KR102332643B1 - Method for lifecycle management based on location information for subminiature Internet of things device - Google Patents

Abstract

Provided is a method for managing a life cycle based on location information on a subminiature IoT device. According to an embodiment of the present invention, the method for managing a life cycle comprises the steps of: downloading, by a service server, a microservice in a connected edge device; detecting, by the service server, an edge device adjacent to the edge device registered in the service server by downloading the microservice, within a preset range; and adjusting, by the service server, a sensing period of the registered edge device to reduce battery consumption of the registered edge device when the adjacent edge device exists. Accordingly, when a distance between the edge devices is located close to each other equal to or less than a predetermined distance on the basis of location information on the edge devices, sensing coverages are regarded to overlap each other, such that sensing periods of the registered edge device and the adjacent edge devices extend to reduce battery consumption without degradation in quality of service.

Description

Location information-based lifecycle management method for ultra-small IoT devices {Method for lifecycle management based on location information for subminiature Internet of things device}

The present invention relates to a lifecycle management method of a micro IoT device, and more particularly, to a method for managing the life cycle based on location information of a micro IoT device.

In general, it is important to increase the operating time of an edge device in order to perform a smooth IoT service.

That is, since the edge device operates using a battery and continuously performs sensing, it is necessary to minimize battery consumption to perform a service for a target time.

In particular, the most representative method is to adjust the sensing period in order to increase the operation time of the terminal by using a software method. However, as the sensing period is increased, the density of data decreases and the quality of service (QoS) is lowered. can occur

The present invention has been devised to solve the above problems, and an object of the present invention is to consider that the sensing coverage overlaps when the distance between edge devices is close to a certain distance or less based on the location information of the edge device. , to provide a location information-based lifecycle management method capable of reducing battery consumption without reducing service quality by increasing the sensing period of a registered edge device and adjacent edge devices.

According to an embodiment of the present invention for achieving the above object, a lifecycle management method includes: a service server, allowing a microservice to be downloaded to a connected edge device; detecting, by the service server, an edge device adjacent to within a preset range from an edge device that is downloaded and registered in the service server; and adjusting, by the service server, a sensing period of the registered edge device in order to reduce battery consumption of the registered edge device when there is an adjacent edge device.

And the step of detecting the adjacent edge device, generating device arrangement information of a sparse graph type based on a hash table, and using the generated device arrangement information, an edge existing within a preset range from itself device can be detected.

In addition, adjusting the sensing period may cause a sampling rate of a registered edge device to be changed.

In addition, the adjusting of the sensing period may change the sampling rate of another adjacent edge device when the sampling rate of a specific edge device is changed.

In addition, adjusting the sensing period may change the sampling rate in inverse proportion to the number of adjacent edge devices.

In addition, the adjusting of the sensing period may include changing the sampling rates of one or more adjacent edge devices at once by using a hash table.

In this case, the sensing period may be n times when n edge devices are adjacent to each other and the sampling rate of each edge device is reduced to 1/n.

And in the step of adjusting the sensing period, in order to prevent the quality of service (QoS) from being deteriorated, when the sampling rate of each edge device is changed, the service server starts sensing each edge device whose sampling rate is changed. You can adjust the time.

In addition, the adjusting of the sensing period may include adjusting the sensing start times of adjacent edge devices to be different by (sampling period/number of adjacent edge devices).

On the other hand, the lifecycle management system according to another embodiment of the present invention provides a microservice to the edge device, registers the edge device, and detects an edge device adjacent to within a preset range from the registered edge device. , a service server that adjusts the sensing period of the registered edge device in order to reduce battery consumption when there is an adjacent edge device; and an edge device that downloads and installs the microservice and transmits sensing data to the service server every sensing cycle.

And according to another embodiment of the present invention, a lifecycle management method includes: detecting, by a service server, an edge device adjacent to within a preset range from a registered edge device; and adjusting, by the service server, a sensing period of the registered edge device in order to reduce battery consumption of the registered edge device when there is an adjacent edge device.

In addition, the lifecycle management system according to another embodiment of the present invention detects an edge device adjacent to within a preset range from a registered edge device, and when there is an adjacent edge device, to reduce battery consumption, a service server that adjusts the sensing cycle of the edge device; and an edge device that transmits sensing data to the service server every sensing period.

