KR101350861B1 - System and method for controlling ir led of camera system using wavelength areness function of light - Google Patents

Abstract

The present invention relates to a system and a method for controlling infrared rays LED of a camera system by using light wavelength recognition function. The device for controlling infrared rays LED of a camera system includes an infrared rays LED emitting unit having at least one infrared rays LED in a monitoring camera. The device for controlling the infrared rays LED of the camera system comprises: an image processing unit for converting incident rays into a wavelength value and outputting it; an illumination detecting unit for detecting light illuminance of the incident rays; a control unit for receiving the wavelength value of the light from the image processing unit, a light illuminance value from the illumination detecting unit, and for converting a current value supplied to the infrared rays LED emitting unit and outputting it in case the illuminance value is greater than a standard illuminance value; and an infrared rays LED emitting driving unit for lighting the infrared rays LED emitting unit with the current value converted by the control unit. Accordingly, high quality screen can be secured by recognizing the wavelength of the incident rays and by emitting the light having a wavelength capable of offsetting the incident rays. The image quality of the monitoring camera at night is provided to be clear such as the image quality in the daytime and the identification of people or vehicle license plates is facilitated by dividing into a visible rays region (380 nm ~ 700 nm) and an infrared rays region (700 nm ~ 1000 nm) according to the wavelength of the incident rays in the monitoring camera recognizing the light wavelength and by controlling the output of the infrared rays LED according to each condition. [Reference numerals] (111) Image photographing unit; (112) Image photographing control unit; (113) Image processing unit; (120) Infrared LED emitting unit; (130) Infrared LED emission driving unit; (140) Control unit; (150) Illuminance sensing unit

Description

Infrared LED Control System and Method of Surveillance Camera System Using Wavelength Recognition Function of Light {SYSTEM AND METHOD FOR CONTROLLING IR LED OF CAMERA SYSTEM USING WAVELENGTH ARENESS FUNCTION OF LIGHT}

The present invention relates to an infrared LED control technology of a surveillance camera system using a wavelength recognition function of light, and more particularly, recognizes the wavelength of incident light and emits light having a wavelength that can cancel the incident light. The present invention relates to an infrared LED control device and method for a surveillance camera system using a wavelength recognition function of light to secure a high quality screen.

Surveillance Cameras In general, surveillance camera systems cannot detect intruders in dim light, so they are monitored using an infrared emitter outside the camera or attached to the camera.

In particular, at night, when the vehicle's headlights are turned on in the opposite direction of the camera, the subjects between the camera and the vehicle are darkly photographed by the back light phenomenon and the subjects cannot be identified by the strong visible light.

And when photographing a dark alley is irradiated with an infrared light emitter at this time infrared light (wavelength) is strongly introduced into the camera by the rear reflector of the vehicle parked in the alley.

At this time, since the illumination difference between the surrounding background of the vehicle and the rear reflector of the vehicle is severe, the camera has an autofocus function, but there is a problem in that it cannot focus.

In addition, the infrared light of multiple diffuse reflections is formed because the distance between the camera and the rear reflector of the vehicle is different for each position where the vehicle is parked. In this case, the camera may not be able to focus according to distance.

In order to prevent such a phenomenon that subject recognition such as back light and reflected light is hindered, in the related art, a specific area is masked (High Light Compensation), or a high speed shutter in a bright area and a low speed shutter in a dark area are combined and shaped (Wide). In order to solve the problem using a method such as dynamic range, there is a problem that it is not efficient.

An embodiment of the present invention is an infrared LED of the surveillance camera system using the wavelength recognition function of the light to recognize the wavelength of the incident light, and to emit a light having a wavelength that can cancel the incident light to secure a good quality screen To provide a control apparatus and method.

An embodiment of the present invention is an infrared LED control device and method of the surveillance camera system using the wavelength recognition function of the light to secure a good quality screen by weakening the infrared diffuse reflection light (wavelength) flowing into the camera by weakening the light of the infrared transmitter. To provide.

That is, according to the incident wavelength of the surveillance camera that recognizes the wavelength of light, the IR LED output is strong or weak depending on each condition by dividing it into visible region (380nm ~ 700nm) and infrared region (700nm ~ 1000nm). By changing and controlling the camera, it provides clear picture quality that is equivalent to the daytime quality of the surveillance camera and facilitates identification of people or license plates.

Among the embodiments, the infrared LED control device of the surveillance camera system having an infrared LED light emitting unit consisting of at least one infrared LED in the surveillance camera, comprising: an image processing unit for converting the incident light into a wavelength value of the light; An illuminance sensor detecting an illuminance of incident light; The controller receives the wavelength value of the light from the image processor, receives the illuminance value from the illuminance sensor, and changes and outputs a current value supplied to the infrared light emitter when the illuminance value is greater than a reference illuminance value. It may include an infrared LED light-emitting driver for lighting the infrared LED light-emitting portion at the current value changed by the.

