KR20200129144A - Wireless remote monitoring system - Google Patents

Abstract

The elevator monitoring device 12, the LTE terminal 13 constantly connected to APN1 of the LTE line network 30, and a first monitoring center 41 connected to the APN1 to transfer data to and from the elevator monitoring device 12. ), and a wireless remote monitoring system 100 that performs remote monitoring of the first elevator 11 via the LTE line network 30, wherein the elevator monitoring device 12 is connected to the first monitoring center 41 When it is not possible to establish a connection of the LTE terminal 13, the regular connection destination of the LTE terminal 13 is switched from APN1 to APN2 to which the second monitoring center 42 is connected, and data is transferred between the second monitoring center 42 and the second monitoring center 42. Handing over. Thereby, when an abnormality occurs in the LTE line, remote monitoring can be backed up in a simple way.

Description

Wireless remote monitoring system

The present invention relates to a structure of an elevator wireless remote monitoring system using an LTE line network.

The elevator remote monitoring system is used to transfer data between the elevator monitoring device and the monitoring center by wireless communication. As a wireless communication line, an LTE line and a 3G line are used in combination, and when it is not possible to establish an LTE line connection due to radio wave strength or base station failure, a method of switching the LTE line to a 3G line to transfer data is proposed. It is made (for example, see Patent Documents 1 and 2).

JP 2016-208296 A JP 6153902 B

However, in the case of communication between the monitoring center and the elevator monitoring device through the LTE line network, the LTE terminal of the elevator monitoring device is always connected to one access point, so if a connection failure occurs between the LTE terminal and one access point, , Communication between the LTE terminal and the monitoring center becomes impossible, and remote monitoring of the elevator becomes impossible.

In this case, it is considered to perform backup of the LTE terminal and the monitoring center communication using a plurality of access points. However, since the LTE terminal cannot receive signals from an access point other than an access point that is always connected, it has been difficult to backup communication using another access point.

In addition, although it is considered to connect a plurality of LTE terminals to the elevator monitoring apparatus and perform communication backup by redundant communication lines with the monitoring center, there is a problem that the system becomes complicated.

Accordingly, an object of the present invention is to perform backup of remote monitoring in a simple manner when an abnormality occurs in an LTE line in a remote monitoring system using an LTE line network.

The wireless remote monitoring system of the present invention includes an elevator monitoring device connected to an elevator to monitor the operating state of the elevator, an LTE terminal connected to the elevator monitoring device and always connected to one access point in an LTE line network, and the As a wireless remote monitoring system that includes one monitoring center connected to the one access point of the LTE line network to transfer data to and from the elevator monitoring device, and performs remote monitoring of the elevator through the LTE line network. , The elevator monitoring device, when it is not possible to establish a connection with the one monitoring center, the constant connection destination of the LTE terminal from the one access point to another access point to which another monitoring center is connected. By switching, it is characterized in that data is transferred to and from the other monitoring center.

In this way, even when data transfer between the elevator monitoring device and one monitoring center cannot be performed due to the occurrence of a connection failure between the LTE terminal and the access point of the regular connection destination, by switching the access point of the regular connection destination, Data transfer between the elevator monitoring device and other monitoring centers is possible, and remote monitoring of elevators can be backed up by other monitoring centers.

In the wireless remote monitoring system of the present invention, the elevator monitoring device, when the constant connection destination of the LTE terminal is switched to the other access point, even if the constant connection with the other access point is maintained for only a predetermined period. do.

By changing the access point to be connected at all times, the state is maintained for a predetermined period of time, thereby securing access to the elevator monitoring device from another monitoring center and suppressing the release of the remote monitoring backup state.

In the wireless remote monitoring system of the present invention, the elevator monitoring device, after switching the constant access point of the LTE terminal to the other access point, a connection state between the LTE terminal and the one access point at a predetermined interval When is confirmed and the connection with the one access point can be established, the constant connection destination of the LTE terminal may be returned to the one access point.

In this way, by returning to remote monitoring from a normal monitoring center, the load of remote monitoring of other monitoring centers can be reduced to the normal state.

In the wireless remote monitoring system of the present invention, the elevator monitoring device, when the LTE terminal fails to establish a connection with the one monitoring center a predetermined number of times, by switching the constant connection destination of the LTE terminal You can do it.

