KR20200049225A - Long range join server and information processing method therefor - Google Patents

Abstract

An objective of the present invention is to eliminate retransmission of downlink messages by non-sequential generation of downlink count values. A long-range (LoRa) network server device making up a LoRa Network with a LoRa join server device and a plurality of LoRa terminal devices comprises: a communication unit to transceive data with the LoRa terminal devices and the LoRa join server device; a data storage unit to store a profile including information on an assignment state of a LoRa service for a first LoRa terminal device which has requested a join among the plurality of LoRa terminal devices; and a control unit. The control unit counts downlink data to be transmitted to the first LoRa terminal device when the downlink data is received by the communication unit, checks whether a LoRa service is temporarily assigned to the first LoRa terminal device based on the profile, increases a downlink count value received from the LoRa join server device via the communication unit by a preset value if the downlink data is counted for the first time, and then controls the communication unit to transmit the downlink data to the first LoRa terminal device by including the downlink count value in the downlink data.

Description

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

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

The Internet of Things (IoT) refers to intelligent technologies and services that connect various things through a network such as the Internet so that people and things, information between things and things can communicate with each other. The IoT is a more advanced technology than conventional wired / wireless communication, and can be used in various fields such as unmanned meter, unmanned vending machine, intelligent transportation service, and real-time monitoring medical service. According to the results of IoT device-related research and analysis, the number of IoT-connected devices is expected to increase to about 30 billion by 2025, and accordingly, research on IoT utilization is actively being conducted.

Conventionally, Wi-Fi, Bluetooth, etc. have been used as a communication method for the construction of the IoT system. However, these methods are disadvantageous in that they can communicate only at a relatively short distance and are not suitable for IoT systems that need to cover a wide range. The communication method for the Internet of Things needs to be designed so that it can cover a wide range as described above, but has low power consumption for the Internet of Things devices where there are many cases where charging restrictions and continuous power supply are required. Accordingly, a demand for so-called low power wide-area (LPWA) has emerged. LPWA is a general term for IoT network technology specialized in small data transmission, where low-speed transmission of 1 kbps or less is acceptable and has characteristics of wide area coverage and low power consumption.

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

The LoRa network may consist of a LoRa terminal device, a LoRa base station device, and a LoRa network server device.

In this LoRa network, a LoRa network server device for LoRa service is allocated to each LoRa terminal device, and when a failure occurs in the first LoRa network server device allocated to any LoRa terminal device, the second LoRa network server device without a failure is random LoRa It is assigned to the terminal device, and when the failure is recovered, the original first LoRa network server device is re-assigned to any LoRa terminal device.

In this way, in case of a failure, the LoRa network server device in charge of the LoRa service for an arbitrary LoRa terminal device is operated in a dual state with a main assignment state and a temporary assignment state, and the LoRa network server device is responsible for call processing as well as LoRa Responsible for the transmission processing of downlink data to be transmitted to the terminal device and uplink data transmitted from the LoRa terminal device.

On the other hand, in the LoRa network, uplink data is counted by the LoRa terminal device, downlink data is counted by the LoRa network server device, and the counted uplink / downlink count values are transmitted in the header of the data. Here, the LoRa terminal device and the LoRa network server device normally process only when the count values included in the uplink / downlink data are sequential.

The second LoRa network server device downlinks in a situation where the LoRa service for the LoRa terminal device is temporarily allocated to the second LoRa network server device due to a failure in the first LoRa network server device to which the LoRa service for the LoRa terminal device is mainly allocated. When the downlink data including the count value for the data is downlink-delivered to the LoRa terminal device, the LoRa terminal device receives from the second LoRa network server device than the downlink coefficient value received from the first LoRa network server device. The downlink count value may be smaller. As described above, when the downlink count value is not sequential, the LoRa terminal device determines that it is an abnormal situation despite the normal situation and does not transmit a response message. Then, there is a problem in that the transmitting side of the downlink message performs retransmission for the downlink message as the response (Ack) message is not received.

In addition, when the failure of the first LoRa network server device is recovered and the LoRa service for the LoRa terminal device is mainly allocated to the first LoRa network server device, the LoRa terminal device receives uplink data including a count value for the uplink data. It can transmit to the first LoRa network server device. However, since the count value for the uplink data exceeds the preset maximum value, the count value of the uplink data that the first LoRa network server device has processed before the failure occurs is currently counted again from "1". A situation may occur that is larger than the count value included in the uplink data of. As described above, when the uplink count values are not sequential, the first LoRa network server device determines that it is an abnormal situation in spite of being a normal situation, and there is a problem of discarding the corresponding uplink data without transmitting it.

