving antenna 1 or the CS receiving antenna 2. By the way, in an ordinary house, a TV antenna terminal and an AC power outlet are buried below the inner wall of the house. For this purpose, in order to operate the transmitter 5 installed on the upper part of the inner wall surface, the antenna terminal and the transmitter 5 are connected with a high-frequency cable, and at the same time, a power line between the AC 100V outlet and the transmitter 5 is also used. Will be connected. In that case, there is a problem that wiring becomes complicated.
[0006]
Further, as in the past, when the antenna and the TV tuner are connected by wire, DC power can be supplied from the TV tuner to the outdoor BS receiving antenna 1 or CS receiving antenna 2. is there. However, in the case of the wireless transmission system shown in FIG. 8, since direct current power cannot be supplied from the TV tuner to the BS receiving antenna 1 or the CS receiving antenna 2, the BS receiving antenna 1 or the CS receiving antenna is separately provided. A means for supplying DC power to 2 is required.
[0007]
SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a microwave / millimeter wave transmission device in which wiring for supplying DC power to an outdoor broadcast wave receiving antenna and an indoor up converter is easy.
[0008]
[Means for Solving the Problems]
In order to achieve the above object, the microwave / millimeter wave transmission device of the present invention includes an indoor transmission device that transmits a broadcast wave received by the broadcast wave reception device to an up-conversion device installed on an indoor wall surface. A DC voltage superimposing device is provided to superimpose a DC voltage on the broadcast wave input via the connected antenna terminal . Therefore, a special path for supplying DC voltage from an outlet or the like placed at the bottom of the indoor wall to the broadcast wave receiving means such as an outdoor broadcast wave receiving antenna and the up-converting means installed at the top of the indoor wall is provided. It is not necessary and wiring becomes easy.
[0009]
Further, the DC voltage superimposing device is connected to an antenna terminal installed at the lower part of the wall surface indoors. By the way, an antenna terminal connected to a normally outdoor broadcast wave receiving antenna with a cable is provided at the lower part of the inner wall of a general household. Therefore, by connecting the DC voltage superimposing device to the antenna terminal, it becomes possible to use an existing antenna cable for supplying DC voltage to the broadcast wave receiving means, and wiring becomes easier.
[0010]
Furthermore, the DC voltage superimposer is provided with an amplifying means for adjusting the gain of the broadcast wave manually or automatically. Therefore, the broadcast wave amplified in advance to the voltage of the broadcast wave required by the up-conversion means is supplied to the up-conversion means. For this reason, it is not necessary to provide the amplifying means for the input broadcast wave in the up-conversion means, the circuit configuration is simplified and the size is reduced.
[0011]
Furthermore, the DC voltage superimposing device is provided with power limiting means for limiting the upper limit value of the power of the broadcast wave to a predetermined value. Therefore, a broadcast wave that is limited in advance to a power that does not damage the up-conversion unit is supplied to the up-conversion unit. Therefore, it is not necessary to provide power limiting means for input broadcast waves in the up-conversion means, and the circuit configuration is simplified and the size is reduced.
[0012]
Furthermore, the DC voltage superimposing device is provided with band limiting means for limiting the band of the broadcast wave. Therefore, a broadcast wave from which unnecessary signals that are not required by the up-conversion unit are removed in advance is supplied to the up-conversion unit. For this reason, it is not necessary to provide band limiting means for input broadcast waves in the up-conversion means, the circuit configuration is simplified and the size is reduced.
[0013]
Further, in the microwave / millimeter wave transmission apparatus of one embodiment, the direct current voltage superimposing device is a direct current having different voltages on the upstream side and the downstream side in the broadcast wave transmission direction than the direct current voltage superimposing device in the wired transmission means. The voltage is superimposed. Therefore, the upstream broadcast wave receiving means and the downstream up-conversion means are supplied with a DC voltage required by each. Therefore, it is not necessary to provide a voltage conversion circuit in the broadcast wave receiving means and the up-converting means, and the circuit configuration of the broadcast wave receiving means and the up-converting means is simplified .