In this way, it is possible to suppress the occurrence of cumbersome switching of the access point to which the connection is to be connected at all times.

In the wireless remote monitoring system of the present invention, the elevator monitoring device, when the LTE terminal fails to establish a connection with the one monitoring center while the passenger is trapped in the car of the elevator, the LTE terminal It is also good to switch the connection destination of

Thereby, when the occurrence of confinement and the occurrence of a connection failure between the LTE terminal and the access point to which the LTE terminal is always connected overlap, the transfer of data between the elevator monitoring device and the monitoring center can be restored in a short time.

In the wireless remote monitoring system of the present invention, the elevator monitoring device, when an earthquake occurs, does not switch the regular connection destination of the LTE terminal, and connects the one access point and a third access point different from the other access point. Intervening, the elevator status signal at the time of an earthquake may be transmitted to the data receiving server at the time of earthquake.

In the case of an earthquake, it is assumed that a connection failure between many LTE terminals and access points occurs. In this case, if the access points of many LTE terminals are switched at once, the monitoring capability of other monitoring centers may be exceeded. For this reason, the data is transmitted to the data receiving server during the earthquake via the third access point without switching the access point in the event of an earthquake, so that the overall function of the wireless remote monitoring system can be suppressed from deteriorating.

In the wireless remote monitoring system of the present invention, when the connection with the elevator monitoring device cannot be established, the one monitoring center transmits a text message or a short message of a command to change a connection destination from SMS to the LTE. Sending to the terminal, and the elevator monitoring device, when the LTE terminal receives the short message, the constant access destination of the LTE terminal from the one access point to another access point to which the other monitoring center is connected By switching, data may be transferred to and from the other monitoring center.

Normally, the elevator monitoring device performs switching of the constant connection destination of the LTE terminal and cannot be directly switched from the monitoring center, but this makes it possible to switch the access point from the monitoring center.

The wireless remote monitoring system of the present invention includes an elevator monitoring device connected to an elevator installed in a first country to monitor the operating state of the elevator, and an elevator monitoring device that is connected to the elevator monitoring device, and is always connected to one access point in the LTE line network. An LTE terminal and one monitoring center installed in the first country and connected to the one access point of the LTE line network to transfer data to and from the elevator monitoring device, and the LTE line network is interposed. Thus, as a wireless remote monitoring system that performs remote monitoring of the elevator, the elevator monitoring device, when it is not possible to establish a connection with the one monitoring center, the one access destination of the LTE terminal at all times. From the point, switching to another access point to which another monitoring center installed in a second country different from the first country is connected, and transferring data to and from the other monitoring center in the second country. do. Further, in the wireless remote monitoring system of the present invention, the other monitoring center may be connected to the LTE line network via the telephone communication network of the second country.

Thereby, the remote monitoring of elevators can be backed up in monitoring centers installed in other countries.

According to the present invention, in a remote monitoring system using an LTE line network, when an abnormality occurs in an LTE line, remote monitoring can be backed up by a simple method.

1 is a system diagram showing the configuration of a wireless remote monitoring system according to an embodiment.
2 is a flow chart showing the operation of the wireless remote monitoring system of the embodiment.
3 is a system diagram showing a wireless remote monitoring system after switching of an access point.
4 is a flowchart showing another operation of the wireless remote monitoring system of the embodiment.
5 is a system diagram showing a wireless remote monitoring system after switching of an access point by another operation.
6 is a system diagram showing the configuration of a wireless remote monitoring system according to another embodiment.
7 is a system diagram showing another wireless remote monitoring system after switching an access point.

<Configuration of wireless remote monitoring system>

Hereinafter, a wireless remote monitoring system 100 of an embodiment will be described with reference to the drawings. As shown in Fig. 1, the wireless remote monitoring system 100 for remote monitoring of the first and second elevators 11 and 21 includes the first and second elevator monitoring devices 12 and 22 (hereinafter, MOP1, MOP2), the first and second LTE terminals 13 and 23 (hereinafter referred to as LTE1 and LTE2), the LTE line network 30, the first and second monitoring centers 41 and 42, It includes data receiving servers 43 and 44 during the first and second earthquakes.