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

According to an embodiment, there is provided a LoRa network server device and a method for processing the information to prevent retransmission of a downlink message due to non-sequential generation of the downlink count value.

And, it provides a LoRa network server apparatus and a method for processing the information so that the discard processing of the uplink data does not occur due to the non-sequential generation of the uplink count value.

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 having ordinary knowledge to which the present invention belongs from the following description.

According to a first aspect, a LoRa join server device and a plurality of LoRa terminal devices and a LoRa network server device constituting a LoRa network include a communication unit for transmitting and receiving data to and from the LoRa terminal device and the LoRa join server device, and the plurality of LoRa A data storage unit for storing a profile including information on an allocation state of a LoRa service for a first LoRa terminal device requesting a join among terminal devices, and a control unit, wherein the control unit is transmitted to the first LoRa terminal device When downlink data to be received is counted, the downlink data is counted, and if the downlink data is first counted after confirming whether to temporarily allocate a LoRa service to the first LoRa terminal device based on the profile, the LoRa The downlink count value received from the join server device through the communication unit is increased by a preset value. Thereafter, the communication unit is controlled to be included in the downlink data and transmitted to the first LoRa terminal device.

According to a second aspect, a LoRa join server device and a plurality of LoRa terminal devices and a LoRa network server device constituting a LoRa network include a communication unit transmitting and receiving data to and from the LoRa terminal device and the LoRa join server device, and the plurality of LoRa A data storage unit for storing a profile including information on an allocation state of a LoRa service for a first LoRa terminal device requesting a join among terminal devices, and a control unit, wherein the control unit is transmitted from the first LoRa terminal device After confirming whether temporary uplink data is received by the communication unit and temporarily assigning a LoRa service to the first LoRa terminal device based on the profile, an uplink count value and a preset value included in the uplink data Based on the result of comparing the request to update the profile for the first LoRa terminal device to the LoRa join server device Controls lock the communication section.

According to a third aspect, an information processing method performed by a LoRa join server device and a plurality of LoRa terminal devices and a LoRa network server device constituting a LoRa network includes: a first LoRa terminal device requesting a join among the plurality of LoRa terminal devices; Storing a profile including information on the allocation status of the LoRa service for the data storage unit, downlink data to be transmitted to the first LoRa terminal device is received, and based on the profile, the first LoRa terminal If the downlink data is the first time after confirming whether the LoRa service is temporarily allocated to the device, requesting the LoRa join server device to receive the downlink count value, and the received downlink count value by a preset value. After increasing, including in the downlink data and transmitting to the first LoRa terminal device.

According to a fourth aspect, an information processing method performed by a LoRa join server device and a plurality of LoRa terminal devices and a LoRa network server device constituting a LoRa network includes: a first LoRa terminal device requesting a join among the plurality of LoRa terminal devices; Storing a profile including information on the allocation status of the LoRa service for the data storage unit, uplink data transmitted from the first LoRa terminal device is received, and based on the profile, the first LoRa terminal device After checking whether the LoRa service is temporarily allocated, comparing the uplink count value and a preset value included in the uplink data, and based on a result of comparing the uplink count value with the preset value. And requesting the LoRa join server device to update the profile for the first LoRa terminal device.

According to an embodiment of the present invention, when there is a possibility of retransmission of a downlink message due to non-sequential generation of the downlink count value, the LoRa network server apparatus changes the downlink count value and transmits it, thereby changing the ratio of the downlink count value. Avoid retransmission of downlink messages due to sequential generation.

In addition, when there is a fear that the uplink data discarding process may occur due to the non-sequential generation of the uplink count value, the LoRa network server device requests information update related to the LoRa join server device, thereby causing the non-sequential generation of the uplink count value. Therefore, the uplink data is not disposed of.

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 network server device included in a LoRa network system according to an embodiment of the present invention.
3 is a flowchart illustrating an example of an information processing method for downlink data performed by a LoRa network server device included in a LoRa network system according to an embodiment of the present invention.
4 is a flowchart illustrating an example of an information processing method for uplink data performed by a LoRa network server device included in a LoRa network system according to an embodiment of the present invention.
5 is a signal flow diagram illustrating an example of transmitting downlink data according to a failure and recovery in a LoRa network system according to an embodiment of the present invention.
6 is a signal flow diagram illustrating an example of transmitting uplink data according to failure and recovery in a LoRa network system according to an embodiment of the present invention.

