KR102159735B1 - Long range join server and information processing method therefor - Google Patents

Abstract

The disclosed LoRa terminal device and a LoRa join server device connected to a plurality of LoRa network server devices constituting a LoRa network include a communication unit that transmits and receives data to and from the LoRa network server device, and a service for a LoRa terminal device among a plurality of LoRa network server devices. It includes a data storage unit for storing a profile including information on the involved LoRa network server devices, and a control unit, and the control unit includes two or more LoRa network server devices among a plurality of LoRa network server devices to service LoRa terminal devices based on the profile. When it is determined that the server device is involved, the communication unit controls to request at least one of the two or more LoRa network server devices to delete information on the LoRa terminal device.

Description

LoRa join server device and its information processing method {LONG RANGE JOIN SERVER AND INFORMATION PROCESSING METHOD THEREFOR}

The present invention relates to a LoRa (Long Range) terminal device and a LoRa join server device connected to a LoRa network server device constituting a LoRa network, and an information processing method performed by the LoRa join server device.

The Internet of Things (IoT) refers to intelligent technologies and services that connect various objects through networks such as the Internet so that information between people and objects and objects and objects can communicate with each other. The IoT is a more advanced technology compared to existing wired/wireless communication, and can be used in various fields such as unmanned meters, unmanned vending machines, intelligent transportation services, and real-time monitoring medical services. According to the research results and analysis of IoT devices, the number of IoT access devices is expected to increase to about 30 billion by 2025, and accordingly, research on IoT application is being actively conducted.

Conventionally, Wi-Fi, Bluetooth, and the like have been used as a communication method for constructing such an IoT system. However, such methods have a disadvantage that communication is possible only in a relatively short distance, and thus, is not suitable for an IoT system that needs to cover a wide range. The communication method for the IoT needs to be designed to cover a wide range as described above, but also to reduce power consumption for IoT devices in which charging restrictions and continuous power supply are often required. Accordingly, a demand for so-called Low Power Wide-Area (LPWA) has emerged. LPWA is a collective term for IoT network technology specialized for small data transmission, which allows low-speed transmission of 1 kbps or less, has wide area coverage and low power consumption.

The LoRa (Long Range) network is one of these LPWA networks. In general, the IoT system does not require high-speed real-time data transmission and reception. Power consumption is reduced by adopting a downlink asymmetric transmission method. The LoRa network is an IoT-only network that can accommodate low-performance devices with small batteries for the implementation of the Internet of Small Things, and can provide coverage with a speed of 293bps to 5.4kbps and a sensitivity of -143dbm. In addition, due to the limitations of data transmission and reception as described above, the LoRa network terminal device cannot receive the data transmitted from the LoRa network base station device only after a certain period of time has elapsed after transmitting the transmission data to the LoRa network base station device. have.

Meanwhile, the LoRa network can be composed of a LoRa terminal device, a LoRa base station device, and a LoRa network server device.

In such a LoRa network, a LoRa network server device that will be in charge of LoRa service is assigned to each LoRa terminal device, and if a failure occurs in the LoRa network server device assigned to a random LoRa terminal device, another LoRa network server device without a failure is assigned to the random LoRa terminal device. When the failure is recovered, the original LoRa network server device is re-allocated to any LoRa terminal device.

In this way, in case a failure occurs, a LoRa network server device in charge of LoRa service to an arbitrary LoRa terminal device is operated by redundancy. If the LoRa network is operated for a long period of time, failure and recovery can occur several times. Information on LoRa terminal devices that have not been recently allocated to the network server device is accumulated, and the accumulated unnecessary information erode the resources of the LoRa network server device, so there is a problem that adversely affects the LoRa service.

Korean Patent Application Publication No. 10-2018-0025613 (published on Mar. 9, 2018)

According to an embodiment, a LoRa join server device capable of managing resources of a LoRa network server device is provided.

In addition, a method of processing information for resource management of a LoRa network server device in a LoRa join server device is provided.

The problem to be solved of the present invention is not limited to those mentioned above, and another problem to be solved that is not mentioned will be clearly understood by those of ordinary skill in the art from the following description.

According to a first aspect, a LoRa join server device connected to a LoRa terminal device and a plurality of LoRa network server devices constituting a LoRa network includes a communication unit for transmitting and receiving data with the LoRa network server device, and one of the plurality of LoRa network server devices. A data storage unit for storing a profile including information on a LoRa network server device involved in a service for the LoRa terminal device, and a control unit, wherein the control unit includes the plurality of LoRa networks in the service based on the profile. When it is determined that two or more LoRa network server devices among server devices are involved, the communication unit controls to request at least one of the two or more LoRa network server devices to delete information on the LoRa terminal device.

