JP6978113B2 - Wireless communication systems, methods and programs - Google Patents

Description

The present invention relates to wireless communication devices, methods and programs, and more particularly to wireless communication devices, methods and programs that perform wireless communication in a changing communication environment.

In point-to-point wireless communication, due to various factors such as failure of the wireless communication device that communicates, deterioration of the communication environment of the wireless communication line between point-to-point due to natural phenomena such as rain and snow, and human error. Communication line failure occurs. The presence or absence of a communication line failure can be recognized by observing a decrease in the received signal level (RSL (Received Signal Level)), an increase in the bit error rate, a interruption of the communication line, and the like. The cause of the failure of the communication line is based on the device failure information acquired from the wireless communication device, the received signal level information, the bit error rate information, and the weather information such as temperature and rainfall measured at the observation station. And it is specified by analyzing the information. However, each of these pieces of information is independent information, and there is a problem that the cause of the communication failure may not be identified. That is, it is difficult to identify whether the cause of the communication failure is a device failure, a natural phenomenon, or an artificial one. In addition, if a failure occurs temporarily and then recovers, it is even more difficult to trace back to the past and identify the cause of the failure.

Various techniques related to communication line failures have been proposed. One of them is disclosed in Patent Document 1. Patent Document 1 discloses a wireless communication device capable of suppressing deterioration of communication quality of a communication line due to mechanical vibration of a structure to which a wireless communication device is attached in point-to-point wireless communication. There is. Specifically, the modulation scheme and / or code rate are adjusted based on the quality indicators associated with the mechanical vibration of the structure to which the antenna is attached, for example. In addition, although the communication line changes depending on the weather conditions, the wireless communication parameters are adjusted according to the change in the communication quality. However, Patent Document 1 does not disclose identifying the cause of communication failure.

In Patent Document 2, it is estimated that the cause of the transfer data not arriving at the user terminal is the rainfall based on the past rainfall data and the C / N data stored in the communication control device in the time series. It has been disclosed. However, the case where there is another cause of communication failure is not disclosed.

International Publication No. 2015/008442 Japanese Unexamined Patent Publication No. 11-122155

As described above, in point-to-point wireless communication, when a communication failure occurs, there is a problem that the cause of the communication failure may not be identified.

The present invention has been made to solve such a problem, and to provide a wireless communication device, a method and a program capable of identifying the cause of a failure when a communication failure occurs. The purpose.

The wireless communication device according to the present invention is a wireless communication device that performs wireless communication with another wireless communication device. The communication environment information acquisition unit that acquires the communication environment information that affects the wireless communication, the communication quality information acquisition unit that acquires the transmission power level of the other wireless communication device that is the communication quality information of the wireless communication, and the above. A control unit that stores the communication environment information corresponding to the time when the communication quality is determined to be less than or equal to a predetermined value based on the communication quality information in the storage unit as cause analysis information for investigating the cause of communication deterioration. Be prepared.

The method according to the present invention includes a step of acquiring communication environment information that affects wireless communication, a step of acquiring a transmission power level of the other wireless communication device which is communication quality information of the wireless communication, and the communication quality. It is provided with a step of storing the communication environment information corresponding to the time when the communication quality is determined to be equal to or less than a predetermined value based on the information in the storage unit as cause analysis information for investigating the cause of communication deterioration.

The program according to the present invention includes a step of acquiring communication environment information that affects wireless communication, a step of acquiring a transmission power level of the other wireless communication device which is communication quality information of the wireless communication, and the communication quality. A step of storing the communication environment information corresponding to the time when the communication quality is determined to be less than or equal to a predetermined value based on the information in the storage unit as cause analysis information for investigating the cause of communication deterioration is executed in the computer. Let me.

According to the present invention, when a communication failure occurs, it is possible to provide a wireless communication device, a method and a program capable of identifying the cause of the failure.

It is a block diagram which illustrates the wireless communication apparatus which concerns on Embodiment 1. FIG. It is a block diagram which illustrates the wireless communication apparatus which concerns on Embodiment 1. FIG. It is a flowchart which illustrates the operation of the monitoring control unit of the wireless communication apparatus which concerns on Embodiment 1. FIG. It is a schematic diagram which illustrates the information stored in the storage part. It is a schematic diagram which illustrates the information stored in the storage part. It is a block diagram which illustrates the wireless communication system which concerns on Embodiment 1. FIG. It is a block diagram which illustrates the wireless communication system which concerns on Embodiment 1. FIG. It is a block diagram which illustrates the wireless communication system which concerns on Embodiment 1. FIG. It is a block diagram which illustrates the wireless communication system which concerns on Embodiment 1. FIG. It is a block diagram which illustrates the wireless communication system which concerns on Embodiment 1. FIG. It is a block diagram which illustrates the wireless communication system which concerns on Embodiment 1. FIG. It is a block diagram which illustrates the wireless communication system which concerns on Embodiment 1. FIG. It is a block diagram which illustrates the wireless communication system which concerns on Embodiment 1. FIG.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In each drawing, the same or corresponding elements are designated by the same reference numerals, and duplicate description will be omitted as necessary for the sake of clarification of the description.

[Embodiment 1]
First, an outline of the wireless communication device 10 according to the first embodiment will be described.
FIG. 1 is a block diagram illustrating the wireless communication device according to the first embodiment.

The wireless communication device 10 according to the first embodiment is a wireless communication device that performs point-to-point wireless communication with another wireless communication device 20.
As shown in FIG. 1, the wireless communication device 10 has a communication environment information acquisition unit 122, a communication quality information acquisition unit 128, a storage unit 123a, and a control unit 125. The communication environment information acquisition unit 122 acquires communication environment information that affects wireless communication. The communication quality information acquisition unit 128 acquires the communication quality information of wireless communication. The control unit 125 stores the communication environment information corresponding to the time t1 when the communication quality is determined to be equal to or less than the predetermined value α based on the communication quality information in the storage unit 123a as the cause analysis information for investigating the cause of the deterioration of the communication. Store.

The wireless communication device 10 according to the first embodiment will be described in detail.
FIG. 2 is a block diagram illustrating the wireless communication device according to the first embodiment.