Advantages and features of the present invention, and methods for achieving them will be clarified with reference to 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, and only the embodiments allow the disclosure of the present invention to be complete, and common knowledge in the art to which the present invention pertains It is provided to completely inform the person having the scope of the invention, and the present invention is only defined by the scope of the claims.

In describing embodiments of the present invention, when it is determined that a detailed description of known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description 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 a user's or operator's intention or practice. Therefore, the definition should be made based on the contents throughout this specification.

1 is a block diagram of a LoRa network system according to an embodiment of the present invention.

As shown in this, the LoRa network system includes LoRa terminal devices 11 and 12, LoRa base station devices 21, 22, 23 and 24, LoRa network server devices 101 and 102, LoRa join server device 30 and applications. It includes a server device (40). However, since the connection relationship between the components of the LoRa network system of FIG. 1 and each component is only an embodiment of the present invention, the technical spirit 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 mobile communication terminal devices in which LoRa applications for automatic metering, LoRa applications for traffic information collection, and the like are installed.

The LoRa base station devices 21, 22, 23, and 24 are uplink data transmitted from the LoRa terminal devices 11, 12 to the LoRa network server devices 101, 102 and LoRa terminals in the LoRa network server devices 101, 102. The downlink data transmitted to the devices 11 and 12 is relayed. The LoRa base station apparatuses 21, 22, 23, and 24 may be connected to the LoRa network server apparatus 101, 102 through a wireless backhaul network and / or a wired backhaul network.

The LoRa network server devices 101 and 102 are responsible for selecting and calling base station devices for LoRa services for the LoRa terminal devices 11 and 12. The LoRa network server device (101, 102) is in charge of the service for the LoRa terminal device (11, 12) allocated or temporarily assigned to manage the service. In FIG. 1, a first LoRa network server device 101 is mainly allocated to a service for a first LoRa terminal device 11, and a second LoRa network server device 102 is assigned to a service for the second LoRa terminal device 12. Shows the main assignment example. In addition, the LoRa network server devices 101 and 102 temporarily control services for other LoRa terminal devices in addition to the main allocated LoRa terminal device when a failure of another LoRa network server device is detected or a temporary allocation command such as a jurisdiction redundancy command occurs. Can be. For example, when a failure occurs in the first LoRa network server device 101, a LoRa service for the first LoRa terminal device 11 may be temporarily allocated to the second LoRa network server device 102, and the second LoRa network When a failure occurs in the server device 102, a LoRa service for the second LoRa terminal device 12 may be temporarily assigned to the first LoRa network server device 101. In the following description, the LoRa service for the first LoRa terminal device 11 is primarily assigned to the first LoRa network server device 101 and temporarily allocated to the second LoRa network server device 102 to help understand the description. It will be described in consideration of the case where the LoRa service for the second LoRa terminal device 12 is mainly allocated to the second LoRa network server device 102 and temporarily allocated to the first LoRa network server device 101. .

In addition, the LoRa network server devices 101 and 102 transmit and receive downlink data and uplink data to and from the LoRa terminal devices 11 and 12 and the application server device 40. The LoRa network server devices 101 and 102 will be described again with reference to FIG. 2.

The LoRa join server device 30 performs registration and authentication management (eg, key management) for the LoRa terminal devices 11 and 12, and LoRa for any LoRa terminal device among the plurality of LoRa terminal devices 11 and 12 It informs which LoRa network server device among the plurality of LoRa network server devices 101 and 102 to perform call processing for service. The LoRa join server device 30 is the uplink data counted by the first LoRa terminal device 11 from the second LoRa network server device 102 to which the LoRa service for the first LoRa terminal device 11 is temporarily allocated. When a profile update request message including information indicating that the count value of the value has reached the maximum value is received, the LoRa service for the first LoRa terminal device 11 is transferred to the first LoRa network server device 101 assigned as the main. It is possible to request initialization of the count value for uplink data being managed. In addition, the LoRa join server device 30 uplinks counted by the second LoRa terminal device 12 from the first LoRa network server device 101 to which the LoRa service for the second LoRa terminal device 12 is temporarily allocated. When a profile update request message including information that the count value of data has reached the maximum value is received, the second LoRa network server device 102 to which the LoRa service for the second LoRa terminal device 12 is mainly allocated It is possible to request the initialization of the count value for the uplink data that is previously managed. For example, the temporary allocation of call processing for the LoRa service is performed to the LoRa network server device in which no failure occurs when any one of the first LoRa network server device 101 and the second LoRa network server device 102 fails. Can be temporarily assigned.