The controller determines whether the wavelength value of the light exists within a preset visible light wavelength value range, and receives an illuminance value of light detected by the illuminance sensor when the wavelength value is within the visible light wavelength value range. It is determined whether the light intensity value is greater than a predetermined reference value, and if the light intensity value is greater than the first reference illuminance value while having a wavelength value within the visible light wavelength range, it is 150% higher than the current value supplied to the infrared LED floodlight. A large current value can be supplied to the infrared LED floodlight through the infrared LED floodlight driver.

If the wavelength value of the light does not exist in the visible light wavelength value range, the controller determines whether it exists within a preset infrared wavelength value range, and detects the illuminance sensor while having a wavelength value within the infrared wavelength value range. When the illuminance value of the received light is input and the illuminance value of the light is greater than the second reference illuminance value, a current value corresponding to 50% of the current value supplied to the infrared LED light emitter is normally transmitted to the infrared LED light emitter through the infrared LED light emitter driver. Can supply

The control unit may further include a step of performing only a preset time when supplying a current value of 150% to the infrared LED light emitter rather than the current value supplied to the infrared LED light emitter.

Preferably, the preset time is 10 seconds.

In an embodiment, the control unit determines whether the wavelength value of the light input through the image processor is within the visible light wavelength value range, and (2) the control unit exists in the visible light wavelength value range. In this case, it is determined whether the illuminance value inputted from the illuminance sensor is greater than the first reference illuminance value. If the illuminance value is large, a current value corresponding to 150% of the current value supplied to the infrared LED light emitter normally is transmitted through the infrared LED light emission driver. It may include the step of being supplied to the infrared LED light emitter.

In one embodiment, (1) the control unit determines whether the wavelength value of the light incident through the image processing unit is within the infrared wavelength value range when it does not exist within the visible light wavelength value range, and (2) the controller If the incident light is within the infrared wavelength range, it is determined whether the illuminance value input from the illuminance sensor is greater than the second reference illuminance value, and if it is large, it corresponds to 50% of the current value supplied to the infrared LED light emitter normally. It may include the step of supplying a current value to the infrared LED floodlight through the infrared LED floodlight driver.

The control unit may further include a step of performing only a preset time when supplying a current value of 150% to the infrared LED light emitter rather than the current value supplied to the infrared LED light emitter.

Preferably, the preset time is 10 seconds.

Infrared LED control device and method of the surveillance camera using the wavelength recognition function of the light according to an embodiment of the present invention recognizes the wavelength of the incident light, and emits light having a wavelength that can cancel the incident light It is effective to secure the screen.

Infrared LED control apparatus and method of the surveillance camera according to an embodiment of the present invention has the effect of weakening the light of the infrared emitter to weaken the infrared diffuse reflection light (wavelength) flowing into the camera to secure a good quality screen.

That is, according to the incident wavelength of the surveillance camera that recognizes the wavelength of light, the IR LED output is strong or weak depending on each condition by dividing it into visible region (380nm ~ 700nm) and infrared region (700nm ~ 1000nm). The camera's night vision of the surveillance camera is as clear as that of the day, making it easy to identify people or license plates.

1 is a view for explaining the configuration of the infrared LED control device of the surveillance camera using the wavelength recognition function of the light according to the present invention.
2 is a flowchart illustrating an infrared LED control method of a surveillance camera using a wavelength recognition function of light according to the present invention.
3 is a control waveform (FET device gate control voltage) and current waveform diagrams normally supplied to an infrared LED.
4 is a waveform diagram of a control voltage (FET device gate control voltage) and a current waveform supplied to an infrared LED when visible light wavelength input and a predetermined illuminance are abnormal.
5 is a control waveform (FET device gate control voltage) and current waveform diagrams supplied to the infrared LED when the infrared wavelength is pulled in and a predetermined illuminance is abnormal.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

1 is a view for explaining the configuration of the infrared LED control device of the surveillance camera using the wavelength recognition function of the light according to the present invention.

Referring to FIG. 1, an infrared LED control apparatus of a surveillance camera includes a surveillance camera unit 110, an infrared LED floodlight 120, an infrared LED floodlight driver 130, a controller 140, and an illuminance sensor 150. .

Surveillance camera 110 is generally made of a CCD sensor or a CMOS sensor, and controls the image capture unit 111, the zoom ratio of the image capture unit 111, the FOCUS, etc. to shoot the subject under the control of the controller 140 The image output controller 112 and the image output to the image capture unit 111 is stored in the internal memory, and the current input image is compared to the previous input image stored in the internal memory to recognize the subject and the movement of the subject The image processing unit 113 converts the light input from the image photographing unit 111 into a wavelength of light and outputs the light.

The illuminance detecting unit 150 is generally made of a CDS sensor or a light receiving element, and detects the illuminance of light incident on the surveillance camera to output an illuminance value (resistance value variation).

