JP2020127114A - Fm relay transmission device - Google Patents

Abstract

To provide a frequency modulation (FM) relay transmission device that makes only a relay transmitter connected to a pseudo antenna activate to enable checking (inspecting) the activation of the FM relay transmission device when FM broadcasting is suspended.SOLUTION: The FM relay transmission device outputs an instruction for forced connection of an intermediate frequency (IF) circuit to a No. 1 relay transmitter 2 and a No. 2 relay transmitter 3 from a switching controller 4, and can activate the relay transmitter connected to a pseudo antenna 6 only when a standby input is selected while shutting off the IF circuit of the relay transmitter connected to a transmitting antenna when the master station's broadcasting is suspended.SELECTED DRAWING: Figure 2

Description

The present invention relates to an FM relay transmission apparatus, and more particularly to an FM relay transmission apparatus capable of performing a start-up confirmation (inspection) work of the apparatus even during a period in which FM (Frequency Modulation) broadcasting from a master station is stopped. Regarding

[FM relay transmitter: FIG. 4]
The configuration of the FM relay transmitter will be described with reference to FIG. FIG. 4 is a schematic diagram of the configuration of the FM relay transmitter.
As shown in FIG. 4, the FM relay transmitter includes an input filter 1, a No. 1 FM relay transmitter 2, a No. 2 FM relay transmitter 3, a switching controller 4, an output filter 5, and a pseudo antenna 6. It has and.
That is, the FM relay transmitter of FIG. 4 is of a two-unit system including two FM relay transmitters 2 and 3.

The input filter 1 includes an input band pass filter (BPF: Band Pass Filter) and a two-way divider. An FM reception input signal is passed by the input BPF in a specific band, and an FM signal in that band is passed by the two-way divider. It is divided into two and is output to the No. 1 FM relay transmitter 2 and the No. 2 FM relay transmitter 3.

The No. 1 FM relay transmitter 2 and the No. 2 FM relay transmitter 3 internally convert the FM signal distributed from the input filter 1 into an intermediate frequency (IF: Intermediate Frequency) and then convert it into an FM signal for relay. Output to the switching controller 4.

The switching controller 4 outputs one (active) FM signal from the No. 1 FM relay transmitter 2 or No. 2 FM relay transmitter 3 to the output filter 5, and outputs the other (standby) to the pseudo antenna 6. Control to be performed.
FIG. 4 shows an example in which the FM signal from the No. 1 FM relay transmitter 2 is output to the output filter 5, and the FM signal from the No. 2 FM relay transmitter 3 is output to the pseudo antenna 6.
The switching controller 4 is configured to perform switching in response to a monitoring signal from the two FM relay transmitters 2 and 3 and an operation from the outside.

The output filter 5 includes an output BPF, passes an FM signal from the switching controller 4 in a specific band, and outputs the FM signal to the outside as an FM transmission output.
The pseudo antenna 6 is a dummy antenna.

[Constitution related to conventional switching control: FIG. 5]
Next, a configuration related to the conventional switching control will be described with reference to FIG. FIG. 5 is a block diagram of a conventional switching control.
As shown in FIG. 5, the configuration related to the conventional switching control includes a No. 1 FM relay transmitter 2', a No. 2 FM relay transmitter 3', and a switching controller 4'.

The No. 1 FM relay transmitter 2′ inputs the FM signal, detects the input of the FM signal, and outputs the presence/absence of the FM input detection to the switching controller 4′. The No. 2 FM relay transmitter 3′ also performs the same operation.
When the presence/absence of FM input detection is input from the No. 1 FM relay transmitter 2'and the No. 2 FM relay transmitter 3', the switching controller 4'for the FM relay transmitter without FM input detection Outputs AMP OFF control signal.

The FM relay transmitter that receives the AMP OFF control signal forcibly turns off the AMP (amplifier) of the FM relay transmitter.
Further, both FM relay transmitters perform AMP OFF control for the FM relay transmitter connected to the pseudo antenna 6 when there is no FM input detection or when standby off is selected.
The specific control in the FM relay transmitter will be described later.

[Internal circuit of conventional relay transmitter: FIG. 6]
Next, an internal circuit of a conventional FM relay transmitter (relay transmitter) will be described with reference to FIG. FIG. 6 is an internal circuit diagram of a conventional relay transmitter.
As shown in FIG. 6, the internal circuit diagram of the conventional relay transmitter 2'includes a reception conversion circuit (RX) 21, a voltage comparator 22, an IF circuit connection relay (RL) 23, a transistor 24, and a transmission circuit. A conversion circuit (TX) 25, a multistage amplifier circuit (AMP) 26, a connection switch 27, an FM input detection switch (SW) 28, and a power supply control circuit (PWR CONT) 29 are provided.

