KR102092318B1 - Emergency response system - Google Patents

Abstract

In an emergency response system, each of the surveillance cameras includes a GPS (GPS: Global Positioning System) receiver, transmits its own location information to a relay server, and relays the event information when an event is detected. To the server. The relay server transmits the location information of the surveillance camera that transmitted the event information and the event information to any one of the navigation devices of the patrol vehicles.

Description

Emergency response system {Emergency response system}

The present invention relates to an emergency response system, and more particularly, to an emergency response system that notifies the patrol vehicle of information on the generated event when an event occurrence is detected in the surveillance camera.

Currently, due to the development of image analysis technology, a surveillance camera can detect the occurrence of various events.

In an emergency-emergency response system using this, in the related art, location information of surveillance cameras is obtained using a map layout technique, and the obtained location information is stored in a database of a host device and used.

In addition, when an event is detected by a surveillance camera, when the surveillance camera transmits event information to the host device, the surveillance agent in the control room finds the location information of the surveillance camera that has transmitted the event information in the database, and The location information of the surveillance camera that transmitted the information and the information of the event are notified to a patrol vehicle.

The conventional emergency-emergency response system has the following problems.

First, it is impossible to accurately measure the positions of surveillance cameras using a map layout technique. Accordingly, in an emergency response system for a relatively large area, a patrol vehicle cannot quickly find an event occurrence point.

Second, since the emergency response system is operated by the operation of the monitoring personnel in the control room, there is a high probability that the operation time of the monitoring personnel is extended. Accordingly, there is a high probability that the emergency response time will be extended.

Republic of Korea Patent Publication No. 2013-0071510 (applicant: British Electronics Co., Ltd., title of the invention: a camera device for surveillance, a wide area surveillance system and a linked monitoring method therefor).

Embodiments of the present invention, in an emergency response system, it is intended to enable the patrol vehicle to quickly find an event occurrence point even in a relatively large area, and to significantly reduce the emergency response time.

In an emergency response system according to an aspect of the present invention, surveillance cameras, relay servers, and navigation devices of patrol vehicles are connected through a communication network.

Each of the surveillance cameras includes a GPS (GPS: Global Positioning System) receiver, transmits its own location information to the relay server, and when an event is detected, transmits the event information to the relay server.

The relay server transmits the location information of the surveillance camera that transmitted the event information and the event information to any one of the navigation devices of the patrol vehicles.

According to the emergency-emergency response system of the embodiment of the present invention, there are the following effects.

First, each of the surveillance cameras has a GPS (GPS: Global Positioning System) receiver, and can transmit its precise location information to the relay server. Accordingly, the patrol vehicle can quickly find the event occurrence point even in a relatively large area.

Second, the relay server transmits the location information of the surveillance camera that transmitted the event information and the event information to any one of the navigation devices of the patrol vehicles. That is, by using the navigation devices of the patrol vehicles, the location information of the surveillance camera and the information of the event can be automatically transmitted to one patrol vehicle and used. Therefore, since the monitoring personnel in the conventional situation room are unnecessary, the possibility of extending the emergency-response time is eliminated. In other words, the emergency response time can be significantly reduced.

1 is a view showing an emergency response system of an embodiment of the present invention.
FIG. 2 is a diagram illustrating transmission / reception signals in the emergency response system of FIG. 1.
FIG. 3 is a flow chart showing the operation of one surveillance camera in FIG. 1.
FIG. 4 is a flowchart showing the operation of the relay server of FIG. 1.
5 is a flow chart showing the operation of the navigation device of any one patrol vehicle of FIG. 1.

The following description and the accompanying drawings are intended to understand the operation according to the present invention, and parts that can be easily implemented by those skilled in the art may be omitted.

In addition, this specification and drawings are not provided for the purpose of limiting the present invention, and the scope of the present invention should be defined by the claims. The terms used in this specification should be interpreted as meanings and concepts consistent with the technical spirit of the present invention in order to best represent the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, in this specification and drawings, the same reference numerals are assigned to components having substantially the same functional configuration, and redundant description is omitted.

1 shows an emergency response system of an embodiment of the present invention.

Referring to FIG. 1, in the emergency-emergency response system of an embodiment of the present invention, the surveillance cameras 101a to 101n, the relay server 102, and the navigation devices of the patrol vehicles 105a to 105m communicate with the communication network ( 103). In the case of this embodiment, the communication network 103 is the Internet. Reference numerals 104a to 104k in FIG. 1 indicate base stations.

Here, identification codes of each of the surveillance cameras 101a to 101n and the navigation devices of the patrol vehicles 105a to 105m are registered in the relay server 102. Therefore, each of the surveillance cameras 101a to 101n and the navigation devices of the patrol vehicles 105a to 105m transmits information to the relay server 102 together with a registered identification code.

Each of the surveillance cameras 101a to 101n includes a GPS (GPS: Global Positioning System) receiver, transmits its own network address information (Cna) and location information (Cgp) to the relay server 102, and generates an event When this is detected, information (Cev) of the generated event is transmitted to the relay server 102.