The application server device 40 receives data from the LoRa network server devices 101 and 102, encrypts / decrypts data packets, provides specific application services to the LoRa terminal devices 11 and 12, and manages related to the application service / Can perform functions such as control. The application server device 40 may transmit downlink data to the LoRa terminal devices 11 and 12 through the LoRa network server devices 101 and 102, and the LoRa terminal device through the LoRa network server devices 101 and 102. Uplink data can be received from (11, 12).

2 is a block diagram of a LoRa network server device 101 included in a LoRa network system according to an embodiment of the present invention.

2, the LoRa network server device 101 includes a communication unit 110, a data storage unit 120, and a control unit 130. Similarly, the LoRa network server device 102 also includes a communication unit 110, a data storage unit 120, and a control unit 130. For example, the control unit 130 may be implemented by including a microprocessor. Since the components of the LoRa network server apparatus 101 of FIG. 2 and the functions of each component are only one embodiment of the present invention, the technical spirit of the present invention is not limitedly interpreted by FIG. 2.

The communication unit 110 of the LoRa network server device 101 transmits and receives various signals to and from the LoRa terminal devices 11 and 12 and the LoRa join server device 30 under the control of the control unit 130. The communication unit 110 transmits the uplink data received from the LoRa terminal devices 11 and 12 to the application server device 40 under the control of the control unit 130 or the downlink data received from the application server device 40. Is transmitted to the LoRa terminal devices 11 and 12.

The data storage unit 120 of the LoRa network server device 101 stores a profile including information on the allocation status of the LoRa service for the LoRa terminal device requesting the join among the plurality of LoRa terminal devices 11 and 12, Various data according to the result of information processing by the control unit 130 are stored. 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, and DVDs. Hardware devices specially configured to store and execute program instructions, such as optical media, magneto-optical media such as floptical disks, and flash memory. Can be.

When the downlink data to be transmitted to the second LoRa terminal device 12 is received by the communication unit 110, the control unit 130 of the LoRa network server device 101 counts the downlink data, and the data storage unit 120 When the downlink data is counted for the first time after it is confirmed as the temporary allocation state of the LoRa service for the second LoRa terminal device 12 based on the profile stored in, it is received from the LoRa join server device 30 through the communication unit 110 After increasing the downlink count value by a preset value, the communication unit 110 is controlled to include the downlink data and transmit it to the second LoRa terminal device 12.

In addition, the control unit 130 may control the communication unit 110 to transmit the count value of the downlink data to the LoRa join server device 30 every predetermined period.

In addition, the control unit 130 receives the uplink data transmitted from the second LoRa terminal device 12 by the communication unit 110, and based on the profile stored in the data storage unit 120, the second LoRa terminal device 12 ), The second LoRa terminal device 12 to the LoRa join server 30 based on the result of comparing the uplink count value and the preset value included in the uplink data to the temporary allocation state of the LoRa service. ) To control the communication unit 110 to request the update of the profile.

In addition, when it is confirmed that the main allocation state of the LoRa service for the second LoRa terminal device 12 is based on the profile stored in the data storage unit 120, the control unit 130 transmits from the second LoRa terminal device 12 If the uplink count value included in the uplink data is smaller than the uplink count value included in the previously transmitted uplink data, the uplink data is discarded, but a specific message is sent from the LoRa join server device 30. When (eg, a request for initializing the previous uplink count value) is received, the corresponding uplink data may be transferred.

3 is a flowchart illustrating an example of an information processing method for downlink data performed by a LoRa network server device included in a LoRa network system according to an embodiment of the present invention.

As shown in FIG. 3, an information processing method according to an example includes storing a profile including information on an allocation state of a LoRa service for a first LoRa terminal device requesting a join among a plurality of LoRa terminal devices in a data storage unit (S301).

And, in the information processing method according to an example, downlink data to be transmitted to the first LoRa terminal device is received (S303), and temporary allocation of the LoRa service to the first LoRa terminal device based on a profile stored in the data storage unit After confirming the state (S305), if the downlink data is the first (S307), a request (S309) to the LoRa join server device further includes receiving a downlink count value (S311).

In addition, the information processing method according to an example further includes the step of increasing the downlink count value received in step S311 by a preset value and including the downlink data to transmit to the first LoRa terminal device (S313).