The operation of the internal circuit diagram of the conventional relay transmitter 2'will be described.
First, the case where the relay transmitter 2'has an FM signal input will be described.
When the FM signal is input to the relay transmitter 2 ′, it is converted to an intermediate frequency (IF) signal by the reception conversion circuit 21 and output to the connection switch 27, and the reception level voltage is output to the voltage comparator 22. ..

In the voltage comparator 22, the squelch level voltage connected to the “−” terminal is compared with the reception level voltage connected to the “+” terminal, and when the FM signal is input to the reception conversion circuit 21, the squelch level voltage is As a result, the reception level voltage becomes High (H). The output is input to the FM input detection SW 28, and the presence/absence of FM input detection is output to the switching controller 4′. Since the signal from the voltage comparator 22 is “H”, the presence of FM input detection (CLOSE) is output.

Further, since the output from the voltage comparator 22 is input to the base of the transistor 24 and the base input becomes H (FM input detection: present), the transistor 24 is turned on and current flows to the IF circuit connection relay 23. It operates, and the connection switch 27 is turned on (connected).
Then, the IF signal from the reception conversion circuit 21 is input to the transmission conversion circuit 25, converted into an FM signal and output to the multistage amplification circuit 26, and the multistage amplification circuit 26 outputs the amplified FM signal.

Next, the case where the FM signal is not input to the relay transmitter 2'will be described.
If the FM signal is not input to the reception conversion circuit 21, the reception level voltage of the voltage comparator 22 becomes lower than the squelch level voltage, and the output voltage becomes “L”.
Then, no (OPEN) is output to the switching controller 4'without FM detection.

Further, since the output voltage from the voltage comparator 22 becomes “L”, the transistor 24 is turned off, the current does not flow through the IF circuit connection relay 23, the transistor does not operate, and the connection switch 27 is turned off (disconnected). Therefore, the IF signal is not input to the transmission conversion circuit 25 and is not FM output from the multistage amplification circuit 26.

Furthermore, when the AMP OFF control signal is input from the switching controller 4′ to the power supply control circuit 29 of the relay transmitter 2′ and the control signal “CLOSE” of powering off the multi-stage amplifier circuit 26 is input, the power supply control circuit. 29 turns off the power supply of the multistage amplifier circuit 26.
Further, when the control signal “OPEN” for turning on the power of the multi-stage amplifier circuit 26 is input, the power supply control circuit 29 turns on the power of the multi-stage amplifier circuit 26.
As the AMP OFF control signal, "CLOSE" or "OPEN" is selected by a push button provided on the switching controller 4'.

[Logic system of conventional switching controller: FIG. 7]
Next, the logical system of the conventional switching controller will be described with reference to FIG. FIG. 7 is a logical system diagram of a conventional switching controller.
In the switching controller 4′, as shown in FIG. 7, FM input detection signals are input from the No. 1 relay transmitter and the No. 2 FM relay transmitter. In FIG. 7, a case where FM input detection not (OPEN) is input will be described.

When No. 1 reception is not performed (No FM input detection from No. 1 relay transmitter), when No. 2 reception is not performed (No FM input detection from No. 2 relay transmitter), the “H” signal is inverted OR (inverted) It is input to the OR circuit 41.
The output of the inverting OR circuit 41 becomes "L" when both inputs are "H", but the output becomes "H" in the case of other inputs.

When the No. 1 relay transmitter is connected to the FM output antenna (No. 1 antenna), “H” is output, and when not connected, “L” is output.
When the No. 2 relay transmitter is connected to the FM output antenna (No. 2 antenna), "H" is output, and when not connected, "L" is output.
Normally, either the No. 1 antenna or the No. 2 antenna is being connected.

Further, when the standby ON is selected by the switch for turning on/off the AMP 26 of the relay transmitter in the standby state provided in the switching controller 4', the "H" signal is output. This input "H" turns on the AMP 26 of the relay transmitter in standby. The standby-off "L" is to turn off the AMP 26 of the relay transmitter in standby.

