KR20200052792A - Measurement data management system - Google Patents

Abstract

According to an embodiment of the present invention, provided is a measurement data management system, which comprises: a measurement unit measuring a gun and a bullet fired toward a target at a test site to generate measurement data; a data management device unit converting a format of the measurement data into an integrated format to generate integrated measurement data; and a master device storing the integrated measurement data and monitoring a measurement situation of the measurement unit in real time based on the integrated measurement data. Launch test measurement data for an induction-free rocket system is integrated and stored so that the measurement situation can be monitored in real time.

Description

Measurement data management system {MEASUREMENT DATA MANAGEMENT SYSTEM}

An embodiment of the present invention relates to a measurement data management system, in particular, a measurement data management system capable of integrating and storing measurement data of a launch test for a non-guided rocket system and monitoring the measurement status in real time.

Generally, a non-guided rocket system refers to a weapon system that uses a rocket propulsion engine but does not use a guided device and is not guided. It is important to identify and analyze the induction-type rocket, which has a variety of factors and a high sensitivity that affects the accuracy rate compared to guided weapons. Therefore, the test scenarios are diverse, the number of test launches is large, the items to be measured are varied, and the data generated is large.

In the related art, after obtaining data in the unstructured analog and digital form for each of a plurality of measurement equipments in a test site, they were separately stored and managed for each measurement person. After returning from the test site to the office, scattered measurement data was collected and the relationship between the data was analyzed to analyze the system test results. The results of this analysis were used as the basis for design reflection and as the basis for decision making.

In this process, there was a risk of inconvenience of measurement itself, possibility of measurement error, and data loss, and a lot of effort and time was required when integrated management of unstructured data scattered in analog form and digital form.

The problem to be solved of the present invention relates to a measurement data management system capable of integrating and storing launch test measurement data for a non-inductive rocket system and monitoring the measurement status in real time.

In order to achieve the above object, the measurement data management system according to an embodiment of the present invention comprises: a measurement unit for measuring a gun and a bullet fired toward a target at a test site to generate measurement data; A data management device unit that converts the format of the measurement data into an integrated format to generate integrated measurement data; It characterized in that it comprises a master device for storing the integrated measurement data, and monitoring the measurement status of the measurement unit in real time based on the integrated measurement data.

In the present invention, the master device includes: a test setup module for generating test setup data and a test setup index comprising at least one of test type information, a full test identification number and a detailed test identification number; A data storage module for setting a data storage structure and storing the integrated measurement data, the test setting data and the test setting index according to the data storage structure; And it characterized in that it comprises a real-time monitoring module for monitoring the test in real time based on the integrated measurement data.

In the present invention, a data storage method using the data storage module of the master device includes: generating a first folder; Storing the test setting data in the first folder and creating a second folder; Storing, in the second folder, the test setting index and the integrated measurement data for the entire test, and creating a third folder; And storing the integrated measurement data for a detailed test in the third folder.

In the present invention, the test setup index is characterized in that it is data of a tree (tree) data structure including an index value for linking the test setup data and the integrated measurement data to each other.

In the present invention, the master device and the data management device are characterized in that they communicate with each other through a transmission control protocol / Internet protocol (TCP / IP; Transmission Control Protocol / Internet Protocol) of the Internet network.

In the present invention, the measurement unit, a first pressure sensor unit for generating a first pressure data by measuring the after-storm pressure of the launch; A second pressure sensor unit measuring pressure in the bullet to generate second pressure data; An acceleration sensor unit measuring acceleration of the gun and generating acceleration data; A sound pressure sensor unit measuring sound pressure to generate sound pressure data; A first high-speed camera unit that captures a launch environment and generates launch data; A second high-speed camera unit that captures the shot of the bullet and generates image data; A radar unit measuring flight of the bullet and generating flight data; And an environmental sensor unit for measuring the test site environment and generating environmental data, wherein the measurement data includes the first pressure data, the second pressure data, the acceleration data, the sound pressure data, the launch data, and the image data, It characterized in that it comprises the flight data and the environment data.

