JP2018166327A - Repeater device, method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a repeater device that can synchronize a radio signal transmitted from a base station and a radio signal transmitted via its own device without a demodulation IC. A repeater device can communicate with a radio device that converts an optical signal related to a downlink signal transmitted from a base station into a radio signal and transmits the radio signal. The repeater device includes a detection unit, a signal conversion unit, a signal processing unit, and a conversion unit. The detector detects a downlink signal transmitted from the base station. The signal conversion unit converts the detected downlink signal into a digital signal. The signal processing unit outputs a pulse signal based on the level of the digital signal. The conversion unit converts a downlink signal transmitted from the base station into the optical signal according to the output of the pulse signal, and outputs the optical signal to the radio apparatus. [Selection] Figure 2

Description

  Embodiments described herein relate generally to a repeater device, a method used in the repeater device, and a program.

  The mainstream of repeater devices used in communications using the TDD (Time Division Duplex) system currently being serviced in Japan is wirelessly connected to a base station. In the TDD scheme, the radio signal output from the repeater device needs to be synchronized with the radio signal transmitted from the base station used in the peripheral area. In order to synchronize the radio signal to be output with the radio signal from the base station, the repeater device extracts timing from the radio signal transmitted from the base station. And a repeater apparatus controls the timing which retransmits the received radio signal based on the extracted timing.

  By the way, when a repeater apparatus receives a radio signal transmitted from a base station, the radio signal can be subjected to a plurality of fluctuations due to interference waves, fading multipath, and the like in a propagated space. The repeater device needs to demodulate the radio signal in order to accurately extract the timing from the received radio signal. Therefore, the repeater device must mount an expensive demodulation IC inside the device.

Japanese translation of PCT publication No. 2008-508781

  As described above, the repeater apparatus needs to include a demodulation IC in order to synchronize the radio signal transmitted from the base station and the radio signal transmitted via the own apparatus.

  Therefore, an object of the present invention is to provide a repeater device that can synchronize a radio signal transmitted from a base station and a radio signal transmitted via its own device without a demodulation IC, and a method used in this repeater device And providing a program.

  According to the embodiment, the repeater apparatus can communicate with a radio apparatus that converts an optical signal related to a downlink signal transmitted from a base station into a radio signal and transmits the radio signal. The repeater device includes a detection unit, a signal conversion unit, a signal processing unit, and a conversion unit. The detector detects a downlink signal transmitted from the base station. The signal conversion unit converts the detected downlink signal into a digital signal. The signal processing unit outputs a pulse signal based on the level of the digital signal. The conversion unit converts a downlink signal transmitted from the base station into the optical signal according to the output of the pulse signal, and outputs the optical signal to the radio apparatus.

It is a block diagram which shows the function structure of the repeater system which concerns on this embodiment. It is a block diagram which shows the function structure of the master unit shown by FIG. It is a figure which shows the protection function with which the detection part shown by FIG. 2 is provided. It is a block diagram which shows the function structure of the signal processing part shown by FIG. 3 is a flowchart showing an operation when the master unit shown in FIG. 2 generates a timing signal. It is a figure which shows the signal produced | generated within the master unit shown by FIG. It is a block diagram which shows the other function structure of the signal processing part shown by FIG. It is a block diagram which shows the other function structure of the signal processing part shown by FIG.

  Hereinafter, embodiments will be described with reference to the drawings.

  FIG. 1 is a block diagram illustrating an example of a functional configuration of a repeater system according to the present embodiment. The repeater system shown in FIG. 1 includes a master unit 10 that is a first repeater device according to the present invention and a remote unit 20 that is a second repeater device. The master unit 10 is connected to the base station 30 via a coaxial cable. The master unit 10 is connected to the remote unit 20 via an optical fiber.

  The base station 30 communicates using a TDD (Time Division Duplex) method. The base station 30 generates an RF (Radio Frequency) band downlink signal and distributes the generated downlink signal to two. The base station 30 outputs one downlink signal to the master unit 10 via a coaxial cable. The base station 30 transmits the other downlink signal from an antenna provided in the station to the space.

  FIG. 2 is a block diagram showing an example of a functional configuration of the master unit 10 shown in FIG. 2 includes a directional coupler 11, a switching unit 12, a detection unit 13, a low-pass filter 14, an analog-digital conversion unit 15, a signal processing unit 16, a photoelectric conversion unit 17, and an instruction input unit 18. .

