KR20180046756A - System of testing iot sensor for power facility management - Google Patents

Abstract

Disclosed is a system to test an Internet of things (IoT) sensor for power facility management, to enhance reliability due to reuse of an existing test environment. According to the present invention, the system comprises: a power IoT sensor test editor to assist defining a test environment of a power IoT sensor and generating a test case; a test information repository to store test information edited by a power IoT sensor test case editor and a test execution result; a power IoT sensor test manager using the test information edited by the power IoT sensor test editor to perform a test for a power IoT sensor; and a power IoT gateway connected to the power IoT sensor through wireless communication to transfer a control command for test execution to the test IoT sensor and receiving the test execution result from the power IoT sensor.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

The present application relates to a test system for an object internet sensor for power facility management.

The electric power facility management system based on Internet of Things (IoT) installs various object internet sensors on the electric power facilities, and the facility management server collects the sensing data in real time from the object internet sensors, And is configured to monitor in real time.

Here, since the object Internet sensor can be manufactured by various sensor manufacturers, compatibility with other sensors and the facility management server may be a problem when object Internet sensors of different sensor manufacturers are installed. In addition, when a new object internet sensor is developed, it is necessary to verify communication suitability and sensor function, but there is no tool for it.

On the other hand, the IoT standard platform technology is applied to communication between the object Internet sensor and the facility management server, and there is a method for verifying compatibility with the standard platform. However, in order to manage the electric power facilities, there is no support for the communication flow verification method between the object Internet sensor and the facility management server and the method for verifying the validity of the sensor data.

In addition, it takes a lot of time, effort, and cost to construct a test environment for testing various types of object Internet sensors, and there is a limit in that the error detection probability of the object Internet sensor is lowered under a weak test system.

Accordingly, in the related art, in order to verify the communication suitability between the object Internet sensor and the electric power facility management server before the object Internet sensor is installed on the field in the electric power facility management system of the object Internet, and to verify the function of the object Internet sensor more efficiently There is a demand.

In order to solve the above problems, an embodiment of the present invention provides a test system for an object Internet sensor for power facility management. A power IoT sensor test editor for supporting a test environment of a power IoT (Internet of Things) sensor to be defined and generating a test case; A test information storage for storing test information and test execution results edited by the power IoT sensor test case editor; A power IoT sensor test manager for performing a test on the power IoT sensor using the test information edited by the power IoT sensor test editor; And a power IoT gateway connected to the power IoT sensor by wireless communication to transmit a control command for performing a test to the power IoT sensor and receive a test result from the power IoT sensor.

In addition, the means for solving the above-mentioned problems are not all enumerating the features of the present invention. The various features of the present invention and the advantages and effects thereof will be more fully understood by reference to the following specific embodiments.

According to an embodiment of the present invention, a test environment can be quickly constructed for a thing Internet sensor, and a test period of a thing Internet sensor can be shortened by improving reliability by reusing an existing test environment and automating a test have.

1 is a configuration diagram of a test system for an object Internet sensor for managing a power facility according to an embodiment of the present invention.
FIG. 2 is a flowchart illustrating a control signal process in the test system for the object Internet sensor for managing the electric power facility shown in FIG. 1. FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order that those skilled in the art can easily carry out the present invention. In the following detailed description of the preferred embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In the drawings, like reference numerals are used throughout the drawings.

In addition, in the entire specification, when a part is referred to as being 'connected' to another part, it may be referred to as 'indirectly connected' not only with 'directly connected' . Also, to "include" an element means that it may include other elements, rather than excluding other elements, unless specifically stated otherwise.

1 is a configuration diagram of a test system for an object Internet sensor for managing a power facility according to an embodiment of the present invention.

Referring to FIG. 1, a test system for an object Internet sensor for managing power facilities according to an embodiment of the present invention includes a power IoT sensor test editor 100, a test information storage 200, a power IoT sensor test manager 300, A power IoT gateway 400, and a power IoT sensor 500. [

The power IoT sensor test editor 100 is for supporting the administrator to define a test environment of the object Internet sensor and to create a test case. The power IoT sensor test editor 100 includes a power IoT sensor test case editor 110, a device under test (DUT) And a power IoT sensor threshold value editing unit 130, and may be implemented as a graphical user interface (GUI) based editor, for example.

The power IoT sensor test case editor 110 supports the creation of a new test case based on the information of the electric power facility to be managed and the sensor information of the object Internet sensor to be tested. The test case created by the power IoT sensor test case editing unit 110 may be stored in the test case list 210 of the test information storage 200 described later.