In the present invention, the environmental sensor unit is characterized by generating the environmental data by measuring the test site environment including at least one of the wind direction, wind speed, temperature, humidity and air pressure of the test site.

In the present invention, the data management device unit converts each format of the first pressure data, the second pressure data, and the acceleration data into the integrated format, so that the first integrated pressure data, the second integrated pressure data, and the integrated acceleration A sensor data management device for generating data; A sound pressure data management device that converts the format of the sound pressure data into the integrated format to generate integrated sound pressure data; A launch data management device for converting the format of the launch data into the integrated format to generate integrated launch data; An image data management device that converts the format of the image data into the integrated format to generate integrated image data; A flight data management device for converting the format of the flight data into the integrated format to generate integrated flight data; And converting the format of the environmental data into the integrated format to generate integrated environmental data.

In the present invention, the environment data management device includes a sound detection sensor, and by using the sound detection sensor, it is characterized by automating the operation by detecting the sound emitted during the launch.

In the present invention, the firing data management apparatus is characterized in that for calculating the muzzle velocity value based on the firing data, and transmitting the muzzle velocity value to the master device.

In the present invention, the bullet is characterized in that it is a non-guided rocket bomb that does not include an induction device.

In order to achieve the above object, the measurement data management system according to an embodiment of the present invention includes a first pressure data generated by measuring a post-storm pressure by a first pressure sensor unit and a second pressure sensor unit generated by measuring an internal pressure. 2 The sensor data management device converts each format of the acceleration data generated by measuring the rebound of the pressure data and the acceleration sensor unit into an integrated format; A sound pressure data management device for converting a sound pressure sensor unit into a format of sound pressure data generated by measuring sound pressure; A launch data management device for converting a format of launch data generated by photographing a launch environment by a first high-speed camera unit into the integrated format; An image data management device for converting a format of image data generated by a second high-speed camera unit photographing a flight of a bullet into the integrated format; A flight data management device that converts a format of flight data generated by measuring the flight of the bullet by the leather unit into the integrated format; An environmental data management device that converts a format of environmental data generated by measuring a test site environment by the environmental sensor unit into the integrated format; And a master device that stores data of the integrated format and monitors the measurement status in real time.

In the present invention, the environment data management device is characterized in that by using a sound detection sensor, by detecting the firing sound generated when the shot is fired, it is characterized in that the operation is automated.

In the present invention, the firing data management device is characterized in that for calculating the muzzle velocity value based on the firing data, and transmitting the muzzle velocity value to the master device.

In the present invention, the bullet is characterized in that it is a non-guided rocket bomb that does not include a guide device.

The measurement data management system according to an embodiment of the present invention can integrate and store measurement data of a launch test for an induction-free rocket system and monitor the measurement status in real time.

In addition, the measurement data management system according to an embodiment of the present invention can systemize the test and measurement task of the launch test for the induction-free rocket system.

In addition, another problem to be solved of the present invention can effectively realize the test data integrated management system of the launch test for the induction-free rocket system.

In addition, another problem to be solved of the present invention is through the visualization of integrated data, it is possible to monitor the test measurement status in the field and review real-time results.

The effects obtainable in the present invention are not limited to the above effects, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a view showing a measurement data management system according to an embodiment of the present invention.
2 is a diagram illustrating in detail a measurement data management system according to an embodiment of the present invention shown in FIG. 1.
3 is a view showing in detail a master device according to an embodiment of the present invention.
4 is a diagram illustrating a data storage method of a master device according to an embodiment of the present invention.
5 is a view showing a data storage structure according to an embodiment of the present invention.
6 is a view showing a display unit of a master device according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention and other matters necessary for those skilled in the art to easily understand the contents of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention can be implemented in a variety of different forms within the scope of the claims, so the embodiments described below are merely illustrative, regardless of whether they are expressed.