According to a second aspect, the information processing method performed by a LoRa terminal device and a LoRa join server device connected to a plurality of LoRa network server devices constituting a LoRa network, is a service for the LoRa terminal device among the plurality of LoRa network server devices. Storing a profile including information on the LoRa network server device involved in the data storage unit, and determining that at least two LoRa network server devices among the plurality of LoRa network server devices are involved in the service based on the profile If so, requesting deletion of information on the LoRa terminal device from at least one of the two or more LoRa network server devices.

According to an embodiment of the present invention, when two or more LoRa network server devices are involved in a service for one LoRa terminal device, the corresponding LoRa corresponds to at least one of two or more LoRa network server devices involved in the service for the corresponding LoRa terminal device. You can request deletion of information on the terminal device. When the LoRa network server device deletes unnecessary information in response to the information deletion request, the resources of the LoRa network server device, which have been eroded by unnecessary information, can be utilized for the LoRa service, thereby improving the quality of the LoRa service.

1 is a block diagram of a LoRa network system according to an embodiment of the present invention.
2 is a block diagram of a LoRa join server device included in a LoRa network system according to an embodiment of the present invention.
3 is a flowchart of an information processing method performed by a LoRa join server device included in a LoRa network system according to an embodiment of the present invention.
4 is a signal flow diagram illustrating an example of a join operation according to failure occurrence and recovery in a LoRa network system according to an embodiment of the present invention.
5 is a signal flow diagram illustrating another example of a join operation according to failure occurrence and recovery in a LoRa network system according to an embodiment of the present invention.
6 is a signal flow diagram of an information deletion operation performed by a LoRa network server device in a LoRa network system according to an embodiment of the present invention.
7 is a signal flow diagram illustrating an example of a profile update operation performed by a LoRa join server device in a system according to an embodiment of the present invention.
8 is a signal flow diagram illustrating another example of a profile update operation performed by a LoRa join server device in a system according to an embodiment of the present invention.

Advantages and features of the present invention, and a method of achieving them will become apparent with reference to the embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms. It is provided to completely inform the scope of the invention to those who have, and the invention is only defined by the scope of the claims.

In describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in an embodiment of the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout this specification.

1 is a configuration diagram of a LoRa network system according to an embodiment of the present invention, and FIG. 2 is a configuration diagram of a LoRa join server device included in a LoRa network system according to an embodiment of the present invention.

As shown, the LoRa network system includes LoRa terminal devices (11, 12), LoRa base station devices (21, 22, 23, 24), LoRa network server devices (31, 32), application server devices (40), and LoRa joins. It includes a server device (100). However, since the components of the LoRa network system of FIG. 1 and the connection relationship between the components are only an embodiment of the present invention, the technical idea of the present invention is not limitedly interpreted by FIG. 1. For example, the number of each component of the LoRa network system is only an example.

The LoRa terminal devices 11 and 12 may be various IoT devices such as automatic meters and traffic information collection devices. For example, the LoRa terminal devices 11 and 12 may include a mobile communication terminal device installed with a LoRa application for automatic metering and a LoRa application for collecting traffic information.

The LoRa base station devices 21, 22, 23, 24 are uplink packets transmitted from the LoRa terminal devices 11, 12 to the LoRa network server devices 31, 32, and the LoRa terminals in the LoRa network server devices 31, 32. It relays downlink packets transmitted to the devices 11 and 12. The LoRa base station devices 21, 22, 23, and 24 may be connected to the LoRa network server devices 31 and 32 through a wireless backhaul network and/or a wired backhaul network.

The LoRa network server devices 31 and 32 are in charge of selecting a base station device for LoRa service and processing a call to the LoRa terminal devices 11 and 12. These LoRa network server devices 31 and 32 are in charge of services for the LoRa terminal devices 11 and 12 allocated to manage the service. In FIG. 1, a first LoRa network server device 31 is assigned to a service for a first LoRa terminal device 11, and a second LoRa network server device 32 is assigned to a service for a second LoRa terminal device 12. Assigned examples are shown. In addition, the LoRa network server devices 31 and 32 can manage services for other LoRa terminal devices in addition to the previously allocated LoRa terminal devices when a failure of other LoRa network server devices is detected or an allocation command such as a jurisdiction redundancy command is issued. . For example, when a failure occurs in the first LoRa network server device 31, the second LoRa network server device 32 may be in charge of a service for the first LoRa terminal device 11.