The network address information Cna of each of the surveillance cameras 101a to 101n includes an Internet Protocol (IP) address and a port number. Here, since the network address information Cna can be variably set, each of the surveillance cameras 101a to 101n periodically transmits its network address information Cna to the relay server 102. In addition, since the surveillance cameras 101a to 101n can also move, the location information Cgp is also periodically transmitted to the relay server 102.

Each of the navigation devices of the patrol vehicles 105a to 105m periodically transmits its network address information Pna and location information Pgp to the relay server 102.

The relay server 102 patrols the network address information (Cna), location information (Cgp), and event information (Cev) of the surveillance cameras (any of 101a to 101n) that have transmitted the information (Cev) of the event. It is transmitted to any one of the navigation devices of the fields 105a to 105m, but is transmitted to the navigation device located closest to the surveillance cameras (any one of 101a to 101n) that transmitted the information Cev of the event.

According to the emergency-emergency response system of this embodiment, there are the following effects.

First, each of the surveillance cameras (any one of 101a to 101n) has a GPS (GPS: Global Positioning System) receiver, and can transmit its precise location information (Cgp) to the relay server 102. Accordingly, even in a relatively large area, the patrol vehicle (any one of 105a to 105m) can quickly find the event occurrence point.

Second, the relay server 102 patrols the vehicles 105a to 105m with the location information Cgp of the surveillance cameras (any of 101a to 101n) and the event information Cev that have transmitted the information Cev. ) To any one of the navigation devices. For example, the information is transmitted to a navigation device located closest to a surveillance camera (any one of 101a to 101n) that has transmitted the event information (Cev). That is, by using the navigation devices of the patrol vehicles 105a to 105m, the location information Cgp and the event information Cev of the surveillance cameras 101a to 101n are automatically generated by any patrol vehicle 105a to It can be transmitted to any one of 105m). Therefore, since the monitoring personnel in the conventional situation room are unnecessary, the possibility of extending the emergency-response time is eliminated. In other words, the emergency response time can be significantly reduced.

On the other hand, the navigation device located closest to the surveillance camera (any one of 101a to 101n) that has transmitted the information of the event, displays the information of the received event (Cev), and the location information (Cgp) of the received surveillance camera Accordingly, a destination is set to perform road guidance. Accordingly, the patrol vehicle (any one of 105a to 105m) can find the event occurrence point more quickly.

In addition, the navigation device located closest to the surveillance camera (any one of 101a to 101n) that transmitted the event information, accesses the network address according to the network address information (Cna) of the received surveillance camera, and displays the event information. The live-view video from the transmitted surveillance cameras (any one of 101a to 101n) is displayed on a part of the screen. Accordingly, the patrol crew on the patrol vehicle (any one of 105a to 105m) can be aware of the situation of the event until it reaches the event occurrence point.

FIG. 2 shows transmission / reception signals in the emergency response system of FIG. 1.

As described above, identification codes of each surveillance camera 101n and navigation devices 205m of patrol vehicles (105a to 105m in FIG. 1) are registered in the relay server 102. Accordingly, each surveillance camera 101n and each of the navigation devices 205m of the patrol vehicles 105a to 105m transmits information to the relay server 102 together with a registered identification code.

1 and 2, each surveillance camera 101n periodically transmits its network address information (Cna) and location information (Cgp) to the relay server 102 (step S201).

Further, each of the navigation devices 205m of the patrol vehicles 105a to 105m periodically transmits its own network address information Pna and location information Pgp to the relay server 102 (step S202).

Further, each surveillance camera 101n transmits information (Cev) of the generated event to the relay server 102 when an event occurrence is detected (step S203).

Then, the relay server 102 transmits the network address information (Cna), location information (Cgp), and event information (Cev) of the surveillance cameras (any one of 101a to 101n) that have transmitted the event information (Cev). It is transmitted to any one of the navigation devices of the patrol vehicles 105a to 105m, but is transmitted to the navigation device that is closest to the surveillance camera (any one of 101a to 101n) that has transmitted the information (Cev) of the event. .

FIG. 3 shows the operation of one surveillance camera in FIG. 1. Referring to Figures 1 and 3, the operation of any one of the surveillance cameras (101a to 101n) will be described.

The surveillance cameras (any of 101a to 101n) periodically transmit the network address information (Cna) and location information (Cgp) of the surveillance camera itself to the relay server 102 (step S301).

Further, if the occurrence of an event is detected (step S302), the surveillance cameras (any of 101a to 101n) transmit information (Cev) of the generated event to the relay server 102 (step S303).

On the other hand, if a request signal for video transmission is received from a navigation device of any one of the patrol vehicles (any of 105a to 105m) (step S304), the surveillance cameras (any of 101a to 101n) live-view The video data is transmitted to the navigation device (step S305).

The above steps S301 to S305 are repeatedly performed until an end signal is generated (step S306).