As shown in FIG. 2, the wireless communication device 10 according to the first embodiment has a wireless unit 110 and a monitoring control unit 120. The radio unit 110 includes a user data interface unit 111, a baseband unit 112, a modem unit 113, and an RF unit 114. The radio unit 110 is connected to the antenna 10a.

The user data interface unit 111 exchanges downlink and uplink user data with an external device to interface with the external device. The direction from the user data interface unit 111 toward the antenna 10a is referred to as descending, and the direction from the antenna 10a toward the user data interface unit 111 is referred to as ascending.

The baseband unit 112 performs a process of converting user data into wireless format transmission data in the downlink, and performs a process of returning the received wireless format data to the user data in the uplink.

In the downlink, the modem unit 113 performs modulation processing and conversion to the intermediate frequency for the data after the baseband processing, and in the uplink, the data converted to the intermediate frequency is converted to the baseband frequency and converted to the intermediate frequency. Perform demodulation processing.

The RF unit 114 converts the frequency of the modulated data from the intermediate frequency to the radio frequency in the downlink, and converts the frequency of the received data from the radio frequency to the intermediate frequency in the uplink.

The antenna 10a radiates the data converted into the radio frequency toward the opposite wireless communication device (another wireless communication device) 20 in the downlink, and receives the data of the radio frequency in the uplink.

Each part of the radio unit 110 has a failure detection function. That is, each of the user data interface unit 111, the baseband unit 112, the modem unit 113, and the RF unit 114 has a failure detection function. Then, using those failure detection functions, the failure of the portion including itself is detected, and it is output to the control unit 125 as failure information.

The RF unit 114 has a transmission power level measurement function for transmission data and a reception level measurement function for reception data.

The baseband unit 112 has a bit error rate measuring function for measuring the bit error rate of the data after the upstream error correction. Instead of the bit error rate of the data after the upstream error correction, the modem unit 113 may measure the bit error rate after the demodulation and use this.

The RF unit 114 measures the transmission power level and outputs it as transmission power level information. Further, the RF unit 114 measures the reception level and outputs it as reception level information. The baseband unit 112 measures the bit error rate and outputs it as bit error rate information.

The transmission power level information, reception level information, and bit error rate information are output to the communication quality information acquisition unit 128, which will be described later.

The monitoring control unit 120 includes a communication environment information acquisition unit 122, a storage unit 123a, another storage unit 123b, a control unit 125, a monitoring control interface unit 126, and a communication quality information acquisition unit 128. The communication environment information acquisition unit 122 has a sensor unit 122a. The other storage unit 123b may be referred to as a storage unit 123b.

The communication environment information acquisition unit 122 acquires monitoring information regarding the communication line with the opposite wireless communication device 20 obtained by using the photographing device 30 provided externally. The photographing device 30 is, for example, a video camera or the like, and photographs the directivity direction of the antenna 10a to obtain monitoring information such as video information. The sensor unit 122a of the communication environment information acquisition unit 122 acquires peripheral information of the wireless communication device 10 by using a sensor. Peripheral information is information that includes at least one of information about vibration, impact, temperature, temperature, and rainfall. The communication environment information acquisition unit 122 outputs these monitoring information and peripheral information to the control unit 125. The monitoring information and peripheral information are referred to as communication environment information. That is, the communication environment information includes at least one of information regarding vibration, impact, temperature, temperature and rainfall, and monitoring information of a communication line for wireless communication.

The storage unit 123a is, for example, a non-volatile storage medium. The storage unit 123a stores cause analysis information for analyzing the cause of the failure. That is, the storage unit 123a stores the cause analysis information for investigating the cause of the deterioration of communication. The storage unit 123a is, for example, a flash memory, and can store information for a long period of time. The storage unit 123b is, for example, a volatile storage medium. The storage unit 123b temporarily stores monitoring information such as video information obtained by the photographing device 30 and all information of peripheral information acquired by the sensor unit 122a. Therefore, the amount of information stored in the storage unit 123b is larger than the amount of information stored in the storage unit 123a. The monitoring control interface unit 126 connects the wireless communication device 10 and the monitoring device 50 provided externally.

The communication quality information acquisition unit 128 acquires transmission power level information, reception level information, and bit error rate information. The transmission power level information, reception level information, and bit error rate information are communication quality information of the communication line. The communication quality information acquisition unit 128 outputs the communication quality information to the control unit 125.

The control unit 125 has, for example, a CPU (Central Processing Unit) and controls the entire wireless communication device 10. The control unit 125 includes communication quality information such as a bit error rate output from the communication quality information acquisition unit 128, failure information of each part output from the radio unit 110, video information output from the photographing device 30, and the like. It manages monitoring information and peripheral information such as vibration, impact, temperature, temperature, and rainfall output from the sensor unit 122a. The control unit 125 determines the occurrence of a failure and the recovery of the failure based on the communication quality information.

When the communication quality information is, for example, an error rate such as a bit error rate or a packet error rate and the error rate is a predetermined value β or more, the control unit 125 determines that a failure has occurred and is less than the predetermined value β. In the case of, it is determined that the failure has been recovered. Further, when the communication quality information is, for example, the reception level and the reception level is the predetermined value γ or less, the control unit 125 determines that a failure has occurred, and when the communication quality information is larger than the predetermined value γ, the failure has been recovered. judge. Further, the communication quality information may be a signal-to-noise ratio, a signal-to-interference wave ratio, or the like. The communication quality information includes at least one of a transmission power level, a reception level, an error rate, a signal-to-noise ratio and a signal-to-interference wave ratio. Further, the control unit 125 has a clock, and when performing point-to-point communication, the time can be synchronized with the opposite wireless communication device 20.

The operation of the wireless communication device 10 according to the first embodiment will be described.

The operation of the radio unit 110 in the downward direction will be described.
User data, which is information to be transmitted from the user, is input to the user data interface unit 111 and then output to the baseband unit 112.

The baseband unit 112 adds synchronization information for wireless data synchronization and error correction information to the user data in order to convert the user data into wireless transmission data. Further, since the baseband unit 112 transmits to the opposite wireless communication device 20 which is the communication partner, the monitoring information, peripheral information, communication quality information, failure information, etc. of the wireless communication device 10 are added to the user data. After that, the user data is subjected to baseband processing and output to the modem unit 113.