The application server device 40 may be included in the LoRa network system as described above, and receives data from the LoRa network server devices 31 and 32, encrypts/decrypts data packets, and provides information to the LoRa terminal devices 11 and 12. Functions such as provision of a specific application service and management/control related to the application service can be performed.

The LoRa join server device 100 performs registration and authentication management (eg, key management) for the LoRa terminal devices 11 and 12, and provides a LoRa for any LoRa terminal device among a plurality of LoRa terminal devices 11 and 12. It indicates which LoRa network server device among the plurality of LoRa network server devices 31 and 32 should perform call processing for the service.

The LoRa join server device 100 includes a communication unit 110, a data storage unit 120, and a communication unit 130 as shown in FIG. 2. However, since the components of the LoRa join server device 100 of FIG. 2 and the functions of each component are only an embodiment of the present invention, the technical idea of the present invention is not limitedly interpreted by FIG. 2.

The communication unit 110 of the LoRa join server device 100 transmits and receives signals to and from the LoRa network server devices 31 and 32 under the control of the controller 130.

The data storage unit 120 of the LoRa join server device 100 contains a profile including information on the LoRa network server device involved in the service to the LoRa terminal devices 11 and 12 among the LoRa network server devices 31 and 32. And stores various types of data resulting from the result of information processing by the control unit 130. The data storage unit 120 may be specifically implemented as a computer-readable recording medium, and examples of the computer-readable recording medium include magnetic media such as hard disks, floppy disks, and magnetic tapes, CD-ROMs, DVDs, and Hardware devices specially configured to store and execute program instructions such as optical media, magneto-optical media such as floptical disks, and flash memory. I can.

The controller 130 of the LoRa join server device 100 provides a service for any LoRa terminal device 11 or 12 based on the profile stored in the data storage unit 120. Two or more of the LoRa network server devices 31 and 32 When it is determined that the LoRa network server device is involved, the communication unit 110 controls to request at least one of the two or more LoRa network server devices to delete information on any LoRa terminal device 11 or 12. For example, the controller 130 generates a session key required for communication between the application server device 40 and the LoRa terminal devices 11 and 12 connected to the LoRa network, and then stores it in the data storage unit 120, and stores the random LoRa. A message requesting deletion of information on the terminal device 11 or 12 may be transmitted to the LoRa network server device 31 or 32 through the communication unit 110. In addition, the control unit 130, when information about the application server device 40 connected to the LoRa network and the generated resource is received from the LoRa network server devices 31 and 32 through the communication unit 110, The information on the profile may be included in the profile and stored in the data storage unit 120. For example, the control unit 130 may be implemented including a microprocessor.

3 is a flowchart of an information processing method performed by the LoRa join server apparatus 100 included in the LoRa network system according to an embodiment of the present invention.

As shown in FIG. 3, the information processing method according to an embodiment includes the step of storing a profile including information on a LoRa network server device involved in a service for a LoRa terminal device among a plurality of LoRa network server devices in a data storage unit. Include. For example, the service for the first LoRa terminal device may be handled by a pre-allocated first LoRa network server device, and when a failure of the first LoRa network server device is detected or an assignment command is issued, the second LoRa network server device It can be in charge of the service for the first LoRa terminal device, and a profile including information on the first LoRa network server device and the second LoRa network server device in charge of the service for the first LoRa terminal device is stored in the data storage unit. I can.

And, the information processing method according to an embodiment is determined that two or more LoRa network server devices among a plurality of LoRa network server devices are involved in a service for a LoRa terminal device based on a profile stored in the data storage unit. A step of requesting deletion of information on the LoRa terminal device from at least one of the network server devices (S220 to S240). For example, if a LoRa terminal device is powered off and then turned on due to a failure and recovery of a LoRa network server device, the join operation can be performed again. If it is determined that the above LoRa network server device is involved, a session key required for communication with other server devices connected to the LoRa network can be created and stored in the data storage unit, and a message requesting deletion of information on any LoRa terminal device is sent. It can be transmitted to any LoRa network server device.

The information processing method performed by the LoRa join server device 100 included in the LoRa network system according to an embodiment of the present invention will be further described below with reference to FIGS. 4 to 8.

4 is a signal flow diagram illustrating an example of a join operation according to failure occurrence and recovery in a LoRa network system according to an embodiment of the present invention. This join operation is a case where the service for the second LoRa terminal device 12 is restored after a failure occurs in the second LoRa network server device 32 while the service for the second LoRa network server device 32 is allocated under the jurisdiction of the second LoRa network server device 32, This is an example in which the second LoRa terminal device 12 requests the second LoRa network server device 32 to join after the failure recovery.

