JP2022036133A - Radio inspection system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique of discriminating and detecting abnormality on transmission side or reception side.

SOLUTION: A first repeating device 80a, upon reception of a reception inspection start request command, instructs a reception inspection start to a second repeating device 80b. A demodulation section 50 of the second repeating device 80b demodulates an electric wave including analog voice and a voice reception section 52 demodulates a demodulation result to create analog voice. A voice coding section 58 voice-codes the created analog voice to create voice data. A data recording section 60 records the voice data and a data transmission section 66 codes the voice data recorded on data recording section 60 and a modulation section 68 modulates the coded voice data to generate an electric wave including the voice data.

SELECTED DRAWING: Figure 2

COPYRIGHT: (C)2022,JPO&INPIT

Description

The present invention relates to a communication technique, and more particularly to a wireless device and an inspection system capable of determining normality or abnormality of a communication function.

In order to determine the normality or abnormality of the communication path of a wireless device in a wireless communication system, a test is performed on the wireless device. In the test, the wireless device connects the speaker output of the received voice to the microphone input and returns it. At that time, by providing a delay in the returned audio signal, it becomes easier to detect an abnormality in the communication path (see, for example, Patent Document 1).

Japanese Patent No. 2912327

According to the inspection method of Patent Document 1, an abnormality in the communication path can be detected, but it cannot be specified whether the abnormality is in the transmission side communication path or the reception side communication path.

The present invention has been made in view of such a situation, and an object of the present invention is to provide a technique for distinguishing and detecting an abnormality on the transmitting side or the receiving side.

In order to solve the above problems, the inspection system according to an aspect of the present invention transmits an analog voice or a radio wave including control information for designating one relay device to be inspected for reception from a plurality of relay devices. It includes an inspection device, a plurality of relay devices that receive radio waves from the inspection device, and a first relay device that receives radio waves from the inspection device and controls the plurality of relay devices. The first relay device is connected to a first demodulation unit that demodulates radio waves, a first reception unit that acquires control information by decoding the demodulation result in the first demodulation unit, and a plurality of relay devices, and follows the control information. It is provided with a first connection unit for instructing one relay device to be in the reception inspection state. The plurality of relay devices are connected to the first connection unit, and the second connection unit that sets the self-relay device to the reception inspection state according to the instruction of the first relay device, the second demodulation unit that demolishes the radio wave, and the second demodulator unit. A voice receiving unit that generates analog voice by decoding the demodulation result in the above, a voice coding unit that generates voice data by voice coding the analog voice generated in the voice receiving unit, and a voice coding unit. A data recording unit that records the recorded audio data, a data transmission unit that encodes the audio data recorded in the data recording unit, and a radio wave that includes the audio data by modulating the encoded audio data in the transmission unit. It is provided with a modulation unit that generates.

Yet another aspect of the invention is also an inspection system. This inspection system is an inspection device that transmits radio waves containing voice-encoded voice data or control information that specifies one relay device to be inspected from a plurality of relay devices, and an inspection device from the inspection device. It includes a plurality of relay devices that receive radio waves and a first relay device that receives radio waves from inspection devices and controls the plurality of relay devices. The first relay device is connected to a first demodulation unit that demodulates radio waves, a first reception unit that acquires control information by decoding the demodulation result in the first demodulation unit, and a plurality of relay devices, and follows the control information. It is provided with a first connection unit for instructing one relay device to be in the transmission inspection state. The plurality of relay devices are connected to the first connection unit, and the second connection unit that puts the self-relay device into the transmission inspection state according to the instruction of the first relay device, the second demodulation unit that demodulates the radio wave, and the second demodulation unit. A data receiving unit that decodes the demodulation result in the above, a data recording unit that records the audio data decoded in the data receiving unit, and an audio decoding unit that generates analog audio by audio decoding the audio data recorded in the data recording unit. A voice transmission unit that encodes an analog voice generated in the voice decoding unit, and a modulation unit that generates a radio wave including the analog voice by modulating the encoded analog voice in the voice transmission unit are provided.

It should be noted that any combination of the above components and the conversion of the expression of the present invention between methods, devices, systems, recording media, computer programs and the like are also effective as aspects of the present invention.

According to the present invention, it is possible to distinguish and detect an abnormality on the transmitting side or the receiving side.