5 is a signal flow diagram illustrating an example of transmitting downlink data according to a failure and recovery in a LoRa network system according to an embodiment of the present invention. Steps S301 to S313 shown in FIG. 3 are performed by the first LoRa network server device 101 while steps S511 to S514 of FIG. 5 are being performed.

Hereinafter, with reference to FIGS. 1, 2, and 5, a description will be given of a process in which downlink data is transmitted according to a failure and recovery in a LoRa network system. 5, steps S501 to S510 are performed after the LoRa service for the second LoRa terminal device 12 is mainly allocated to the second LoRa network server device 102, and the second LoRa network server device 102 has a failure. This is a case where the LoRa service for the second LoRa terminal device 12 is temporarily allocated to the first LoRa network server device 101 from S511 to S517.

The LoRa service for the second LoRa terminal device 12 is primarily allocated to the second LoRa network server device 102 by the join procedure, and the second LoRa network server device 102 requests the second LoRa terminal device ( 12) stores a profile including information on the main allocation of the LoRa service for the data storage unit 120 (S501, S502).

When the application server 40 transmits downlink data to be transmitted to the second LoRa terminal device 12, the second LoRa network server device 102 counts downlink data. For example, the control unit 130 of the second LoRa network server apparatus 102 may count the count value of the downlink data as "50" (S503).

Subsequently, the second LoRa network server device 102 confirms that the LoRa service for the second LoRa terminal device 12 is mainly allocated based on the profile stored in the data storage unit 120, and the LoRa join server device ( 30) Request a profile (eg, a key value, etc.) for the second LoRa terminal device 12 (S504) to receive a response (S505), and receive the downlink data received in step S503, the second LoRa terminal device 12 Transfer processing to (S506).

The second LoRa terminal device 12 receiving the downlink data transmits a response (Ack) message to the second LoRa network server device 102 (S507), and the second LoRa network server device 102 responds (Ack) ) The message is transmitted to the application server device 40 (S508).

Thereafter, the second LoRa network server device 102 includes the downlink count value of the second LoRa terminal device 12 in the LoRa join server device 30 because the count value for the downlink data has been updated in step S503. Request the update of the profile (S509), and receives a response to the profile update request from the LoRa join server (30) (S510).

These steps S509 and S510 are performed so that the LoRa join server device 30 can manage the downlink count value for the second LoRa terminal device 12, and can be performed whenever the downlink count value is changed. , In consideration of the load of the LoRa join server device 30, it may be performed at predetermined cycles. For example, steps S509 and S510 may be performed whenever the downlink count value for the second LoRa terminal device 12 increases by “50”.

Meanwhile, when a failure occurs in the second LoRa network server apparatus 102, a LoRa service for the second LoRa terminal apparatus 12 is temporarily allocated to the first LoRa network server apparatus 101. The temporary allocation may be by a jurisdiction redundancy command provided by the operator, and the first LoRa according to status information that can be exchanged between the first LoRa network server device 101 and the second LoRa network server device 102. The network server device 101 may detect the occurrence of a failure of the second LoRa network server device 102 and temporarily allocate the LoRa service for the second LoRa terminal device 12 itself.

Thereafter, the application server 40 sharing the state in which the LoRa service for the second LoRa terminal device 12 temporarily allocated to the first LoRa network server device 101 is transmitted to the second LoRa terminal device 12. Link data may be transmitted to the first LoRa network server device 101.

Then, the first LoRa network server device 101 counts downlink data for the second LoRa terminal device 12. At this time, if the first LoRa network server device 101 counts that the downlink data is the first after the LoRa service for the second LoRa terminal device 12 is temporarily allocated, the second LoRa join server device 30 Request the profile including the downlink count value for the terminal device 12 (S512), and receive a profile including the downlink count value through the response of the LoRa join server device (S513).

Then, the first LoRa network server device 101 increases the downlink count value for the second LoRa terminal device 12 received in step S513 by a preset value and includes it in the downlink data to include the second LoRa terminal device. (12). For example, the first LoRa network server device 101 may receive “150” stored in the LoRa join server device 30 according to a preset period as a downlink count value for the second LoRa terminal device 12. Thereafter, after adding "50" to the downlink coefficient value for the received second LoRa terminal device 12 and increasing it, the downlink data transmitted to the second LoRa terminal device 12 is "200" as the downlink coefficient value. It may include "(S514).