The modem unit 113 performs modulation processing and conversion to an intermediate frequency on the user data, and then outputs the user data to the RF unit 114.

The RF unit 114 converts the frequency of the user data from the intermediate frequency to the radio frequency, controls the transmission output, and outputs it to the antenna 10a. User data is radiated from the antenna 10a toward the opposite wireless communication device 20. Further, the RF unit 114 outputs the transmission power level of the user data as the transmission power level information to the control unit 125 via the communication quality information acquisition unit 128.

The operation of the radio unit 110 in the upward direction will be described.
The radio frequency reception data received by the antenna 10a is output to the RF unit 114.

The RF unit 114 converts the frequency of the received data from the radio frequency to the intermediate frequency and outputs it to the modem unit 113. Further, the RF unit 114 outputs the reception level of the received data as the reception level information to the control unit 125 via the communication quality information acquisition unit 128.

The modem unit 113 converts the frequency of the received data from an intermediate frequency into a baseband signal, performs demodulation processing on the received data, and outputs the received data to the baseband unit 112.

The baseband unit 112 performs an error correction process and an operation for obtaining a bit error rate for the received data. The baseband unit 112 separates the monitoring information, peripheral information, communication quality information, failure information, and other failure information added by the communication partner (transmitting side), and returns them to the user data. The baseband unit 112 outputs the bit error rate obtained by this calculation as bit error rate information to the control unit 125 via the communication quality information acquisition unit 128. Further, the baseband unit 112 outputs the failure information of the opposite wireless communication device 20 transmitted from the opposite wireless communication device 20 which is the communication partner to the control unit 125.

The user data is output to the user via the user data interface unit 111.

The failure information detected in each part of the radio unit 110 is output to the control unit 125.

Next, the operation of the monitoring control unit 120 will be described.
FIG. 3 is a flowchart illustrating the operation of the monitoring control unit of the wireless communication device according to the first embodiment.

As shown in FIG. 3, the sensor unit 122a of the communication environment information acquisition unit 122 acquires peripheral information related to the surrounding environment such as vibration, impact, temperature, temperature, and rainfall by using a sensor. The communication environment information acquisition unit 122 acquires monitoring information regarding the communication line acquired by the external photographing device 30. As the monitoring information, for example, using a photographing device 30 such as a video camera, video information in the directivity direction of the antenna 10a is acquired as monitoring information. Information including peripheral information and monitoring information is called communication environment information. That is, the communication environment information acquisition unit 122 acquires communication environment information that affects wireless communication (step S101). Then, the communication environment information acquisition unit 122 outputs the communication environment information to the control unit 125.

The communication quality information acquisition unit 128 acquires communication quality information regarding a communication line with a communication partner and failure information regarding a failure of the wireless communication device 10 (step S102). The failure information is information related to a failure of each part of the wireless unit 110. The communication quality information is, for example, transmission power level information, reception level information, bit error rate information, and the like.

The control unit 125 temporarily stores the monitoring information, peripheral information, communication quality information, and failure information for each time series from the past including the current time in the storage unit 123b. That is, the control unit 125 temporarily stores the time information, the monitoring information, the peripheral information, the communication quality information, and the failure information in the storage unit 123b in association with each other (step S103).

The control unit 125 communicates the communication environment information corresponding to the time when the communication quality is determined to be the predetermined value α or less based on the communication quality information or the time when the failure information is detected and the communication quality information corresponding to the time. It is stored in the storage unit 123a as the cause analysis information for investigating the cause of the deterioration of the above (step S104). The time when the communication quality is determined to be equal to or less than the predetermined value α or the time when the failure information is detected is set as the time t1.

The control unit 125 corresponds to the communication environment information corresponding to the time when the communication quality is determined to be larger than the predetermined value α based on the communication quality information, or the time when the failure is recovered after detecting the failure information, and the time. The communication quality information is stored in the storage unit 123a as cause analysis information for investigating the cause of communication restoration (step S105). The time when it is determined that the communication quality is higher than the predetermined value α or the time when the failure is recovered after the failure information is detected is set as the time t2.

In this example, the failure occurrence time is, for example, the time when the communication quality is determined to be the predetermined value α or less based on the communication quality information, or the time when the failure information is detected, and the time is set to time t1. Further, the failure recovery time is, for example, the time when the communication quality is determined to be larger than the predetermined value α based on the communication quality information, or the time when the failure is recovered after the failure information is detected, and that time is time t2. It is supposed to be.

Further, in the following description, for the sake of simplicity, the time t1 may be described as a time determined to be a predetermined value α or less. Further, the time t2 may be described as a time determined to be larger than the predetermined value α.

Further, the control unit 125 has the failure information (other failure information) of the opposite wireless communication device 20 input from the opposite wireless communication device 20 to the control unit 125 via the communication quality information acquisition unit 128, and the occurrence time of another failure. It is temporarily stored in the storage unit 123b in association with t11.

Further, the control unit 125 temporarily stores the other failure information of the opposite wireless communication device 20 and the recovery time t21 of the other failure in the storage unit 123b. In this example, the time when the other failure occurs is, for example, the time t11 when the communication quality is determined to be the predetermined value α1 or less based on the communication quality information. Further, the recovery time of other failures is set to, for example, the time t21 when it is determined that the communication quality is larger than the predetermined value α1 based on the communication quality information.

Further, the opposite wireless communication device 20 also acquires communication quality information by itself. The opposite wireless communication device 20 stores the communication environment information corresponding to the time t11 when the communication quality is determined to be a predetermined value α1 or less based on the communication quality information acquired by itself in the storage unit 223a described later as the cause analysis information. .. Then, the opposite wireless communication device 20 notifies the wireless communication device 10 of the time t11. When the time t11 when the communication quality is determined to be the predetermined value α1 or less by the opposite wireless communication device 20 is notified from the opposite wireless communication device 20, the control unit 125 of the wireless communication device 10 is determined by the opposite wireless communication device 20. The communication environment information corresponding to the time t11 is stored in the storage unit 123a.

Further, the control unit 125 performs an interface with the external monitoring device 50 via the monitoring control interface unit 126.