It is a figure which shows the structure of the inspection system which concerns on Example. It is a figure which shows the structure of the wireless device of FIG. It is a figure which shows the structure of the relay device which uses the wireless device of FIG. It is a figure which shows the data format of the control signal in the inspection system of FIG. It is a sequence diagram which shows the procedure of the reception inspection by the inspection system of FIG. It is a sequence diagram which shows the procedure of the transmission inspection by the inspection system of FIG.

Before explaining the present invention in detail, first, an outline will be given. An embodiment of the present invention relates to an inspection system for inspecting the presence or absence of an abnormality on the transmitting side or the receiving side of a wireless device installed in a remote location. It is necessary to routinely inspect that each wireless device constituting the wireless communication system is operating normally without any abnormality, and to repair the wireless device promptly if an abnormality is found. As an inspection of a wireless device, not only an objective quality inspection such as a received electric field strength and a transmission output, but also a subjective voice quality inspection of a received voice of a speaker output and a transmitted voice of a microphone input are important. Inspection workers are dispatched to the site where the radio device is installed to perform the voice quality inspection. However, the relay device, which is one of the wireless devices, may be installed in an inconvenient place such as a mountainous area. The entry of inspection workers into such places is difficult, and the cost for dispatching is high. Therefore, it is required to carry out inspections without dispatching inspection workers to the site. In the above-mentioned inspection method according to Patent Document 1, the wireless device connects the speaker output of the received voice to the microphone input and returns it, so that subjective voice deterioration is detected without dispatching an inspection worker to the site. It is possible. However, in the above-mentioned inspection method, it cannot be specified whether the deterioration of the voice is caused by the transmitting side or the receiving side.

In the inspection system according to the present embodiment, the wireless device that executes the inspection is referred to as an "inspection device", and the wireless device such as a relay device inspected by the inspection device is referred to as a "wireless device". In the inspection system, the reception inspection and the transmission inspection for the wireless device are performed independently. In the reception inspection, the inspection device transmits a reception inspection start command to the wireless device, and then transmits a voice signal including analog voice. When the wireless device receives the audio signal after receiving the reception inspection start command from the inspection device, the wireless device digitizes the speaker output of the analog audio and records it as audio data. The wireless device transmits a data signal including voice data to the inspection device, and when the inspection device receives the data signal from the wireless device, the inspection device records the voice data. Here, even if the voice data is lost in the communication of the data signal, the data signal is retransmitted, so that the inspection device can acquire the complete voice data. The inspection device transmits a reception inspection end command to the wireless device, and the wireless device ends the process when it receives the reception inspection end command from the inspection device. In the inspection device, the recorded voice data is converted into analog voice, and the analog voice is output from the speaker. By the above procedure, the analog voice of the same quality as the speaker output of the wireless device is heard by the speaker output of the inspection device, so that the subjective evaluation of the receiving side of the wireless device becomes possible.

On the other hand, in the transmission inspection, the inspection device transmits a transmission inspection start command to the wireless device, and then transmits a data signal including voice data. When the wireless device receives the data signal after receiving the transmission inspection start command from the inspection device, the wireless device records voice data. The wireless device converts the recorded voice data into analog voice and transmits a voice signal including the analog voice to the inspection device. Upon receiving the audio signal from the wireless device, the inspection device outputs analog audio from the speaker. The inspection device transmits a transmission inspection end command to the wireless device, and the wireless device ends the process when it receives the transmission inspection end command from the inspection device. Since the analog voice is heard at the speaker output, subjective evaluation of the transmitting side of the wireless device becomes possible.

FIG. 1 shows the configuration of the inspection system 100. The inspection system 100 includes an inspection device 10 and a wireless device 20. The inspection device 10 and the wireless device 20 comply with a predetermined wireless communication method, and can wirelessly communicate with each other. One form of wireless communication is voice communication using a voice signal (radio wave) including analog voice, and another form of wireless communication is data communication using a data signal (radio wave) containing voice data. be. The wireless device 20 is a device to be inspected for voice quality inspection, and the inspection device 10 is a device that executes a voice quality inspection for the wireless device 20. Hereinafter, the quality inspection of the analog voice received by the wireless device 20 is referred to as a “reception inspection”, and the quality inspection of the analog voice transmitted from the wireless device 20 is referred to as a “transmission inspection”. In the inspection system 100, the reception inspection and the transmission inspection are executed independently.