Then, in the second LoRa terminal apparatus 12, since the downlink count value included in the downlink data of step S514 is larger than the downlink count value included in the previously received downlink data, the downlink count value is sequentially It is determined as an increasing normal situation (S515), and sends a response (Ack) message to the first LoRa network server device 101 (S516), and the first LoRa network server device 101 applies the response (Ack) message to the application. It is transferred to the server device 40 (S517). The application server device 40 receiving the response (Ack) message performs retransmission for the same downlink data as it is confirmed that the downlink data transmitted in step S511 is normally delivered to the second LoRa terminal device 12. I never do that.

4 is a flowchart illustrating an example of an information processing method for uplink data performed by a LoRa network server device included in a LoRa network system according to an embodiment of the present invention.

As illustrated in FIG. 4, an information processing method according to an example includes storing a profile including information on an allocation state of a LoRa service for a first LoRa terminal device requesting a join among a plurality of LoRa terminal devices in a data storage unit (S401).

And, in the information processing method according to an example, the uplink data transmitted from the first LoRa terminal device is received (S403), and the temporary allocation state of the LoRa service for the first LoRa terminal device based on the profile stored in the data storage unit If it is confirmed as (S405), it further includes the step of comparing the preset value by checking the uplink coefficient value included in the uplink data (S407) (S409).

In addition, the information processing method according to an example is a step of requesting an update of the profile for the first LoRa terminal device to the LoRa join server device based on the result of comparing the uplink count value and the preset value identified in step S407 ( S411).

6 is a signal flow diagram illustrating an example of transmitting uplink data according to failure and recovery in a LoRa network system according to an embodiment of the present invention. Steps S401 to S411 shown in FIG. 4 are performed by the first LoRa network server device 101 while steps S603 to S610 of FIG. 6 are being performed.

Hereinafter, a process in which uplink data is transmitted according to occurrence and recovery of a failure in a LoRa network system will be described with reference to FIGS. 1, 2, and 6.

6 to steps S601 and S602, the LoRa service for the second LoRa terminal device 12 is primarily allocated to the second LoRa network server device 102, and then the step S603 after a failure occurs in the second network server device 102. To S610, the LoRa service for the second LoRa terminal device 12 is temporarily allocated to the first LoRa network server device 101, and after the failure of the second LoRa network server device 102 is recovered, the second to S611 to S619 This is a case where the LoRa service for the LoRa terminal device 12 is mainly allocated to the second LoRa network server device 102.

The LoRa service for the second LoRa terminal device 12 is primarily allocated to the second LoRa network server device 102 by the join procedure, and the second LoRa network server device 102 requests the second LoRa terminal device ( 12) stores a profile including information on the main allocation of the LoRa service for the data storage unit 120 (S601, S602).

However, when a failure occurs in the second LoRa network server apparatus 102, a LoRa service for the second LoRa terminal apparatus 12 is temporarily allocated to the first LoRa network server apparatus 101. The temporary allocation may be by a jurisdiction redundancy command provided by the operator, and the first LoRa according to status information that can be exchanged between the first LoRa network server device 101 and the second LoRa network server device 102. The network server device 101 may detect the occurrence of a failure of the second LoRa network server device 102 and temporarily allocate the LoRa service for the second LoRa terminal device 12 itself. Then, the first LoRa network server device 101 stores the profile including information on the temporary allocation state of the LoRa service for the second LoRa terminal device 12 in the data storage unit 120.

Subsequently, the second LoRa terminal device 12 sharing the temporarily allocated state of the LoRa service for the second LoRa terminal device 12 to the first LoRa network server device 101 is transmitted to the application server device 40. The uplink data may be transmitted to the first LoRa network server device 101. At this time, the second LoRa terminal device 12 counts uplink data and transmits the counted uplink count value in the header of the uplink data. For example, the second LoRa terminal device 12 may count “65535” as the uplink count value, and may include it in the uplink data and transmit it to the first LoRa network server device 101 (S603). .

Then, the first LoRa network server device 101 confirms that the LoRa service for the second LoRa terminal device 12 is temporarily allocated based on the profile stored in the data storage unit 120, and the LoRa join server device ( 30) Request a profile (eg, key value, etc.) for the second LoRa terminal device 12 (S604) and receive a response (S605), and deliver the uplink data received in step S603 to the application server device 40 Processing (S606).

The application server device 40 receiving the uplink data transmits a response (Ack) message to the first LoRa network server device 101 (S607), and the first LoRa network server device 101 responds with an Ack message To the second LoRa terminal device 12 (S608).