In addition, the power IoT sensor test case editor 110 searches for test cases classified according to the power equipment and the sensor type stored in the test case list 210, and provides them to the administrator and supports editing thereof.

In addition, the power IoT sensor test case editing unit 110 may store the test data necessary for the execution of each test case in the test case input data 220 of the test information storage 200 described later.

The DUT information editing unit 120 may be configured to set DUT information including communication access information for the object Internet sensor to be tested, definition of sensing data generated by the object internet sensor, Support.

The information set by the DUT information editing unit 120 may be stored in the DUT information 230 of the test information storage 200 described later.

Since one or more object internet sensors may be required to manage one electric power facility, the DUT information editing unit 120 may support editing of the information of one or more DUTs, i.e., object Internet sensors.

The power IoT sensor threshold value editing unit 130 supports the setting of the effective range, that is, the threshold value, of the sensing value for each type of the managed power equipment required for validating the sensor data acquired at the time of executing each test case.

The power IoT sensor threshold value information set by the power IoT sensor threshold value editing unit 130 may be stored in the power IoT sensor threshold value information 240 of the test information storage 200 described later.

The test information storage 200 stores test information edited by the power IoT sensor test case editing unit 110 and test results obtained based on the test information. .

The test information store 200 may include a test case list 210, test case input data 220, DUT information 230, and power IoT sensor threshold information 240.

Here, each of the test cases stored in the test case list 210 can be mapped to the effective range of the sensing value for each type of power equipment stored in the power IoT sensor threshold value information 240, and when the DUT object It can be utilized for validation of the sensing data acquired from the Internet sensor.

Table 1 below shows an example of the power IoT sensor threshold value information table.

Taking the case of performing a test case for testing a tilt sensor attached to the pole of a telephone pole as an example, based on Table 1, it is determined that the sensing data is valid when the tilt sensing value is within the maximum / minimum value ± 90 as a result of the test, In this case, the test case can be evaluated as being successfully executed.

[Table 1]

The power IoT sensor test manager 300 performs a test on the power IoT sensor to be tested using the DUT information and the test case defined by the power IoT sensor test editor 100 and determines whether the result is successful A test result determination module 310, a DUT sensor test environment setting module 320, a test case execution module 330, a power facility management module 340, and an IOT server platform 350, As shown in FIG.

The DUT sensor test environment setting module 320 reads the information of the object Internet sensor to be tested from the DUT information 230 and registers the object Internet sensor to be tested in the power equipment management module 340 to establish a facility management simulation environment .

The test case execution module 330 sequentially reads the test case list of the object Internet sensor to be tested stored in the test case list 210 and then interprets the script language for describing each test case, ) To send a sensor test request.

The electric power facility management module 340 can construct a simulated environment of the electric power facility management functions using the object Internet sensor. Here, the electric power facility management functions include, for example, registration of the object internet sensor, publication of the object internet sensor OID (Object IDentification) Object internet sensor network management, and power facility information to be managed.

The sensor test request received from the test case execution module 330 by the power facility management module 340 is a function of the facility management service unit and may be configured to perform a plurality of object internet sensor control functions to perform a corresponding task.

The power facility management module 340 may invoke the sensor control functions necessary to perform the test according to the sensor test request. The invocation of and response to such sensor control functions may be accomplished by exchanging messages between the IoT server platform 350 and the IoT device platform 410 based on wired and wireless communications (e.g., TCP / IP communications).

Meanwhile, the power facility management module 340 may receive the test result of the object Internet sensor to be tested from the power IOT gateway 400, and may transmit the test result to the test case execution module 330. Here, the test execution result may include communication failure information with respect to the object Internet sensor to be tested, function processing error information, sensing value of the object internet sensor, and the like.

If the test result includes the sensing value of the object Internet sensor, the test result determination module 310 determines the validity of the sensing value using the power IoT sensor threshold value information 240 and determines whether the test is successful or not .

The IOT server platform 350 is for performing communication with the power IOT gateway 400 according to a predefined communication method.

The power IoT gateway 400 is connected to the power IoT sensor 500 on a wireless communication basis to transmit a control command for performing a test and receives a test result in response thereto. The IoT gateway 400 includes an IoT device platform 410, An IoT sensor management module 420 and a wireless communication interface 430. [

The IoT device platform 410 is for performing communication with the IoT server platform 350 according to a predefined communication method.

For example, the IoT device platform 410 delivers the control command received from the IoT server platform 350 to the power IoT sensor management module 420, receives the test result from the IoT device management module 420, and transmits the result to the IoT server platform 350 .