FIG. 4 is a schematic diagram illustrating information stored in the storage unit.
FIG. 5 is a schematic diagram illustrating information stored in the storage unit.

As shown in FIGS. 4 and 5, the storage unit 123b includes the areas 123b1 to 123b5.

Various types of information such as video information, transmission power level information, and reception level information are stored in the receivable area of the storage unit 123b with the passage of time. The video information is stored in the area 123b5 of the storage unit 123b with the passage of time, for example. Since the storable area of the storage unit 123b is finite, when the free area of the storage unit 123b is exhausted, the storage unit 123b returns to the originally saved area and is saved in the overwrite format. The storage unit 123b operates as, for example, a ring buffer.

The area 123b1 indicates an area where failure information is stored, the area 123b2 indicates an area where peripheral information is stored, the area 123b3 indicates an area where bit error rate information is stored, and the area 123b4 is. The area where the transmission power level information and the reception level information are stored is shown, and the area 123b5 shows the area where the video information is saved.

FIG. 5 shows that a failure occurred at time t1 and the failure was restored at time t2. Information for the front Δt time and the rear Δt time including the respective times of the failure occurrence time t1 and the failure recovery time t2 is stored in the storage unit 123a as the cause analysis information. The control unit 125 stores the failure information including the monitoring information of the predetermined time 2Δt including the failure occurrence time t1, the peripheral information, the communication quality information, and the failure information in the storage unit 123a different from the storage unit 123b, and the failure unit 125 stores the failure information. The failure information of the predetermined time 2Δt including the restoration time t2 of the above is stored in the storage unit 123a. That is, the control unit 125 stores the communication environment information corresponding to the predetermined time 2Δt including the time t1 determined that the communication quality is equal to or less than the predetermined value α based on the communication quality information in the storage unit 123a.

For example, when the bit error rate increases, the control unit 125 determines that a failure has occurred, and when the bit error rate decreases, determines that the failure has been restored. When the control unit 125 detects the occurrence of a failure of the wireless communication device 10 and the recovery of the failure, the failure occurs with respect to the opposite wireless communication device 20 which is the communication partner and the monitoring device 50 which monitors the wireless communication device 10. And notify event information about disaster recovery. That is, the control unit 125 determines that the communication quality is equal to or less than the predetermined value α based on the communication quality information, that is, the failure occurrence time t1, the content of the failure, the failure recovery time t2, and the recovered recovery. Notifies the content of the above to the opposite wireless communication device 20 which is the other party of communication. The content of the failure includes event information. Further, the content of the failure may be, for example, a part of the failure information such as the monitoring information, the peripheral information, the communication quality information, and the failure information of the wireless communication device 10. Further, the content of the failure may be the content obtained by processing the failure information of the wireless communication device 10 so that the user can easily identify the cause of the failure occurrence and the failure recovery.

Further, the control unit 125 moves and stores information for each Δt time before and after the failure occurrence time t1 from the storage unit 123b to the storage unit 123a. This information is used to analyze the cause of the failure. Since the amount of cause analysis information stored in the storage unit 123a for failure cause analysis is smaller than the amount of information stored in the storage unit 123b, the user can easily identify the cause of the failure occurrence and failure recovery. ..

Further, when the wireless communication device 10 is notified of the event information regarding the occurrence of the failure of the opposite wireless communication device 20 and the recovery of the failure from the opposite wireless communication device 20, the failure of the opposite wireless communication device 20 is notified to the monitoring device 50. Notify event information about the occurrence of. At the same time, the wireless communication device 10 moves and stores information for Δt hours before and after the failure occurrence time t1 from the storage unit 123b to the storage unit 123a.

It is also conceivable that the cause of the failure of the opposite wireless communication device 20 is the wireless communication device 10. For example, there is a case where the transmission power level of the wireless communication device 10 is lowered and the reception level of the opposite wireless communication device 20 is lowered to cause a failure. Therefore, when the opposite wireless communication device 20 notifies the event information regarding the occurrence of the failure of the opposite wireless communication device 20 and the recovery of the failure, the wireless communication device 10 provides information for Δt hours before and after the failure occurrence time t1. , The cause analysis information is moved from the storage unit 123b to the storage unit 123a and stored, and the cause analysis information is used to analyze the cause of the failure.

That is, when the opposite wireless communication device 20 that is the other party of the communication notifies the occurrence time t11 of another failure detected by the opposite wireless communication device 20, the control unit 125 has a predetermined time including the occurrence time t11 of the other failure. Other failure information including the monitoring information, peripheral information, communication quality information, and failure information of the wireless communication device 10 at time 2Δt1 is stored in the storage unit 123a. Further, when the opposite wireless communication device 20 notifies the recovery time t21 of another failure, the control unit 125 transmits other failure information of the wireless communication device 10 having a predetermined time 2Δt1 including the recovery time t21 of the other failure. It is stored in the storage unit 123a.

When the wireless communication device 10 completes the storage of the cause analysis information for Δt hours before and after the failure occurrence time t1, the monitoring device 50 is notified of the storage completion. The cause analysis information stored in the storage unit 123a is taken out from the monitoring device 50 via the monitoring control interface unit 126, and is analyzed by the network administrator.

The capacity of the storable area of the storage unit 123b must be large to some extent so that the failure information can be used even when the information is notified later than the failure occurrence time t1 and the failure recovery time t2. Is desirable.

Further, since the cause analysis information for analyzing the cause of the failure is stored in the storage unit 123a, it can be retrieved even when the power supply of the wireless communication device 10 is stopped.

Further, by enlarging the storable area of the storage unit 123a, it is possible to store information for cause analysis for a plurality of times.

Further, the value of the Δt time before and after the failure occurrence time t1 can be set by the user as a time range effective for the cause analysis.

Next, an example will be described in which a failure occurs in the downlink line L1 of the communication line between the wireless communication device 10 and the opposite wireless communication device 20.
FIG. 6 is a block diagram illustrating the wireless communication system according to the first embodiment.
FIG. 7 is a block diagram illustrating the wireless communication system according to the first embodiment.

