KR20180124690A - Array station design apparatus for Detects sound waves for extremely low frequency signals by using Satellite map - Google Patents

Abstract

The present invention comprises: an administrative district search module (110) searching for an area, on which the observatory will be installed, by matching a subject administrative district and location information with location coordinates of a satellite map (500) and displaying the area on a screen so as to enable a user to confirm geographical characteristics of the area on which an observatory will be installed; an array generating unit (300) defining an array of the observatory by generating regular polygons for designing the array of the observatory from input values according to an array definition; an array changing unit (400) overlapping the plurality of regular polygons provided from the array generating unit (300) and making a finally targeted array of the observatory through a movement and a rotation; and a satellite map display unit (200) applying the finally targeted array of observatory made by the array changing unit (400) onto the area searched by the administrative district search module (110) and displaying the same on the screen so as to enable the user to confirm whether the array of observatory is applicable to an area where the array will actually be located. The present invention enables the user to confirm geographical characteristics with reference to the location of the observatory by using a satellite map and to find an optimal location of the observatory, and thus, the location of the observatory can be easily selected even in a mountainous area that cannot be easily accessed.

Description

TECHNICAL FIELD [0001] The present invention relates to an apparatus for designing an array station for detecting a sound source of a very low frequency signal using a satellite map,

The present invention relates to an apparatus for designing an array station for detecting a sound source of a very low frequency signal using a satellite map.

The United Nations is operating an integrated seismic monitoring network system for the CTBT (Comprehensive Nuclear Test Ban Treaty) surveillance system.

Ultra-sonic waves are transmitted through the atmosphere as a medium due to shock waves at the same time as earthquakes due to nuclear test or artificial blasting.

The sound waves propagated in the atmosphere can be measured by a sound pressure sensor, but since the energy is small, several sound pressure sensors can be installed in a specific area to superimpose the signals using the spatial correlation of the sound pressure sensor to calculate the propagation direction and speed of the sound source. have.

The characteristics of the spatial correlation (array response function (ARF)) are different according to the arrangement of the sound pressure sensors, and resolution and accuracy of the analysis are different according to the array response function.

Array design is a very important process in the design of sonar station.

In the case of offshore, the sound observation station is located in a plain or forest area, and this is a good environment for acquiring sound waves. However, in Korea, most of the plains are mostly urban and agricultural areas and other mountainous areas are difficult to access. There are difficulties in selecting the location.

Therefore, it is necessary to develop a program to identify geographical characteristics and find the optimal location of the station using a satellite map based on the location of the station using satellite map to solve such difficulties.

Related Prior Art Document Information: Registration No. 10-1364516 (Date of Publication: February 19, 2014) " Calibration Method of Very Low Frequency Acoustic Wave Detection System "

However, such a "correction method for a very low frequency sound wave detection system" can not find the optimal observation site position by using the satellite map to check the geographical characteristics of the satellite map based on the location of the station.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a low-frequency signal using a satellite map that enables to find an optimal observing site position, The present invention provides an apparatus for designing an array observation station for detecting a sound source of an array.

In order to achieve this object,

According to an aspect of the present invention,

An administrative zone search module (110) for searching the area to be installed with the location information of the administrative area and the location information of the satellite map (500) and searching for the area to be installed and confirming the topographical characteristics of the area where the observatory is to be installed;

An array generator (300) for generating a regular polygon for designing an array of observation stations from input values according to the array definition and defining an array of observation stations;

An arrangement changing unit 400 which superimposes a plurality of regular polygons provided from the arrangement generating unit 300 and converts them into an array of observation stations as a final target through movement and rotation; And

The administrative area search module 110 applies the arrangement of the final target stations created by the arrangement change unit 400 on the area searched by the administrative area search module 110 and displays them on the screen to determine whether the array of the observation stations can be applied to the area A satellite map display unit 200 for confirming the satellite map;

And a control unit.

And the input value according to the array definition includes the number of sides of the regular polygon.

According to another aspect of the present invention,

A satellite map of the satellite map 500 is derived based on the center point of the observing site array based on the input coordinates of the observing site, and the observation points are arranged on the satellite map derived from the satellite map and displayed on the screen. An analysis result display unit 800 for displaying an analysis result provided from the analysis result display unit on a screen;

An array response function analyzing unit for analyzing an array response function, an array transfer function (ATF), a sound wave velocity-frequency correlation function, and providing an analysis result to the analysis result display unit 800, 900); And

An observing location changing unit 700 for changing the coordinates of the corresponding observing station as the user selects the individual observing station displayed on the satellite map and moves the selected observing station to the corresponding place with the mouse;

And a control unit.

The present invention is able to identify geographical characteristics of a satellite map using the satellite map based on the location of the station, and to find an optimal location of the station, so that the location of the station can be easily selected It is effective.

Figure 1 is a view of an observatory And a functional block diagram for performing the array design.
FIG. 2 is a diagram illustrating a screen for explaining the operation of the functional block diagram according to FIG. 1. FIG.
Figure 3 is a graphical representation of an < RTI ID = Figure 2 is a functional block diagram of performing an array response function analysis.
FIG. 4 is a view for explaining the operation of the functional block diagram according to FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 is a view of an observatory An administrative area search module 110, a satellite map display section 200, an arrangement generating section 300, an arrangement changing section 400, and a satellite (not shown) And a map 500.

FIG. 2 is a diagram illustrating a screen for explaining the operation of the functional block diagram according to FIG. 1. FIG.

2 and 3, the administrative area search module 110 searches the administrative area and location information of the ROK and the location coordinates of the satellite map 500, (20) as shown in FIG. 2 and displays the area on the screen so that the user can confirm the geographical characteristics of the area where the observatory is to be installed. At this time, the satellite map 500 can be expressed through coordinate conversion using a satellite map API which is open to the public in Google.