The same reference numerals refer to the same components. In addition, in the drawings, the thickness, ratio, and dimensions of the components are exaggerated for effective description of technical content. “And / or” can include any combination of one or more that the associated configurations can define.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from other components. For example, the first component may be referred to as a second component without departing from the scope of the present invention, and similarly, the second component may be referred to as a first component. Singular expressions may include plural expressions unless the context clearly indicates otherwise.

In addition, terms such as "below", "below", "above", "above", etc. are used to describe the relationship between the components shown in the drawings. The terms are relative concepts and are explained based on the directions indicated in the drawings.

The terms "include" or "have" are intended to indicate the presence of a feature, number, step, action, component, part, or combination thereof described in the specification, one or more other features, numbers, or steps. It should be understood that it does not preclude the existence or addition possibility of the operation, components, parts or combinations thereof.

That is, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms. In the following description, when a part is connected to another part, it is directly connected. In addition, it may also include a case in which other devices are electrically connected in the middle. In addition, it should be noted that the same components in the drawings are indicated by the same reference numerals and symbols as possible, even if they are displayed on different drawings.

1 is a view showing a measurement data management system 10 according to an embodiment of the present invention.

Referring to FIG. 1, the measurement data management system 10 may include a measurement unit 100, a data management device unit 200, and a master device 300.

The measurement unit 100 may generate the measurement data MD by measuring the gun 20, the bullet 30, the target 40, and the test site 50 surrounding it. Here, the gun 20 may fire the bullet 30 toward the target 40, and the test site 50 may indicate a launch environment. According to an embodiment, the bullet 30 may be a non-guided rocket bomb that includes a rocket propulsion engine but does not include a guide device. For example, the measurement unit 100 may include various types of sensors, cameras, or radars. Therefore, the measurement data MD generated by the measurement unit 100 may have different formats depending on the subject of detection. The measurement data MD may have at least one of a cine format, a cine format, a data format dat, and an excel format.

The measurement unit 100 may transmit measurement data MD to the data management device unit 200.

The data management device unit 200 may receive measurement data MD from the measurement unit 100. The data management device unit 200 may store measurement data MD. In addition, the data management apparatus unit 200 may generate the integrated measurement data IMD by changing the format of the measurement data MD to the integrated format. For example, the data management device unit 200 may include various data management devices. Data management devices included in the data management device 200 may store corresponding measurement data MD and convert the format to an integrated format to generate integrated measurement data IMD.

The data management device unit 200 may transmit integrated measurement data (IMD) to the master device 300.

For example, the master device 300 and the data management device unit 200 may communicate with each other through a transmission control protocol / Internet protocol (TCP / IP; Transmission Control Protocol / Internet Protocol) of the Internet network.

The master device 300 may receive integrated measurement data (IMD). The master device 300 may store integrated measurement data (IMD) and monitor the measurement status of the measurement unit 100 in real time based on the integrated measurement data (IMD).

In addition, the master device 300 may generate test setup data for a launch test, and a launch test may be performed based on this. For example, the test setup data may include a full test identification number, detailed test identification number, test date, test type, test purpose, and the like.

2 is a view showing in detail the measurement data management system 10 according to the embodiment of the present invention shown in FIG.

1 and 2, the measurement unit 100 includes a first pressure sensor unit 110, a second pressure sensor unit 120, an acceleration sensor unit 130, a sound pressure sensor unit 140, and a first high-speed camera It may include a unit 150, the second high-speed camera unit 160, the radar unit 170 and the environmental sensor unit 180.

The first pressure sensor unit 110 is disposed at the rear of the gun 20 and can measure the post-storm pressure according to the launch. According to an embodiment, the first pressure sensor unit 110 may include a plurality of pressure sensors. The first pressure sensor unit 110 may measure the post-storm pressure and generate first pressure data PD1. The first pressure sensor unit 110 may transmit the first pressure data PD1 to the data management device unit 200. For example, the first pressure data PD1 may include a value for a post storm pressure.

