KR20120114510A - Intelligently safety lighting system - Google Patents

Abstract

PURPOSE: An intelligent security light system is provided to handle emergency by photographing and transmitting emergency situations to a security light managing server. CONSTITUTION: A security light managing server controls a plurality of security light devices. A relay wirelessly communicates with the security light devices. The relay relays the communication between the security light devices and the security light managing server. The security light devices include one or more memories(303) and a MICOM(301). The MICOM controls a communication module(306) based on a motion detection signal. [Reference numerals] (301) MICOM; (302) Motion sensor; (303) Memory; (305) Camera; (306) Communication module; (308) Infrared sensor; (309) Mist sensor; (310) Illumination sensor

Description

Intelligent security light system {INTELLIGENTLY SAFETY LIGHTING SYSTEM}

The present invention relates to an intelligent security light system, and in particular, to control the color and brightness of the security light in accordance with the presence or absence of pedestrians, ambient brightness and weather, and, if an emergency situation occurs in the vicinity of the security light, it is taken and secured through the communication network It relates to a system such as intelligent security that can be transmitted to the management server.

For the convenience of management and energy saving, various systems for automating the lighting of security lights have been proposed.

Conventional security lighting systems control the lighting according to seasonal sunset and sunrise time, or automate the lighting based on the brightness of the surroundings using an illumination sensor.

When the security light is turned off according to the seasonal sunset and sunrise time, it is not possible to cope with the brightness of the installation environment of the security light and the change of the weather around, there is a problem that can not respond to the environment around the security light.

In addition, in the case of controlling the flashing lights such as security according to the ambient brightness, in the environment where the traffic is frequent, the obstruction by noise such as the lighting of the vehicle, the shortening of the lifespan of the security lighting due to the frequent flashing and the following There is management difficulty.

In addition, the two technologies are controlled by turning on and off only by time and ambient brightness, so there is no further advantage in terms of energy savings because they operate at the same brightness even when there is no passerby.

Accordingly, the present invention has been made in view of the above-described circumstances, and an object of the present invention is to provide an intelligent security light system that is easy to manage and can control the lighting and brightness of security lights according to weather conditions, seasons, and surrounding conditions. It is. However, the problems to be solved by the present invention are not limited to the problems described above, and other problems not described can be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the intelligent security light system according to the present invention comprises a plurality of security light devices; A security light management server for controlling each of the plurality of security light devices; And a repeater capable of wirelessly communicating with each of the plurality of security light devices, the relay for relaying communication between the plurality of security light devices and the security light management server, wherein each of the plurality of security light devices One or more security lights, a motion sensor, an illuminance sensor, a fog sensor, a wireless communication module, a memory and a micom, wherein the micom comprises an illuminance detection signal, a fog sensed by the illuminance sensor, the fog sensor, and the motion sensor, respectively; Based on a detection signal and a motion detection signal, control whether the one or more security lights are turned on, lighting color, and brightness, and control the communication module to communicate with the security light management server through the repeater; The at least one security light is controlled according to a control signal from a management server.

The microcomputer determines the illumination color based on the degree of fog detected by the fog sensor when the illuminance detected by the illuminance sensor is equal to or less than a predetermined reference illuminance, and detects the movement of the pedestrian by the motion sensor. It controls the brightness of the one or more security lights depending on whether or not.

When the microcomputer detects the movement of the passerby by the motion detection sensor, the microcomputer controls the brightness of the one or more security lamps with reference to the illumination sensed by the illumination sensor, so that the ambient brightness becomes a predetermined walking brightness, When the motion of the pedestrian is not detected by the motion sensor, the brightness of the at least one security lamp is controlled with reference to the illuminance sensed by the illuminance sensor so that the ambient brightness becomes a predetermined reference brightness. Herein, the predetermined reference brightness is an average of seasonal and time-of-day brightnesses.

Meanwhile, each of the plurality of security light devices further includes an infrared camera and a voice sensor, and the memory stores one or more voice data indicating an emergency, and the micom includes a voice detected by the voice sensor. The emergency situation is determined in preparation for the voice data representing the emergency stored in the memory, and when the determination result is an emergency situation, the infrared camera is driven and the image data and the voice detection sensor photographed by the infrared camera are driven. The voice data sensed by the security server is transmitted to the security server.

In addition, each of the plurality of security light devices further comprises an infrared sensor, the microcomputer determines the location where the emergency occurs based on the infrared detection signal detected by the infrared sensor, the emergency situation is generated To control the shooting orientation of the infrared camera to capture the position.

According to the present invention, according to the security light devices, the lighting, lighting color and brightness of the security light device is controlled according to the ambient illumination, weather and pedestrian entry, minimizing unnecessary power consumption, When an emergency situation such as a crime occurs, it is photographed and transmitted to a management server such as security, so that an administrator can immediately respond to an emergency situation.

1 is a block diagram showing an intelligent security light system according to an embodiment of the present invention.
FIG. 2 is a block diagram illustrating an example of the security lamp device of FIG. 1.
3 is a flowchart for describing an operation of the system illustrated in FIG. 1.