The output of the inverting OR circuit 41 becomes “L” when both No. 1 reception and No. 2 reception are performed, the output is input to the inverting circuit 48, and the inverting output “H” is input to the on-delay timer 49. Broadcast pause is output after 10 seconds (10 seconds).
Therefore, if the No. 1 relay transmitter or the No. 2 relay transmitter has the FM input signal, the broadcasting is not suspended.
Further, the output from the inverting OR circuit 41 is input to the logical product (AND) circuits 42, 43, 44 and 45.

The AND circuits 42 to 45 output "L" when the output from the inverting OR circuit 41 is "L" (both No. 1 reception and No. 2 reception). In this state, the outputs from the exclusive OR circuits 46 and 47 are “H”, and “CLOSE” (AMP OFF/1 AMP OFF) is transmitted to the No. 1 relay transmitter by No. 2 relay transmission. "CLOSE" (AMP OFF/2 No. AMP OFF) is output to the machine.

When the output of the inverting OR circuit 41 is "H" (when receiving No. 1 or receiving No. 2 or both receiving), the No. 1 antenna is connected and the No. 2 antenna is not connected. In the case of “L” and the standby input is “H”, the AND circuits 42 and 45 output “H”, the AND circuits 43 and 44 output “L”, and the exclusive OR circuits 46 and 47 output. Becomes "L", and neither the No. 1 relay transmitter nor the No. 2 relay transmitter is turned off.
Even when the output of the inverting OR circuit 41 is “H”, the second antenna is connected “H”, the first antenna is not connected “L”, and the standby input is “H”, the same result as above is obtained. ..

When the output of the inverting OR circuit 41 is "H", the antenna 1 is connected "H", the antenna 2 is not connected "L", and the standby is off "L", the output of the AND circuit 42 is “H”, the outputs of the other AND circuits 43 to 45 are “L”, the output of the exclusive OR circuit 46 is “L”, the output of the exclusive OR circuit 47 is “H”, and the output for FM is output. Turn off the AMP 26 of the No. 2 relay transmitter not connected to the antenna.

When the output of the inverting OR circuit 41 is “H”, the second antenna is connected “H”, the first antenna is not connected “L”, and the standby is “L”, the output of the AND circuit 44 is "H", the outputs of the other AND circuits 42, 43, 45 are "L", the output of the exclusive OR circuit 47 is "L", the output of the exclusive OR circuit 46 is "H", and the FM output Turn off the power of the AMP 26 of the No. 1 relay transmitter not connected to the antenna.

[Related technology]
Incidentally, as related prior arts, Japanese Patent Laid-Open No. 2005-053662 “Wireless relay device setting method” (Patent Document 1), Japanese Patent Laid-Open No. 2008-177804 “Switch control device” (Patent Document 2), and Japanese Patent Laid-Open No. 2005 -210299 gazette "wireless relay system" (patent document 3) exists.

Patent Document 1 discloses that various settings are made from a management wireless communication terminal by using a downlink frequency of a wireless relay device.
Patent Document 2 discloses that switching control of a signal transmission path is performed without interrupting broadcasting when a transmitter used for relay fails.
Patent Document 3 discloses that a mode selector switch is provided at the output of the high-frequency reception unit to switch between the digital reception control unit and the analog reception control unit.

JP, 2005-053662, A JP, 2008-177804, A JP, 2005-210299, A

However, in the conventional FM relay transmission device, when there is no FM input to the relay transmitter, the relay transmitter cannot be activated, and the FM relay transmission is performed during the period when the FM broadcast from the master station is stopped. There is a problem in that it is not possible to confirm (check) the startup of the device.

It should be noted that Patent Documents 1 to 3 do not describe a configuration for performing a start confirmation (inspection) operation of the FM relay transmission device during a period in which FM broadcasting from the master station is stopped.

The present invention has been made in view of the above circumstances, and when the FM broadcasting is stopped, only the relay transmitter connected to the pseudo antenna is activated, and the activation confirmation (inspection) work of the FM relay transmission device is performed. It is an object of the present invention to provide an FM relay transmitter capable of performing the above.

The present invention for solving the above-mentioned problems of the conventional example is an FM relay transmitter having a plurality of relay transmitters and a switching controller for performing switching control of a plurality of relay wireless devices. , Of the multiple relay radios, the relay radio that outputs the forced connection instruction of the intermediate frequency circuit to the relay radio connected to the pseudo antenna and inputs the instruction of the forced connection is It is characterized by performing forced connection.