When a failure occurs in the second LoRa network server device 32, the operator assigns the service for the second LoRa terminal device 12 to the jurisdiction of the first LoRa network server device 31 until the failure is restored. It can be entered into the device 100. Alternatively, the first LoRa network server device 31, the second LoRa network server device 32, and the LoRa join server device 100 may periodically transmit and receive status messages to each other, and based on these status messages, the LoRa join server The device 100 may detect that a failure has occurred in the second LoRa network server device 32.

In a state in which a failure occurs in the second LoRa network server device 32, the second LoRa terminal device 12 connects the first LoRa network server device 31 through the nearby LoRa base station devices 21, 22, 23, 24. A join request message is transmitted to and requesting a join (S301).

Subsequently, since the first LoRa network server device 31 does not know which LoRa network server device is under the jurisdiction of the service for the second LoRa terminal device 12, it inquires about the jurisdiction of the LoRa join server device 100 (S303). Then, perform the procedure to receive a response. Here, the LoRa join server device 100 notifies the first LoRa network server device 31 that the service for the second LoRa terminal device 12 is in an assigned state through a jurisdiction response (S305).

Then, the first LoRa network server device 31 requests the LoRa join server device 100 to join the second LoRa terminal device 12 (S307), and the LoRa join server device 100 is the second LoRa terminal device. (12) generates and stores a session key required for communication with the application server device 40, and responds to the joining of the second LoRa terminal device 12 (S309), and the first LoRa network server device 31 Transmits a join acceptance message to the second LoRa terminal device 12 to accept the requested join in step S301 (S311).

Through these steps S301 to S311, the first LoRa network server device 31 stores various information related to the service for the second LoRa terminal device 12, and the data storage unit of the LoRa join server device 100 ( In 120), information on the first LoRa network server device 31 involved in the service to the second LoRa terminal device 12 is stored.

Thereafter, the failure of the second LoRa network server device 32 is recovered, and when the power of the second LoRa terminal device 12 is turned off by the user and then turned on again, the join operation is performed again.

When performing this join operation again, the second LoRa terminal device 12 transmits a join request message to the second LoRa network server device 32 through the nearby LoRa base station devices 21, 22, 23, and 24. A join is requested (S313).

Subsequently, since the second LoRa network server device 32 does not know which LoRa network server device is under the jurisdiction of the service for the second LoRa terminal device 12, it inquires about the jurisdiction of the LoRa join server device 100 (S315). Then, perform the procedure to receive a response. Here, the LoRa join server device 100 notifies the second LoRa network server device 32 that the service for the second LoRa terminal device 12 is allocated through a jurisdiction response (S317).

Then, the second LoRa network server device 32 requests the LoRa join server device 100 to join the second LoRa terminal device 12 (S319), and the LoRa join server device 100 is the second LoRa terminal device. (12) generates and stores a session key required for communication with the application server device 40, and responds to the joining of the second LoRa terminal device 12 (S321), and the second LoRa network server device 32 Transmits a join acceptance message to the second LoRa terminal device 12 to accept the requested join in step S313 (S323).

Meanwhile, as described above, various information related to the service for the second LoRa terminal device 12 was stored in the first LoRa network server device 31 while going through steps S301 to S311, and the second LoRa network server device ( After the failure of 32) is recovered, since the second LoRa network server device 32 is in charge of the service for the second LoRa terminal device 12, the second LoRa terminal device from the perspective of the first LoRa network server device 31 (12) The information on the service corresponds to unnecessary information. Such unnecessary information may adversely affect the LoRa service because it consumes resources of the first LoRa network server device 31.

Therefore, after the LoRa join server device 100 responds to the join of the second LoRa terminal device 12, the profile including information on the LoRa network server device involved in the service to the second LoRa terminal device 12 On the basis of, it is checked whether two or more of the LoRa network server devices are involved in the service for the second LoRa terminal device 12, and two or more of the LoRa network server devices are involved in the service for the second LoRa terminal device 12. If it is determined that it is determined that, a message requesting deletion of information on the second LoRa terminal device 120 is transmitted to at least one of the two or more LoRa network server devices. For example, the LoRa join server device 100 is a second LoRa network server device 31 in charge of a service to the second LoRa terminal device 12 during a failure of the second LoRa network server device 32. A request is made to delete information stored in relation to the LoRa terminal device 12 (S325).

Then, the first LoRa network server device 31 deletes various information related to the service for the second LoRa terminal device 12 accumulated through steps S301 to S311, and then responds to the information deletion request in step S325. It responds to the LoRa join server device 100 (S327).