In the reception inspection, the inspection device 10 transmits an audio signal, and the wireless device 20 receives the audio signal. Further, the wireless device 20 transmits a data signal, and the inspection device 10 receives the data signal. That is, voice communication is performed from the inspection device 10 to the wireless device 20, and data communication is performed from the wireless device 20 to the inspection device 10. In the transmission inspection, the inspection device 10 transmits a data signal, and the wireless device 20 receives the data signal. Further, the wireless device 20 transmits an audio signal, and the inspection device 10 receives the audio signal. That is, data communication is performed from the inspection device 10 to the wireless device 20, and voice communication is performed from the wireless device 20 to the inspection device 10.

FIG. 2 shows the configuration of the wireless device 20. The wireless device 20 includes a processing unit 30, a speaker 32, a control unit 34, a display unit 36, an operation unit 38, an I / F 40, and a microphone 42. The processing unit 30 includes a demodulation unit 50, a voice receiving unit 52, a data receiving unit 54, a switch unit 56, a voice coding unit 58, a data recording unit 60, a voice decoding unit 62, a voice transmitting unit 64, a data transmitting unit 66, and a modulation unit. Includes part 68. Here, (1) reception inspection, (2) transmission inspection, and (3) other processing will be described in this order.
(1) Reception inspection The demodulation unit 50 receives an audio signal from the inspection device 10 (not shown) via the antenna. An example of a voice signal is a radio wave containing analog voice for reception inspection. The demodulation unit 50 demodulates the audio signal. The demodulation unit 50 outputs the demodulation result to the voice receiving unit 52. The voice receiving unit 52 generates analog voice by decoding the demodulation result in the demodulation unit 50. Decoding of the demodulation result includes Vocoder, which is an audio compression technique for communication. The voice receiving unit 52 outputs analog voice to the switch unit 56. When the switch unit 56 receives the analog voice from the voice receiving unit 52, the switch unit 56 outputs the analog voice to the voice coding unit 58.

The voice coding unit 58 converts the analog voice into digital voice by performing analog / digital conversion on the analog voice from the switch unit 56. The voice coding unit 58 generates voice data by voice-coding the digital voice. Audio data is composed of data strings. The method of voice coding in the voice coding unit 58 is not limited, but a method such as MPEG-4 ALS (MPEG-4 Audio Lossless Coding) that is losslessly compressed and filed is used. This is defined by FLAC (Free Lossless Audio Code) and ISO / IEC 14496-3 Subpart 11 which digitize analog audio by linear PCM (Pulse Code Modulation) and open source (BSD license). That is, it is desirable to adopt a voice coding method at a level that enables subjective evaluation of voice quality.

The data recording unit 60 is a storage element that can store data, and is, for example, an EEPROM (Electrically Erasable Programmable Read-Only Memory). The data recording unit 60 records the voice data generated by the voice coding unit 58. Recording voice-encoded voice data in the data recording unit 60 is also called "recording". After the recording of the voice data is completed, the data recording unit 60 outputs the voice data to the switch unit 56. When the switch unit 56 receives the voice data from the data recording unit 60, the switch unit 56 outputs the voice data to the data transmission unit 66. The data transmission unit 66 encodes the voice data from the switch unit 56. The data transmission unit 66 outputs the encoded voice data to the modulation unit 68.

The modulation unit 68 generates a data signal by modulating the voice data from the data transmission unit 66. It can be said that the data signal is a radio wave including voice data. At that time, modulation is performed by a carrier wave having a frequency different from that of the radio wave received by the demodulation unit 50. The modulation unit 68 transmits a data signal from the antenna toward the inspection device 10. The data signal is received by the inspection device 10, converted into analog voice by the inspection device 10, and output from the speaker as analog voice. The output of this analog voice makes a subjective evaluation of the receiving side of the wireless device 20.
(2) Transmission inspection The demodulation unit 50 receives a data signal from the inspection device 10 (not shown) via the antenna. An example of a data signal is a radio wave containing voice data for transmission inspection. The voice data is voice-coded. The demodulation unit 50 demodulates the data signal. The demodulation unit 50 outputs the demodulation result to the data receiving unit 54. The data receiving unit 54 generates voice data by decoding the demodulation result of the demodulation unit 50. The data receiving unit 54 outputs voice data to the switch unit 56. When the switch unit 56 receives the voice data from the data receiving unit 54, the switch unit 56 outputs the voice data to the data recording unit 60.