As described above, according to embodiments of the present invention, when the distance between edge devices is located close to a certain distance or less based on the location information of the edge device, sensing coverage is considered to overlap, and the registered edge device and the adjacent By increasing the sensing period of edge devices, it is possible to reduce battery consumption without reducing the quality of service.

1 is a view provided for the description of a location information-based lifecycle management system according to an embodiment of the present invention;
2 is a view provided for the description of a service server according to an embodiment of the present invention;
3 is a diagram provided in the description of an edge device according to an embodiment of the present invention;
4 is a view provided for the description of a location information-based lifecycle management method according to an embodiment of the present invention;
5 is a diagram illustrating device placement information according to an embodiment of the present invention, and
6 is a diagram provided to explain a sensing period adjustment process according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

1 is a view provided for explanation of a location information-based lifecycle management system (hereinafter, collectively referred to as a 'lifecycle management system') according to an embodiment of the present invention.

The lifecycle management system according to this embodiment considers that the sensing coverage overlaps when the distance between the edge devices 200 is close to a certain distance or less based on the location information of the edge device 200, and the registered edge By increasing the sensing period of the device 200 and the adjacent edge devices 200 , battery consumption may be reduced without a decrease in service quality.

To this end, the lifecycle management system according to the service server 100 for registering the edge device 200 by providing microservices to the edge device 200 and microservices to operate the IoT service. It may be composed of an edge device 200 that is downloaded and installed.

The service server 100 may be provided to operate an IoT service, may provide microservices to the edge device 200 , and may register the edge device 200 .

And the service server 100 detects the edge device 200 adjacent to within a preset range from the registered edge device 200, and when the adjacent edge device 200 exists, the battery of the registered edge device 200 In order to reduce consumption, the sensing period of the registered edge device 200 may be adjusted.

Specifically, the service server 100 generates device arrangement information of a sparse graph type based on a hash table generated for the registered edge devices 200, and the generated The edge device 200 existing within a preset range from the registered edge device 200 may be detected using the device arrangement information.

That is, the service server 100 checks the adjacent edge devices 200 when registering the edge device 200 to the edge, and at this time, the information on the adjacent edge devices 200 is poor graph ( It can be managed in the form of a sparse graph).

This is to change the sampling rate of other adjacent edge devices 200 when changing the sampling rate of a specific edge device 200 because the edge devices 200 are not registered at once and may be registered at different times. .

Meanwhile, the service server 100 may change the sampling rate of the registered edge device 200 in order to adjust the sensing period.

At this time, there is a fixed value of the sampling rate for each task. The service server 100 may change the sampling rate in inverse proportion to the number of adjacent edge devices 200, and using a hash table, one or more adjacent edge devices ( 200) can be collectively changed.

That is, the adjusted sensing period may be multiplied by n when the n edge devices 200 are adjacent and the sampling rate of each edge device 200 is reduced to 1/n. For example, the sensing period to be adjusted is that when two edge devices 200 are adjacent to each other and the sampling rate of each edge device 200 is reduced by half, the sensing period is doubled.

And when the sampling rate of the adjacent edge devices 200 is changed, the service server 100 prevents the quality of service (QoS) from being deteriorated. (200) It is possible to adjust the sensing start time.

Specifically, for example, the service server 100 may adjust the sensing start times of the adjacent edge devices 200 to be different by (sampling period/number of adjacent edge devices).

Through this, when the distance between the edge devices 200 is located close to a certain distance or less based on the location information of the edge device 200, the sensing coverage is regarded as overlapping, and the sensing period of the adjacent edge devices 200 is increased Battery consumption can be reduced without reducing the quality of service.

After the edge device 200 is distributed/installed and registered with the service server 100 , the edge device 200 collects sensing data every sensing period and transmits it to the service server 100 .

In addition, a gateway (not shown) may be provided between the service server 100 and the edge device 200 to support communication connection between the server 100 and the device 200 .

2 is a diagram provided to explain the service server 100 according to an embodiment of the present invention.

Referring to FIG. 2 , the service server 100 includes a first communication unit 110 , a first processor 120 , and a storage unit 130 .

The first communication unit 110 may be connected to one or more edge devices 200 , provide microservices, and receive sensing data from the edge device 200 at every sensing cycle.

The storage unit 130 is a storage medium for storing programs and data necessary for the operation of the first processor 120 .