The power IoT sensor management module 420 is for managing the power IoT sensor 500. The power IoT sensor management module 420 communicates with the power IoT sensor 500 through the wireless communication interface 430 to transmit a control command, The power IoT sensor 500 can be managed.

The wireless communication interface 430 may provide various communication interfaces such as BLE (Bluetooth Low Energy), Zigbee, LoRa, etc. to support communication with the power IoT sensors 500 using various wireless communication technologies.

The power IoT sensor 500 is installed in an electric power facility for the purpose of managing electric power facilities and collects sensing data. For example, the electric power IoT sensor 500 includes various sensors such as a tilt sensor, a temperature sensor, a humidity sensor, Type sensors.

The power IoT sensor 500 is connected to the power IoT sensor test manager 300 through the power IoT gateway 400 without being directly connected to the power IoT sensor test manager 300 due to restrictions such as computing power, Lt; / RTI >

FIG. 2 is a flowchart illustrating a control signal processing process in a test system for an object Internet sensor for managing the electric power equipment shown in FIG. 1. In the process of testing a object Internet sensor, as shown in FIG. 2, A case management module 330, a power facility management module 340, an IoT server platform 350, an IoT device platform 410, a power IoT sensor management module 420, a wireless communication interface 430 and a power IoT sensor 500 ) Are processed in this order.

The present invention is not limited to the above-described embodiments and the accompanying drawings. It will be apparent to those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100: Power IoT Sensor Test Editor
110: Power IoT Sensor Test Case Editor
120: DUT information editor
130: Power IoT sensor threshold value editor
200: Test information store
210: Test case list
220: Test case input data
230: DUT information
240: Power IoT sensor threshold information
300: Power IoT Sensor Test Manager
310: test result judgment module
320: DUT sensor test configuration module
330: Test case execution module
340: Power facility management module
350: IoT Server Platform
400: Power IoT gateway
410: IoT Device Platform
420: Power IoT sensor management module
430: Wireless communication interface
500: Power IoT sensor

Claims (6)

Power IoT sensor test editor that supports defining the test environment of a power Internet (IoT) sensor and creating test cases;
A test information storage for storing test information and test execution results edited by the power IoT sensor test case editor;
A power IoT sensor test manager for performing a test on the power IoT sensor using the test information edited by the power IoT sensor test editor; And
And a power IoT gateway connected to the power IoT sensor by radio communication to transmit a control command for performing a test to the power IoT sensor and receive a test result from the power IoT sensor, Of the test system.
The apparatus of claim 1, wherein the power IoT sensor test editor comprises:
A power IoT sensor test case editor for supporting a test case to be created based on power facility information and sensor information to be managed by the power IoT sensor;
A DUT information editing unit for supporting setting of DUT (Device Under Test) information including communication access information to the power IoT sensor, definition of sensing data generated by the power IoT sensor, and power facility information to be managed by the power IoT sensor; And
And a power IoT sensor threshold value editor for setting an effective range of a sensing value for each type of managed power equipment required for validating the sensor data acquired at the time of execution of each test case. Test system.
3. The method of claim 2,
The power IoT sensor test case editing unit searches for test cases classified according to the power equipment and the sensor type stored in the test case list stored in the test information storage and provides the test cases to the administrator, Testing system for things internet sensor for facility management.
The apparatus of claim 1, wherein the power IoT sensor test manager comprises:
And a control unit for controlling the power IoT sensor to perform a test case execution based on the test result received from the power IoT gateway, An electric power facility management module for transferring electric power to a module;
A DUT sensor test environment setting module for reading the information of the power IoT sensor stored in the test information storage and registering the power IoT sensor in the power facility management module to establish a facility management simulation environment;
A test case execution module that sequentially reads the test case list of the power IoT sensor stored in the test information storage and then transmits the sensor test request to the power facility management module; And
And an IoT server platform that communicates with the power IoT gateway according to a predefined communication method.
5. The apparatus of claim 4, wherein the power IoT sensor test manager comprises:
Further comprising a test result determination module for determining the validity of the sensing value included in the test result and determining whether the test is successful or not.
The method of claim 1, wherein the power IoT gateway comprises:
An IoT device platform that communicates with the power IoT sensor test manager according to a predefined communication scheme;
A wireless communication interface for providing one or more communication interfaces for communication with the power IoT sensor; And
And a power IoT sensor management module for transmitting a control command to the power IoT sensor through the wireless communication interface and receiving a test result from the power IoT sensor.

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