KR20190131334A - Gunshot detection system - Google Patents

Abstract

The present invention relates to a gunshot detection system for quickly detecting and analyzing gunshots, calculating an optimal evacuation path, and providing the evacuation path to a user. The gunshot detection system comprises: a first mobile terminal comparing an input sound with a previously stored setting value, determining whether the sound satisfies the setting value, and generating sound detection information including the sound and position information when the sound satisfies the setting value; a system server receiving the sound detection information from the first mobile terminal to determine whether the sound is a gunshot, and analyzing the sound by pre-stored gunshot analysis data when the sound is a gunshot to generate notification information including at least one among an occurred location of the gunshot, a kind of a gun, and the number of guns; and a second mobile terminal receiving and outputting the notification information.

Description

Gunshot detection system

The present invention relates to a gunfire detection system, and more particularly, to a gunfire detection system intended to quickly detect and analyze gunfire, calculate an optimal evacuation path and provide it to the user.

In general, the issue of gunshots is a social problem that has risen exponentially since the 21st century and is rapidly rising above the water. For example, in the United States, guns are relatively easy to obtain, resulting in a number of firearms incidents, such as the Florida high school shootings and the Virginia Tech shootings.

In countries where gunfire incidents occur, gun control has been discussed every time such an incident occurs, but gun control is being defeated every time.

Therefore, bulletproof backpacks and small baseball bats have been developed to cope with subsequent firearms accidents, but this is advantageous in the situation where the shooter is faced at close range and has become useless at a long distance.

In addition, there is no quick way to find out about such crimes in the event of a gunshot accident. In addition, the majority of students have time to evacuate to shooters, but due to mass panic or confusion, it was impossible to determine the exact situation and to escape. .

Republic of Korea Patent No. 10-0904777 (June 18, 2009)

The present invention has been proposed to solve all the problems occurring in the prior art as described above, quickly detect and analyze gunshots, calculate the optimal evacuation route through the analyzed value, and calculate the evacuation route to the user Provides a gun detection system to be provided.

Another object of the present invention is to provide a gun detection system to ensure the evacuation time of the user until the shooter is overpowered by providing information about the shooter when the user can not evacuate through a safe evacuation route.

In order to solve the above problems, the gun detection system according to the present invention compares the input sound with a preset stored value, determines whether the sound satisfies the set value, and when the set value satisfies the set value, A first mobile terminal for preparing sound detection information including location information; Receiving the sound detection information from the first mobile terminal to determine whether the sound is gunfire, and if the sound is gunfire analyzes the sound by the pre-stored gunshot analysis data, the generation position of the gunfire, the type of firearm, System server for generating notification information including any one or more of the number of firearms; And a second mobile terminal for receiving and outputting the notification information.

According to the gunshot detection system according to the present invention, by quickly detecting and analyzing gunshots, calculating the optimal evacuation route through the analyzed values, and providing the calculated evacuation route to the user, the user may be in a group panic and confusion. Evacuation routes are provided to ensure safety.

In addition, according to the gunshot detection system according to the present invention, if the user can not evacuate through a safe evacuation route by providing information about the shooter, to ensure the evacuation time of the user until the shooter is overpowered by damage caused by gun fire accident Can be prevented.

1 is a diagram showing the configuration of a gun detection system according to a first embodiment of the present invention.
2 is a view showing a state of use of the gunfire detection system according to the present invention.
3 is a diagram illustrating an example in which FIG. 2 is actually applied.
4 is a diagram showing the configuration of a gun detection system according to a second embodiment of the present invention.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings that describe exemplary embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

1 is a diagram showing the configuration of a gun detection system according to a first embodiment of the present invention.

Referring to FIG. 1, the gunshot detection system 10 according to the present invention includes a first mobile terminal 20, a system server 30, and a second mobile terminal 40.

The first mobile terminal 20 collects sounds that may be shot and transmits them to the system server 30.

The first mobile terminal 20 compares the input sound with a previously stored setting value (hereinafter, referred to as a setting value) to determine whether the sound satisfies the setting value, and when the setting value satisfies the setting value, a sound detection including sound and position information. Fill out the information.