[0014]
Also, in the microwave and millimeter wave transmission device 1 embodiment, the DC voltage superimposing unit, a broadcast wave generator and a broadcast wave output terminal generates a broadcast wave does not overlap the DC voltage The broadcast wave on which the DC voltage is not superimposed is output from the broadcast wave output terminal. Therefore, the method of transmitting the broadcast wave on which the DC voltage is not superimposed to a TV tuner or the like by a cable and the method of transmitting the broadcast wave up-converted from the up-conversion means to the TV tuner or the like simultaneously are performed. It becomes possible.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail with reference to the illustrated embodiments.
[0016]
<First embodiment>
FIG. 1 is a schematic configuration diagram of a microwave / millimeter wave transmission apparatus according to the present embodiment. In FIG. 1, 11 is a BS receiving antenna as the broadcast wave receiving means, 12 is a first IF cable as the wired transmission means, 13 is a second IF cable as the wired transmission means, 14 is a DC voltage superimposer, 15 Is an AC adapter, 16 is an antenna terminal, and 17 is an AC outlet. Reference numeral 18 denotes a millimeter wave transmitter as the up-conversion means, 19 denotes a millimeter wave receiver, and 20 denotes a television receiver.
[0017]
The BS broadcast receiving antenna 11 and the antenna terminal 16 are connected by a first IF cable 12 disposed inside the wall of the house. Further, the first IF cable 12 and the second IF cable 13 are connected via a DC voltage superimposing device 14 inserted into the antenna terminal 16. In this DC voltage superimposing unit 14, a DC voltage of 15 V is superimposed on the first IF cable 12 side, a DC voltage of 5 V is superimposed on the second IF cable 13 side, and the IF signal is transmitted from the first IF cable 12 to the second IF cable 13. It has a passing structure.
[0018]
In the millimeter wave transmitter 18, the IF signal on which the 5V DC voltage from the second IF cable 13 is superimposed is separated into an IF signal and a 5V DC voltage. Then, necessary current / voltage is supplied to each block by a power supply circuit (not shown), and the IF signal is up-converted into a millimeter wave signal and then released to the space. Thus, the millimeter wave signal emitted to the space is received by the receiver 19, down-converted to the original IF signal, and sent to the TV receiver 20 and the tuner.
[0019]
Next, a specific circuit configuration of the DC voltage superimposing unit 14 will be described. FIG. 2 is a circuit diagram showing an example of the configuration of the DC voltage superimposing unit 14. The DC voltage superimposing device 14 includes a terminal 21, a jack 22, choke coils 23 and 24, capacitors 25 to 27, and a 15V / 5V converter 28.
[0020]
The jack 22 has a shape in which a pin 29 of the AC adapter 15 is inserted and can be connected to each other. The terminal 21 has a shape that can be connected to the antenna terminal 16 by being inserted into the antenna terminal 16 on the wall surface. The IF signal input from the terminal 21 passes through the capacitor 27 and is transmitted to the millimeter wave transmitter 18, but does not pass through the choke coils 23 and 24. On the other hand, the DC voltage of 15 V supplied from the AC adapter 15 is subjected to removal of unnecessary noise by the capacitor 25, and 15 V is directly applied to the antenna terminal 16 and the first IF cable 12 side via the choke coil 23. Further, the voltage is stepped down to a DC voltage of 5V by the 15V / 5V converter 28, unnecessary noise is removed by the capacitor 26, and 5V is applied to the second IF cable 13 side via the choke coil 24.
[0021]
Next, a specific circuit configuration of the millimeter wave transmitter 18 will be described. FIG. 3 is a circuit diagram showing an example of the configuration of the millimeter wave transmitter 18. The millimeter wave transmitter 18 includes an IF signal filter 31, an IF signal amplifier 32, an even harmonic mixer 33, a millimeter wave filter 34, a millimeter wave amplifier 35, local oscillation signal filters 36 and 38, a 16 multiplier 37, The phase-locked oscillator 39, the millimeter wave antenna 40, the DC cut capacitor 41, the choke coil 42, the bypass capacitor 43, and the power supply circuit 44 are configured.