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

1 is a block diagram showing an intelligent security light system according to an embodiment of the invention, Figure 2 is a block diagram showing an example of the security light device shown in Figure 1, Figure 3 is shown in Figure 1 A flowchart for explaining the operation of the system.

First, referring to FIGS. 1 and 2, an intelligent security light system according to an exemplary embodiment of the present invention includes a security light management server 100, a repeater 200, and a plurality of security light devices 300.

The plurality of security light devices 300 are each disposed in a place where security light is required. The security light management server 100 may communicate with the plurality of security light devices 300 through the repeater 200, and control each of the plurality of security light devices 300.

The security lamp management server 100 communicates with the repeater 200 through a wired or wireless communication network, and the repeater 200 communicates wirelessly with the plurality of security lamp devices 300.

The one or more security lights 307 are composed of one or more RGB LEDs to vary the brightness of the flashing lights, the illumination, and the color thereof, under the control of the microcomputer 301.

According to an embodiment, as shown in FIG. 1, the intelligent security lamp system further includes a display 110 and a database 130 connected to the security lamp management server 100. The security light management server 100 displays the control state of the plurality of security light devices 300 on the display 110 and displays various data related to the control of the plurality of security light devices 300. Stored in the database 130.

Each of the plurality of security light devices 300 includes one or more security light 307, a motion sensor 302, an illuminance sensor 310, a fog sensor 309, a wireless communication module 306, a memory 303, A microphone 304 as a voice sensor, an infrared camera 305, a GPS receiver 311, and a microcomputer 301.

The motion sensor 302 detects the pedestrian entry and movement into the illumination area of the security light device 300 and provides the detected signal to the microcomputer 301.

The illuminance sensor 310 detects the ambient illuminance of the security light device 300, and the fog sensor 309 detects the surrounding fog and provides the degree to the microcomputer 301.

The wireless communication module 306 is used for communication between peripheral security light devices under the control of the microcomputer 301, or for communication with the security light management server 100 through the repeater 200.

The microphone 304 detects the voice generated from the surroundings and provides the voice to the microcomputer 301, and the infrared sensor 308 detects the infrared rays of the surroundings. The infrared camera 305 is driven under the control of the microcomputer 301 to photograph the surroundings.

The memory 303 stores various data necessary for controlling the security lamp device 300, and stores audio and image data sensed by the microphone 304 and the infrared camera 305.

The microcomputer 301 is based on the illuminance detection signal, the fog detection signal, and the motion detection signal detected by the illumination sensor 310, the fog sensor 309, and the motion sensor 302, respectively. Whether the security lamp 307 is turned on, the lighting color, and the brightness are controlled. The microcomputer 301 controls the wireless communication module 306 to communicate with the security lamp management server 100 through the repeater 200, and according to a control signal from the security lamp management server 100. Control each part including one or more security lights (307).

In addition, when the illuminance detected by the illuminance sensor 310 is less than or equal to a predetermined reference illuminance, the micom 301 determines the illumination color based on the degree of fog detected by the fog sensor 309. The brightness of the at least one security light 307 is controlled by the motion detection sensor 302 according to whether the pedestrian detects a motion.

In addition, when the microcomputer 301 detects the movement of the passerby by the motion detection sensor 302, the brightness of the at least one security light 307 is determined by referring to the illuminance detected by the illuminance sensor 310. Control the peripheral brightness to be a predetermined walking brightness, and when the motion detection sensor 302 does not detect the movement of the pedestrian, the one or more security with reference to the illumination detected by the illumination sensor 310. The brightness of the back 307 is controlled to cause the ambient brightness to be a predetermined reference brightness. According to an embodiment, the predetermined reference brightness is an average of seasonal and time-of-day brightnesses.

On the other hand, the microcomputer 301 determines the emergency situation by comparing the voice detected by the microphone 304 as the voice sensor and the voice data indicating the emergency stored in the memory 303. When the microcomputer 301 determines that an emergency situation has occurred, the microcomputer 301 drives the infrared camera 305, and image data captured by the infrared camera 305 and voice data detected by the microphone 304. To notify the occurrence of an emergency situation by transmitting the security server such as management.

In addition, the microcomputer 301 determines the location where the emergency situation occurs based on the infrared detection signal detected by the infrared sensor 308, and the infrared camera 305 to photograph the location where the emergency situation occurs. Control the shooting direction.

Hereinafter, the operation of the intelligent security light system according to an embodiment of the present invention having the above-described configuration will be described in more detail with reference to FIG.

First, the micom 301 compares the current time and date from the GPS receiver 311 with the sunset time for each date stored in the memory 303, and determines whether the current time falls within the sunset time zone (S1).

In step S1, when the current time does not belong to the sunset time zone, the microcomputer 301 turns off the security light 307. On the contrary, when the current time belongs to the sunset time zone, the microcomputer 301 contrasts the current peripheral illumination sensed by the illumination sensor 310 with a predetermined reference illumination (S2 and S3).

As a result of the comparison in step S3, when the current illuminance is greater than or equal to the predetermined reference illuminance, when it is less than the above, the microcomputer 140 turns off the security lamp 307. On the contrary, when the current illuminance is less than or equal to the predetermined reference illuminance, the microcomputer 301 determines the illumination color of the security lamp 307 based on the degree of fog detected by the fog sensor 309 (S4). .