As shown in FIG. 6A, the wireless communication system according to the first embodiment monitors and controls the opposite wireless communication device 20 capable of point-to-point communication with the wireless communication device 10 and a plurality of wireless communication devices. The monitoring device 50 is provided.

The wireless communication device 10 and the opposite wireless communication device 20 use the frequency f1 as the radio frequency of the downlink line L1 and the frequency f2 as the radio frequency of the uplink line L2. That is, in this example, the wireless communication device 10 adopts an FDD (Frequency Division Duplex) method in which transmission and reception use different frequencies. The opposite wireless communication device 20 is the same device as the wireless communication device 10 of FIG. 2 described above.

The monitoring device 50 is directly connected to the monitoring control interface unit 126 of the wireless communication device 10, and directly monitors and controls the wireless communication device 10. Further, the monitoring device 50 remotely monitors and controls the opposite wireless communication device 20 via the wireless communication device 10 by the opposite wireless communication using the line L1 and the line L2.

FIG. 6A shows a wireless communication system in a normal case.
6 (B), 6 (C), and 7 (A) to 7 (C) show the operation of the wireless communication system when a communication line failure occurs in the downlink line L1. This operation is performed in the order of FIG. 6 (A), FIG. 6 (B), FIG. 6 (C), FIG. 7 (A), FIG. 7 (B), and FIG. 7 (C).

As shown in FIG. 6B, when a communication line failure occurs in the downlink line L1, the opposite wireless communication device 20 detects the occurrence of the line L1 failure and enters the failure detection state. Then, the opposite wireless communication device 20 notifies the wireless communication device 10 and the monitoring device 50 of the event information regarding the occurrence of the failure of the line L1 detected by the opposite wireless communication device 20 and the failure occurrence time t1. Not only the event information related to the occurrence of the failure, but also a part of the failure information such as the monitoring information, the peripheral information, the communication quality information, and the failure information of the opposite wireless communication device 20 may be notified.

Next, as shown in FIG. 6C, the opposite wireless communication device 20 has monitoring information and peripheral information stored in the storage unit 223b for Δt hours before and after the failure occurrence time t1 of the line L1. The failure information including the communication quality information and the failure information is stored in the storage unit 223a as information for analyzing the cause of the failure of the line L1. While the fault information is being stored, the opposite wireless communication device 20 is in the state of storing the cause analysis information. Further, the wireless communication device 10 notified by the opposite wireless communication device 20 of the event information regarding the occurrence of the failure of the line L1 and the failure occurrence time t1 is in the failure detection state, and the failure of the line L1 is caused to the monitoring device 50. Notify the event information regarding the occurrence and the failure occurrence time t1. The storage unit 223a is, for example, a non-volatile storage medium. The storage unit 223b is, for example, a volatile storage medium. The storage unit 223b may be referred to as another storage unit 223b.

Next, as shown in FIG. 7A, when the storage of the cause analysis information in the storage unit 223a is completed and the cause analysis information storage is completed, the opposite wireless communication device 20 transmits the cause analysis information to the monitoring device 50. , Notifies the completion of saving of the cause analysis information via the line L2 and the wireless communication device 10. Further, in parallel, similarly to the opposite wireless communication device 20, the wireless communication device 10 is Δt before and after the failure occurrence time t1 of the line L1 based on the failure occurrence time t1 notified from the opposite wireless communication device 20. The failure information stored in the storage unit 123b in the own device for hours is stored in the storage unit 123a as information for analyzing the cause of the failure of the line L1. While the failure information is being stored, the wireless communication device 10 is in the state of storing the cause analysis information.

Next, as shown in FIG. 7B, when the storage of the cause analysis information in the storage unit 123a is completed and the cause analysis information storage is completed, the wireless communication device 10 transmits the cause analysis information to the monitoring device 50. Notifies the completion of saving the cause analysis information. Further, the opposite wireless communication device 20 is in the failure detection state.

Next, as shown in FIG. 7C, each of the wireless communication device 10 and the opposite wireless communication device 20 completes the acquisition of the cause analysis information. Each of the wireless communication device 10 and the opposite wireless communication device 20 is in a failure detection state until the failure of the line L1 is restored (resolved).

Next, for example, a user such as a network administrator uses the monitoring device 50 to check the failure of one line called the line L1 with the wireless communication device 10 and the opposite wireless communication device 20. That is, the user uses the monitoring device 50 to confirm that the wireless communication device 10 has completed the storage of the cause analysis information and that the opposite wireless communication device 20 has completed the storage of the cause analysis information. After that, the user acquires the cause analysis information stored in each of the storage unit 123a and the storage unit 223a at an arbitrary timing and analyzes the information to identify the cause of the failure of the line L1.

When the line L1 is an obstacle, the user cannot acquire the cause analysis information stored in the storage unit 223a of the opposite wireless communication device 20 via the line L1. In this case, after the line L1 is restored, the user acquires the cause analysis information stored in the storage unit 223a of the opposite wireless communication device 20 via the line L1, or the opposite wireless communication device 20 has a PC (Personal). Computer) etc. are directly connected to acquire the cause analysis information stored in the storage unit 223a.

In this way, since the information of the two wireless communication devices of the wireless communication device 10 and the opposite wireless communication device 20 is confirmed, the accuracy of the cause analysis can be improved.

Further, the network administrator can easily identify the cause of the line failure as follows, for example.

When a failure occurs, the user confirms, for example, the failure information stored in the storage unit 123a, which is a non-volatile storage unit. Then, when it is confirmed that the failure information of the wireless communication device 10 indicates the presence or absence of a failure at the same time as the communication quality information such as the bit error rate is deteriorated, the user causes a failure. The cause can be assumed to be a failure of the wireless communication device 10. That is, when the failure of the wireless communication device 10 can be confirmed from the failure information, the user can identify the cause of the failure as the failure of the wireless communication device 10. Further, when there is a correlation between the deterioration of the communication quality information and the failure information of the wireless communication device 10, the user can determine that the cause of the failure is the failure of the wireless communication device 10.

Further, when the user confirms that the communication quality information has deteriorated with the increase in the amount of rainfall, it can be assumed that the cause of the failure is rainfall. The rainfall may be confirmed by a rainfall sensor or by a video camera.