  When the downlink signal is supplied from the base station 30 via the coaxial cable, the directional coupler 11 outputs the supplied downlink signal to the switching unit 12 and also detects a part of the downlink signal as the detection unit 13. Output to.

  The detector 13 performs envelope detection on the downlink signal. The detection unit 13 outputs the detected envelope signal to the low-pass filter 14.

  In addition, the detection unit 13 refers to the internal clock and determines whether or not to detect a downlink signal at a preset level or higher at a preset timing. Specifically, the detection unit 13 detects a downlink signal using, for example, the front protection function and the rear protection function shown in FIG.

  First, the detection unit 13 waits for reception of a downlink signal in the state 0 indicating the hunting state. When the detection unit 13 receives a downlink signal that is equal to or higher than the set level, the detection unit 13 transitions to a state 1 indicating a backward protection state.

  When the detection unit 13 receives a downlink signal of a set level or higher before the number of clocks set in advance in the state 1 is counted, the detection unit 13 transits to the state 2 indicating the synchronization state. When the detection unit 13 enters the state 2, the detection unit 13 outputs a synchronization signal to the signal processing unit 16. On the other hand, if no downlink signal higher than the set level is received before the preset number of clocks is counted, the detector 13 returns to the state 0.

  When the detection unit 13 receives a downlink signal of a set level or higher during the state 2 until a preset number of clocks are counted, the detection unit 13 maintains the state 2. On the other hand, when a downlink signal higher than the set level is not received until the preset number of clocks is counted, the detector 13 transits to state 3 indicating the forward protection state.

  When the detection unit 13 receives a downlink signal of a set level or higher during the state 3 until the preset number of clocks is counted, the detection unit 13 returns to the state 2. On the other hand, when a downlink signal higher than the set level is not received before the preset number of clocks is counted, the detector 13 transits to state 4 indicating the forward protection state.

  The detection unit 13 transitions to a state 5 indicating a forward protection state when a downlink signal equal to or higher than the set level is not received for three consecutive times. The detector 13 returns to the state 4 when receiving a downlink signal at a set level or higher before the preset number of clocks is counted in the state 5. On the other hand, if no downlink signal higher than the set level is received before the preset number of clocks is counted, the detector 13 outputs a synchronization cancellation signal to the signal processor 16.

  The low-pass filter 14 performs low-pass filtering on the envelope signal supplied from the detection unit 13. The low-pass filter 14 removes a frequency other than a desired frequency from the envelope signal by low-pass filtering. The low pass filter 14 outputs the signal after the low pass filtering to the analog-digital conversion unit 15.

  The analog-digital converter 15 converts the signal supplied from the low-pass filter 14 into a digital signal. The analog-digital conversion unit 15 outputs a digital signal to the signal processing unit 16.

  The signal processing unit 16 includes, for example, an FPGA (Field-Programmable Gate Array). An FPGA is a programmable device that can program logic functions. The FPGA includes a pulse generation unit 161, a timing adjustment unit 162, a timing signal generation unit 163, and a control unit 164 shown in FIG.

  The pulse generation unit 161 receives a system pattern supplied from the outside via the instruction input unit 18. The system pattern is obtained by patterning a period in which an uplink signal appears and a period in which a downlink signal appears. The pulse generation unit 161 refers to the system pattern and sets a window for detecting the level of the digital signal during the period in which the downlink signal appears. The pulse generator 161 generates a pulse signal when the level of the digital signal exceeds a preset value within the set window.

  The timing adjustment unit 162 adjusts the timing at which the pulse signal generated by the pulse generation unit 161 is output. For example, the timing adjustment unit 162 sets the timing for outputting the pulse signal based on the time required for the digital conversion in the analog-digital conversion unit 15 and the time required for transmitting the downlink signal from the master unit 10 to the remote unit 20. adjust.

  The timing signal generation unit 163 outputs the pulse signal whose timing is adjusted by the timing adjustment unit 162 to the switching unit 12 as a timing signal.

  The control unit 164 enters the training state when the power is turned on, at the time of resetting, and when a synchronization cancellation signal is input. When the control unit 164 enters the training state, the control unit 164 stops the operation of switching the connection to the uplink signal in the switching unit 12 and stops outputting the downlink signal to the antenna. The stop of the output of the downlink signal to the aerial line may be the stop of the output of the downlink signal to the photoelectric conversion unit 17 in the switching unit 12, the stop of the conversion to the optical signal by the photoelectric conversion unit 17, or the wireless by the remote unit This is realized by stopping signal transmission. Note that the control unit 164 may output an alarm notifying the timing abnormality to the outside when the synchronization cancellation signal is input.