The first processor 120 provides a microservice to the edge device 200 to register the edge device 200 , and an edge device 200 adjacent to within a preset range from the registered edge device 200 . to reduce battery consumption when an adjacent edge device 200 exists by detecting , the sensing period of the registered edge device 200 may be adjusted.

Specifically, the first processor 120 generates device arrangement information of a sparse graph type based on a hash table generated for the registered edge devices 200, and the generated The edge device 200 existing within a preset range from the registered edge device 200 may be detected using the device arrangement information.

Also, the first processor 120 may change a sampling rate of the registered edge device 200 in order to adjust the sensing period.

Specifically, the first processor 120 may change the sampling rate in inverse proportion to the number of adjacent edge devices 200 , and collectively set the sampling rate of one or more adjacent edge devices 200 using a hash table. can be changed

In addition, in order to prevent the quality of service (QoS) from being deteriorated when the sampling rate of the adjacent edge devices 200 is changed, the first processor 120 is The sensing start time of the edge devices 200 may be adjusted.

3 is a view provided for the description of the edge device 200 according to an embodiment of the present invention.

Referring to FIG. 3 , the edge device 200 may include a sensor unit 210 , a second communication unit 220 , and a second processor 230 .

The sensor unit 210 may collect data necessary to support the IoT service.

The second communication unit 220 is provided with a communication module for connecting to the first communication unit 110 .

When the second processor 230 is registered in the service server 100 , it collects sensing data through the sensor unit 210 every sensing period, and transmits it to the service server 100 through the second communication unit 220 . do.

4 is a diagram provided to explain a location information-based lifecycle management method according to an embodiment of the present invention, and FIG. 5 is a diagram illustrating device arrangement information according to an embodiment of the present invention.

Referring to FIG. 4 , the location information-based lifecycle management method according to this embodiment uses the location information-based lifecycle management system described above with reference to FIGS. 1 to 3 to store location information of the edge device 200 . Based on the base, when the distance between the edge devices 200 is located close to a certain distance or less, the sensing period of the registered edge device 200 and the adjacent edge devices 200 may be adjusted.

Specifically, the location information-based lifecycle management method provides a microservice to the edge device 200 through the service server 100 ( S410 ), and provides the edge device 200 to the service server 100 . In order to register and detect an adjacent edge device 200 within a preset range from the registered edge device 200 (S420), and if there is an adjacent edge device 200 (S430-Y), to reduce battery consumption , it is possible to adjust the sensing period of the registered edge device 200 (S440).

The location information-based lifecycle management method is a poor graph (sparse graph) type of device arrangement information as illustrated in FIG. 5 based on a hash table generated for the registered edge devices 200 . may be generated and the edge device 200 existing within a preset range from the registered edge device 200 may be detected using the generated device arrangement information.

Through this, by increasing the sensing period of the registered edge device 200 and the adjacent edge devices 200, it is possible to reduce battery consumption without reducing the quality of service.

6 is a diagram provided to explain in more detail a sensing cycle adjustment process in a location information-based lifecycle management method according to an embodiment of the present invention.

Referring to FIG. 6 , in the location information-based lifecycle management method, when the adjacent edge device 200 exists (S610-Y), in order to adjust the sensing period, the sampling rate of the registered edge device 200 (Sampling) Rate) can be changed (S620).

Specifically, the location information-based lifecycle management method may change the sampling rate in inverse proportion to the number of adjacent edge devices 200, and collectively control the sampling rate of one or more adjacent edge devices 200 using a hash table. can be changed to

In addition, in the location information-based lifecycle management method, when the sampling rate of the adjacent edge devices 200 is changed, in order to prevent the quality of service (QoS) from being deteriorated, the service server 100 determines that the sampling rate is changed. The sensing start time of each edge device 200 may be adjusted (S630).

In addition, the location information-based lifecycle management method may deliver information on the changed sampling rate of each edge device 200 and the adjusted sensing start time to each edge device 200 ( S640 ).

On the other hand, it goes without saying that the technical idea of the present invention can also be applied to a computer-readable recording medium containing a computer program for performing the functions of the apparatus and method according to the present embodiment. In addition, the technical ideas according to various embodiments of the present invention may be implemented in the form of computer-readable codes recorded on a computer-readable recording medium. The computer-readable recording medium may be any data storage device readable by the computer and capable of storing data. For example, the computer-readable recording medium may be a ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical disk, hard disk drive, or the like. In addition, the computer-readable code or program stored in the computer-readable recording medium may be transmitted through a network connected between computers.