The second pressure sensor unit 120 is disposed on the gun 20 and can measure the pressure in the bullet according to firing. According to an embodiment, the second pressure sensor unit 120 may include a plurality of pressure sensors. The second pressure sensor unit 120 may measure the pressure in the bullet to generate second pressure data PD2. The second pressure sensor unit 120 may transmit the second pressure data PD2 to the data management device unit 200. For example, the second pressure data PD2 may include a value for the position of the bullet 30.

The acceleration sensor unit 130 is disposed on the gun 20 and can measure the recoil of the gun (eg, the acceleration of the gun) according to the firing. According to an embodiment, the acceleration sensor unit 130 may include a plurality of acceleration sensors. The acceleration sensor unit 130 may measure the recoil of the gun and generate acceleration data AD. The acceleration sensor unit 130 may transmit the acceleration data AD to the data management device unit 200. For example, the acceleration data AD may include a value for reaction force.

Sound pressure sensor unit 140 is disposed around the gun 20, it is possible to measure the sound pressure of the gun according to the firing sound. According to an embodiment, the sound pressure sensor unit 140 may include a plurality of sound pressure sensors. The sound pressure sensor unit 140 may measure sound pressure of the gun and generate sound pressure data SD. The sound pressure sensor unit 140 may transmit sound pressure data SD to the data management device unit 200. For example, the sound pressure data SD may include a value for sound pressure.

The first high-speed camera unit 150 is disposed around the gun 20 and may photograph a launch environment. According to an embodiment, the first high-speed camera unit 150 may include a plurality of high-speed cameras. The first high-speed camera unit 150 may photograph a launch environment and generate launch data LD. The first high-speed camera unit 150 may transmit the launch data LD to the data management device unit 200. For example, the launch data LD includes values for elevation before launch, elevation after launch, azimuth before launch, azimuth after launch, safety state of ignition line, resistance value of ignition line before launch, resistance value of ignition line before launch, launch time, etc. can do.

The second high-speed camera unit 160 is disposed around the traveling trajectory of the bullet 30, and can photograph the flight of the bullet 30. According to an embodiment, the second high-speed camera unit 160 may include a plurality of high-speed cameras. The second high-speed camera unit 160 may photograph the flight of the bullet 30 and generate image data VD. The second high-speed camera unit 160 may transmit the image data VD to the data management device unit 200. For example, the image data VD may include values for a bullet velocity, a launch tube, an impact group, a bullet rotation, and a post-storm.

The radar unit 170 is disposed around the traveling trajectory of the bullet 30 and can measure the flight of the bullet 30. According to an embodiment, the radar unit 170 may include a plurality of Doppler radars. The radar unit 170 may measure the flight of the bullet 30 and generate flight data BD. The radar unit 170 may transmit flight data BD to the data management device unit 200. For example, the flight data BD may include values for Doppler superspeed and Doppler dependence.

The environment sensor unit 180 is disposed throughout the test site 50 and can measure the environment of the test site 50. According to an embodiment, the environmental sensor unit 180 may include a wind vane, anemometer, thermometer, hygrometer, and barometer. The environmental sensor unit 180 may measure the environment of the test site 50 and generate environmental data ED. The environmental sensor unit 180 may transmit the environmental data ED to the data management device unit 200. For example, the environmental data ED may include values for wind direction, wind speed, temperature, humidity, and air pressure.

The data management device unit 200 may receive measurement data MD. For example, the measurement data MD includes first pressure data PD1, second pressure data PD2, acceleration data AD, sound pressure data SD, launch data LD, image data VD, flight data (BD) and environmental data (ED).

The data management device unit 200 includes a sensor data management device 210, a sound pressure data management device 220, a launch data management device 230, an image data management device 240, a flight data management device 250, and environmental data It may include a management device (260).