[0022]
An IF signal and a DC voltage of 5V are transmitted to the millimeter wave transmitter 18 through the second IF cable 13. However, the DC voltage of 5V cannot pass through the DC cut capacitor 41 and is applied to the power supply circuit 44 via the choke coil 42. At that time, the noise component superimposed on the DC voltage is removed by the bypass capacitor 43. The power supply circuit 44 supplies DC power to a circuit block including active elements such as an IF signal amplifier 32, a millimeter wave amplifier 35, a 16 multiplier 37, and a phase locked oscillator 39 by a power regulator (not shown). To do.
[0023]
On the other hand, an IF signal having a frequency of 1.035 GHz to 1.335 GHz from the second IF cable 13 passes through the DC cut capacitor 41, the IF signal filter 31, and the IF signal amplifier 32, and then enters the even harmonic mixer 33. Entered. The 1.844 GHz sine wave generated by the phase-locked oscillator 39 becomes a 29.505 GHz local oscillation signal by the 16 multiplier 37 and the local oscillation signal filters 36 and 38 and is input to the even harmonic mixer 33. Is done. Then, in the even harmonic mixer 33, the IF signal is mixed with the local oscillation signal to become a millimeter wave signal having a frequency of 60.045 GHz to 60.345. Then, after passing through the millimeter wave filter 34 and the millimeter wave amplifier 35, the millimeter wave antenna 40 radiates it into space.
[0024]
With the above configuration, the cable connected to the millimeter wave transmitter 18 is only one second IF cable 13 between the antenna terminal 16 and wiring is easy. Moreover, since direct current power is supplied to the external BS broadcast receiving antenna 11 from the direct current voltage superimposer 14 inserted into the antenna terminal 16 on the inner wall via the first IF cable 12, a separate direct current power supply source is provided. There is no need to provide it.
[0025]
As described above, in the present embodiment, the AC adapter 15 is inserted into the AC outlet 17 provided on the inner wall of the house, while the DC voltage superimposer 14 is inserted into the antenna terminal 16, A DC voltage of 15 V is supplied from the AC adapter 15. Then, the DC voltage superimposing unit 14 superimposes the DC voltage of 15V from the AC adapter 15 on the first IF cable 12 side as it is. Further, a 15V DC voltage from the AC adapter 15 is stepped down to a 5V DC voltage by the built-in 15V / 5V converter 28 and superimposed on the second IF cable 13 side. Therefore, direct-current power is supplied to the BS broadcast receiving antenna 11 via the first IF cable 12, and there is no need to provide a separate direct-current power supply source.
[0026]
On the other hand, the millimeter wave transmitter 18 separates the IF signal on which the DC voltage of 5V from the second IF cable 13 is superimposed into an IF signal and a DC voltage of 5V. Then, a 5V DC voltage is supplied to each block by a built-in power supply circuit 44. Accordingly, the millimeter wave transmitter 18 can be supplied with the IF signal and the DC power through the single second IF cable 13, and wiring becomes easy.
[0027]
In addition, in the DC voltage superimposing unit 14, the power supply voltage 15V required for the outdoor BS broadcast receiving antenna 11 and the power supply voltage 5V required for up-conversion of the indoor millimeter wave transmitter 18 are generated in advance. ing. Therefore, the power supply circuit in the broadcast wave receiving antenna or the indoor upconverter can be simplified.
[0028]
In the above embodiment, the case where the BS receiving antenna 11 is used as an outdoor broadcast wave receiving antenna has been described as an example. However, the present invention is not limited to this, and a CS receiving antenna or a terrestrial receiving antenna may be used, and the present invention is applicable even when there are a plurality of these antennas.
[0029]
<Second Embodiment>
The present embodiment relates to a configuration different from the first embodiment of the DC voltage superimposing device 14 in FIG.
[0030]
FIG. 4 shows a circuit diagram of the DC voltage superimposing device 14 in the present embodiment. The DC voltage superimposing device 14 includes a terminal 51, a jack 52, choke coils 53 and 54, capacitors 55 to 58, a 15V / 5V converter 59, an amplifier 60 as the amplification means, and a power supply regulator 61. It is configured.
[0031]
The present embodiment is different from the first embodiment in that an amplifier 60 and a power supply regulator 61 are provided, and the other parts function in the same manner as in the first embodiment. Therefore, detailed description is omitted.