On the other hand, the first LoRa network server device 101 checks the uplink coefficient value included in the uplink data received from the second LoRa terminal device 12 in step S603, compares the preset value, and confirms the uplink Based on the result of comparing the count value with the preset value, the LoRa join server device 30 is requested to update the profile for the second LoRa terminal device 12. According to the LoRa network communication standard, the uplink count value is a 16-bit field, and if the uplink count value exceeds "65535", counts again from "1". For example, a value of “65535” may be pre-set in the first LoRa network server device 101, and the first LoRa network server device 101 receives from the second LoRa terminal device 12 in step S603. When the uplink count value included in the uplink data reaches a preset value, the LoRa join server device 30 may request to update the profile for the second LoRa terminal device 12.

Thereafter, after the failure of the second LoRa network server device 102 is recovered, the LoRa service for the second LoRa terminal device 12 is primarily assigned to the second LoRa network server device 102. The return to the main allocation state may be by a jurisdiction return command provided by an operator, and the state information that can be exchanged between the first LoRa network server device 101 and the second LoRa network server device 102 may be determined. Accordingly, the first LoRa network server device 101 can detect the failure recovery of the second LoRa network server device 102 and release the temporary allocation state of the LoRa service for the second LoRa terminal device 12 itself. Then, the second LoRa network server device 101 stores the profile including information on the main allocation state of the LoRa service for the second LoRa terminal device 12 in the data storage unit 120.

Meanwhile, the second LoRa terminal device 12 that shares a state in which the LoRa service for the second LoRa terminal device 12 is primarily assigned to the second LoRa network server device 102 is transmitted to the application server device 40. The uplink data may be transmitted to the second LoRa network server device 102. At this time, the second LoRa terminal device 12 counts uplink data and transmits the counted uplink count value in the header of the uplink data. For example, the second LoRa terminal device 12 may count “8” as an uplink count value, and may include it in the uplink data and transmit it to the second LoRa network server device 102 (S611). .

Then, the second LoRa network server device 102 confirms that the LoRa service for the second LoRa terminal device 12 is mainly allocated based on the profile stored in the data storage unit 120, and the LoRa join server device ( 30) Request a profile (eg, key value, etc.) for the second LoRa terminal device 12 (S612) and receive a response. At this time, the LoRa join server device 30 receives a profile update request message including information that the count value of the uplink data counted by the second LoRa terminal device 12 has reached the maximum value in step S609. Because of this, the second LoRa network server device 102 is requested to initialize the count value for the uplink data previously managed (S613).

Accordingly, in the second LoRa network server apparatus 102, the uplink count value included in the uplink data received from the second LoRa terminal apparatus 12 in step S611 is added to the previously managed uplink data initialized in step S613. Since it is larger than the count value for the upper link, it is determined that the uplink count value is sequentially increased (S614), and the uplink data received in step S611 is transferred to the application server device 40 (S615).

The application server device 40 receiving the uplink data transmits an acknowledgment (Ack) message to the second LoRa network server device 102 (S616), and the second LoRa network server device 102 responds with an Ack message To the second LoRa terminal device 12 (S617).

Thereafter, the second LoRa network server apparatus 102 updates the uplink count of the second LoRa terminal apparatus 12 to the LoRa join server apparatus 30 because the count value for the uplink data has been updated by steps S613 and S615. Request to update the profile including the value (S618), and receives a response to the update request of the profile from the LoRa join server device (S619).

As described so far, according to an embodiment of the present invention, when there is a possibility that retransmission of a downlink message due to non-sequential generation of the downlink count value may occur, the LoRa network server apparatus changes and transmits the downlink count value, The retransmission of the downlink message according to the non-sequential generation of the downlink count value does not occur.

In addition, when there is a fear that the uplink data discarding process may occur due to the non-sequential generation of the uplink count value, the LoRa network server device requests information update related to the LoRa join server device, thereby causing the non-sequential generation of the uplink count value. Therefore, the uplink data is not disposed of.

The combination of each block in the block diagram and each step of the flowchart attached to the present invention may be performed by computer program instructions. Since these computer program instructions may be mounted on an encoding processor of a general purpose computer, special purpose computer, or other programmable data processing equipment, the instructions performed through the encoding processor of a computer or other programmable data processing equipment may include each block in the block diagram or In each step of the flowchart, means are created to perform the functions described. These computer program instructions can also be stored on a computer-readable or computer-readable recording medium that can be oriented to a computer or other programmable data processing equipment to implement a function in a particular way, so that it is computer- or computer-readable. It is also possible for the instructions stored in the recording medium to produce an article of manufacture containing instructions means for performing the functions described in each block or flowchart step of the block diagram. Computer program instructions can also be mounted on a computer or other programmable data processing equipment, so a series of operational steps are performed on a computer or other programmable data processing equipment to create a process that is executed by the computer to generate a computer or other programmable data. It is also possible for instructions to perform processing equipment to provide steps for performing the functions described in each block of the block diagram and in each step of the flowchart.