Further, when the user confirms that the communication quality information has deteriorated with the occurrence of vibration, the cause of the failure can be considered to be vibration. The vibration may be confirmed by a vibration sensor or may be confirmed by a video camera.

When the user confirms that the communication quality information has deteriorated sharply, the user confirms the video information and the like, and confirms whether the communication line is free from obstacles such as birds, small aircraft, and large trailers. If there are any obstacles, the user can assume that the cause of the failure is that the line is cut off by these obstacles. That is, when the user can confirm the shield that blocks the communication line from the monitoring information, the user can identify that the cause of the failure is the shield.

Next, an example when the failure of the line L1 is recovered will be described.
FIG. 8 is a block diagram illustrating the wireless communication system according to the first embodiment.
FIG. 9 is a block diagram illustrating the wireless communication system according to the first embodiment.

The operation is performed in the order of FIG. 8 (A), FIG. 8 (B), FIG. 8 (C), FIG. 9 (A), FIG. 9 (B), and FIG. 9 (C).

FIG. 8A shows a state in which the failure continues in the line L1.
Next, as shown in FIG. 8B, when the failure in the line L1 is restored, the opposite wireless communication device 20 detects that the failure in the line L1 has been restored. Then, the opposite wireless communication device 20 notifies the wireless communication device 10 and the monitoring device 50 of the event information regarding the recovery of the failure of the line L1 and the failure recovery time t2. The opposite wireless communication device 20 is in a normal state (restoration state). The wireless communication device 10 remains in the failure detection state. Not only the event information related to the recovery of the failure, but also a part of the failure information such as the monitoring information, the peripheral information, the communication quality information, and the failure information of the opposite wireless communication device 20 may be notified.

Next, as shown in FIG. 8C, the opposite wireless communication device 20 displays the failure information stored in the storage unit 223b for Δt hours before and after the failure recovery time t2 of the line L1. It is stored in the storage unit 223a as the cause analysis information for the recovery of the failure of L1. The opposite wireless communication device 20 is storing information for cause analysis. Further, the wireless communication device 10 notified by the opposite wireless communication device 20 of the event information regarding the recovery of the failure of the line L1 and the failure recovery time t2 is in the recovery state (normal state), and the line L1 is returned to the monitoring device 50. Notifies the event information regarding the recovery of the failure and the recovery time t2 of the failure.

Next, as shown in FIG. 9A, when the opposite wireless communication device 20 completes the storage of the cause analysis information in the storage unit 223a and reaches the cause analysis information storage completion state, the opposite wireless communication device 20 informs the monitoring device 50. Then, the completion of saving of the cause analysis information is notified via the line L2 and the wireless communication device 10. Further, in parallel, the wireless communication device 10 has its own Δt hours before and after the failure recovery time t2 of the line L1 based on the notified failure recovery time t2, similarly to the opposite wireless communication device 20. The failure information stored in the storage unit 123b in the device is stored in the storage unit 123a as the cause analysis information for the restoration of the line L1. The wireless communication device 10 is in the state of storing information for cause analysis.

Next, as shown in FIG. 9B, when the storage of the cause analysis information in the storage unit 123a is completed and the cause analysis information storage is completed, the wireless communication device 10 causes the monitoring device 50. Notifies the completion of saving the cause analysis information. The opposite wireless communication device 20 is in the restored state (normal state).

Next, as shown in FIG. 9C, the wireless communication device 10 is in a normal state after the storage of the cause analysis information is completed.

Next, the user uses the monitoring device 50 to confirm the restoration of one line called the line L1 with the wireless communication device 10 and the opposite wireless communication device 20. That is, the user uses the monitoring device 50 to confirm that the wireless communication device 10 has completed the storage of the cause analysis information and that the opposite wireless communication device 20 has completed the storage of the cause analysis information. After that, the user acquires the cause analysis information stored in each of the storage unit 123a and the storage unit 223a at an arbitrary timing, analyzes the information, and identifies the cause of recovery from the failure of the line L1.

Next, an example will be described in which a failure occurs in the upstream line L2 of the communication line between the wireless communication device 10 and the opposite wireless communication device 20.
FIG. 10 is a block diagram illustrating the wireless communication system according to the first embodiment.
FIG. 11 is a block diagram illustrating the wireless communication system according to the first embodiment.

FIG. 10A shows a wireless communication system in a normal case.
10 (B), 10 (C), and 11 (A) to 11 (C) show the operation of the wireless communication system when a communication line failure occurs in the upstream line L2. This operation is performed in the order of FIG. 10 (A), FIG. 10 (B), FIG. 10 (C), FIG. 11 (A), FIG. 11 (B), and FIG. 11 (C).

As shown in FIG. 10B, when a communication line failure occurs in the upstream line L2, the wireless communication device 10 detects the occurrence of the line L2 failure and enters the failure detection state. Then, the wireless communication device 10 notifies the opposite wireless communication device 20 and the monitoring device 50 of the event information regarding the occurrence of the failure of the line L2 detected by the wireless communication device 10 and the failure occurrence time t1. Not only the event information related to the occurrence of the failure, but also a part of the failure information such as the monitoring information, the peripheral information, the communication quality information, and the failure information of the wireless communication device 10 may be notified.

Next, as shown in FIG. 10C, the wireless communication device 10 includes monitoring information and peripheral information stored in the storage unit 123b for Δt hours before and after the failure occurrence time t1 of the line L2, respectively. The failure information including the communication quality information and the failure information is stored in the storage unit 123a as information for analyzing the cause of the failure of the line L2. While the failure information is being stored, the wireless communication device 10 is in the state of storing the cause analysis information. Further, the opposite wireless communication device 20 notified by the wireless communication device 10 of the event information regarding the occurrence of the failure of the line L2 and the failure occurrence time t1 is in the failure detection state. The opposite wireless communication device 20 performs an operation of notifying the monitoring device 50 of the event information regarding the occurrence of the failure of the line L2 and the failure occurrence time t1, but since the failure has occurred in the line L2, the event information and the event information The failure occurrence time t1 has not arrived.