5 is a signal flow diagram illustrating another example of a join operation according to failure occurrence and recovery in a LoRa network system according to an embodiment of the present invention. This join operation is a case where the service for the second LoRa terminal device 12 is restored after a failure occurs in the second LoRa network server device 32 while the service for the second LoRa network server device 32 is allocated under the jurisdiction of the second LoRa network server device 32, This is an example in which the second LoRa terminal device 12 requests the first LoRa network server device 31 to join after failure recovery.

When a failure occurs in the second LoRa network server device 32, the operator assigns the service for the second LoRa terminal device 12 to the jurisdiction of the first LoRa network server device 31 until the failure is restored. It can be entered into the device 100. Alternatively, the first LoRa network server device 31, the second LoRa network server device 32, and the LoRa join server device 100 may periodically transmit and receive status messages to each other, and based on these status messages, the LoRa join server The device 100 may detect that a failure has occurred in the second LoRa network server device 32.

In a state in which a failure occurs in the second LoRa network server device 32, the second LoRa terminal device 12 connects the first LoRa network server device 31 through the nearby LoRa base station devices 21, 22, 23, 24. A join request message is transmitted to and requesting a join (S401).

Subsequently, since the first LoRa network server device 31 does not know which LoRa network server device is under the jurisdiction of the service for the second LoRa terminal device 12, it queries the LoRa join server device 100 for jurisdiction (S403). Then, perform the procedure to receive a response. Here, the LoRa join server device 100 notifies the first LoRa network server device 31 that the service for the second LoRa terminal device 12 is in an assigned state through a jurisdiction response (S405).

Then, the first LoRa network server device 31 requests the LoRa join server device 100 to join the second LoRa terminal device 12 (S407), and the LoRa join server device 100 is the second LoRa terminal device. (12) generates and stores a session key required for communication with the application server device 40, and responds to the joining of the second LoRa terminal device 12 (S409), and the first LoRa network server device 31 Transmits a join acceptance message to the second LoRa terminal device 12 to accept the join requested in step S301 (S411).

Through these steps S401 to S411, various information related to the service for the second LoRa terminal device 12 is stored in the first LoRa network server device 31, and a data storage unit of the LoRa join server device 100 ( In 120), information on the first LoRa network server device 31 involved in the service to the second LoRa terminal device 12 is stored.

Thereafter, the failure of the second LoRa network server device 32 is recovered, and when the power of the second LoRa terminal device 12 is turned off by the user and then turned on again, the join operation is performed again.

When performing this join operation again, the second LoRa terminal device 12 transmits a join request message to the first LoRa network server device 31 through the nearby LoRa base station devices 21, 22, 23, and 24. A join is requested (S413).

Subsequently, since the first LoRa network server device 31 does not know which LoRa network server device has jurisdiction over which service for the second LoRa terminal device 12 is under the jurisdiction of the LoRa network server device, it inquires about the jurisdiction of the LoRa join server device 100 (S415). Then, perform the procedure to receive a response. Here, the LoRa join server device 100 indicates that the service for the second LoRa terminal device 12 is allocated to the second LoRa network server device 32 to the first LoRa network server device 31 through a jurisdiction response. Inform (S417).

Then, the first LoRa network server device 31 requests the second LoRa network server device 32 to join the second LoRa terminal device 12 (S419), and the second LoRa network server device 32 is 2 The join request for the LoRa terminal device 12 is transmitted to the LoRa join server device 100 (S421), and in the LoRa join server device 100, the second LoRa terminal device 12 is connected to the application server device 40. A session key required for communication is generated and stored, and responds to the join of the second LoRa terminal device 12 (S423), and the second LoRa network server device 32 responds to the second LoRa terminal device 12. The join response is transmitted to the first LoRa network server device 31, and the first LoRa network server device 31 transmits a join acceptance message to the second LoRa terminal device 12 to accept the requested join in step S413. (S427).

Meanwhile, as described above, various information related to the service for the second LoRa terminal device 12 was stored in the first LoRa network server device 31 through steps S401 to S427. The second LoRa network server device ( After the failure of 32) is recovered, since the second LoRa network server device 32 is in charge of the service for the second LoRa terminal device 12, the second LoRa terminal device from the perspective of the first LoRa network server device 31 (12) The information on the service corresponds to unnecessary information. Such unnecessary information may adversely affect the LoRa service because it consumes resources of the first LoRa network server device 31.