The present invention is characterized in that, in the above-mentioned FM relay transmitter, the relay wireless device, which has input a forced connection instruction, releases the power-off of the amplifier.

The present invention is characterized in that, in the FM relay transmitter, when the switching controller outputs an instruction to forcibly connect the intermediate frequency circuit, a standby input is set.

The present invention is characterized in that, in the above-mentioned FM relay transmitter, the relay wireless device performs a forced connection by forcibly operating the connection relay of the intermediate frequency circuit.

According to the present invention, the switching controller outputs an instruction for forcibly connecting the intermediate frequency circuit to the relay radio connected to the pseudo antenna among the plurality of relay radios, and inputs the instruction for forced connection Since the relay wireless device that is used is an FM relay transmitter that forcibly connects the intermediate frequency circuit, only the relay transmitter connected to the pseudo antenna is activated, and the FM broadcast from the master station is suspended In addition, there is an effect that the activation confirmation (inspection) work of the FM relay transmitter can be performed.

It is a block diagram concerning the switching control of this device. It is an internal circuit diagram of the relay transmitter of this device. It is a logic system diagram of a switching controller of this device. It is a schematic diagram of a configuration of an FM relay transmitter. It is a block diagram which concerns on the conventional switching control. It is an internal circuit diagram of the conventional relay transmitter. It is a logic system diagram of the conventional switching controller.

Embodiments of the present invention will be described with reference to the drawings.
[Outline of Embodiment]
The FM relay transmission apparatus (this apparatus) according to the embodiment of the present invention transmits an out-of-specification FM signal from the output terminal of the FM relay transmission apparatus to the transmission antenna when the FM broadcast from the master station is stopped. Do not output, and start only the relay transmitter connected to the pseudo antenna, so that the start confirmation (inspection) work of the FM relay transmitter during the period when the FM broadcast from the master station is stopped Is what you can do.

[This device]
This device basically has the configuration shown in FIG. 4, but in that, the specific configurations of the switching controller 4 and the FM relay transmitters 2 and 3 are different from the conventional configuration.

[Configuration relating to switching control of this device: FIG. 1]
Next, the configuration related to the switching control of this device will be described with reference to FIG. FIG. 1 is a block diagram of a configuration related to switching control of this device.
As shown in FIG. 1, the configuration related to the switching control of the present apparatus includes a No. 1 FM relay transmitter 2, a No. 2 FM relay transmitter 3, and a switching controller 4.

Here, a control line (a control line for transmitting an instruction for forced connection of an IF circuit, which will be described later) between the switching controller 4 and a unit of the two relay transmitters (in the device rack) is added for two lines each. To do. However, if wiring (one unused line for two systems) has already been connected to the empty terminals of the D-sub connector of the control line (bundle line) for each system, it is not necessary to add a control line between units. Is.

The No. 1 FM relay transmitter 2 inputs the FM signal, detects the input of the FM signal, and outputs the presence/absence of the FM input detection to the switching controller 4. The No. 2 FM relay transmitter 3 also performs the same operation.
The switching controller 4, when No FM input detection is simultaneously input from the No. 1 FM relay transmitter 2 and the No. 2 FM relay transmitter 3, causes the No. 1 FM relay transmitter 2 and the No. 2 FM relay transmitter 3 to operate. In response, the AMP OFF control signal is output.
The FM relay transmitter to which the AMP OFF control signal is input forcibly turns off the AMP (amplifier) of the FM relay transmitter.

Further, the switching controller 4 outputs an instruction to forcibly connect the IF circuit using the control lines added to the No. 1 FM relay transmitter 2 and the No. 2 FM relay transmitter 3.
The FM relay transmitter that has input the instruction to forcibly connect the IF circuit activates the relay that shuts off the IF circuit (IF circuit connection relay and connection switch), regardless of whether the AMP is started or stopped. Output FM signal out of specification.

[Internal circuit of relay transmitter of this device: Fig. 2]
Next, the internal circuit of the FM relay transmitter (relay transmitter) of this apparatus will be described with reference to FIG. FIG. 2 is an internal circuit diagram of the relay transmitter of this device.
As shown in FIG. 2, the internal circuit diagram of the relay transmitter 2 of the present complaint is, as shown in FIG. 2, a reception conversion circuit (RX) 21, a voltage comparator 22, an IF circuit connection relay (RL) 23, a transistor 24, and a transmission conversion circuit. A circuit (TX) 25, a multistage amplifier circuit (AMP) 26, a connection switch 27, an FM input detection switch (SW) 28, and a power supply control circuit (PWR CONT) 29 are provided.