Next, as shown in FIG. 11A, when the storage of the cause analysis information in the storage unit 123a is completed and the cause analysis information storage is completed, the wireless communication device 10 informs the monitoring device 50. Notifies the completion of saving the cause analysis information. Further, in parallel, the opposite wireless communication device 20, like the wireless communication device 10, is Δt before and after the failure occurrence time t1 of the line L2 based on the failure occurrence time t1 notified from the wireless communication device 10. The failure information stored in the storage unit 223b in the own device for hours is stored in the storage unit 223a as information for analyzing the cause of the failure of the line L2. While the fault information is being stored, the opposite wireless communication device 20 is in the state of storing the cause analysis information.

Next, as shown in FIG. 11B, the opposite wireless communication device 20 completes the storage of the cause analysis information in the storage unit 223a and enters the cause analysis information storage completion state. The opposite wireless communication device 20 performs an operation of notifying the monitoring device 50 of the completion of saving of the cause analysis information via the line L2 and the wireless communication device 10, but since a failure has occurred in the line L2. I haven't received a notification of the completion of saving.

Next, as shown in FIG. 11C, each of the wireless communication device 10 and the opposite wireless communication device 20 completes the acquisition of the cause analysis information. Each of the wireless communication device 10 and the opposite wireless communication device 20 is in a failure detection state until the failure of the line L2 is restored (resolved).

Next, the user uses the monitoring device 50 to confirm that the storage of the cause analysis information in the storage unit 123a is completed by the notification from the wireless communication device 10. At this time, since the line L2 has a failure, the user cannot confirm the completion of saving the cause analysis information of the opposite wireless communication device 20. However, since the user can confirm that a failure has occurred in the communication line between the wireless communication device 10 and the opposite wireless communication device 20, the cause analysis is performed from the wireless communication device 10 and the opposite wireless communication device 20 at an arbitrary timing. Information can be acquired to identify the cause of the failure of the line L2.

After the failure of the line L2 is restored, the user acquires the cause analysis report stored in the storage unit 223a of the opposite wireless communication device 20 from the monitoring device 50 via the wireless communication device 10 and the line L2. May be good. Further, the user may directly connect a PC or the like to the opposite wireless communication device 20 and acquire the cause analysis report stored in the storage unit 223a.

Next, an example when the failure of the line L2 is recovered will be described.
FIG. 12 is a block diagram illustrating the wireless communication system according to the first embodiment.
FIG. 13 is a block diagram illustrating the wireless communication system according to the first embodiment.

The operation is performed in the order of FIG. 12 (A), FIG. 12 (B), FIG. 12 (C), FIG. 13 (A), FIG. 13 (B), and FIG. 13 (C).

FIG. 12A shows a state in which the failure continues in the line L2.
Next, as shown in FIG. 12B, when the failure in the line L2 is restored (resolved), the wireless communication device 10 detects that the failure in the line L2 has been restored. Then, the wireless communication device 10 notifies the opposite wireless communication device 20 and the monitoring device 50 of the event information regarding the recovery of the failure of the line L2 and the failure recovery time t2. The wireless communication device 10 is in a normal state (restoration state). The opposite wireless communication device 20 remains in the fault detection state.

Next, as shown in FIG. 12C, the wireless communication device 10 transfers the failure information stored in the storage unit 123b for Δt hours before and after the failure recovery time t2 of the line L2 to the line L2. It is stored in the storage unit 123a as information for analyzing the cause of the recovery of the failure. The wireless communication device 10 is storing information for cause analysis. At the same time, the opposite wireless communication device 20 notified by the wireless communication device 10 of the event information regarding the recovery of the failure of the line L2 and the failure recovery time t2 is in the recovery state (normal state), and the monitoring device 50 is in the recovery state. On the other hand, the event information regarding the recovery of the failure of the line L2 and the recovery time t2 of the failure are notified via the line L2 and the monitoring control interface unit 126 of the wireless communication device 10.

Next, as shown in FIG. 13A, when the storage of the cause analysis information in the storage unit 123a is completed and the cause analysis information storage is completed, the wireless communication device 10 causes the monitoring device 50. , Notifies the completion of saving the cause analysis information. Further, in parallel, the opposite wireless communication device 20, like the wireless communication device 10, has Δt hours before and after the failure recovery time t2 of the line L2 based on the notified failure recovery time t2. The failure information stored in the storage unit 223b in the own device is stored in the storage unit 223a as the cause analysis information for the restoration of the line L2. The opposite wireless communication device 20 is in the state of storing information for cause analysis.

Next, as shown in FIG. 13 (B), when the opposite wireless communication device 20 completes the storage of the cause analysis information in the storage unit 223a and reaches the cause analysis information storage completion state, the opposite wireless communication device 20 informs the monitoring device 50. Notification of the completion of saving of the cause analysis information is performed via the line L2 and the monitoring control interface unit 126 of the wireless communication device 10. The wireless communication device 10 is in the restored state (normal state).

Next, as shown in FIG. 13C, the opposite wireless communication device 20 goes into a normal state after completing the storage of the cause analysis information.

Next, the user uses the monitoring device 50 to confirm the restoration of one line called the line L2 with respect to the opposite wireless communication device 20 and the wireless communication device 10. That is, the user confirms that the opposite wireless communication device 20 has completed the storage of the cause analysis information and the wireless communication device 10 has completed the storage of the cause analysis information by using the monitoring device 50. After that, the user acquires and analyzes the cause analysis information stored in each of the storage unit 123a and the storage unit 223a at an arbitrary timing, and identifies the recovery cause of the failure of the line L2.

In the first embodiment, monitoring information acquired by using a photographing device 30 such as a video camera, peripheral information acquired by a sensor, communication quality information related to a communication line, and failure information of a wireless communication device are used. The occurrence and recovery of the failure are determined. Then, the external environment (peripheral information) of the wireless communication device can be easily grasped at the time of failure occurrence and failure recovery. This makes it possible to easily identify the cause of line failure caused by natural phenomena such as rainfall, storms, and lightning damage, which are external factors, and human disasters such as mischief.

Further, in the first embodiment, when a line failure occurs, the opposite wireless communication device 20 is notified that the line failure has occurred. As a result, a user such as a network administrator obtains information for cause analysis of two devices, the wireless communication device 10 and the opposite wireless communication device 20 related to the line in which the failure has occurred. As a result, the user can identify which of the wireless communication device 10 and the opposite wireless communication device 20 causes the line failure.