In more detail, the first mobile terminal 20 is provided with a microphone for collecting sound, and compares the sound input to the microphone with a set value. Here, the set value may be defined as a reference value or a comparison value for determining whether the sound input through the microphone is the target of the shot analysis. Therefore, the set value may include a reference decibel or a reference frequency value to determine the loudness and the frequency concentration of the sound. Since the set value may vary in decibels or frequencies of the gun sounds according to the type of firearm, the set values are preset in various reference decibels or reference frequencies according to the type of firearms and are stored in the first mobile terminal 20.

The first mobile terminal 20 may maintain an idle state to maintain the minimum function to determine whether the set value is satisfied. When the sound input to the microphone in the idle state satisfies the setting value, the first mobile terminal 20 performs the predetermined procedure by releasing the idle mode. Here, the predetermined procedure refers to a procedure of generating sound detection information and transmitting it to the system server 30.

Therefore, the first mobile terminal 20 generates sound detection information including sound and location information satisfying the set value and transmits the sound detection information to the system server 30. Here, the location information is the location information of the user who uses the first mobile terminal 20, which can be obtained through GPS in the outdoors, and receives a WiFi signal from an access point (AP) indoors to obtain a fingerprint technique. Or triangulation. As another method, location information of a mobile communication network may be used in addition to GPS, or another method for indoor positioning may be used.

The system server 30 receives sound detection information from the first mobile terminal 20 to determine whether the sound is a gunshot, and if the sound is a gunshot, the system server 30 analyzes the sound based on prestored gunshot analysis data and fires the gun. Generates notification information including any one or more of the type, the number of firearms. In addition, the system server 30 transmits the notification information to the second mobile terminal 40. Here, the pre-stored gun analysis data may include the sounds, types, specifications of all firearms used and distributed. The notification information may include location information of the first mobile terminal.

In addition, the system server 30 is built a database for storing the total analysis data, the database stores the setting information and evacuation information. The setting information includes subscriber information, subscriber group, service provision target, etc. necessary for providing a service installed in the first mobile terminal 20. In addition, the evacuation information includes 3D virtual building data or an indoor map of a place where gunfire occurred in order to calculate an evacuation route.

In addition, the system server 30 calculates the generation position of the gunfire using the sound detection information transmitted from the first mobile terminal 20. In detail, the system server 30 receives the sound detection information from the first mobile terminal 20, and analyzes the received sound detection information through cluster analysis.

At this time, the cluster analysis is a multivariate analysis technique for grouping similar objects based on the characteristics of a plurality of objects, and used to determine the location of occurrence of gunfire (shooter position) and the location of the first mobile terminal 20 in the present invention. do. That is, the system server 30 classifies the first mobile terminal 20 that detects the gunshot from the position where the gunshot occurs through cluster analysis into the same group. In this case, the first mobile terminal 20 may be configured in plurality. In addition, since the plurality of first mobile terminals 20 differ in the order of sensing gunshots according to the magnitude of gunshots, the system server 30 analyzes the distance between the first mobile terminals 20 which sequentially detects gunshots. To determine the location of gunshots.

At this time, the method of analyzing the sound detection information can calculate the occurrence location of the gunfire using various analysis methods, the cluster analysis is only one example for easy understanding of the present invention, it is to limit the present invention to the presented method no. That is, as long as it is a method capable of effectively analyzing sound detection information, it is possible to apply and use various known analysis methods.

Therefore, the system server 30 analyzes the sound detection information using the cluster analysis, and then generates notification information including any one or more of the location of the gunfire, the type of the firearm, the number of firearms, and the second mobile terminal ( 40).

The second mobile terminal 40 outputs notification information to notify the user of the occurrence of gunfire and recommends an evacuation route. That is, the system receives the notification information including the location information of the first mobile terminal 20 from the server 30 and outputs the location and the notification information of the first mobile terminal 20. At the same time, the second mobile terminal 40 calculates the evacuation route using the evacuation information stored in the system server 30, and provides the evacuation route to the user.