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

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and variations without departing from the essential quality of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit 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 interpreted as being included in the scope of the present invention.

According to an embodiment of the present invention, retransmission of a downlink message due to non-sequential generation of the downlink count value does not occur, and discard processing of uplink data due to non-sequential generation of the uplink count value does not occur. do.

The present invention can be applied to various IoT network technology fields as well as LoRa network systems.

11, 12: LoRa terminal device 21, 22, 23, 24: LoRa base station device
30: LoRa join server device 40: application server device
101, 102: LoRa network server device 110: communication unit
120: data storage unit 130: control unit

Claims (6)

A LoRa (Long Range) join server device and a plurality of LoRa terminal devices and a LoRa network server device constituting a LoRa network,
Communication unit for transmitting and receiving data with the LoRa terminal device and the LoRa join server device,
A data storage unit for storing a profile including information on an allocation state of a LoRa service for a first LoRa terminal device requesting a join among the plurality of LoRa terminal devices;
It includes a control unit,
The control unit counts the downlink data when downlink data to be transmitted to the first LoRa terminal device is received by the communication unit, and temporarily allocates a LoRa service to the first LoRa terminal device based on the profile. When the downlink data is first counted after checking whether the downlink count value received through the communication unit from the LoRa join server device is increased by a preset value and included in the downlink data, the first LoRa terminal is included. To control the communication unit to transmit to the device
LoRa network server device. According to claim 1,
The control unit controls the communication unit to transmit the count value of the downlink data to the LoRa join server device every predetermined period.
LoRa network server device. A LoRa (Long Range) join server device and a plurality of LoRa terminal devices and a LoRa network server device constituting a LoRa network,
Communication unit for transmitting and receiving data with the LoRa terminal device and the LoRa join server device,
A data storage unit for storing a profile including information on an allocation state of a LoRa service for a first LoRa terminal device requesting a join among the plurality of LoRa terminal devices;
It includes a control unit,
The controller checks whether the uplink data transmitted from the first LoRa terminal device is received by the communication unit and temporarily allocates the LoRa service to the first LoRa terminal device based on the profile. Control the communication unit to request the LoRa join server device to update the profile for the first LoRa terminal device based on the result of comparing the uplink count value included in the data with a preset value.
LoRa network server device. The method of claim 3,
When the controller determines that the main allocation state of the LoRa service for the first LoRa terminal device is based on the profile, the uplink count value included in the uplink data is included in the uplink data previously processed. If it is smaller than the uplink count value, the corresponding uplink data is discarded, but when a specific message is received from the LoRa join server device, the uplink data is transmitted and processed.
LoRa network server device. As a method for processing information performed by a LoRa (Long Range) join server device and a plurality of LoRa terminal devices and a LoRa network server device constituting a LoRa network,
Storing a profile including information on an allocation state of a LoRa service for a first LoRa terminal device requesting a join among the plurality of LoRa terminal devices;
If the downlink data to be transmitted to the first LoRa terminal device is received, and if the downlink data is the first time after checking whether the LoRa service is temporarily allocated to the first LoRa terminal device based on the profile, the LoRa join Requesting the server device to receive a downlink count value,
Increasing the received downlink count value by a preset value and then including the downlink data and transmitting it to the first LoRa terminal device
LoRa network server information processing method comprising a. As a method for processing information performed by a LoRa (Long Range) join server device and a plurality of LoRa terminal devices and a LoRa network server device constituting a LoRa network,
Storing a profile including information on an allocation state of a LoRa service for a first LoRa terminal device requesting a join among the plurality of LoRa terminal devices;
After receiving the uplink data transmitted from the first LoRa terminal device and confirming whether or not the LoRa service is temporarily allocated to the first LoRa terminal device based on the profile, an uplink count value included in the uplink data Comparing the preset value and,
Requesting an update of the profile for the first LoRa terminal device to the LoRa join server device based on a result of comparing the uplink count value with the preset value.
LoRa network server information processing method comprising a.

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