Then, inside the two relay transmitters, wiring is added to the rear surface of the D-sub connector, and a terminal for control contact input “IF circuit forced connection” is added.
Specifically, one wiring is connected to the point a on the collector side of the transistor 24, the other wiring is connected to the point b on the emitter side of the transistor 24, and the two wirings are connected to the IF circuit forced connection terminal.

If the voltage of "H" is not input to the base of the transistor 24, the transistor 24 is not turned on, the IF line connection relay 23 does not operate, and the changeover switch 27 remains unconnected.
However, if a point a on the collector side and a point b on the emitter side of the transistor 24 are forcibly connected by using the IF circuit forcible connection terminal according to the instruction of the IF circuit forcible connection from the switching controller 4, a current flows, The IF line connection relay 23 operates and the changeover switch 27 enters the connected state.
As a result, even if there is no FM signal, the IF signal from the reception conversion circuit 21 is output to the AMP 26 via the transmission conversion circuit 25, and can be amplified by the AMP 26 to output the FM signal.

The operation of the internal circuit diagram of the relay transmitter 2 of this device will be described.
First, the case where the relay transmitter 2 receives an FM signal will be described.
When the FM signal is input to the relay transmitter 2, the reception conversion circuit 21 converts the FM signal into an intermediate frequency (IF) signal, which is output to the connection switch 27 and the reception level voltage to the voltage comparator 22.

In the voltage comparator 22, the squelch level voltage connected to the “−” terminal is compared with the reception level voltage connected to the “+” terminal, and when the FM signal is input to the reception conversion circuit 21, it is compared with the squelch level voltage. As a result, the reception level voltage becomes High (H). The output is input to the FM input detection SW 28, and the presence/absence of FM input detection is output to the switching controller 4. Since the signal from the voltage comparator 22 is “H”, the presence of FM input detection (CLOSE) is output.

Further, since the output from the voltage comparator 22 is input to the base of the transistor 24 and the base input is H (FM input detection: present), the transistor 24 is turned on and a current flows through the IF circuit connection relay 23. It operates, and the connection switch 27 is turned on (connected).
Further, one wiring of the IF circuit forced connection terminal is connected to the point a on the collector side of the transistor 24, and the other wiring of the IF circuit forced connection terminal is connected to the point b on the emitter side of the transistor 24. The IF circuit connection relay 23 is forcibly operated by connecting the point a and the point b at the IF circuit compulsory connection terminal.
Then, the IF signal from the reception conversion circuit 21 is input to the transmission conversion circuit 25, converted into an FM signal and output to the AMP 26, and the AMP 26 outputs the amplified FM signal.

Next, the case where the FM signal is not input to the relay transmitter 2 will be described.
If the FM signal is not input to the reception conversion circuit 21, the reception level voltage of the voltage comparator 22 becomes lower than the squelch level voltage, and the output voltage becomes “L”.
Then, no (OPEN) is output to the switching controller 4 without the FM input detection.

Further, since the output voltage from the voltage comparator 22 becomes “L”, the transistor 24 is turned off, the current does not flow through the IF circuit connection relay 23, the transistor does not operate, and the connection switch 27 is turned off (disconnected). Therefore, the IF signal is not input to the transmission conversion circuit 25 and is not FM output from the AMP 26.

However, when the IF circuit compulsory connection instruction is received from the switching controller 4 at the IF circuit compulsory connection terminal, the point a on the collector side and the point b on the emitter side of the transistor 24 are compulsorily connected and there is no FM input. Nevertheless, the IF line connection relay 23 can be operated and the connection switch 27 can be connected.

Further, when the AMP OFF control signal is input from the switching controller 4 to the power supply control circuit 29 of the relay transmitter 2 and the “CLOSE” control signal for powering off the AMP 26 is input, the power supply control circuit 29 causes the AMP 26 to turn off. Turn off the power.
Further, when the control signal of "OPEN" for turning on the power of the AMP 26 is input, the power control circuit 29 turns on the power of the AMP 26.
As the AMP OFF control signal, "CLOSE" or "OPEN" is selected by a push button provided in the switching controller 4.