  When the synchronization signal is input, the control unit 164 cancels the training state and performs control so as to execute the steady operation.

  The switching unit 12 illustrated in FIG. 2 receives a downlink signal supplied via the directional coupler 11 and an uplink signal supplied from the photoelectric conversion unit 17. In addition, the switching unit 12 receives a timing signal generated by the signal processing unit 16. The switching unit 12 switches the path so as to output a downlink signal to the photoelectric conversion unit 17 or output an uplink signal to the base station 30 according to the timing signal. That is, the switching unit 12 switches the path in the switching unit 12 so that the downlink signal is output to the photoelectric conversion unit 17 when the timing signal rises. Further, the switching unit 12 switches the path in the switching unit 12 so that the uplink signal is output to the base station 30 when the timing signal becomes zero.

  The photoelectric conversion unit 17 converts the downlink signal supplied from the switching unit 12 into an optical signal, and outputs the optical signal to the remote unit 20 via the optical fiber. In addition, the photoelectric conversion unit 17 converts the optical signal supplied from the remote unit 20 into an uplink signal and outputs the uplink signal to the switching unit 12.

  Next, the operation of the master unit 10 configured as described above will be described in detail. FIG. 5 is a flowchart illustrating an example of an operation when the master unit 10 generates a timing signal. FIG. 6 is a schematic diagram showing an example of signals generated in the master unit 10.

  First, the detector 13 detects the envelope signal shown in FIG. 6A from the downlink signal supplied from the base station 30 via the coaxial cable (step S51).

  The low pass filter 14 filters the envelope signal detected by the detection unit 13 to remove high frequency components from the envelope signal as shown in FIG. 6B (step S52).

  The analog-digital conversion unit 15 converts the filtered signal into a digital signal (step S53), and outputs the converted digital signal to the signal processing unit 16.

  In the signal processing unit 16, the pulse generation unit 161 generates a pulse signal based on the level of the digital signal (step S54). The generated pulse signal is delayed by the time required for analog-digital conversion, as shown in FIG.

  The timing adjustment unit 162 adjusts the timing for outputting the pulse signal based on the delay time due to digital conversion and the time required to transmit the downlink signal from the master unit 10 to the remote unit 20 (step S55). The timing signal generator 163 outputs the signal shown in FIG. 6D as a timing signal to the switching unit 12 (step S56).

  As described above, the master unit 10 according to the present embodiment directly receives a stable downlink signal from the base station 30 via the coaxial cable. Then, the master unit 10 generates a timing signal by performing level detection on the received downlink signal. As a result, the master unit 10 can extract the timing signal without demodulating the downlink signal as in the prior art.

  Therefore, according to the master unit 10 according to the present embodiment, a downlink signal transmitted by radio from the base station and a downlink transmitted from the remote unit 20 via the master unit 10 even without a demodulation IC. The signal can be synchronized. Further, the master unit 10 can be provided with a simple and inexpensive circuit.

  In the above embodiment, the pulse generator 161 refers to a system pattern supplied from the outside, and sets a window for detecting the level of the downlink signal. Thereby, the pulse generation unit 161 can accurately generate the pulse signal.

  Moreover, in the said embodiment, the detection part 13 is provided with a front protection function. That is, the detection unit 13 outputs a synchronization signal to the signal processing unit 16 when it continuously detects a downlink signal at a set level or higher at a preset timing. When receiving the synchronization signal, the signal processing unit 16 controls the switching unit 12 and the like so as to shift from the training state to the steady operation. Moreover, the detection part 13 is provided with a back protection function. That is, the detector 13 outputs a synchronization cancellation signal to the signal processor 16 when a state in which a downlink signal higher than a set level is not continuously received at a preset timing in a synchronized state continues. When receiving the synchronization cancellation signal, the signal processing unit 16 controls the switching unit 12 and the like so as to enter the training state. The signal processing unit 16 prevents the unnecessary radio wave from being emitted and stops the output of the uplink signal to the base station 30 by setting the training state. Thereby, the repeater system according to the present embodiment can prevent synchronization at an incorrect timing even when the downlink signal from the base station 30 cannot be accurately captured. Further, the repeater system can hold the timing signal even when the timing signal may be lost momentarily.

  In the above embodiment, the case where the signal processing unit 16 is configured by an FPGA has been described as an example. However, it is not limited to this. For example, the FPGA may be a general-purpose processor, a DSP (Digital Signal Processor), or the like designed to perform the above functions.