In more detail, the second mobile terminal 40 outputs 3D virtual building data or an indoor map stored in the system server 30 as an image on the screen of the terminal. Then, the second mobile terminal 40 outputs the current position through the location information, and matches it with the image output on the screen. In addition, the second mobile terminal 40 matches the location of the first mobile terminal 20 clustered by the system server 30 and the gunshot generation position with the image output on the screen.

The second mobile terminal 40 provides an evacuation route in either the same direction as the movement route of the user who uses the first mobile terminal 20 or a direction other than the expected movement route of the shooter. In this case, when the shooter moves, the expected movement path of the shooter moves because the user of the first mobile terminal 20 moves away from the moving direction of the shooter.

In addition, the second mobile terminal 40 provides a user with a path and a safety zone nearest to the building that can be avoided on the moving path of the shooter through 3D virtual building data or an indoor map in a building of at least one floor. Accordingly, the user of the second mobile terminal 40 can be safely evacuated along the evacuation path output to the second mobile terminal 40.

In addition, when it is determined that the location where the gunfire occurs is within a predetermined range, the second mobile terminal 40 forcibly switches the brightness of the sound or lighting that may be exposed to the outside to a silent or power saving mode through a function installed in the terminal. In this case, the pre-installed function may be implemented through an application program.

In addition, the second mobile terminal 40 providing an evacuation route automatically sends an emergency message designated as a previously designated destination. In this case, the previously designated destination may include a family, a friend, and the like, and the designated emergency message may include at least one of a voice, a video, and a text.

On the other hand, the second mobile terminal 40 includes the first mobile terminal 20 described above. That is, the role of the first mobile terminal 20 and the second mobile terminal 40 may be changed depending on the situation.

The first mobile terminal 20 may be a terminal that is located near the occurrence of gunfire and detects gunshot, and the second mobile terminal 40 may be a terminal that does not detect gunshot. The terminal that detects the gunshot becomes the first mobile terminal 20, and the terminal that does not detect the gunshot becomes the second mobile terminal 20.

Therefore, the first mobile terminal 20 and the second mobile terminal 40 is not physically divided, but functionally divided for convenience of description.

2 is a view showing a state of use of the gunfire detection system according to the present invention.

Hereinafter, the first mobile terminals 20a to 20c also output the notification information and the evacuation path like the second mobile terminals 40a to 40c, and assuming that gunfire has occurred.

As shown in FIG. 2, the gun detection system 10 of the present invention includes a group of first mobile terminals 20a to 20c positioned around a gunfire occurrence and a second mobile terminal 40a to 40c not positioned around the gunfire occurrence. ) Are roughly divided into groups. When gunfire is generated, the first mobile terminals 20a to 20c positioned around the gunfire generate sound detection information including location information by detecting and determining whether the sound is gunfire.

In this case, the first mobile terminals 20a to 20c detect the gunshots in the order closest to the gunshot generating position. That is, as shown in the figure, the first mobile terminal 20a in the third zone detects gunshot first. Then, the first mobile terminal 20b in the fourth zone detects the gunshot, and the first mobile terminal 20c in the fifth zone detects the gunshot. Accordingly, the first mobile terminals 20a to 20c sequentially detect gunshots, prepare sound detection information, and transmit the sound detection information to the system server 30.

The system server 30 analyzes sound detection information received from the first mobile terminals 20a to 20c through cluster analysis to classify the first mobile terminals 20a to 20c into the same group, and sequentially detects gunshots. By analyzing the distance between the first mobile terminal (20a ~ 20c) to determine the location of the gunshot. Therefore, the system server 30 analyzes the sound detection information using cluster analysis, generates notification information, and transfers the generated notification information to the second mobile terminal 40.

The second mobile terminals 40a to 40c receive notification information from the system server 30 and output the notification information to provide the user with the location of the gunshot and the location of the user of the first mobile terminals 20a to 20c. In addition, the second mobile terminals 40a to 40c provide the user with the evacuation route except for the shot shooting location or the expected movement route of the shooter through the evacuation information stored in the system server 30.