The first and second monitoring centers (41, 42) installed in the first and second regions are, respectively, of the first and second elevators (11, 21) installed in the first and second regions. Conduct surveillance. Further, the first and second monitoring centers 41 and 42 may monitor a plurality of elevators 11 and 21, respectively. Here, the first region and the second region may be, for example, East Japan and West Japan. In this case, remote monitoring of elevators installed in East Japan is performed by a monitoring center installed in East Japan, and remote monitoring of elevators installed in West Japan is performed by monitoring centers installed in West Japan. The first and second monitoring centers 41 and 42 may be configured with a server storing data of the first and second elevators 11 and 21, an operation panel, and the like.

MOP1 and MOP2 are connected to the first and second elevators 11 and 21, respectively, and the operating state of the first and second elevators 11 and 21 from the respective control devices of the first and second elevators 11 and 21 The data indicating the error or a failure signal, etc. are acquired and stored. LTE1 and LTE2 are connected to MOP1 and MOP2, respectively. MOP1 and MOP2 may be constituted by a computer including a CPU and a memory for processing information therein.

The LTE line network 30 includes four access points APN1 to APN4. LTE1 is always connected to one access point, APN1, and LTE2, to another access point, APN2. The first monitoring center 41 and the second monitoring center 42 are connected to APN1 and APN2, respectively. In addition, a short message system (hereinafter referred to as SMS) for sending short messages to LTE1 and LTE2 is attached to the first and second monitoring centers 41 and 42, respectively.

The first earthquake data reception server 43 and the second earthquake data reception server 44 installed in the first and second regions are connected to APN3 and APN4, respectively.

When the connection state of the LTE line is normal, as shown in the dashed-dotted line 91 in FIG. 1, the MOP1 controls the elevator 11 to control data or failure signals indicating the operating state of the first elevator 11 It acquires from the device, stores it, and transmits the data to the first monitoring center 41 via LTE1 and APN1. Moreover, the 1st monitoring center 41 accesses MOP1 via APN1 and LTE1 by polling, and acquires operation data etc. of the 1st elevator 11 from MOP1. Further, the first monitoring center 41 connects to the intercom in the car of the first elevator 11 via APN1 and LTE1, and makes a call with the passenger in the car. In this way, the MOP1 and the first monitoring center 41 transfer data via APN1.

Similarly, MOP2 transfers data to and from the second monitoring center 42 via APN2, as shown by the dashed-dotted line 92 in FIG. 1.

In the event of an earthquake, the MOP1 connects LTE1 to APN4 as shown in the dashed-dotted line 93 in FIG. 1, and the second earthquake data reception server 44 as shown in the dashed line 94 in FIG. It outputs elevator status signals such as operation data and failure signals at the time of an earthquake. Similarly, MOP2 connects LTE2 to APN3 as shown in the dashed-dotted line 95 in FIG. 1, and sends the data receiving server 43 at the time of an earthquake to the first earthquake data reception server 43 as shown in the broken line 96 in FIG. It outputs elevator status signals such as operation data and fault signals. In this way, when an earthquake occurs, the MOP1 and MOP2 transmit data to the earthquake data receiving server installed in an area different from the area in which the first and second elevators 11 and 21 are installed. In addition, APN3 and APN4 correspond to the third access point.

<MOP1 operation>

Next, the operation of the wireless remote monitoring system 100 when a connection failure between LTE1 and APN1 occurs with reference to FIGS. 2 and 3 will be described. In addition, in the following description, the operation of MOP1 will be described. In addition, the operation of MOP2 is the same as that of MOP1.

As shown in step S101 of Fig. 2, the MOP1 refers to an LTE1 always connected destination as APN1 at startup. If the MOP1 is not always connected to APN1 at the time of startup, the LTE1 is always connected to APN1, and the LTE1 is restarted, and the LTE is always connected to LTE1.

As shown in step S102 of Fig. 2, the MOP1 determines whether the connection between LTE1 and APN1 has been established. If the connection with APN1 is established, it is determined that no connection failure has occurred, and the process proceeds to step S103 of FIG. 2 to maintain a constant connection between LTE1 and APN1, and as shown in step S104, one monitoring center Data is transferred to and from the first monitoring center 41.