[Logic system of switching controller of this device: Fig. 3]
Next, the logical system of the switching controller of this device will be described with reference to FIG. FIG. 3 is a logical system diagram of the switching controller of this device.
In the switching controller 4, as shown in FIG. 3, FM input detection signals are input from the No. 1 relay transmitter and the No. 2 FM relay transmitter. In FIG. 3, description will be made on the case where no FM input detection (OPEN) is input.

When No. 1 reception is not performed (No FM input detection from No. 1 relay transmitter), when No. 2 reception is not performed (No FM input detection from No. 2 relay transmitter), the “H” signal is inverted OR (inverted) It is input to the OR circuit 41.
The output of the inverting OR circuit 41 becomes "L" when both inputs are "H", but the output becomes "H" in the case of other inputs.

When the No. 1 relay transmitter is connected to the FM output antenna (No. 1 antenna), “H” is output, and when not connected, “L” is output.
When the No. 2 relay transmitter is connected to the FM output antenna (No. 2 antenna), "H" is output, and when not connected, "L" is output.
Normally, either the No. 1 antenna or the No. 2 antenna is being connected.

Further, when the standby input is selected by the switch for turning on/off the AMP 26 of the relay transmitter in the standby state provided in the switching controller 4, the “H” signal is output. This input "H" turns on the AMP 26 of the relay transmitter in standby. The standby-off "L" is to turn off the AMP 26 of the relay transmitter in standby.

The output of the inverting OR circuit 41 becomes “L” when both No. 1 reception and No. 2 reception are performed, the output is input to the inverting circuit 48, and the inverting output “H” is input to the on-delay timer 49. Broadcast pause is output after 10 seconds (10 seconds).
Therefore, if the No. 1 relay transmitter or the No. 2 relay transmitter has the FM input signal, the broadcasting is not suspended.

A logical product circuit (AND) 51 to 54 is newly provided as a feature of this device.
The AND circuit 51 receives a signal indicating that the No. 2 antenna is connected (the No. 2 FM relay transmitter is connected to the antenna), a standby signal, and a signal from the on-delay timer 49. When all of these signals are "H", an instruction to forcibly connect the IF circuit is output to the No. 1 relay transmitter.
The AND circuit 52 receives a signal indicating that the 1st antenna is connected (the 1st FM relay transmitter is connected to the antenna), a standby signal, and a signal from the on-delay timer 49. When all of these signals are "H", an instruction to forcibly connect the IF circuit is output to the No. 2 relay transmitter.

The AND circuit 53 is supplied with a signal indicating that the No. 2 antenna is connected, a standby signal and a signal from the on-delay timer 49. When all of these signals are "H", "H" is output to the exclusive OR circuit 46.
The AND circuit 54 is supplied with a signal indicating that the No. 1 antenna is connected, a standby signal and a signal from the on-delay timer 49. When all of these signals are "H", "H" is output to the exclusive OR circuit 47.

Further, the output from the inverting OR circuit 41 is input to the logical product (AND) circuits 42, 43, 44 and 45.
The AND circuits 42 to 45 output "L" when the output from the inverting OR circuit 41 is "L" (both No. 1 reception and No. 2 reception).
Further, the AND circuit 53 outputs “H” if it is “H” during the connection of No. 2 antenna and is in the standby input “H”, and otherwise outputs “L”. Further, the AND circuit 54 has an output of "H" if it is "H" while the antenna No. 1 is connected and is in a standby state of "H", and otherwise outputs "L".

In this state (broadcast stop determination), the exclusive OR (exclusive OR) circuit 46 is connected to the 2nd antenna (the 2nd FM relay transmitter is connected to the antenna) "H" and the 1st antenna is connected to the dummy. (No. 1 FM relay transmitter is connected to the dummy antenna) When "L" is in standby input "H" (broadcast paused), the output becomes "L" and the No. 1 relay transmitter is "OPEN" (AMP ON) /No. 1 AMP ON) is output. That is, the AMP 26 of the No. 1 relay transmitter connected to the dummy antenna is not turned off when the No. 1 antenna is connected and the standby mode is entered.
Further, the exclusive OR circuit 47 is connected to No. 1 antenna (No. 1 FM relay transmitter is connected to antenna) "H" and connected to No. 2 antenna dummy (No. 2 FM relay transmitter is connected to dummy antenna). In the state of "L" for standby input "H", the output becomes "L" and "OPEN" (AMP ON/2 AMP ON) is output to the No. 2 relay transmitter. That is, when the No. 2 antenna is connected and the standby mode is entered, the AMP 26 of the No. 2 relay transmitter connected to the dummy antenna is not turned off.