The sensor data management device 210 may receive the first pressure data PD1, the second pressure data PD2, and the acceleration data AD. The sensor data management device 210 may store the first pressure data PD1, the second pressure data PD2, and the acceleration data AD. In addition, the sensor data management device 210 converts the formats of the first pressure data PD1, the second pressure data PD2, and the acceleration data AD into an integrated format, so that the first integrated pressure data IPD1 and the first 2 Integrated pressure data (IPD2) and integrated acceleration data (IAD) can be generated. The sensor data management device 210 may transmit the first integrated pressure data IPD1, the second integrated pressure data IPD2, and the integrated acceleration data IAD to the master device 300.

The sound pressure data management device 220 may receive sound pressure data SD. The sound pressure data management device 220 may store sound pressure data SD. In addition, the sound pressure data management apparatus 220 may convert the format of the sound pressure data SD into an integrated format to generate integrated sound pressure data ISD. The sound pressure data management device 220 may transmit the integrated sound pressure data (ISD) to the master device 300.

The launch data management device 230 may receive launch data LD. The launch data management device 230 may store launch data LD. In addition, the launch data management apparatus 230 may convert the format of the launch data LD into an integrated format to generate integrated launch data ILD. The launch data management device 230 may transmit integrated launch data (ILD) to the master device 300. According to an embodiment, the launch data management device 230 may calculate a muzzle velocity value based on the launch data LD. In addition, the launch data management device 230 may transmit the muzzle velocity value to the master device 300.

The image data management device 240 may receive image data VD. The image data management device 240 may store image data VD. In addition, the image data management apparatus 240 may convert the format of the image data VD into an integrated format to generate the integrated image data IVD. The image data management device 240 may transmit integrated image data (IVD) to the master device 300.

The flight data management device 250 may receive flight data BD. The flight data management device 250 may store flight data BD. In addition, the flight data management device 250 may convert the format of the flight data BD into an integrated format to generate integrated flight data IBD. The flight data management device 250 may transmit integrated flight data (IBD) to the master device 300.

The environmental data management device 260 may receive the environmental data ED. The environmental data management device 260 may store environmental data ED. In addition, the environment data management apparatus 260 may convert the format of the environment data ED into an integrated format to generate integrated environment data (IED). The environment data management device 260 may transmit integrated environment data (IED) to the master device 300.

According to an embodiment, the environment data management device 260 may include a sound detection sensor. The environment data management device 260 may detect a sound emitted when a sound is detected using a sound detection sensor, and may operate when the sound is detected, thereby automating the operation.

According to an embodiment, the sensor data management device 210, sound pressure data management device 220, launch data management device 230, image data management device 240, flight data management device 250 and environmental data management device ( At least some of 260) may be integrated and implemented integrally.

The master device 300 may receive integrated measurement data (IMD). The master device 300 may store integrated measurement data (IMD) and monitor the measurement status of the measurement unit 100 in real time based on the integrated measurement data (IMD). For example, the integrated measurement data (IMD) includes first integrated pressure data (IPD1), second integrated pressure data (IPD2), integrated acceleration data (IAD), integrated sound pressure data (ISD), integrated launch data (ILD), and integrated image Data (IVD), integrated flight data (IBD), and integrated environmental data (IED).

1 and 2, the first pressure sensor unit 110 is disposed at the rear of the gun 20, and can measure the post-storm pressure according to the launch. According to an embodiment, the first pressure sensor unit 110 may include four pressure sensors that are sequentially arranged according to the distance to the rear of the gun 20.

The second pressure sensor unit 120 is disposed on the gun 20 and can measure the pressure in the bullet according to firing. According to an embodiment, the second pressure sensor unit 120 may include a plurality of pressure sensors.

The acceleration sensor unit 130 is disposed on the gun 20 and can measure the recoil of the gun (eg, the acceleration of the gun) according to the firing. According to an embodiment, the acceleration sensor unit 130 may include a plurality of acceleration sensors.

The sound pressure sensor unit 140 is disposed around the gun 20 and can measure sound pressure according to the sound of the launch. According to an embodiment, the sound pressure sensor unit 140 may include two sound pressure sensors.