The data recording unit 60 records the voice data decoded by the data receiving unit 54. Recording the received voice data in the data recording unit 60 is also called "data recording". After the recording of the voice data is completed, the data recording unit 60 outputs the voice data to the voice decoding unit 62. The voice decoding unit 62 generates digital voice by voice decoding the voice data from the data recording unit 60. For voice decoding, a decoding method corresponding to the voice coding method performed on the voice data is used. The voice decoding unit 62 converts digital voice into analog voice by performing digital / analog conversion on the digital voice. The audio decoding unit 62 outputs analog audio to the switch unit 56.

When the switch unit 56 receives the analog voice from the voice decoding unit 62, the switch unit 56 outputs the analog voice to the voice transmission unit 64. The voice transmission unit 64 encodes the analog voice from the switch unit 56. Analog audio coding includes Vocoder, an audio compression technology for communication. The voice transmission unit 64 outputs the encoded analog voice to the modulation unit 68. The modulation unit 68 generates a voice signal by modulating the analog voice from the voice transmission unit 64. It can be said that the audio signal is a radio wave including analog audio. At that time, modulation is performed by a carrier wave having a frequency different from that of the radio wave received by the demodulation unit 50. The modulation unit 68 transmits an audio signal from the antenna toward the inspection device 10. The voice signal is received by the inspection device 10 and is output from the speaker as analog voice in the inspection device 10. The output of this analog voice makes a subjective evaluation of the transmitting side of the wireless device 20.
(3) Other processing The control unit 34 controls the operation of the processing unit 30. In particular, the control unit 34 controls the operations of the reception inspection and the transmission inspection in the processing unit 30. When the processing unit 30 receives the reception inspection start command from the inspection device 10, the control unit 34 receives the reception inspection start command. When the control unit 34 receives the reception inspection start command, the control unit 34 confirms whether or not the processing unit 30 is executing voice communication or data communication. When the processing unit 30 is not executing voice communication and data communication, the control unit 34 causes the processing unit 30 to transition to the reception inspection start state. In the reception inspection start state, the processing unit 30 executes the above-mentioned reception inspection processing. Further, the control unit 34 causes the processing unit 30 to transmit a reception inspection start response indicating that the start is OK to the inspection device 10. The inspection device 10 receives the reception inspection start response, and if the reception inspection start response indicates that the start is OK, the inspection device 10 starts transmitting the voice signal for the reception inspection. On the other hand, when the processing unit 30 is executing voice communication and data communication, the control unit 34 causes the processing unit 30 to transmit a reception inspection start response indicating a start NG to the inspection device 10. The inspection device 10 receives the reception inspection start response, and if the reception inspection start response indicates a start NG, the inspection device 10 does not start transmitting the voice signal for the reception inspection. At that time, the inspection device 10 may notify the inspection worker that the inspection is not possible.

Before transmitting the voice data in the reception inspection state, the control unit 34 causes the processing unit 30 to transmit the voice data transmission start command to the inspection device 10. When the transmission of voice data is completed in the reception inspection state, the control unit 34 causes the processing unit 30 to transmit the voice data transmission end command to the inspection device 10. Further, when the processing unit 30 receives the reception inspection end command from the inspection device 10, the control unit 34 receives the reception inspection end command. In response to this, the control unit 34 causes the processing unit 30 to transition to the normal state. In the normal state, the processing unit 30 executes voice communication or data communication. Further, the control unit 34 causes the processing unit 30 to transmit the reception inspection end response to the inspection device 10.