In addition, although preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and the technical field to which the present invention belongs without departing from the gist of the present invention as claimed in the claims Various modifications are possible by those of ordinary skill in the art, and these modifications should not be individually understood from the technical spirit or prospect of the present invention.

100 : service server
110: first communication unit
120: first processor
130: storage
200: edge device
210: sensor unit
220: second communication unit
230: second processor

Claims (12)

A service server, the step of allowing a microservice (Microservice) to be downloaded to the connected edge device (Edge Device);
detecting, by the service server, an edge device adjacent to within a preset range from an edge device that is downloaded and registered in the service server; and
When there is an adjacent edge device, the service server adjusting the sensing period of the registered edge device to reduce battery consumption of the registered edge device;
The step of detecting an adjacent edge device comprises:
It generates device placement information of a sparse graph type based on a hash table, and uses the generated device placement information to detect an edge device existing within a preset range from a registered edge device. lifecycle management method.
delete The method according to claim 1,
The step of adjusting the sensing period is,
A lifecycle management method characterized in that the sampling rate (Sampling Rate) of the registered edge device is changed.
4. The method according to claim 3,
The step of adjusting the sensing period is,
A lifecycle management method, characterized in that when the sampling rate of a specific edge device is changed, the sampling rate of other adjacent edge devices is also changed.
A service server, the step of allowing a microservice (Microservice) to be downloaded to the connected edge device (Edge Device);
detecting, by the service server, an edge device adjacent to within a preset range from an edge device that is downloaded and registered in the service server; and
When there is an adjacent edge device, the service server adjusting the sensing period of the registered edge device to reduce battery consumption of the registered edge device;
The step of adjusting the sensing period is,
to change the sampling rate of the registered edge device,
The step of adjusting the sensing period is,
When the sampling rate of a specific edge device is changed, the sampling rate of other adjacent edge devices is also changed.
The step of adjusting the sensing period is,
A lifecycle management method, characterized in that the sampling rate is changed in inverse proportion to the number of adjacent edge devices.
6. The method of claim 5,
The step of adjusting the sensing period is,
A lifecycle management method characterized in that the sampling rate of one or more adjacent edge devices is changed at once by using a hash table.
7. The method of claim 6,
The sensing cycle is
When n edge devices are adjacent and the sampling rate of each edge device is reduced to 1/n, the lifecycle management method, characterized in that it is multiplied by n.
7. The method of claim 6,
The step of adjusting the sensing period is,
In order to prevent quality of service (QoS) from being deteriorated, when the sampling rate of each edge device is changed, the service server adjusts the sensing start time of each edge device whose sampling rate is changed Life characterized in that How to manage your cycle.
9. The method of claim 8,
The step of adjusting the sensing period is,
A lifecycle management method, characterized in that the sensing start time of adjacent edge devices is adjusted to be different by (sampling period/number of adjacent edge devices).
To provide microservices to edge devices to register edge devices, detect adjacent edge devices within a preset range from the registered edge devices, and to reduce battery consumption when adjacent edge devices exist, register a service server that adjusts the sensing cycle of the edge device; and
It includes; an edge device that downloads and installs the microservice, and transmits the sensing data to the service server every sensing cycle;
service server,
It generates device placement information of a sparse graph type based on a hash table, and uses the generated device placement information to detect an edge device existing within a preset range from a registered edge device. lifecycle management system.
detecting, by the service server, an edge device adjacent to within a preset range from a registered edge device; and
When there is an adjacent edge device, the service server adjusting the sensing period of the registered edge device to reduce battery consumption of the registered edge device;
The step of detecting an adjacent edge device comprises:
It generates device placement information of a sparse graph type based on a hash table, and uses the generated device placement information to detect an edge device existing within a preset range from a registered edge device. lifecycle management method.
a service server that detects an adjacent edge device within a preset range from the registered edge device and adjusts a sensing period of the registered edge device to reduce battery consumption when there is an adjacent edge device; and
Including; an edge device that transmits sensing data to the service server every sensing cycle;
service server,
It generates device placement information of a sparse graph type based on a hash table, and uses the generated device placement information to detect an edge device existing within a preset range from a registered edge device. lifecycle management system.

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