On the other hand, when MOP1 cannot establish connection between LTE1 and APN1 in step S102 of FIG. 2, it determines that a communication failure has occurred, and proceeds to step S105 of FIG. In step S105, when MOP1 determines that there is a state in which the passenger is trapped in the car, for example, the intercom button of the first elevator 11 is continuously pressed or the door opening button is continuously pressed. Then, the process proceeds to step S108 of FIG. 2 to switch the LTE1 constant access destination from APN1 to APN2. Thereby, as shown in Fig. 3, LTE1 is always connected to APN2. The MOP1 proceeds to step S109 in Fig. 2 and transfers data to and from the second monitoring center 42, which is another monitoring center connected to APN2, as shown by the dashed-dotted line 91a in Fig. 3.

Thereby, the passenger in the car can make a phone call with the guard of the second monitoring center 42 through the interphone. In this way, when the occurrence of trapping and occurrence of the APN1 and the connection failure overlap, the transfer of data between the MOP1 and the monitoring center can be restored in a short time.

Further, when the MOP1 judges "No" in step S105 of Fig. 2, it proceeds to step S106 of Fig. 2 to check whether the connection recovery operation has been performed a predetermined number of times. And, if it is determined as "No" in step S106 of FIG. 2, the process proceeds to step S107 of FIG. 2, and the LTE1 performs a connection operation with APN1, and returns to step S102 of FIG. 2 to establish a connection with APN1. Check whether or not. Here, the predetermined number of times can be set freely, but may be set to, for example, 3 times, 5 times, 10 times, or the like.

When the connection with APN1 is established by the connection recovery operation, the MOP1 determines "Yes" in step S102 of FIG. 2, and proceeds to steps S103 and S104 of FIG. 2, and the first monitoring center 41 through APN1. Send and receive data between ).

On the other hand, if the connection with APN1 cannot be established even if the connection recovery operation is performed a predetermined number of times, and the state of the connection failure continues, the MOP1 determines "Yes" in steps S102 and S106 of FIG. Proceeds to step S108 of, and the constant access destination of LTE1 is switched from APN1 to APN2 as shown in FIG. 3, and proceeds to step S109 of FIG. 2 to access APN2 as shown in dashed-dotted line 91a of FIG. Data is transferred between the second monitoring center 42, which is another monitoring center that has been established.

When MOP1 transfers data to and from the second monitoring center 42 in step S109 of FIG. 2, as shown in step S110 of FIG. 2, the LTE1 and APN2 are always connected until a predetermined period has elapsed. Keep it. Here, the predetermined period can be set to, for example, 30 minutes or 1 hour.

In this way, even if the connection recovery operation is performed a predetermined number of times, if the connection failure continues, the access point of the connection destination is always switched and the switching state is maintained for a predetermined period. What happens can be suppressed. Further, when the access point is switched to APN2, access to the MOP1 from the second monitoring center 42 can be reliably performed.

If the MOP1 determines "Yes" in step S110 of FIG. 2 after a predetermined period has elapsed, it proceeds to step S111 of FIG. 2 to perform a connection operation between LTE1 and APN1. In addition, when the connection between LTE1 and APN1 is established in step S112 of FIG. 2, the process proceeds to step S113 of FIG. 2, and the constant access destination of LTE1 is returned from APN2 to APN1, and the process proceeds to step S103 of FIG. Always connect. Then, the wireless remote monitoring system 100 returns to the system configuration shown in FIG. Thus, the MOP1 proceeds to step S104 in FIG. 2 to transfer data to and from the first monitoring center 41.

On the other hand, when MOP1 cannot establish connection between LTE1 and APN1 in step S112 of FIG. 2, it proceeds to step S113 of FIG. 2, waits for a predetermined interval, and when time elapses by a predetermined interval, FIG. Returning to step S111 of 2, the connection operation of LTE1 and APN1 is performed. Here, the predetermined interval can be, for example, about 10 minutes or 30 minutes.

MOP1 repeats the operations of step S111 to step S113 of FIG. 2 until the connection between LTE1 and APN1 is established, and when the connection between LTE1 and APN1 is established, the always-on connection destination of LTE1 is APN2 in step S113 of FIG. It returns to APN1 from, and proceeds to steps S103 and S104 in FIG. 2 to connect LTE1 to APN1 at all times to transfer data to and from the first monitoring center 41.

In this way, MOP1 continuously performs the operation of establishing a connection with APN1 after a predetermined period of LTE1 at a predetermined interval, and when the connection between LTE1 and APN1 is established, the connection destination is always returned from APN2 to APN1, and the first monitoring is performed. Since data is transferred to and from the center 41, the load of the second monitoring center 42, which has been increased by the backup of the remote monitoring, can be lowered and returned to the normal state.