The first high-speed camera unit 150 is disposed around the gun 20 and can photograph a launch environment (eg, flame, muzzle speed, wing deployment, etc.). According to an embodiment, the first high speed camera unit 150 may include two high speed cameras.

The second high-speed camera unit 160 is disposed around the traveling trajectory of the bullet 30 and may photograph the flight of the bullet 30 (eg, the number of shot revolutions, initial behavior, and the target 50). Accordingly, the second high-speed camera unit 160 may include three high-speed cameras.

The radar unit 170 is disposed around the traveling trajectory of the bullet 30 and can measure the flight of the bullet 30. According to an embodiment, the radar unit 170 may include different types of Doppler radars.

The environment sensor unit 180 is disposed throughout the test site 50 and can measure the environment of the test site 50. According to an embodiment, the environmental sensor unit 180 may include a wind vane, anemometer, thermometer, hygrometer, and barometer.

3 is a view showing in detail the master device 300 according to an embodiment of the present invention.

1 to 3, the master device 300 may include a control unit 310, a memory unit 320, a communication unit 330, a display unit 340, and a bus unit 350.

The control unit 310 may control the overall operation of the master device 300. According to an embodiment, the control unit 310 may be implemented as a central processing unit (CPU), a micro processing unit (MPU), or a graphic processing unit (GPU).

The memory unit 320 may store a number of instructions constituting a program that can be executed by the control unit 310, parts list data for a parts list, and part property data indicating part properties. According to an embodiment, the memory unit 320 may be implemented as a read only memory (ROM), a random access memory (RAM), a hard disk drive (HDD), or a solid state drive (SSD).

The communication unit 330 may perform communication between the master device 300 and an external (eg, database server). For example, the communication unit 330 may communicate with an external server through a network. According to an embodiment, the communication unit 330 may perform communication using all types of wired / wireless networks such as a local area network (LAN), a wide area network (WAN), a mobile communication network, and a Wibro.

The display unit 340 may display an image based on image data received from the master device 300. For example, the display unit 340 may be implemented as a display panel. According to an embodiment, the display unit 340 may be implemented as any one of a liquid crystal display device, an organic light emitting display device, and the like. However, the present invention is not limited to this, and the display unit 340 may be implemented with various devices as long as it satisfies the purpose of displaying an image.

The bus unit 350 may transmit and receive data between the control unit 310, the memory unit 320, the communication unit 330, and the display unit 340. According to an embodiment, the bus unit 350 may be implemented as a bus interface.

The control unit 310 may include a test setting module 400, a data storage module 500, and a real-time monitoring module 600. In the present specification, a module means a software (program) in which instructions constituting a program stored in the memory unit 320 are executed by the controller 310.

The test setting module 400 may generate test setting data and a test setting index including at least one of test type information, a full test identification number, and a detailed test identification number.

Here, the test type information may include overall information on the type and characteristics of the test, such as the number of shots, the firing distance, the purpose of the test, the test method, and the test duration. The full test identification number means a comprehensive identification number for the entire test, and the detailed test identification number may mean a detailed identification number for a detailed test (eg, one bullet 30 firing unit).

The test setup index may include index values that link test setup data and integrated measurement data (IMD) to each other. According to an embodiment, the test setup index may be implemented as a tree data structure.

The data storage module 500 may set a data storage structure and store integrated measurement data (IMD), test setting data, and test setting index according to the data storage structure. Details of the data storage structure are described in FIGS. 5 and 6.

The real-time monitoring module 600 may monitor the test in real time based on integrated measurement data (IMD).

4 is a view showing a data storage method of the master device 300 according to an embodiment of the present invention. 5 is a view showing a data storage structure according to an embodiment of the present invention.

1 to 5, the data storage method of the master device 300 implemented by the data storage module 500 will be described in detail.