  In the above embodiment, the case where the detection unit 13 protects the loss of the timing signal by monitoring the detection timing of the downlink signal has been described as an example. However, it is not limited to this. For example, as illustrated in FIG. 7, the signal processing unit 16 may include a determination unit 165. The determination unit 165 has, for example, a front protection function and a rear protection function shown in FIG. The determination unit 165 receives the timing signal generated by the timing signal generation unit 163. The determination unit 165 refers to the internal clock, and outputs a synchronization signal to the control unit 164 assuming that the timing signal is synchronized with the TDD timing when the timing signal is continuously generated at a preset timing. . In addition, the determination unit 165 outputs a synchronization release signal to the signal processing unit 16 when the state in which the timing signal is not generated at the preset timing continues continuously in the synchronized state.

  In the above embodiment, the case where the pulse signal is generated based on the envelope signal without correcting the level of the envelope signal detected by the detector 13 has been described as an example. However, it is not limited to this. For example, the low-pass filter 14 may hold the peak voltage of the input envelope signal for a preset period. The preset period may be set based on the system pattern. The peak voltage may be held only in the training state.

  In WiMAX (registered trademark), the preamble portion in the first symbol of each frame is at a certain level or higher. Also in WiMAX2 + (TD-LTE), the PDCCH (Physical Downlink Control CHannel) in the head symbol becomes a certain level or more. For this reason, if the reception level of the first symbol is held, the voltage level in the set period is always higher than a certain level. This makes it possible to prevent erroneous detection of timing signals even when the level of the downlink signal increases or decreases due to traffic fluctuations.

  In addition to holding the voltage level by the low-pass filter 14, for example, the signal processing unit 16 may be provided with a peak holding unit 166 as shown in FIG. The peak holding unit 166 refers to a system pattern input from the outside, and holds the peak voltage of the input digital signal during a period in which the downlink signal appears. The pulse generation unit 161 generates a pulse signal based on the digital signal output from the peak holding unit 166. This makes it possible to prevent erroneous detection of timing signals even when the level of the downlink signal increases or decreases due to traffic fluctuations. The peak voltage may be retained only in the training state.

  Although the embodiment of the present invention has been described, this embodiment is presented as an example and is not intended to limit the scope of the invention. This embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. This embodiment and its modifications are included in the scope of the present invention and the gist thereof, and are also included in the invention described in the claims and the equivalent scope thereof.