<Operation of the first and second monitoring centers>

Next, the operation of the first monitoring center 41 will be described with reference to FIGS. 4 and 5. Further, the operation of the second monitoring center 42 is the same as that of the first monitoring center 41.

As shown in step S201 of Fig. 4, the first monitoring center 41 transmits a polling signal to MOP1 and transmits operation data of the first elevator 11 to MOP1. Therefore, as shown in Fig. 5, when the connection between the first monitoring center 41 and APN1 becomes bad, the MOP1 does not receive a polling signal from the first monitoring center 41 and does not transmit data. , In some cases, it may not be possible to detect that a connection failure has occurred between the first monitoring center 41 and the first monitoring center 41. In this case, the MOP1 does not always switch the connection destination. On the other hand, the 1st monitoring center 41 cannot directly access LTE1 and switch the connection destination of LTE1 at all times. For this reason, a state in which data transfer between the MOP1 and the first monitoring center 41 cannot be performed may continue.

Therefore, when the polling signal cannot be transmitted/received during the polling operation to MOP1 in step S201 of FIG. 4, the first monitoring center 41 determines that the connection with MOP1 is not established in step S202 of FIG. Then, the process proceeds to step S204 in FIG. 4 to determine whether the polling operation has failed a predetermined number of times. And, if the polling operation fails a predetermined number of times, it is determined as "Yes" in step S204 of FIG. 4 and proceeds to step S205 of FIG. 4, and, as shown in FIG. 5, backup of communication in the LTE line network is performed. To do this, a short message is transmitted from the SMS 45 to LTE1, indicating a command to change the connection destination at all times. When LTE1 receives this short message, it outputs a predetermined signal to MOP1. When this predetermined signal is input, the MOP1 executes steps S108 and S109 in Fig. 2, and, as shown in Fig. 5, switches the access point of the always-to-connect from APN1 to APN2. It takes about 1 to 2 minutes to switch the access point of the constant connection destination.

2 to 3 minutes after the first monitoring center 41 sent a short message from SMS to LTE1, when the switching of the access point to which the access point is always connected is finished, the second monitoring center 42 returns to step S206 of FIG. As shown, the polling operation is performed on the MOP1, and operation data of the first elevator 11 and the like are acquired from the MOP1 as shown in steps S207 and S208 in Fig. 2 and the dashed-dotted line 91a in Fig. 5. As shown in steps S207 and S208 of FIG. 4, the second monitoring center 42 proceeds to step S209 of FIG. 4 to transfer data to and from MOP1 after performing data transfer between MOP1 for a predetermined period. Is stopped, the flow returns to step S201 in FIG. 4 to perform a polling operation from the first monitoring center 41 to MOP1. Then, in step S202 of Fig. 4, when the connection with the MOP1 is established, the process proceeds to step S203 of Fig. 4 to transfer data between the first monitoring center 41 and the MOP1.

By the operation as described above, since the access point of the LTE1 constant access point can be switched from the first monitoring center 41, even when a connection failure occurs between the first monitoring center 41 and the APN1, the remote monitoring Backup can be done.

<Action in case of an earthquake>

In the case of an earthquake, it is assumed that many connection problems between LTE1 and APN1 occur. In this case, if many LTE1 access points are switched from APN1 to APN2 at once, the monitoring capability of the second monitoring center 42 may be exceeded. Therefore, MOP1, in the case of a connection failure between LTE1 and APN1 due to an earthquake, does not switch the regular connection destination of LTE1 from APN1 to APN2, and transmits the elevator status signal at the time of the earthquake through APN4 through the second earthquake data. It transmits to the reception server 44. This suppresses the deterioration of the overall function of the wireless remote monitoring system 100. The operation of MOP2 during an earthquake is the same as that of MOP1.

<Wireless remote monitoring system of another embodiment>

A wireless remote monitoring system 200 according to another embodiment will be described with reference to FIGS. 6 and 7. First, parts that are the same as those of the wireless remote monitoring system 100 described with reference to FIG. 1 are denoted by the same reference numerals, and the description is omitted.