FIG. 4 shows the operation of the relay server 102 of FIG. 1. Referring to Figures 1 and 4, the operation of the relay server 102 will be described as follows.

If any of the surveillance cameras (any of 101a to 101n) or network address information (Cna or Pna) and location information (Cgp or Pgp) of any navigation device is received (step S401), the relay server 102 receives The information is updated and stored (step S402).

If the event information (Cev) is received from any one of the surveillance cameras (any one of 101a to 101n) (step S403), the relay server 102 is a navigation device located closest to the surveillance camera that transmitted the event information (Cev). Search for (step S404). Further, the relay server 102 transmits the network address information Cna, location information Cgp, and event information Cev of the surveillance cameras 101 to 101n to the navigation device of the search result ( Step S405).

The above steps S401 to S405 are repeatedly performed until an end signal is generated (step S406).

FIG. 5 shows the operation of the navigation device of any one of the patrol vehicles 105a to 105m in FIG. 1. This will be described with reference to FIGS. 1 and 5.

If the user, for example, the patrol officer inputs the destination information (step S501), the navigation device of the patrol vehicle (any one of 105a to 105m) sets the destination according to the inputted destination information and proceeds with the road guidance (step S502). ).

If the network address information Cna, location information Cgp, and event information Cev of the surveillance cameras 101a to 101n are input from the relay server 102 (step S503), the patrol vehicle 105a to The navigation device of any one of 105m) performs the following steps S504 to S506.

The navigation device of the patrol vehicle (any one of 105a to 105m) displays information Cev of the received event (step S504).

Further, the navigation device of the patrol vehicle (any one of 105a to 105m) sets a destination according to the received location information Cgp of the surveillance camera and proceeds with the road guidance (step S505). As the road guidance automatically proceeds in this way, the patrol vehicle (any one of 105a to 105m) can more quickly find the event occurrence point.

Further, the navigation device of the patrol vehicle (any one of 105a to 105m) accesses a network address according to the network address information (Cna) of the received surveillance camera, and among the surveillance cameras 101a to 101n that transmits the information of the event. A live-view video from either) is displayed on a part of the screen (step S506). Accordingly, the patrol crew who boarded the patrol vehicle (any one of 105a to 105m) can be aware of the situation of the event until reaching the event occurrence point.

Thus, when the navigation device of the patrol vehicle (any one of 105a to 105m) arrives at the destination while operating (step S507), the road guidance ends (step S508).

The above steps S501 to S508 are repeatedly performed until an end signal is generated (step S509).

As described above, according to the emergency-emergency response system of one embodiment of the present invention, there are the following effects.

First, each of the surveillance cameras is equipped with a GPS (GPS: Global Positioning System) receiver, and can transmit its precise location information to the relay server. Accordingly, the patrol vehicle can quickly find the event occurrence point even in a relatively large area.

Second, the relay server transmits the location information of the surveillance camera that transmitted the event information and the event information to any one of the navigation devices of the patrol vehicles. That is, by using the navigation devices of the patrol vehicles, the location information of the surveillance camera and the information of the event can be automatically transmitted to a patrol vehicle and used. Therefore, since the monitoring personnel in the conventional situation room are unnecessary, the possibility of extending the emergency-response time is eliminated. In other words, the emergency response time can be significantly reduced.

So far, the present invention has been focused on a preferred embodiment. Those skilled in the art to which the present invention pertains will understand that the present invention can be implemented in a modified form without departing from the essential characteristics of the present invention.

Therefore, one embodiment disclosed above should be considered from a descriptive point of view, not a limiting point of view. The scope of the present invention is shown in the claims rather than the foregoing description, and the invention claimed by the claims and the inventions equivalent to the claimed invention should be construed as being included in the present invention.

It has the potential to be used in a variety of surveillance systems as well as emergency response systems.

101a to 101n: surveillance cameras, 102: relay server,
103: communication network,
104a to 104k: base stations,
105a to 105m: patrol vehicles,
205m: navigation device for patrol vehicles.

Claims (3)

delete In an emergency response system in which surveillance cameras, relay servers, and navigation devices of patrol vehicles are connected through a communication network,
Each of the surveillance cameras,
It has a GPS (GPS: Global Positioning System) receiver, transmits its own network address information and location information to the relay server, and when an event is detected, transmits the information of the generated event to the relay server,
Each of the navigation devices of the patrol vehicles,
Periodically transmits its network address information and location information to the relay server,
The relay server,
The network address information, the location information of the surveillance camera that transmitted the information of the event, and the information of the event are transmitted to any one of the navigation devices of the patrol vehicles. An emergency response system that transmits to a nearby navigation device. According to claim 2, The navigation device is located closest to the surveillance camera that transmitted the information of the event,
Display the information of the received event,
Set the destination according to the location information of the received surveillance camera to perform road guidance,
An emergency-emergency response system that displays a live-view video from a surveillance camera that transmits the information of the event on a part of the screen by accessing the network address according to the received network information of the surveillance camera.

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