The above embodiment can be described as, for example, the following supplementary notes.
[1] A first repeater device connected via a cable to a base station adopting a TDD (Time Division Duplex) method;
A second repeater device connected to the first repeater device via an optical fiber cable;
The first repeater device is:
A detector for detecting a downlink signal supplied from the base station via the cable;
An analog-to-digital converter that converts the detected signal into a digital signal;
A signal processing unit for generating a pulse signal when the level of the digital signal exceeds a preset value, and using the pulse signal as a timing signal;
According to the timing signal, a switching unit that switches connection so as to output a downlink signal supplied via the cable to the second repeater device;
A conversion unit that converts a downlink signal output from the switching unit into an optical signal, and outputs the optical signal to the second repeater device;
The second repeater device is a repeater system that converts the optical signal supplied from the first repeater device via the optical fiber cable into a radio signal and transmits the radio signal.
[2] The signal processing unit detects the level of the digital signal based on a system pattern in which a first period in which a downlink signal appears and a second period in which an uplink signal appears are patterned. The repeater system according to [1], wherein a window is set.
[3] Based on whether or not a downlink signal of a setting level or higher is received at a preset timing, the detection unit is synchronized with a timing at which the downlink signal is received, Or, determine if it is out of sync,
The signal processing unit stops outputting an uplink signal to the base station and stops transmitting the radio signal from the second repeater device when it is determined by the detection unit that synchronization has been lost. The repeater system according to [1] or [2].
[4] The signal processing unit includes:
Based on whether or not the timing signal is generated at a preset timing, it is determined whether the timing signal is synchronized with a preset timing or out of synchronization;
Any of [1] to [3], when it is determined that the synchronization is lost, the output of the uplink signal to the base station is stopped and the transmission of the radio signal from the second repeater device is stopped. Repeater system according to.
[5] The first repeater device further includes a low-pass filter that performs low-pass filtering on the signal detected by the detection unit and holds the peak value of the detected signal for a preset period. A repeater system according to any one of [1] to [4].
[6] The signal processing unit holds the peak value of the digital signal for a preset period, and generates a pulse signal when the level of the digital signal holding the peak value exceeds a preset value [ 1] to the repeater system according to any one of [4].
[7] A detection unit that detects a downlink signal supplied from a base station that employs a TDD (Time Division Duplex) method via a cable;
An analog-to-digital converter that converts the detected signal into a digital signal;
A signal processing unit for generating a pulse signal when the level of the digital signal exceeds a preset value, and using the pulse signal as a timing signal;
In accordance with the timing signal, a switching unit that switches connection to output a downlink signal supplied via the cable to a subsequent stage,
A repeater device comprising: a conversion unit that converts a downlink signal output from the switching unit into an optical signal and that converts the optical signal into a radio signal via an optical fiber cable.
[8] The signal processing unit detects the level of the digital signal based on a system pattern in which a first period in which a downlink signal appears and a second period in which an uplink signal appears are patterned. The repeater device according to [7], wherein a window is set.
[9] Based on whether or not a downlink signal of a setting level or higher is received at a preset timing, the detection unit is synchronized with a timing at which the downlink signal is received, Or, determine if it is out of sync,
When the signal processing unit determines that synchronization is lost, the signal processing unit stops outputting the uplink signal to the base station and stops outputting the downlink signal to the subsequent stage [7]. Or the repeater apparatus as described in [8].
[10] The signal processing unit includes:
Based on whether or not the timing signal is generated at a preset timing, it is determined whether the timing signal is synchronized with a preset timing or out of synchronization;
The repeater according to any one of [7] to [9], wherein when it is determined that synchronization is lost, output of the uplink signal to the base station is stopped and output to the subsequent stage of the downlink signal is stopped. apparatus.
[11] The apparatus further includes a low-pass filter that performs low-pass filtering on the signal detected by the detector and holds a peak value of the detected signal for a preset period. ] The repeater apparatus in any one of.
[12] The signal processing unit holds the peak value of the digital signal for a preset period, and generates a pulse signal when the level of the digital signal holding the peak value exceeds a preset value [ The repeater device according to any one of [7] to [10].
[13] Detects a downlink signal supplied via a cable from a base station adopting a TDD (Time Division Duplex) method,
Converting the detected signal into a digital signal;
When the level of the digital signal exceeds a preset value, a pulse signal is generated,
A timing signal generation method for converting a downlink signal output to a subsequent stage as an optical signal via an optical fiber cable into a radio signal by outputting the pulse signal as a timing signal.
[14] A window for detecting the level of the digital signal is set based on a system pattern in which a first period in which a downlink signal appears and a second period in which an uplink signal appears is patterned [13] ] Timing signal generation method.
[15] Whether the timing at which the downlink signal is received is synchronized with the timing set in advance based on whether or not a downlink signal of a setting level or higher is received at a timing set in advance during the detection. Or determine if it is out of sync,
The timing signal generation according to [13] or [14], in which, when it is determined that the synchronization is lost, the output of the uplink signal to the base station is stopped and the output to the subsequent stage of the downlink signal is stopped. Method.
[16] Based on whether the timing signal is generated at a preset timing, it is determined whether the timing signal is synchronized with a preset timing or out of synchronization;
The timing according to any one of [13] to [15], wherein when it is determined that synchronization has been lost, the output of the uplink signal to the base station is stopped and the output to the subsequent stage of the downlink signal is stopped. Signal generation method.
[17] Low-pass filtering the detected signal;
The timing signal generation method according to any one of [13] to [16], wherein a signal obtained by holding a peak value of the low-pass filtered signal for a preset period is converted into a digital signal.
[18] Hold the peak value of the digital signal for a preset period,
The timing signal generation method according to any one of [13] to [16], wherein a pulse signal is generated when a level of a digital signal holding the peak value exceeds a preset value.

  DESCRIPTION OF SYMBOLS 10 ... Master unit, 11 ... Directional coupler, 12 ... Switching part, 13 ... Detection part, 14 ... Low pass filter, 15 ... Analog-digital conversion part, 16 ... Signal processing part, 161 ... Pulse generation part, 162 ... Timing Adjustment unit, 163 ... timing signal generation unit, 164 ... control unit, 165 ... determination unit, 166 ... peak holding unit, 17 ... photoelectric conversion unit, 18 ... instruction input unit, 20 ... remote unit, 30 ... base station.