Accordingly, as shown in the figure, when the shooter moves in the expected movement path, the user of the first mobile terminals 20a to 20c may move in a direction (west, south, north) excluding the shot shooting occurrence position or the expected movement path of the shooter. Evacuate. In addition, the user of the second mobile terminal (40a ~ 40c) can evacuate along the evacuation route of the user of the first mobile terminal (20a ~ 20c) or in the direction except the expected movement path of the shooter through the evacuation route output on the screen. have.

At this time, the user of the first mobile terminal (20a ~ 20c) and the second mobile terminal (40a ~ 40c) may be exposed to the shooter while evacuating along the evacuation path. Therefore, when the first mobile terminal 20a to 20c and the second mobile terminal 40a to 40c are determined to be within a predetermined range of gunfire generation, the first mobile terminal 20a to 20c forcibly switches the sound to silent and forcibly switches the brightness of the light to the power saving mode. To prevent the user from being exposed from the shooter.

In addition, the first mobile terminal (20a ~ 20c) and the second mobile terminal (40a ~ 40c), when outputting the notification information and the evacuation route, automatically sends an emergency message designated as a predetermined destination. At this time, the designated emergency message is automatically sent silently to prevent the risk of exposure to the shooter.

Accordingly, the user can be safely evacuated through the evacuation route guided by the first mobile terminal (20a ~ 20c) and the second mobile terminal (40a ~ 40c), it is possible to prevent gun fire in advance.

FIG. 3 is a diagram illustrating an example in which FIG. 2 is actually applied, which is described using 3D virtual building data or an indoor map. Hereinafter, a description overlapping with FIG. 2 will be omitted.

As shown in FIG. 3, a firearm accident may occur in a room more than a single floor. In this case, the mobile terminals located on the first floor may be the second mobile terminals 40a to 40c, and the mobile terminals located on the same floor (the second floor) or the second stair 210 as the shooter may be the first mobile terminals 20a to 20c. May be).

According to the shooting position generated from the shooter, an optimal evacuation path is output on the screens of the first mobile terminals 20a to 20c and the second mobile terminals 40a to 40c. Here, the optimal evacuation route is calculated from the evacuation information stored in the system server 30 and is provided to the user by being expressed as a line or a symbol such as navigation. In addition, the evacuation information may include an algorithm for providing an optimal evacuation route or an optimal hiding place.

Accordingly, since the first mobile terminal 20a is close to the first staircase 200, the evacuation route is recommended to the user to evacuate to the first staircase 200 and to escape through the first exit 100. In addition, the first mobile terminals 20b and 20c located in the second stair 210 descend to the first floor by using the second stair 210 to the user, and then evacuate the evacuation path to escape through the second exit 110. Recommended.

In addition, since the second mobile terminal 40a located on the first floor is close to the first exit 100, an evacuation route is recommended to escape through the first exit 100. Since the other second mobile terminals 40b and 40c are close to the second exit 110, an evacuation route is recommended to escape through the second exit 110.

Although not shown in the drawing, a user of the first mobile terminal 20 and the second mobile terminal 40 may be located close to the location of the shooter and far from the first and second outlets 100 and 110. For such a user, the first mobile terminal 20 and the second mobile terminal 40 may not recommend an escape, but may recommend a place for hiding. The place to hide can be calculated using the evacuation information stored in the system server (30).

Thus, the user can be advised to use a firearm detection system 10 to safely evacuate or hide from indoors to outside.

4 is a diagram showing the configuration of a gun detection system according to a second embodiment of the present invention.

As shown in FIG. 4, the gunshot detection system 10 according to the second embodiment includes a first mobile terminal 120, a system server 130, and a second mobile terminal 40 like the first embodiment. do.

However, unlike the first embodiment described above, the second embodiment of the present invention has a difference in that the analysis process of gunshot is performed in the first mobile terminal 120 and the processing of the portion associated with it.