When the processing unit 30 receives the transmission inspection start command from the inspection device 10, the control unit 34 receives the transmission inspection start command. When the control unit 34 receives the transmission inspection start command, the control unit 34 confirms whether or not the processing unit 30 is executing voice communication or data communication. When the processing unit 30 is not executing voice communication and data communication, the control unit 34 causes the processing unit 30 to transition to the transmission inspection start state. In the transmission inspection start state, the processing unit 30 executes the above-mentioned transmission inspection processing. Further, the control unit 34 causes the processing unit 30 to transmit a transmission inspection start response indicating that the start is OK to the inspection device 10. The inspection device 10 receives the transmission inspection start response, and if the transmission inspection start response indicates start OK, the inspection device 10 starts transmission of the data signal for the transmission inspection. On the other hand, when the processing unit 30 is executing voice communication and data communication, the control unit 34 causes the processing unit 30 to transmit a transmission inspection start response indicating a start NG to the inspection device 10. The inspection device 10 receives the transmission inspection start response, and if the transmission inspection start response indicates a start NG, the inspection device 10 does not start the transmission of the data signal for the transmission inspection.

Before receiving the voice data in the transmission inspection state, the control unit 34 receives the voice data transmission start command from the inspection device 10 via the processing unit 30. When the transmission of voice data is completed in the transmission inspection state, the control unit 34 receives the voice data transmission end command from the inspection device 10 via the processing unit 30. Further, when the processing unit 30 receives the transmission inspection end command from the inspection device 10, the control unit 34 receives the transmission inspection end command. In response to this, the control unit 34 causes the processing unit 30 to transition to the normal state. In the normal state, the processing unit 30 executes voice communication or data communication. Further, the control unit 34 causes the processing unit 30 to transmit the transmission inspection end response to the inspection device 10.

In addition to the operations of the reception inspection and the transmission inspection in the processing unit 30, the control unit 34 may execute the following control. The control unit 34 outputs analog voice or control data from the speaker 32 in the processing unit 30, displays it on the display unit 36, and records it on the data recording unit 60. Further, the control unit 34 outputs the analog voice captured from the microphone 42 to the processing unit 30, and outputs the information input from the operation unit 38 to the processing unit 30 as data.

The operation unit 38 is, for example, a keyboard, a button, a touch panel, or the like, and receives operations related to the operation of the wireless device 20 from the user. The display unit 36 is, for example, an LCD (Liquid Crystal Display) or an LED (Light Emitting Diode), and displays processed data, an operation status, and the like. The speaker 32 outputs analog audio. The microphone 42 captures analog audio. The speaker 32 and the microphone 42 may not be provided in the wireless device 20. When connecting a plurality of wireless devices 20, the I / F 40 inputs / outputs information to / from another wireless device 20.

This configuration can be realized by the CPU, memory, or other LSI of any computer in terms of hardware, and by programs loaded in memory in terms of software, but here it is realized by cooperation between them. It depicts a functional block that will be used. Therefore, it is understood by those skilled in the art that these functional blocks can be realized in various forms only by hardware and by a combination of hardware and software.

In the following, assuming that the wireless device 20 described so far is a relay device, a wireless relay system composed of a plurality of relay devices will be described. A control channel (hereinafter referred to as “CCH”) and a plurality of communication channels (Traffic Channel) (hereinafter referred to as “TCH”) are set in the wireless relay system. Relay calls between individual or group terminals using different transmit and receive frequencies on each channel. The CCH is used to control voice communication, such as receiving a transmission request from a terminal device and notifying a TCH to be used for a call. Various configurations are possible for the wireless relay system, such as providing the relay device for CCH with a TCH function, but in this embodiment, the configuration shown in FIG. 3 is assumed for the sake of simplicity.

FIG. 3 shows the configuration of the relay device 80 using the wireless device 20. As shown in the figure, the first relay device 80a, the second relay device 80b, the third relay device 80c, and the fourth relay device 80d are included in the wireless relay system. The first relay device 80a to the fourth relay device 80d are collectively referred to as the relay device 80. The first relay device 80a is a relay device 80 for CCH, and the second relay device 80b to the fourth relay device 80d are relay devices 80 for TCH. The number of relay devices 80 for TCH is not limited to "3". The first relay device 80a includes the first I / F40a, the second relay device 80b includes the second I / F40b, the third relay device 80c includes the third I / F40c, and the fourth relay device 80d includes the fourth I / F40d. include. The first I / F40a is connected to the second I / F40b, the second I / F40b is connected to the third I / F40c, and the third I / F40c is connected to the fourth I / F40d. The connection between the two I / F 40s is made, for example, by wire. By such connection of I / F 40, a plurality of relay devices 80 are connected in series. As a result, when the first relay device 80a receives the transmission request from the terminal device, the first relay device 80a controls any of the second relay device 80b to the fourth relay device 80d used for the call.