Therefore, after the LoRa join server device 100 responds to the join of the second LoRa terminal device 12, the profile including information on the LoRa network server device involved in the service to the second LoRa terminal device 12 On the basis of, it is checked whether two or more of the LoRa network server devices are involved in the service for the second LoRa terminal device 12, and two or more of the LoRa network server devices are involved in the service for the second LoRa terminal device 12. If it is determined that it is determined that, a message requesting deletion of information on the second LoRa terminal device 120 is transmitted to at least one of the two or more LoRa network server devices. For example, the LoRa join server device 100 is a second LoRa network server device 31 in charge of a service to the second LoRa terminal device 12 during a failure of the second LoRa network server device 32. A request is made to delete information stored in relation to the LoRa terminal device 12 (S429).

Then, the first LoRa network server device 31 deletes various information related to the service for the second LoRa terminal device 12 accumulated through steps S401 to S427, and then responds to the information deletion request in step S429. It responds to the LoRa join server device 100 (S431).

6 is a signal flow diagram of an information deletion operation performed by a LoRa network server device in a LoRa network system according to an embodiment of the present invention.

As shown in FIG. 4 or 5 described above, the first LoRa network server device 31 may participate in a service for the second LoRa terminal device 12 while a failure of the second LoRa network server device 32 occurs. 2 After the failure of the LoRa network server device 32 is recovered, the second LoRa network server device 32 is in charge of the service for the second LoRa terminal device 12, so the first LoRa network server device 31 enters the position. The information on the service of the second LoRa terminal device 12 corresponds to unnecessary information. Such unnecessary information may adversely affect the LoRa service because it consumes resources of the first LoRa network server device 31.

Therefore, the first LoRa network server device 31 may request the LoRa join server device 100 to check the profile for the second LoRa terminal device 12. For example, when the packet transmission/reception of the second LoRa terminal device 12 does not occur for a preset threshold time, the first LoRa network server device 31 may transmit a second LoRa terminal device to the LoRa join server device 100. You can request confirmation of the profile for 12).

Then, the LoRa join server device 100 checks the profile for the second LoRa terminal device 12 in response to the information confirmation request from the first LoRa network server device 31, and at the current time based on the verified profile. By providing information on the LoRa network server device that has jurisdiction over the service for the second LoRa terminal device 12, it is possible to respond to the information confirmation request in step S501. Accordingly, the first LoRa network server device 31 is accumulated while participating in the service to the second LoRa terminal device 12 during a failure of the second LoRa network server device 32 as shown in FIG. 4 or 5. Various information related to the service for the LoRa terminal device 12 may be deleted (S503).

7 is a signal flow diagram showing an example of a profile update operation performed by a LoRa join server device in the system according to an embodiment of the present invention, wherein the second LoRa terminal device 12 is a second LoRa network server device 32 This is an example of requesting to join.

As shown in FIG. 4 or 5 described above, the first LoRa network server device 31 may participate in a service for the second LoRa terminal device 12 while a failure of the second LoRa network server device 32 occurs. However, if resources such as the application server device 40 and the security key are created before the failure of the second LoRa network server device 32 occurs, the second LoRa terminal device during the failure of the second LoRa network server device 32 The first LoRa network server device 31 involved in the service for (12) cannot grasp the resources created between the second LoRa network server device 32 and the LoRa join server device 100, so the second LoRa terminal When providing a service to the device 12, the resource cannot be provided to the LoRa join server device 100, and thus, the service to the second LoRa terminal device 12 may not be normally performed.

The second LoRa terminal device 12 transmits a join request message to the second LoRa network server device 32 through the nearby LoRa base station devices 21, 22, 23, and 24 to request a join (S601).

Subsequently, since the second LoRa network server device 32 does not know which LoRa network server device is under the jurisdiction of the service for the second LoRa terminal device 12, the second LoRa network server device 32 inquires about the jurisdiction of the LoRa join server device 100 (S603). Then, perform the procedure to receive a response. Here, the LoRa join server device 100 notifies the second LoRa network server device 32 that the service for the second LoRa terminal device 12 is allocated through a jurisdiction response (S605).

Then, the second LoRa network server device 32 requests the LoRa join server device 100 to join the second LoRa terminal device 12 (S607), and the LoRa join server device 100 is the second LoRa terminal device. (12) generates and stores a session key required for communication with the application server device 40, and responds to the join request of the second LoRa terminal device 12 (S609).

Here, the second LoRa network server device 32 and the LoRa join server device 100 generate resources such as a security key required for the second LoRa terminal device 12 to communicate with the application server device 40 ( S611). Then, the second LoRa network server device 32 requests the LoRa join server device 100 to update the profile of the second LoRa terminal device 12 (S613). Then, the LoRa join server device 100 updates the profile for the second LoRa terminal device 12 including resources such as the security key generated in step S611 according to the request of the second LoRa network server device 32. Later, it responds to the profile update request of step S613 (S615).