When the output of the inverting OR circuit 41 is "H" (when receiving No. 1 or receiving No. 2 or both receiving), the No. 1 antenna is connected and the No. 2 antenna is not connected. In the case of “L” and the standby input is “H”, the outputs of the AND circuits 42 and 45 are “H”, and the outputs of the AND circuits 43, 44, 53 and 54 are “L”, and the exclusive OR circuit 46. , 47 output becomes “L”, and neither the No. 1 relay transmitter nor the No. 2 relay transmitter is turned off.
Even when the output of the inverting OR circuit 41 is “H”, the second antenna is connected “H”, the first antenna is not connected “L”, and the standby input is “H”, the same result as above is obtained. ..

When the output of the inverting OR circuit 41 is "H", the antenna 1 is connected "H", the antenna 2 is not connected "L", and the standby is off "L", the output of the AND circuit 42 is "H", the outputs of the other AND circuits 43 to 45, 53, 54 are "L", the output of the exclusive OR circuit 46 is "L", the output of the exclusive OR circuit 47 is "H", The power of the AMP 26 of the No. 2 relay transmitter not connected to the FM output antenna is turned off.

When the output of the inverting OR circuit 41 is “H”, the second antenna is connected “H”, the first antenna is not connected “L”, and the standby is “L”, the output of the AND circuit 44 is "H", the outputs of the other AND circuits 42, 43, 45, 53, 54 are "L", the output of the exclusive OR circuit 47 is "L", and the output of the exclusive OR circuit 46 is "H". Then, the power of the AMP 26 of the No. 1 relay transmitter which is not connected to the FM output antenna is turned off.

As shown in FIG. 3, in the processing of the logical system of the switching controller 4, the relay transmitter connected to the transmitting antenna is not controlled to forcibly connect the IF circuit when the broadcasting is stopped, and the AMP is turned off. The IF circuit forced connection control is performed for the relay transmitter connected to the pseudo antenna 6 only when the standby input is selected when the broadcasting is stopped, and the AMP OFF control is released.

[Effect of Embodiment]
According to the present device, the switching controller 4 outputs an instruction to forcibly connect the IF circuit to the No. 1 relay transmitter 2 and the No. 2 relay transmitter 3 and is connected to the transmission antenna during the broadcasting suspension of the master station. The relay transmitter connected to the pseudo antenna 6 can be activated only when the standby input is selected while shutting off the IF circuit of the relay transmitter, and the activation confirmation (inspection) work of the FM relay transmitter can be performed easily. There is an effect that can.

INDUSTRIAL APPLICABILITY The present invention provides an FM relay transmission device capable of activating only a relay transmitter connected to a pseudo antenna and performing start confirmation (inspection) work of the FM relay transmission device when FM broadcasting is stopped. It is suitable.

1... Input filter, 2, 2'... No. 1 FM relay transmitter, 3, 3'... No. 2 FM relay transmitter, 4, 4'... Switching controller, 5... Output filter, 6... Pseudo antenna, 21... Reception conversion circuit (RX), 22... Voltage comparator, 23... IF circuit connection relay (RL), 24... Transistor, 25... Transmission conversion circuit (TX), 26... Multistage amplifier circuit (AMP), 27... Connection switch, 28... FM input detection switch (SW), 29... Power supply control circuit (PWR CONT), 41... Inversion OR circuit (inversion OR circuit), 42-45, 51-54... AND circuit, 46, 47... Exclusive logic Sum circuit (exclusive OR circuit), 48... Inversion circuit, 49... On-delay timer

Claims (4)

An FM relay transmitter having a plurality of relay transmitters, and a switching controller for controlling switching of the plurality of relay radios,
The switching controller outputs an instruction to forcibly connect the intermediate frequency circuit to the relay radio connected to the pseudo antenna among the plurality of relay radios,
The FM relay transmitter, wherein the relay wireless device that has input the forced connection instruction performs forced connection of the intermediate frequency circuit. The FM relay transmitter according to claim 1, wherein the relay wireless device that has input the instruction for forced connection releases the power off of the amplifier. The FM relay transmitter according to claim 1 or 2, wherein the switching controller is set to standby when it outputs an instruction to forcibly connect the intermediate frequency circuit. The FM relay transmitter according to any one of claims 1 to 3, wherein the relay radio makes a forced connection by forcibly operating a connection relay of the intermediate frequency circuit.

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