Next, the definition of data (hereinafter, referred to as “control command”) included in the control signal transmitted from the inspection device 10 to the relay device 80 or the wireless device 20 will be described. Here, the control signal corresponds to a radio wave including a control command. The demodulation unit 50 in the first relay device 80a acquires a control command by demodulating the control signal. FIG. 4 shows the data format of the control signal in the inspection system 100. This is an example of a control command, but the control command is not limited to this. The command unit stores values indicating reception inspection start, reception inspection end, transmission inspection start, transmission inspection end, data transmission start, and data transmission end. In the target channel section, a value indicating the relay device 80 to be inspected, particularly the relay device (TCH) is stored. In addition, a plurality of relay devices 80 may be designated. The terminal ID of the source of the control command is stored in the source address unit. For example, a terminal ID that identifies the inspection device 10 is stored.

The file format unit stores information that specifies a file format for storing the encoded audio data. The voice coding method unit stores a value that specifies a voice coding method, for example, the FLAC described above. That is, the control command contains information for specifying the method of voice coding. Parameters for converting analog voice to linear PCM are stored in the sampling frequency part and the quantization bit number part. The delay amount unit includes a delay amount when each of the second relay device 80b to the fourth relay device 80d transmits a data signal in the case of reception inspection or an audio signal in the case of transmission inspection. It can be said that this is information on the timing at which the relay device (TCH) should transmit the radio wave generated by the modulation unit 68. Here, the delay amount (TCH1) is the delay amount with respect to the second relay device 80b, the delay amount (TCH2) is the delay amount with respect to the third relay device 80c, and the delay amount (TCH3) is the delay amount with respect to the fourth relay device 80d. The quantity. Further, the delay amount with respect to the relay device 80 designated in the target channel unit is included.

The operation of the inspection system 100 with the above configuration will be described. FIG. 5 is a sequence diagram showing a procedure of reception inspection by the inspection system 100. This shows a processing flow in the case of performing a reception inspection for the second relay device 80b of the second relay device 80b to the fourth relay device 80d in FIG. Here, the frequency of CCH is used for communication between the inspection device 10 and the first relay device 80a, the frequency of TCH is used for communication between the inspection device 10 and the second relay device 80b, and the first relay device 80a is used. And the wire connected by the I / F unit 40 are used for communication with the second relay device 80b.

When the inspection device 10 starts the reception inspection, the inspection device 10 transmits a reception inspection start request command to the first relay device 80a (S10). When the first relay device 80a receives the reception inspection start request command, the first relay device 80a instructs the second relay device 80b to start the reception inspection (S12). At least one of the reception inspection start request command and the reception inspection start instruction corresponds to the above-mentioned reception inspection start command. The second relay device 80b receives the instruction to start the reception inspection, and if the reception inspection is possible, the second relay device 80b transitions to the reception inspection state (S14). The second relay device 80b responds to the start of the reception inspection to the first relay device 80a (S16). When the first relay device 80a receives the response for starting the reception inspection, the first relay device 80a transmits a reception inspection start response command to the inspection device 10 (S18). At least one of the reception inspection start response command and the reception inspection start response corresponds to the above-mentioned reception inspection start response.

Upon receiving the reception inspection start response command, the inspection device 10 starts transmitting voice to the second relay device 80b (S20). Upon receiving the voice, the second relay device 80b executes recording (S22). In order to transmit the recorded voice data to the inspection device 10, the second relay device 80b transmits a voice data transmission start command to the inspection device 10 (S24), and subsequently transmits voice data (S26). The voice data transmission start command corresponds to the above-mentioned voice data transmission start command. Upon receiving the voice data transmission start command, the inspection device 10 continuously records the voice data (S28). When the second relay device 80b finishes transmitting the voice data, the second relay device 80b transmits a voice data transmission end command to the inspection device 10 (S30). The voice data transmission end command corresponds to the above-mentioned voice data transmission end command.