[0032]
The amplifier 60 provided between the capacitor 57 and the capacitor 58 amplifies the IF signal input from the terminal 51. At this time, a bias voltage necessary for operating the amplifier 60 is supplied to the amplifier 60 after being converted into a necessary voltage by the power supply regulator 61 from the 5V side of the 15V / 5V converter 59, for example. Here, the amplifier 60 may be a constant gain amplifier, an amplifier having a function of manually adjusting the gain, or an amplifier having a function of automatically adjusting the gain so as to obtain a desired constant output. Good. The DC voltage superimposing device 14 may be provided with a function of detecting a part of the output signal and displaying the output power value.
[0033]
When an amplifier having a function of manually adjusting the gain is used as the amplifier 60, a lamp indicating whether or not the output level is optimum may be added to the DC voltage superimposing device 14. For example, assuming that the optimum output level is −4 dBm, when the output power is in the range of −3.5 dBm to −4.5 dBm, the green light-emitting diode is turned on and −3.5 dBm or less or −4. In the case of 5 dBm or more, the red light emitting diode is turned on. By adopting such a configuration, the operator only has to adjust the gain of the amplifier 60 so that the green light emitting diode is lit, and an optimum output level can be easily obtained.
[0034]
As described above, in the present embodiment, the amplifier 60 for amplifying the IF signal from the BS broadcast receiving antenna 11 input from the terminal 51 is provided in the DC voltage superimposing unit 14. Therefore, it is not necessary to provide an IF signal amplifier in the millimeter wave transmitter 18 installed on the indoor wall, the circuit configuration of the millimeter wave transmitter 18 can be simplified, and the size of the millimeter wave transmitter 18 can be reduced.
[0035]
<Third Embodiment>
The present embodiment relates to a configuration different from the first and second embodiments of the DC voltage superimposing device 14 in FIG.
[0036]
FIG. 5 shows a circuit diagram of the DC voltage superimposing device 14 in the present embodiment. The DC voltage superimposing device 14 includes a terminal 71, a jack 72, choke coils 73 and 74, capacitors 75 to 79, a 15V / 5V converter 80, an amplifier 81, a power supply regulator 82, and the power limiting means. And the limiter 83.
[0037]
The difference of this embodiment from the second embodiment is that a limiter 83 and a capacitor 79 are provided, and other parts are the same as those in the first and second embodiments. Therefore, detailed description is omitted.
[0038]
The IF signal input from the terminal 71 is amplified by the amplifier 81 and input to a limiter 83 provided between the capacitor 78 and the capacitor 79. Here, when the power level of the IF signal input to the limiter 83 is small, the power of the signal output from the limiter 83 is proportional to the input power. However, when the power level of the input IF signal exceeds a predetermined level, the output power of the limiter 83 is constant. For example, when the maximum output of the limiter 83 is −5 dBm and the gain of the amplifier 81 is 20 dB, the output of the limiter 83 becomes a constant value of −5 dBm even if the input power becomes −25 dBm or more.
[0039]
By adopting such a configuration, even if excessive power is input to the terminal 71, the output power of the IF signal of the DC voltage superimposing device 14 can be suppressed to a constant level. For this reason, it is possible to prevent the millimeter wave transmitter 18 connected to the subsequent stage of the DC voltage superimposing device 14 from being damaged, or to prevent the millimeter wave transmitter 18 from emitting a millimeter wave of a predetermined power or higher. is there.
[0040]
As described above, in the present embodiment, the DC voltage superimposing unit 14 is provided with the limiter 83 that makes the output power constant when the power level of the IF signal input from the terminal 71 is equal to or higher than a predetermined level. ing. Therefore, it is not necessary to provide a limiter for input signals in the millimeter wave transmitter 18 installed on the indoor wall, the circuit configuration of the millimeter wave transmitter 18 can be simplified, and the size of the millimeter wave transmitter 18 can be reduced. .
[0041]
<Fourth embodiment>
The present embodiment relates to a configuration different from the first to third embodiments of the DC voltage superimposing device 14 in FIG.