Further, in the first embodiment, the failure information for Δt hours before and after each of the failure occurrence time t1 and the failure recovery time t2 is stored in the non-volatile storage unit. As a result, the amount of failure information stored in the non-volatile storage unit can be minimized.

In the first embodiment, the present invention shows an example in which the wireless communication method is FDD, but the present invention is not limited thereto. The present invention can also be implemented, for example, in the case of a TDD (Time Division Duplex) system as a wireless communication system.

Further, in the first embodiment, for example, the user causes the failure based on the failure information for Δt hours before and after each of the failure occurrence time t1 and the failure recovery time t2 of the line L1. To identify. Apart from this, the failure of a communication line other than the wireless communication line, such as a failure of a wired communication line, is caused by adding a video camera of the shooting device 30 or changing the installation position of the video camera. It is also applicable to identify the cause.

Further, in the above-described embodiment, the present invention has been described as a hardware configuration, but the present invention is not limited thereto. The present invention can also realize the processing of each component by causing a CPU (Central Processing Unit) to execute a computer program.

In the above example, the program can be stored and supplied to a computer using various types of non-transitory computer readable medium. Non-temporary computer-readable media include various types of real-world storage media. Examples of non-temporary computer-readable media include magnetic recording media (eg, flexible disks, magnetic tapes, hard disk drives), magneto-optical recording media (eg, magneto-optical disks), CD-ROMs (Read Only Memory), CD-Rs. It includes a CD-R / W, a semiconductor memory (for example, a mask ROM, a PROM (Programable ROM), an EPROM (Erasable PROM)), a flash ROM, and a RAM (Random Access Memory). The program may also be supplied to the computer by various types of transient computer readable medium. Examples of temporary computer-readable media include electrical, optical, and electromagnetic waves. The temporary computer-readable medium can supply the program to the computer via a wired communication path such as an electric wire and an optical fiber, or a wireless communication path.

The present invention is not limited to the above embodiment, and can be appropriately modified without departing from the spirit.

10 ... Wireless communication device 10a, 20a ... Antenna 20 ... Opposite wireless communication device 30, 31 ... Imaging device 50 ... Monitoring device 110, 210 ... Wireless section 111 ... User data interface section 112 ... Base band section 113 ... Modem section 114 ... RF Units 120, 220 ... Monitoring control unit 122 ... Communication environment information acquisition unit 122a ... Sensor unit 123a ... 223a ... Storage unit 123b1 to 123b5 ... Area 123b, 223b ... Other storage unit 125 ... Control unit 126 ... Monitoring control interface unit 128 ... Communication quality information acquisition unit t1, t11 ... Failure occurrence time t2, t21 ... Failure recovery time Δt, Δt1 ... Time α, α1, β, γ ... Predetermined values L1, L2 ... Line

Claims (3)

A wireless communication device, an opposite wireless communication device capable of communicating with the wireless communication device, and a monitoring device connected only to the wireless communication device are provided.
The opposite wireless communication device is
When a failure of the downlink communication line from the wireless communication device to the opposite wireless communication device occurs, the wireless unit of the opposite wireless communication device that detects the occurrence of the failure of the downlink communication line, and
The event information regarding the occurrence of the failure of the downlink communication line and the time of occurrence of the failure of the downlink communication line are stored, and the monitoring information of the opposite wireless communication device and its surroundings for a predetermined period including the time of occurrence of the failure of the downlink communication line. It has a storage unit of the opposite wireless communication device, which further stores failure information including information, communication quality information, and failure information.
The wireless communication device is
A storage unit of the wireless communication device that stores failure information including monitoring information, peripheral information, communication quality information, and failure information of the wireless communication device for a predetermined period.
It has a wireless unit of the wireless communication device that acquires the failure information of the opposite wireless communication device, and has.
The monitoring device is
The failure information of the wireless communication device and the failure information of the opposite wireless communication device are taken out, and the cause of the failure of the downlink communication line is specified based on the taken out failure information.
Wireless communication system. A method of a wireless communication system including a wireless communication device, an opposite wireless communication device capable of communicating with the wireless communication device, and a monitoring device connected only to the wireless communication device .
The opposite wireless communication device
When a failure of the downlink communication line from the wireless communication device to the opposite wireless communication device occurs, the occurrence of the failure of the downlink communication line is detected.
The event information regarding the occurrence of the failure of the downlink communication line and the time of occurrence of the failure of the downlink communication line are stored, and the monitoring information of the opposite wireless communication device and its surroundings for a predetermined period including the time of occurrence of the failure of the downlink communication line. Further save failure information, including information and communication quality information and failure information,
The wireless communication device
Failure information including monitoring information, peripheral information, communication quality information, and failure information of the wireless communication device for the predetermined period is stored.
The failure information of the opposite wireless communication device is acquired, and the failure information is acquired.
The monitoring device
The failure information of the wireless communication device and the failure information of the opposite wireless communication device are taken out, and the cause of the failure of the downlink communication line is specified based on the taken out failure information.
Method. A program of a wireless communication system including a wireless communication device, an opposite wireless communication device capable of communicating with the wireless communication device, and a monitoring device connected only to the wireless communication device.
The opposite wireless communication device
When a failure of the downlink communication line from the wireless communication device to the opposite wireless communication device occurs, the occurrence of the failure of the downlink communication line is detected.
The event information regarding the occurrence of the failure of the downlink communication line and the time of occurrence of the failure of the downlink communication line are stored, and the monitoring information of the opposite wireless communication device and its surroundings for a predetermined period including the time of occurrence of the failure of the downlink communication line. Further save failure information, including information and communication quality information and failure information,
The wireless communication device
Failure information including monitoring information, peripheral information, communication quality information, and failure information of the wireless communication device for the predetermined period is stored.
The failure information of the opposite wireless communication device is acquired, and the failure information is acquired.
The monitoring device
The failure information of the wireless communication device and the failure information of the opposite wireless communication device are taken out, and the cause of the failure of the downlink communication line is specified based on the taken out failure information.
A program that lets a computer do things.

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