Upon receiving the voice data transmission end command, the inspection device 10 stops recording the voice data, and subsequently transmits a reception inspection end request command to the first relay device 80a (S32). Upon receiving the reception inspection end request command, the first relay device 80a instructs the second relay device 80b to end the reception inspection (S34). At least one of the reception inspection end request command and the reception inspection end instruction corresponds to the above-mentioned reception inspection end command. When the second relay device 80b receives the instruction to end the reception inspection, it transitions to the normal state (S36) and responds to the end of the reception inspection (S38). When the first relay device 80a receives the response of the end of the reception inspection, the first relay device 80a transmits a reception inspection end response command to the inspection device 10 (S40). At least one of the reception inspection end response command and the reception inspection end response corresponds to the above-mentioned reception inspection end response. Upon receiving the reception inspection end response command, the inspection device 10 notifies the inspection worker that the reception inspection is completed and ends the inspection.

FIG. 6 is a sequence diagram showing a transmission inspection procedure by the inspection system 100. When the inspection device 10 starts the transmission inspection, the inspection device 10 transmits a transmission inspection start request command to the first relay device 80a (S100). Upon receiving the transmission inspection start request command, the first relay device 80a instructs the second relay device 80b to start the transmission inspection (S102). At least one of the transmission inspection start request command and the transmission inspection start instruction corresponds to the above-mentioned transmission inspection start command. The second relay device 80b receives the instruction to start the transmission inspection, and if the transmission inspection is possible, the second relay device 80b transitions to the transmission inspection state (S104). The second relay device 80b responds to the start of the transmission inspection to the first relay device 80a (S106). When the first relay device 80a receives the response for starting the transmission inspection, the first relay device 80a transmits a transmission inspection start response command to the inspection device 10 (S108). At least one of the transmission inspection start response command and the transmission inspection start response corresponds to the transmission inspection start response described above.

Upon receiving the transmission inspection start response command, the inspection device 10 transmits a voice data transmission start command to the second relay device 80b (S110), and subsequently transmits voice data (S112). The voice data transmission start command corresponds to the above-mentioned voice data transmission start command. Upon receiving the voice data transmission start command, the second relay device 80b records the voice data (S114). When the inspection device 10 finishes transmitting the voice data, the inspection device 10 transmits a voice data transmission end command to the second relay device 80b (S116). The voice data transmission end command corresponds to the above-mentioned voice data transmission end command. When the second relay device 80b receives the voice data transmission end command, the recording of the voice data is stopped, and the voice in which the voice data is continuously reproduced is transmitted to the inspection device 10 (S118). The inspection device 10 starts recording voice (S120).

When the inspection device 10 stops recording the voice, the inspection device 10 continuously transmits a transmission inspection end request command to the first relay device 80a (S122). Upon receiving the transmission inspection end request command, the first relay device 80a instructs the second relay device 80b to end the transmission inspection (S124). At least one of the transmission inspection end request command and the transmission inspection end instruction corresponds to the above-mentioned transmission inspection end command. When the second relay device 80b receives the instruction to end the transmission inspection, it transitions to the normal state (S126) and responds to the end of the transmission inspection (S128). When the first relay device 80a receives the response of the end of the transmission inspection, the first relay device 80a transmits a transmission inspection end response command to the inspection device 10 (S130). At least one of the transmission inspection end response command and the transmission inspection end response corresponds to the transmission inspection end response described above. Upon receiving the transmission inspection end response command, the inspection device 10 notifies the inspection worker that the transmission inspection is completed and ends the transmission inspection.

According to this embodiment, the received analog voice is converted into voice data and recorded, and then the voice data is transmitted to the inspection device. Therefore, in the inspection device, the analog voice has the same quality as when it is received by the wireless device. Can be heard from the speaker. Further, in the inspection device, since the analog voice is heard from the speaker with the same quality as that at the time of reception by the wireless device, it is possible to detect an abnormality on the receiving side of the wireless device. In addition, since the analog voice is heard from the speaker in the inspection device with the same quality as when it is received by the wireless device, the subjective voice quality of the received voice by the wireless device can be obtained without going to the installation location of the wireless device. Can be inspected. In addition, since a coding method that enables subjective evaluation of voice quality is adopted, if the voice data sent from the wireless device is decoded into analog voice on the inspection device side, the inspection device can receive the wireless device. You can inspect voice quality.