Subsequently, the microcomputer 301 determines whether the microcomputer 301 enters or exists in the lighting area that is currently passing by based on the motion detection signal detected by the motion detection sensor 302 (S5).

As a result of the determination in step S5, when the motion detection sensor 302 detects the movement of the pedestrian, the brightness of the at least one security light 307 is controlled by referring to the illumination detected by the illumination sensor 310. The ambient brightness is a predetermined walking brightness. On the contrary, when the motion detection sensor 302 does not detect the movement of the passerby, the brightness of the at least one security light 307 is controlled by referring to the illuminance sensed by the illuminance sensor 310, The ambient brightness is made a predetermined reference brightness. Since the predetermined reference brightness is an average of season and time periods of the new moon brightnesses, when the ambient brightness is brighter than the reference brightness, the microcomputer 301 is the brightness of the security light as the difference between the mood brightness and the walking brightness ( The brightness of 307 is controlled (S6 and S7).

On the other hand, when a voice informing of an emergency situation occurs around the security light, the voice informing the emergency is detected by the microphone 304. The microcomputer 301, when a voice of a predetermined size or more is input from the microphone 304, compares the voice detected by the microphone 304 with voice data representing an emergency stored in the memory 303, and thus, the voice of the emergency situation. It is determined whether or not it occurs (S8).

When the determination result of the step S8 determines that the emergency situation, the microcomputer 301 drives the infrared camera 305, while an emergency situation occurs based on the infrared detection signal detected by the infrared sensor 308. In order to determine the position and to photograph the position where the emergency occurs, the photographing direction of the infrared camera 305 is controlled (S9).

Subsequently, the microcomputer 301 stores the image data photographed by the infrared camera 305 and the voice data input through the microphone, and transmits the data to the management server 100 such as the security, to generate an emergency situation. Inform (S10).

Then, the security light management server 100 stores the video and audio from the security light device 300 in the database 130 and displays it on the display 110. Then, after the administrator takes appropriate measures, if the shooting stop command is transmitted to the security light device 300, the microcomputer 301 stops shooting and stops the transmission of data (S11, S13).

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

100: the management server 110, such as security display
130: database 200: repeater
300: security light device 301: micom
302: motion sensor 303: memory
304: microphone 305: infrared camera
306: communication module 307: RGB LED
308: infrared sensor 309: fog sensor
310: light sensor 311: GPS

Claims (7)

Multiple security light devices;
A security light management server for controlling each of the plurality of security light devices; And
Is capable of wirelessly communicating with each of the plurality of security light devices, including a repeater for relaying communication between the plurality of security light devices and the security light management server,
Each of the plurality of security light devices includes one or more security light, motion sensor, illumination sensor, fog sensor, wireless communication module, memory and micom,
The microcomputer determines whether the one or more security lights are turned on, lighting color, and brightness based on the illumination detection signal, the fog detection signal, and the motion detection signal respectively detected by the illumination sensor, the fog sensor, and the motion sensor. And control the communication module to communicate with the security lamp management server through the repeater, and control the one or more security lamps according to a control signal from the security lamp management server.
Intelligent security light system. The method of claim 1, wherein the microcomputer
When the illuminance sensed by the illuminance sensor is less than a predetermined reference illuminance, the illumination color is determined based on the degree of fog detected by the fog sensor, and the motion detection sensor determines whether the pedestrian moves. Controlling the brightness of the at least one security light;
Intelligent security light system. The method of claim 2, wherein the microcomputer
When the motion detection sensor detects a pedestrian's movement, the brightness of the at least one security light is controlled with reference to the illuminance sensed by the illuminance sensor so that the ambient brightness becomes a predetermined walking brightness,
If the motion detection sensor does not detect the movement of the pedestrian, the brightness of the at least one security lamp is controlled with reference to the illumination detected by the illumination sensor, so that the ambient brightness becomes a predetermined reference brightness. doing
Intelligent security light system. The method of claim 3, wherein the predetermined reference brightness is
Characterized by the average of the lunar brightnesses seasonally and seasonally
Intelligent security light system. The method according to any one of claims 1 to 4,
Each of the plurality of security light devices
An infrared camera, and a voice sensor;
The memory stores one or more voice data representing an emergency,
The microcomputer determines the emergency situation by comparing the voice detected by the voice detection sensor and the voice data indicating the emergency stored in the memory, and when the determination result is an emergency situation, drives the infrared camera, and The image data photographed by the infrared camera and the voice data detected by the voice sensor is transmitted to the security lamp management server.
Intelligent security light system. 6. The apparatus of claim 5, wherein each of the plurality of security light devices
Further includes an infrared sensor,
The microcomputer determines a location where an emergency situation occurs based on an infrared detection signal sensed by the infrared sensor, and controls a photographing direction of the infrared camera to capture a location where the emergency situation occurs.
Intelligent security light system. 7. The method of claim 6, wherein the one or more security lights
Characterized by comprising one or more RGB LEDs
Intelligent security light system.

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