Claims (9)

In a repeater apparatus capable of communicating with a radio apparatus that converts an optical signal related to a downlink signal transmitted from a base station into a radio signal and transmits the radio signal,
A detector for detecting a downlink signal transmitted from the base station;
A signal converter for converting the detected downlink signal into a digital signal;
A signal processing unit that outputs a pulse signal based on the level of the digital signal;
A repeater apparatus comprising: a conversion unit that converts a downlink signal transmitted from the base station into the optical signal and outputs the optical signal to the radio apparatus according to the output of the pulse signal. In a repeater apparatus capable of communicating with a radio apparatus that converts an optical signal related to a downlink signal transmitted from a base station into a radio signal and transmits the radio signal,
A detector for detecting a downlink signal transmitted from the base station;
A signal converter for converting the detected downlink signal into a digital signal;
A signal processing unit that outputs a pulse signal based on the level of the digital signal;
A switching unit that switches output / stop of a downlink signal transmitted from the base station according to the output of the pulse signal;
A repeater device comprising: a conversion unit that converts the downlink signal output from the switching unit into the optical signal and outputs the optical signal to the wireless device. In a repeater apparatus capable of communicating with a radio apparatus that converts an optical signal related to a downlink signal transmitted from a base station into a radio signal and transmits the radio signal,
A detector for detecting a downlink signal transmitted from the base station;
A signal converter for converting the detected downlink signal into a digital signal;
A pulse generator that generates a pulse signal based on the level of the digital signal;
A timing signal generator for outputting the pulse signal as a timing signal;
A switching unit that switches output / stop of a downlink signal transmitted from the base station according to the output of the timing signal;
A repeater device comprising: a conversion unit that converts the downlink signal output from the switching unit into the optical signal and outputs the optical signal to the wireless device. In a repeater apparatus capable of communicating with a radio apparatus that converts an optical signal related to a downlink signal transmitted from a base station into a radio signal and transmits the radio signal,
A detector for detecting a downlink signal transmitted from the base station;
A signal converter for converting the detected downlink signal into a digital signal;
A pulse generator that generates a pulse signal based on the level of the digital signal;
A timing adjustment unit that adjusts the timing at which the pulse signal generated by the pulse generation unit is output;
A switching unit that switches output / stop of a downlink signal transmitted from the base station according to the output of the pulse signal whose timing is adjusted by the timing adjustment unit;
A repeater device comprising: a conversion unit that converts the downlink signal output from the switching unit into the optical signal and outputs the optical signal to the wireless device. In a repeater device that can communicate with a remote unit that converts an optical signal into a radio signal and transmits it,
A detector for detecting a downlink signal from the base station;
A signal converter for converting the detected downlink signal into a digital signal;
A signal processing unit that outputs a pulse signal based on the level of the digital signal;
A repeater apparatus comprising: a conversion unit that converts a downlink signal transmitted from the base station into the optical signal and outputs the optical signal to the remote unit according to the output of the pulse signal. In a repeater device that can communicate with a wireless device that converts an optical signal into a wireless signal and transmits it,
A detector for detecting a downlink signal from the base station;
A signal converter for converting the detected downlink signal into a digital signal;
A signal processing unit that outputs a timing signal generated based on the digital signal;
A switching unit that switches output / stop of a downlink signal transmitted from the base station according to the timing signal;
A repeater device comprising: a conversion unit that converts the downlink signal output from the switching unit into the optical signal and outputs the optical signal to the wireless device. In a repeater device that can communicate with a wireless device that converts an optical signal into a wireless signal and transmits it to space,
A detector for detecting a downlink signal transmitted from the base station to the space as a radio signal and supplied via a cable;
A signal converter for converting the detected downlink signal into a digital signal;
A signal processing unit that outputs a pulse signal based on the level of the digital signal;
A repeater apparatus comprising: a conversion unit that converts a downlink signal supplied from the base station into the optical signal and outputs the optical signal to the radio apparatus according to the output of the pulse signal. Detect the downlink signal transmitted from the base station,
Converting the detected signal into a digital signal;
Output a pulse signal based on the level of the digital signal,
A method of converting a downlink signal transmitted from the base station into an optical signal according to the output of the pulse signal. A process of detecting a downlink signal transmitted from the base station;
A process of converting the detected signal into a digital signal;
Processing to output a pulse signal based on the level of the digital signal;
A program for causing a processor to execute processing for converting a downlink signal transmitted from the base station into an optical signal in accordance with the output of the pulse signal.