Further, since the received voice data is converted into analog voice and the analog voice is transmitted to the inspection device, the inspection device can detect an abnormality on the transmitting side of the wireless device. Further, since the received voice data is converted into analog voice and the analog voice is transmitted to the inspection device, the subjective voice quality of the transmitted voice by the wireless device can be inspected. In addition, if voice-encoded voice data is converted into analog voice at the same level as the quality evaluation of received voice, the quality of voice transmission from the wireless device in the inspection device without dispatching an inspection worker to the wireless device side. Can be inspected. In addition, subjective evaluation of voice in a wireless device, which could not be done without dispatching an inspection worker to the installation position of the wireless device, can be performed without dispatching an inspection worker. Further, since the control command includes information for specifying the voice coding method, the voice coding method can be changed. Further, since the control command includes information on the timing at which the radio wave should be transmitted, the timing at which the signal is transmitted can be changed for each wireless device.

The present invention has been described above based on the examples. This embodiment is an example, and it is understood by those skilled in the art that various modifications are possible for each of these components and combinations of each processing process, and that such modifications are also within the scope of the present invention. ..

At the time of reception inspection, the wireless device 20 in this embodiment is decoded into analog voice and then encoded again. However, the present invention is not limited to this, and for example, the encoded voice before being decoded into analog voice may be modulated by the transmission frequency and transmitted as a radio wave. According to this modification, the degree of freedom of configuration can be expanded.

10 Inspection device, 20 Radio device, 30 Processing unit, 32 Speaker, 34 Control unit, 36 Display unit, 38 Operation unit, 40 I / F, 42 Microphone, 50 Demodulation unit, 52 Voice receiver, 54 Data receiver, 56 Switch unit, 58 voice coding unit, 60 data recording unit, 62 voice decoding unit, 64 voice transmission unit, 66 data transmission unit, 68 modulation unit, 80 relay device, 100 inspection system.

Claims (2)

An inspection device that transmits analog voice or radio waves containing control information that specifies one relay device to be inspected for reception from multiple relay devices.
A plurality of relay devices that receive radio waves from the inspection device, and
A first relay device that receives radio waves from the inspection device and controls the plurality of relay devices is provided.
The first relay device is
The first demodulation unit that demodulates radio waves,
A first receiving unit that acquires the control information by decoding the demodulation result in the first demodulation unit.
It is provided with a first connection unit that is connected to the plurality of relay devices and instructs the one relay device to be in the reception inspection state according to the control information.
The plurality of relay devices are
A second connection unit that is connected to the first connection unit and puts the self-relaying device in the reception inspection state according to the instruction of the first relay device.
The second demodulation unit that demodulates radio waves,
An audio receiving unit that generates analog audio by decoding the demodulation result in the second demodulation unit,
A voice coding unit that generates voice data by voice-coding the analog voice generated in the voice receiving unit, and a voice coding unit.
A data recording unit that records voice data generated in the voice coding unit, and a data recording unit.
A data transmission unit that encodes the voice data recorded in the data recording unit, and
The transmission unit includes a modulation unit that generates radio waves containing audio data by modulating the encoded audio data.
An inspection system characterized by that. An inspection device that transmits voice-encoded voice data or radio waves containing control information that specifies one relay device to be inspected for transmission from multiple relay devices.
A plurality of relay devices that receive radio waves from the inspection device, and
A first relay device that receives radio waves from the inspection device and controls the plurality of relay devices is provided.
The first relay device is
The first demodulation unit that demodulates radio waves,
A first receiving unit that acquires the control information by decoding the demodulation result in the first demodulation unit.
The plurality of relay devices are connected to the plurality of relay devices, and include a first connection unit that instructs the one relay device to be in a transmission inspection state according to the control information.
A second connection unit that is connected to the first connection unit and puts the self-relaying device in a transmission inspection state according to the instruction of the first relay device.
The second demodulation unit that demodulates radio waves,
A data receiving unit that decodes the demodulation result in the second demodulation unit, and
A data recording unit that records the voice data decoded by the data receiving unit, and a data recording unit.
A voice decoding unit that generates analog voice by voice decoding of voice data recorded in the data recording unit, and a voice decoding unit.
An audio transmission unit that encodes analog audio generated by the audio decoding unit, and
The voice transmission unit includes a modulation unit that generates radio waves including analog voice by modulating the encoded analog voice.
An inspection system characterized by that.

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