The data storage method of the master device 300 includes the steps of creating a first folder (S110), storing test setup data in a first folder, and generating a second folder (S120), and a test setup index in the second folder. And storing integrated measurement data for the entire test, generating a third folder (S130), and storing integrated measurement data for a detailed test in the third folder (S140).

The master device 300 may create a first folder at a depth of the first level LEVEL 1 (S110). For example, the first level LEVEL 1 may refer to a drive folder of a storage device.

The master device 300 may store test setting data in a first folder that is the second level (LEVEL 2) depth, and create a second folder (S120).

The master device 300 may store the test setting index and the integrated measurement data for the entire test in the second folder at the third level (LEVEL 3) depth (S130).

The master device 300 may store the integrated measurement data for the detailed test in the third folder, which is the fourth level (LEVEL 4) depth (S140).

For example, the integrated measurement data (IMD) may include integrated measurement data for a full test and integrated measurement data for a detailed test.

6 is a view showing a display unit 340 of the master device 300 according to an embodiment of the present invention.

1 to 6, the display unit 340 of the master device 300 may include a first window W1, a second window W2, and a third window W3.

The display unit 340 of the master device 300, through the first window (W1), test setting data (eg, all test identification (ID) numbers, detailed test identification (ID) numbers, test dates, test times, etc.) And set content can be displayed.

In addition, the display unit 340 of the master device 300, through the first window (W1), detailed test information (test location, test description, bullet shape information, bullet number, bullet type, target information, fire control information, Range, reference elevation, reference azimuth, etc.) can be set, and the set contents can be displayed.

The master device 300 may display the connection status of the measurement unit 100 and the reception status of measurement data (MD) through the second window W2. As shown in FIG. 7, the master device 300 connects the data measurement unit 100 for each of the detailed items (eg, camera, bullet pressure, wind direction, wind speed, temperature, air pressure, etc.) through the second window W2 The current status and the reception status of the measurement data (MD) can be displayed.

The master device 300 may monitor the test status in real time through the third window W3. For example, the master device 300 may display a real-time test status as a graph or a launch image through the third window W3. According to an embodiment, the master device 300 may further display an elevation graph, a bullet velocity graph, an azimuth angle graph, a wind speed graph, a resistance value graph, a temperature graph, a humidity graph, an impact graph, etc. through a third window W3. have.

Through the above, the measurement data management system according to an embodiment of the present invention can integrate and store the launch test measurement data for the induction-free rocket system and monitor the measurement status in real time.

In addition, the measurement data management system according to an embodiment of the present invention can systemize the test and measurement task of the launch test for the induction-free rocket system.

In addition, another problem to be solved of the present invention can effectively realize the test data integrated management system of the launch test for the induction-free rocket system.

In addition, another problem to be solved of the present invention is through the visualization of integrated data, it is possible to monitor the test measurement status in the field and review real-time results.

Although described above with reference to the preferred embodiment of the present invention, those skilled in the art or those skilled in the art will depart from the spirit and technical scope of the invention described in the claims below. It will be understood that various modifications and changes can be made to the present invention without departing from the scope.

Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

10: measurement data management system 20: Po
30: shot 40: target
50: test site 100: measurement unit
200: data management unit 300: master device

Claims (15)