Hereinafter, in describing the second embodiment, detailed descriptions of the same parts as those of the first embodiment described above or parts that can be easily understood with reference to the first embodiment will be omitted.

First, the first mobile terminal 120 detects sound and determines whether it is a shot.

If the sound is determined to be gunshot, the gunshot is analyzed by the prestored gunshot analysis data to calculate analysis information. That is, unlike the first embodiment, the system server 130 does not receive and analyze the sound detection information, but analyzes the gunshot using the gunshot analysis data by the first mobile terminal 120 itself.

In this case, the method for analyzing the totality may be analyzed using the cluster analysis described in the first embodiment, and information for analysis may be received from another first mobile terminal 120. To this end, the first mobile terminal 120 may share data using WI-FI Direct or Bluetooth to enable the analysis information analyzed through cluster analysis to be connected between terminals without an Internet connection or an AP.

The analysis information calculated from the first mobile terminal 120 may include any one or more of the generation position of gunfire, the type of firearm, the specification of the firearm, and the position information, and is transmitted to the system server 130.

The system server 130 receives the analysis information calculated from the first mobile terminal 120, generates notification information, and serves to deliver the second mobile terminal 40. In this case, the notification information includes analysis information.

Thereafter, the second mobile terminal 40 receives and outputs notification information generated from the system server 130.

Accordingly, the analysis process is performed on the first mobile terminal 120 without performing the analysis process on the system server 130. Therefore, even when the system server 130 is down, the user who needs the gun detection system 10 may receive a service from the first mobile terminal 120.

On the other hand, although not shown in the drawing, as the number of the first mobile terminal 220 and the second mobile terminal 240 increases, the system server 230 for the total analysis causes a lot of load.

Therefore, the gun detection system 10 of the present invention may be configured to analyze the gunshot in any one of the system server 230 and the first mobile terminal 220.

Although the invention made by the present inventors has been described in detail with reference to the accompanying drawings, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the gist of the invention. to be.

10; Gunshot detection system 20,120: the first mobile terminal
30,130: system server 40: the second mobile terminal
100: first exit 110: second exit
200: first step 210: second step

Claims (7)

A first mobile terminal that compares an input sound with a previously stored setting value, determines whether the sound satisfies the setting value, and generates sound detection information including the sound and position information when the sound satisfies the setting value;
Receiving the sound detection information from the first mobile terminal to determine whether the sound is gunfire, and if the sound is gunfire analysis of the sound by the pre-stored gunshot analysis data, the generation position of the gunfire, the type of firearm, System server for generating notification information including any one or more of the number of firearms; And
And a second mobile terminal configured to receive and output the notification information. It is determined whether the sound is gunfire by comparing the input sound with a preset stored value, and if the sound is gunfire, the sound is analyzed by prestored gun analysis data to generate the gunfire location, type of firearm, A first mobile terminal for calculating analysis information including any one or more of quantity and location information;
A system server for generating notification information including the analysis information calculated by the first mobile terminal; And
And a second mobile terminal configured to receive and output the notification information. The method according to any one of claims 1 and 2,
The first mobile terminal is composed of a plurality, gunshot detection system, characterized in that included in the second mobile terminal. The method according to any one of claims 1 and 2,
And the system server calculates a location of occurrence of the gunfire using the sound detection information transmitted from each of the plurality of first mobile terminals. The method according to any one of claims 1 and 2,
The notification information
Including location information of the first mobile terminal,
The second mobile terminal
Gunfire detection system, characterized in that for outputting the location of the first mobile terminal using the location information. The method according to any one of claims 1 and 2,
The system server
Contain evacuation information including 3D virtual building data or indoor maps of the locations where gunfire occurred
The second mobile terminal
And a evacuation route using the evacuation information according to the occurrence location of the gunfire and the position of the first mobile terminal, and automatically outputs an emergency message designated to a predetermined destination. The method according to any one of claims 1 and 2,
The first mobile terminal and the second mobile terminal,
And if the sound is determined to be gunshot, when the gunshot location is within a predetermined range, forcibly switching the notification sound and the ringtone to silence.

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