The array generator 300 defines an array of observation stations by generating a basic regular polygon for designing an array of observation stations from input values according to the array definition 30 as shown in FIG. At this time, the array of observation stations is the most ideal arrangement when it is configured as regular polygon.

That is, the array generator 300 generates a corresponding regular polygon by inputting the number of sides of the regular polygon in the array definition 30 shown in FIG. 2, and provides the generated regular polygon to the array modifier 400 by pressing the array adding button .

The arrangement changing unit 400 superimposes a plurality of regular polygons provided from the arrangement generating unit 300 in the same manner as the arrangement creating unit 40 in FIG. Design the form. At this time, the arrangement change unit 400 may add a plurality of regular polygons, and the plurality of added regular polygons are sequentially listed in the arrangement type list, and a single regular polygon can be selected or deleted. The selected regular polygon is parallel Can be moved.

The satellite map display unit 200 applies the arrangement of the final target stations created by the arrangement change unit 400 on the area searched by the administrative area search module 110 to obtain the map application As shown in FIG. 2, the user presses the button 20 to display 20 on the screen so that the user can confirm whether or not the arrangement of the observation station is applicable to the actual location.

The optimal array is searched by repeatedly changing the regular polygons and applying the map.

Figure 3 is a graphical representation of an < RTI ID = A satellite map 500, an observing site location coordinate input 600, an observing site location changing unit 700, an analysis result display unit 800, and an arrangement response function analyzing unit 900 to perform an array response function analysis .

FIG. 4 is a view for explaining the operation of the functional block diagram according to FIG.

3 and 4, the analysis result display unit 800 displays a satellite map of the relevant part in the satellite map 500 based on the center point of the observing site array based on the coordinates of the observatory site coordinates according to the observing site position coordinate input 600 (50) on the screen as shown in FIG. 4 and displays the analysis result provided from the arrangement response function analysis unit 900 on the screen as shown in FIG. 4 (60).

The array response function analyzing unit 900 analyzes an array response function, an array transfer function, and a sound wave velocity-frequency correlation function at an observing site position coordinate according to an observing site position coordinate input 600 and outputs the analysis result to the analysis result display unit 800 to provide.

Meanwhile, the analytic values analyzed by the array response function analyzing unit 900 are a combination of constant values indicating numerical values. In order to use the combination of the constant values as the significant data, the analysis result display unit 800 displays a combination of constant values (60) on the screen as shown in FIG.

Observation stations are important in terms of arrangement, but since they need to be able to determine the area that can be installed, it is necessary to find the optimal array reaction function while checking the array design and actual geographical characteristics in real time.

To this end, the user changes the position coordinates of the corresponding observation point as the user selects the individual observation point displayed on the satellite map derived by the observation point position changing unit 700 and moves the selected observation point to the corresponding place.

When the coordinates of the observing site are changed, the array response function analyzing unit 900 re-analyzes the array response function, the array transfer function, and the sound wave velocity-frequency correlation function at the changed coordinates of the observing site and outputs the analysis result to the analysis result display unit 800 ).

Also, the analysis result display unit 800 re-displays the analysis result according to the re-analysis provided from the arrangement reaction function analysis unit 900 on the screen as shown in FIG. 4 (60).

4, when the user clicks the button for changing the station location, the user can change the position of the station on the derived satellite map by moving the satellite map by clicking the corresponding button with the mouse. At this time, if an observation station to be changed is selected on the screen 50 of FIG. 4 and then a movement position is selected, the position of the observation station is changed and an array reaction function is automatically calculated and displayed.

Through this process, we find the optimal array of observatories.

The present invention makes it possible to easily locate an observation station in a mountainous region where access is difficult because the satellite map can be used to identify geographical characteristics and locate an optimal observation station using a satellite map based on a satellite map .

Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. In addition, it is a matter of course that various modifications and variations are possible without departing from the scope of the technical idea of the present invention by anyone having ordinary skill in the art.

Claims (3)

An administrative zone search module (110) for searching the area to be installed with the location information of the administrative area and the location information of the satellite map (500) and searching for the area to be installed and confirming the topographical characteristics of the area where the observatory is to be installed;
An array generator (300) for generating a regular polygon for designing an array of observation stations from input values according to the array definition and defining an array of observation stations;
An arrangement changing unit 400 which superimposes a plurality of regular polygons provided from the arrangement generating unit 300 and converts them into an array of observation stations as a final target through movement and rotation; And
The administrative area search module 110 applies the arrangement of the final target stations created by the arrangement change unit 400 on the area searched by the administrative area search module 110 and displays them on the screen to determine whether the array of the observation stations can be applied to the area A satellite map display unit 200 for confirming the satellite map;
Wherein the satellite observation map is used for designing an array station for detecting a sound source of a very low frequency signal. The method according to claim 1,
And an input value according to the array definition includes the number of sides of a regular polygon. The apparatus for designing an array station for detecting a sound source of a very low frequency signal using a satellite map. A satellite map of the satellite map 500 is derived based on the center point of the observing site array based on the input coordinates of the observing site, and the observation points are arranged on the satellite map derived from the satellite map and displayed on the screen. An analysis result display unit 800 for displaying an analysis result provided from the analysis result display unit on a screen;
An array response function analyzing unit 900 for analyzing an array response function, an array transfer function, and a sound wave velocity-frequency correlation function as coordinates of an observing station provided and providing analysis results to the analysis result display unit 800; And
An observing location changing unit 700 for changing the coordinates of the corresponding observing station as the user selects the individual observing station displayed on the satellite map and moves the selected observing station to the corresponding place with the mouse;
Wherein the satellite observation map is used for designing an array station for detecting a sound source of a very low frequency signal.

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