A measurement unit for measuring a gun and a bullet fired toward a target at a test site to generate measurement data;
A data management device unit that converts the format of the measurement data into an integrated format to generate integrated measurement data;
And a master device for storing the integrated measurement data and monitoring the measurement status of the measurement unit in real time based on the integrated measurement data. According to claim 1,
The master device,
A test setting module for generating test setting data and test setting indexes including at least one of test type information, a full test identification number and a detailed test identification number;
A data storage module for setting a data storage structure and storing the integrated measurement data, the test setting data and the test setting index according to the data storage structure; And
Measurement data management system comprising a real-time monitoring module for monitoring the test in real time based on the integrated measurement data. According to claim 2,
The data storage method using the data storage module of the master device,
Creating a first folder;
Storing the test setting data in the first folder and creating a second folder;
Storing, in the second folder, the test setting index and the integrated measurement data for the entire test, and creating a third folder; And
And storing the integrated measurement data for a detailed test in the third folder. According to claim 3,
The test setting index is a measurement data management system, characterized in that the data of a tree (tree) data structure including an index value for linking the test setting data and the integrated measurement data to each other. According to claim 1,
The master device and the data management device is a measurement data management system characterized in that they communicate with each other through a Transmission Control Protocol / Internet Protocol (TCP / IP) of an Internet network. According to claim 1,
The measurement unit,
A first pressure sensor unit measuring the post-storm pressure of the launch to generate first pressure data;
A second pressure sensor unit measuring pressure in the bullet to generate second pressure data;
An acceleration sensor unit measuring acceleration of the gun and generating acceleration data;
A sound pressure sensor unit measuring sound pressure to generate sound pressure data;
A first high-speed camera unit that captures a launch environment and generates launch data;
A second high-speed camera unit that captures the shot of the bullet and generates image data;
A radar unit measuring flight of the bullet and generating flight data; And
Includes an environmental sensor unit for measuring the environment of the test site to generate environmental data,
The measurement data, measurement data management characterized in that it comprises the first pressure data, the second pressure data, the acceleration data, the sound pressure data, the launch data, the image data, the flight data and the environment data system. The method of claim 6,
The environmental sensor unit, the measurement data management system, characterized in that for generating the environmental data by measuring the test site environment including at least one of the wind direction, wind speed, temperature, humidity and air pressure of the test site. The method of claim 6,
The data management device unit,
A sensor data management device for converting each format of the first pressure data, the second pressure data and the acceleration data into the integrated format to generate first integrated pressure data, second integrated pressure data and integrated acceleration data;
A sound pressure data management device that converts the format of the sound pressure data into the integrated format to generate integrated sound pressure data;
A launch data management device for converting the format of the launch data into the integrated format to generate integrated launch data;
An image data management device that converts the format of the image data into the integrated format to generate integrated image data;
A flight data management device for converting the format of the flight data into the integrated format to generate integrated flight data; And
And an environmental data management device that converts the format of the environmental data into the integrated format to generate integrated environmental data. The method of claim 8,
The environment data management device includes a sound detection sensor, and the measurement data management system characterized in that by using the sound detection sensor to detect the sound generated during the launch, to automate the operation. The method of claim 8,
The firing data management apparatus calculates a muzzle velocity value based on the firing data, and transmits the muzzle velocity value to the master device. According to claim 1,
The bullet is a measurement data management system, characterized in that it is a non-guided rocket bullet that does not include a guide device. Format of each of the first pressure data generated by the first pressure sensor unit by measuring the post-storm pressure, the second pressure data generated by the second pressure sensor unit by measuring the bullet pressure, and the acceleration data generated by the acceleration sensor unit measuring the rebound reaction Sensor data management device to convert to an integrated format;
A sound pressure data management device for converting the sound pressure data generated by measuring the sound pressure sensor unit into the integrated format;
A launch data management device for converting a format of launch data generated by photographing a launch environment by a first high-speed camera unit into the integrated format;
An image data management device for converting a format of image data generated by a second high-speed camera unit photographing a flight of a bullet into the integrated format;
A flight data management device for converting a format of flight data generated by measuring the flight of the bullet by the leather unit into the integrated format;
An environmental data management device for converting a format of environmental data generated by measuring the environment of a test site by the environmental sensor unit into the integrated format; And
And a master device that stores data in the integrated format and monitors the measurement status in real time. The method of claim 12,
The environmental data management apparatus, by using a sound detection sensor, by detecting the firing sound generated when the shot is fired, the measurement data management system, characterized in that to automate the operation. The method of claim 12,
The firing data management apparatus calculates a muzzle velocity value based on the firing data, and transmits the muzzle velocity value to the master device. The method of claim 12,
The bullet is a measurement data management system, characterized in that it is a non-guided rocket bullet that does not include a guide device.

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