[0042]
FIG. 6 shows a circuit diagram of the DC voltage superimposing device 14 in the present embodiment. The DC voltage superimposing device 14 includes a terminal 91, a jack 92, choke coils 93 and 94, capacitors 95 to 98, a 15V / 5V converter 100, an amplifier 101, a power supply regulator 102, a limiter 103, and the above. It comprises a band pass filter 105 as band limiting means.
[0043]
The difference of this embodiment from the third embodiment is that a band pass filter 105 is provided in the subsequent stage of the limiter 103 in place of the capacitor, and the other parts are the first to third embodiments. Since it functions in the same manner as the embodiment, detailed description thereof is omitted.
[0044]
In the present embodiment, by adding the band-pass filter 105, unnecessary signals outside the band sent to the millimeter wave transmitter 18 are reduced, so that unnecessary wave radiation from the millimeter wave transmitter 18 is reduced. It is reduced. In FIG. 6, the band pass filter 105 is installed at the subsequent stage of the limiter 103, but is not limited to this position. For example, it may be between the amplifier 101 and the limiter 103 or before the amplifier 101.
[0045]
As described above, in the present embodiment, the DC voltage superimposing device 14 is provided with the band-pass filter 105 that reduces unnecessary signals that are sent to the millimeter wave transmitter 18 out of the band. Therefore, it is not necessary to provide a filter for IF signals in the millimeter wave transmitter 18 installed on the indoor wall, the circuit configuration of the millimeter wave transmitter 18 can be simplified, and the size of the millimeter wave transmitter 18 can be reduced. As a result, the installation of the millimeter wave transmitter 18 is facilitated.
[0046]
<Fifth embodiment>
The present embodiment relates to a configuration different from the first to fourth embodiments of the DC voltage superimposing device 14 in FIG.
[0047]
FIG. 7 shows a circuit diagram of the DC voltage superimposing device 14 in the present embodiment. The DC voltage superimposing device 14 includes a terminal 111, a jack 112, choke coils 113 and 114, capacitors 115 to 117, a 15V / 5V converter 118, a distributor 119, and a capacitor 120 as the broadcast wave generating means. And output terminals 121 and 122.
[0048]
The present embodiment is different from the first embodiment in that a distributor 119, a capacitor 120, and output terminals 121 and 122 are provided, and other parts are the same as those in the first embodiment. Since it works in the same way as in the case, detailed description is omitted.
[0049]
The IF signal on which the DC voltage 5V is superimposed is divided into two by the distributor 119. One of the two divided signals is output from the output terminal 122 to the millimeter wave transmitter 18 as it is. On the other hand, the other of the two divided signals is an IF signal with no DC voltage superimposed via the capacitor 120 and is output from the output terminal 121 as the broadcast wave output terminal.
[0050]
By adopting such a configuration, an IF signal and a DC voltage of 5 V are supplied from the output terminal 122 to the millimeter wave transmitter 18, and the IF signal is supplied from the output terminal 121 to a tuner or video (not shown) via a cable. Can only supply. Therefore, for example, an IF signal is output from the output terminal 121 via a cable to a main television (not shown) installed near the antenna terminal 16 (see FIG. 1) on the inner wall of the house. On the other hand, in the sub-television 20 (see FIG. 1) arranged away from the antenna terminal 16, the millimeter wave transmitter 18 connected to the output terminal 122 via the second IF cable 13 is used to increase the millimeter wave signal. Usage such as transmitting the converted IF signal becomes possible.
[0051]
Moreover, the DC voltage superimposing device 14 in the present embodiment can be used by being embedded in an indoor inner wall in advance.
[0052]
【The invention's effect】
As is clear from the above, the microwave / millimeter wave transmission device of the present invention uses indoors as a wired transmission means for transmitting broadcast waves received by the broadcast wave receiving means to up-conversion means installed on the indoor wall surface. A broadcast wave receiving means such as an outdoor broadcast wave receiving antenna is provided with a DC voltage superimposing device that is arranged at the lower part of the wall and superimposes a DC voltage on the broadcast wave input through the connected antenna terminal. A DC voltage can be supplied to an up-conversion unit such as a millimeter wave transmitter installed on the upper wall surface of the room by using a wired transmission unit originally necessary. Therefore, a special path for supplying a DC voltage to the broadcast wave receiving means and the up-converting means is not required, and wiring can be facilitated.