Then, the second LoRa network server device 32 transmits a join acceptance message to the second LoRa terminal device 12 according to the profile update response of the LoRa join server device 100, thereby performing a join in response to the join request in step S601. Accept (S617).

Thereafter, as shown in FIG. 4 or 5 described above, the first LoRa network server device 31 may participate in a service for the second LoRa terminal device 12 while a failure of the second LoRa network server device 32 occurs. . However, if resources such as the application server device 40 and the security key are created before the failure of the second LoRa network server device 32 occurs, the second LoRa terminal device during the failure of the second LoRa network server device 32 The first LoRa network server device 31 involved in the service for (12) cannot grasp the resources created between the second LoRa network server device 32 and the LoRa join server device 100, so the second LoRa terminal When providing a service to the device 12, the resource cannot be provided to the LoRa join server device 100. However, since the LoRa join server device 100 has updated the profile for the second LoRa terminal device 12 through steps S613 and S615, the service for the second LoRa terminal device 12 is normally provided.

8 is a signal flow diagram showing an example of a profile update operation performed by a LoRa join server device in the system according to an embodiment of the present invention, wherein the second LoRa terminal device 12 is a first LoRa network server device 31 This is an example of requesting to join.

As shown in FIG. 4 or 5 described above, the first LoRa network server device 31 may participate in a service for the second LoRa terminal device 12 while a failure of the second LoRa network server device 32 occurs. However, if resources such as the application server device 40 and the security key are created before the failure of the second LoRa network server device 32 occurs, the second LoRa terminal device during the failure of the second LoRa network server device 32 The first LoRa network server device 31 involved in the service for (12) cannot grasp the resources created between the second LoRa network server device 32 and the LoRa join server device 100, so the second LoRa terminal When providing a service to the device 12, the resource cannot be provided to the LoRa join server device 100, and thus, the service to the second LoRa terminal device 12 may not be normally performed.

The second LoRa terminal device 12 transmits a join request message to the first LoRa network server device 31 through the nearby LoRa base station devices 21, 22, 23, and 24 to request a join (S701).

Subsequently, since the first LoRa network server device 31 does not know which LoRa network server device is under the jurisdiction of the service for the second LoRa terminal device 12, it inquires about the jurisdiction of the LoRa join server device 100 (S703). Then, perform the procedure to receive a response. Here, the LoRa join server device 100 informs the first LoRa network server device 31 that the service for the second LoRa terminal device 12 is allocated to the second LoRa network server device 32 through a competent response. (S705).

Then, the first LoRa network server device 31 requests the second LoRa network server device 32 to join the second LoRa terminal device 12 (S707), and the second LoRa network server device 32 The join for the second LoRa terminal device 12 is transmitted to the join server device 100 (S709), and the LoRa join server device 100 communicates with the application server device 40 by the second LoRa terminal device 12 A session key required to perform an operation is generated and stored, and responds to a join request from the second LoRa terminal device 12 (S711).

Here, the second LoRa network server device 32 and the LoRa join server device 100 generate resources such as a security key required for the second LoRa terminal device 12 to communicate with the application server device 40 ( S713). Then, the second LoRa network server device 32 requests the LoRa join server device 100 to update the profile for the second LoRa terminal device 12 (S715). Then, the LoRa join server device 100 updates the profile for the second LoRa terminal device 12 including resources such as the security key generated in step S713 according to the request of the second LoRa network server device 32. Later, it responds to the profile update request in step S715 (S717).

Then, the second LoRa network server device 32 transmits a join acceptance message to the first LoRa network server device 31 according to the profile update response of the LoRa join server device 100 (S719), and the first LoRa network server The device 31 transmits the join acceptance message to the second LoRa terminal device 12 to accept the join in response to the join request in step S701 (S721).

Thereafter, as shown in FIG. 4 or 5 described above, the first LoRa network server device 31 may participate in a service for the second LoRa terminal device 12 while a failure of the second LoRa network server device 32 occurs. . However, if resources such as the application server device 40 and the security key are created before the failure of the second LoRa network server device 32 occurs, the second LoRa terminal device during the failure of the second LoRa network server device 32 The first LoRa network server device 31 involved in the service for (12) cannot grasp the resources created between the second LoRa network server device 32 and the LoRa join server device 100, so the second LoRa terminal When providing a service to the device 12, the resource cannot be provided to the LoRa join server device 100. However, since the LoRa join server device 100 has updated the profile for the second LoRa terminal device 12 through steps S715 and S717, the service for the second LoRa terminal device 12 is normally provided.