As shown in FIG. 6, the wireless remote monitoring system 200 includes a first elevator 11 and a first monitoring center 41 installed in a first country, and a second elevator 21 and a second monitoring center. (42) is installed in a second country different from the first country. Usually, the remote monitoring of the first elevator 11 installed in the first country is performed by the first monitoring center 41 installed in the first country, and the second elevator 21 installed in the second country Remote monitoring is performed by the second monitoring center 42 in the second country.

As shown in Fig. 7, when the connection between LTE1 and APN1 cannot be established, the MOP1 switches the access point of the LTE1 constant connection destination to APN2 to which the second monitoring center 42 is connected. Then, remote monitoring of the first elevator 11 installed in the first country is performed by the second monitoring center 42 installed in the second country.

In this way, it is possible to perform backup of remote monitoring of many elevators installed more widely.

Moreover, the 2nd monitoring center 42 may be comprised so that it may be connected to the LTE line network 30 via the telephone communication network of a 2nd country.

11, 21: elevator
12, 22: Elevator monitoring device (MOP1, MOP2)
13, 23: LTE terminal (LTE1, LTE2)
30: LTE line network
41, 42: surveillance center
43, 44: data receiving server in case of earthquake
45, 46: SMS
100, 200: wireless remote monitoring system.

Claims (9)

An elevator monitoring device connected to an elevator to monitor the operating state of the elevator;
An LTE terminal connected to the elevator monitoring device and always connected to one access point in the LTE line network,
And one monitoring center connected to the one access point of the LTE line network to transfer data to and from the elevator monitoring device,
As a wireless remote monitoring system for remote monitoring of the elevator via the LTE line network,
The elevator monitoring device, when it is not possible to establish a connection with the one monitoring center, switches the regular connection destination of the LTE terminal from the one access point to another access point to which another monitoring center is connected. Thus, the wireless remote monitoring system, characterized in that the data transfer between the said other monitoring center. The method of claim 1,
The elevator monitoring device, when the LTE terminal is constantly connected to the other access point, maintains a constant connection with the other access point for only a predetermined period of time. The method of claim 2,
The elevator monitoring device, after switching the constant access destination of the LTE terminal to the other access point, checks the connection state between the LTE terminal and the one access point at a predetermined interval, and the one access point and When it is possible to establish a connection between the two, the wireless remote monitoring system, characterized in that the always-connected destination of the LTE terminal is returned to the one access point. The method according to any one of claims 1 to 3,
The elevator monitoring device, when the LTE terminal fails to establish a connection with the one monitoring center a predetermined number of times, the wireless remote monitoring system, characterized in that for switching the constant connection destination of the LTE terminal. The method according to any one of claims 1 to 3,
The elevator monitoring device is characterized in that, in a state in which a passenger is trapped in the car of the elevator, when the LTE terminal fails to establish a connection with the one monitoring center, the LTE terminal always switches a connection destination. Wireless remote monitoring system. The method according to any one of claims 1 to 3,
When an earthquake occurs, the elevator monitoring device transmits an elevator status signal at the time of an earthquake through the one access point and a third access point different from the other access point without switching the connection destination of the LTE terminal. Wireless remote monitoring system, characterized in that transmitting to the data reception server in case of an earthquake. The method according to any one of claims 1 to 3,
The one monitoring center, when it is not possible to establish a connection with the elevator monitoring device, sends a short message to the LTE terminal for a command to change the connection destination at all times from SMS,
The elevator monitoring device, when the LTE terminal receives the short message, switches the constant access destination of the LTE terminal from the one access point to another access point to which the other monitoring center is connected, and the other A wireless remote monitoring system, characterized in that data is transferred to and from a monitoring center. An elevator monitoring device connected to an elevator installed in the first country to monitor the operating state of the elevator;
An LTE terminal connected to the elevator monitoring device and always connected to one access point in the LTE line network,
And one monitoring center installed in the first country and connected to the one access point of the LTE line network to transfer data to and from the elevator monitoring device,
As a wireless remote monitoring system for remote monitoring of the elevator through the LTE line network,
The elevator monitoring device, when it is not possible to establish a connection with the one monitoring center, from the one access point to the constant connection destination of the LTE terminal to a second country different from the first country A wireless remote monitoring system, characterized in that, by switching to another access point to which another installed monitoring center is connected, data is transferred to and from the other monitoring center in the second country. The method of claim 8,
And the other monitoring center is connected to the LTE line network through a telephone communication network of the second country.

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