[0053]
Furthermore, the above DC voltage superimposing unit, the amplifying means to said broadcast wave, is provided with the power limiting means and band limiting means, amplification means for inputting a broadcast wave in the up-conversion unit, a power limiting means or band limiting means There is no need to provide it. Therefore, the circuit configuration of the up-conversion means can be simplified and the size can be reduced.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of a microwave / millimeter wave transmission apparatus according to the present invention.
2 is a circuit diagram showing an example of a configuration of a DC voltage superimposing device in FIG. 1; FIG.
3 is a circuit diagram showing an example of a configuration of a millimeter wave transmitter in FIG. 1. FIG.
FIG. 4 is a circuit diagram of a DC voltage superposition device different from FIG.
5 is a circuit diagram of a DC voltage superpositioner different from those in FIGS. 2 and 4. FIG.
6 is a circuit diagram of a DC voltage superpositioner different from those in FIGS. 2, 4 and 5. FIG.
7 is a circuit diagram of a DC voltage superpositioner different from those in FIGS. 2 and 4 to 6; FIG.
FIG. 8 is a diagram illustrating a configuration of a conventional millimeter-wave image transmission wireless facility.
[Explanation of symbols]
11 ... BS receiving antenna,
12 ... 1st IF cable,
13 ... 2nd IF cable,
14: DC voltage superimposer,
15 ... AC adapter,
16: Antenna terminal,
17 ... AC outlet,
18 ... Millimeter wave transmitter,
19: Millimeter wave receiver,
20 ... TV receiver,
21, 51, 71, 91, 111 ... terminals,
22,52,72,92,112 ... Jack,
23, 24, 42, 53, 54, 73, 74, 93, 94, 113, 114 ... choke coil,
25-27,55-58,75-79,95-98,115-117,120 ... capacitor,
28, 59, 80, 100, 118 ... 15V / 5V converter,
31 ... IF signal filter,
32 ... IF signal amplifier,
33 ... even harmonic mixer,
34 ... Millimeter wave filter,
35 ... Millimeter wave amplifier,
36, 38 ... local oscillation signal filter,
37 ... 16 multiplier,
39: Phase-locked oscillator,
40 ... millimeter wave antenna,
41 ... DC cut capacitor,
43. Bypass capacitor,
44 ... power supply circuit,
60, 81, 101 ... amplifier,
61, 82, 102 ... power regulator,
83,103 ... limiter,
105: band pass filter,
119 ... distributor,
121, 122 ... Output terminals.

Claims (3)

Broadcast wave receiving means for receiving broadcast waves outdoors;
An up-conversion means that is installed on an upper wall surface indoors, and that up-converts the broadcast wave from the broadcast wave reception means into a microwave or a millimeter wave and emits it into space;
A wired transmission means for transmitting the broadcast wave received by the broadcast wave receiving means to the up-conversion means;
An antenna terminal installed at the lower part of the wall surface indoors and interposed in the wired transmission means
With
The aforementioned wire transmission means, is disposed on the wall surface lower in Indoor connected to the antenna terminal Rutotomoni, superimposed with a direct current voltage to the broadcast wave input through the antenna terminal, and manually the broadcast wave Alternatively , a DC voltage superimposing unit including an amplification unit that automatically adjusts the gain, a power limiting unit that limits the upper limit value of the broadcast wave power to a predetermined value, and a band limiting unit that limits the band of the broadcast wave is provided. Microwave and millimeter wave transmission device according to claim <br/> that it is. The microwave / millimeter wave transmission device according to claim 1,
The DC voltage superimposing unit is configured to superimpose a DC voltage having a different voltage on the upstream side and the downstream side in the transmission direction of the broadcast wave than the DC voltage superimposing unit in the wired transmission means. Microwave / millimeter wave transmitter. The microwave / millimeter wave transmission device according to claim 1,
The DC voltage superimposing device includes a broadcast wave generating means for generating a broadcast wave on which the DC voltage is not superimposed and a broadcast wave output terminal, and a broadcast wave on which the DC voltage is not superimposed from the broadcast wave output terminal. output to microwave and millimeter wave transmission device according to claim Rukoto.

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