As described so far, according to an embodiment of the present invention, when two or more LoRa network server devices are involved in a service for one LoRa terminal device, two or more LoRa network server devices are involved in a service for the corresponding LoRa terminal device. It is possible to request deletion of information on the corresponding LoRa terminal device from at least one of them. When the LoRa network server device deletes unnecessary information in response to the information deletion request, the resources of the LoRa network server device, which have been eroded by unnecessary information, can be utilized for the LoRa service, thereby improving the quality of the LoRa service.

Combinations of each block in the block diagram attached to the present invention and each step in the flowchart may be performed by computer program instructions. Since these computer program instructions can be mounted on the encoding processor of a general-purpose computer, special purpose computer or other programmable data processing equipment, the instructions executed by the encoding processor of the computer or other programmable data processing equipment are each block of the block diagram or Each step of the flow chart will create a means to perform the functions described. These computer program instructions can also be stored on a computer-usable or computer-readable recording medium that can be directed to a computer or other programmable data processing equipment to implement a function in a specific manner, so that the computer-readable or computer-readable medium. It is also possible to produce an article of manufacture in which the instructions stored on the recording medium contain instruction means for performing the functions described in each block of the block diagram or each step of the flowchart. Computer program instructions can also be mounted on a computer or other programmable data processing equipment, so that a series of operating steps are performed on a computer or other programmable data processing equipment to create a computer-executable process to create a computer or other programmable data processing equipment. It is also possible for the instructions to perform the processing equipment to provide steps for performing the functions described in each block of the block diagram and each step of the flowchart.

In addition, each block or each step may represent a module, segment, or part of code comprising one or more executable instructions for executing the specified logical function(s). In addition, it should be noted that in some alternative embodiments, functions mentioned in blocks or steps may occur out of order. For example, two blocks or steps shown in succession may in fact be performed substantially simultaneously, or the blocks or steps may sometimes be performed in the reverse order depending on the corresponding function.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential quality of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

According to an embodiment of the present invention, by deleting unnecessary information on the LoRa terminal device stored in the LoRa network server device, the resources of the LoRa network server device that have been encroached by unnecessary information can be utilized for the LoRa service. Quality is improved.

The present invention can be applied not only to a LoRa network system but also to various IoT network technology fields.

11, 12: LoRa terminal equipment 21, 22, 23, 24: LoRa base station equipment
31, 32: LoRa network server device 40: Application server device
100: LoRa join server device 110: Communication unit
120: data storage unit 130: control unit

Claims (5)

As a LoRa join server device connected to a LoRa (Long Range) terminal device and a plurality of LoRa network server devices constituting a LoRa network,
A communication unit for transmitting and receiving data with the LoRa network server device,
Information on a pre-allocated first LoRa network server device involved in a service to the LoRa terminal device among the plurality of LoRa network server devices and a second LoRa network server allocated based on a failure of the first LoRa network server device A data storage unit that stores a profile including information on the device,
Including a control unit,
The control unit,
In response to the acceptance of the join request of the LoRa terminal device from the first LoRa network server device, it is confirmed that at least two LoRa network server devices among the plurality of LoRa network server devices are involved in the service based on the profile, Based on the confirmation, controlling the communication unit to request the second LoRa network server device to delete information on the LoRa terminal device.
LoRa join server device. delete The method of claim 1,
The control unit generates a session key required for communication between the LoRa terminal device and another server device connected to the LoRa network, and then transmits a message requesting deletion of the information to the second LoRa network server device through the communication unit. doing
LoRa join server device. The method of claim 1,
The control unit includes information on the resource in the profile when information on the resource generated by another server device connected to the LoRa network is received from one of the plurality of LoRa network server devices through the communication unit. To save
LoRa join server device. As an information processing method performed by a LoRa (Long Range) terminal device and a LoRa join server device connected to a plurality of LoRa network server devices constituting a LoRa network,
Information on a pre-allocated first LoRa network server device involved in a service to the LoRa terminal device among the plurality of LoRa network server devices and a second LoRa network server allocated based on a failure of the first LoRa network server device Storing the profile including information on the device in the data storage unit,
In response to the acceptance of the join request from the LoRa terminal device from the first LoRa network server device, it is confirmed that at least two LoRa network server devices among the plurality of LoRa network server devices are involved in the service based on the profile, And requesting deletion of information on the LoRa terminal device from the second LoRa network server device based on the confirmation
Information processing method of LoRa join server device.

Images