The controller 140 receives a visible light wavelength value or an infrared wavelength value output from the image processor 113, receives an illuminance value from the illuminance sensor unit 150, compares the light intensity value with a reference illuminance value, and then exceeds the reference illuminance value. The current value supplied to the infrared LED light emitter 120 is changed and output.

The infrared LED floodlight driver 130 turns on the infrared LED floodlight 120 with the current value changed by the controller 140.

That is, the controller 140 determines whether the wavelength value of the light input from the image processor 113 is a wavelength value within a preset visible light wavelength value range, and detects illuminance when the wavelength value is within a visible light wavelength value range. The controller 150 receives an illuminance value of the light sensed by the unit 150, and determines whether the illuminance value of the light is greater than a first preset illuminance value. When greater than the illuminance value, a current value 150% larger than the current value supplied to the infrared LED light emitter 120 is normally supplied to the infrared LED light emitter 120 through the infrared LED light emitter driver 130.

The controller 140 determines whether the wavelength value of the light input from the image processor 113 exists within the infrared wavelength value range when the wavelength value of the light input from the image processor 113 does not exist within the visible wavelength value range, and when it exists within the infrared wavelength value range. The illuminance detection unit 150 receives the illuminance value of the light, determines whether the illuminance value of the light is greater than the second preset illuminance value, and has a wavelength value within the infrared wavelength range and the illuminance value is the second reference illuminance. If greater than the value, the current value corresponding to 50% of the current value supplied to the infrared LED light emitter 120 is normally supplied to the infrared LED light emitter 120 through the infrared LED light emitter driver 130.

At this time, the controller 150 may be made only for a predetermined time when supplying a current value of 150% than the current value supplied to the infrared LED light emitter 120 normally.

The preset time is preferably 10 seconds.

The infrared LED control method of the surveillance camera system using the wavelength recognition function of light made as described above is as follows.

2 is a flowchart illustrating an infrared LED control method of a surveillance camera using a wavelength recognition function of light according to the present invention.

Referring to FIG. 2, the controller 140 determines whether a wavelength value of light is input through the image processor 113 (S210). If the wavelength value of the light is input as a result of the determination, the controller 140 determines whether the input wavelength value is within the visible wavelength range (S220). As a result of the determination, when the wavelength value of the light input from the image processor 113 exists within the visible light wavelength value range, the controller 140 receives the input while receiving the illuminance value from the illuminance sensor 114 (S230).

The controller 140 determines whether the illuminance value input from the illuminance sensor 150 is greater than the first reference illuminance value (S240).

As a result of the determination in step S230, when the input illuminance value is greater than the first reference illuminance value, the control unit 140 transmits a current value corresponding to 150% of the current value supplied to the infrared LED light emitter through the infrared LED light emission driver 130. Supply to the infrared LED light emitting unit 120 (S250).

The controller 140 determines whether the set time has elapsed (S260). As a result of the determination, when the set time has elapsed, the controller 140 cuts off the driving current of the infrared LED floodlight 120 supplied to the infrared LED floodlight driver 130 and ends.

If the wavelength value of the light input from the image processor 113 does not exist within the visible wavelength range, the controller 140 determines whether the wavelength is within the infrared wavelength range (S270). As a result of the determination, when the wavelength value of the light exists within the infrared wavelength value range, the illuminance value output from the illuminance detection unit 150 is received (S280).

In addition, the controller 140 determines whether the input illuminance value is greater than the second reference illuminance value (S290), and when the control unit 140 is large, the controller 140 controls the 50% of the current value supplied to the infrared LED light emitter 120. The corresponding current value is supplied to the infrared LED floodlight 120 through the infrared LED floodlight driver 130 (S295).

Normally, the current value supplied to the infrared LED light emitting unit 120 controls the infrared LED light emitting driver 130 to supply only a current value corresponding to 80% when the total (maximum current) is 100% (S295).

Herein, while the present invention has been described with reference to the preferred embodiments, those skilled in the art will variously modify the present invention without departing from the spirit and scope of the invention as set forth in the claims below. And can be changed.

110: surveillance camera unit
111: video recording unit
112: image recording control unit
113: image processing unit
120: infrared LED floodlight
130: infrared LED floodlight driver
140:
150: illuminance detection unit

Claims (9)

In the infrared LED control device of the surveillance camera system having an infrared LED light emitting unit consisting of at least one infrared LED in the surveillance camera,
An image processor converting incident light into wavelengths of light and outputting the light;
An illuminance sensor detecting an illuminance of incident light;
A controller which receives a wavelength value of light from the image processor, receives an illuminance value from the illuminance sensor, and changes and outputs a current value supplied to an infrared light emitter when the illuminance value is greater than a reference illuminance value; And
An infrared LED floodlight driver for lighting the infrared LED floodlight with a current value changed by the controller;
The control unit
When the wavelength value of the light does not exist within the gas light wavelength value range, it is determined whether the wavelength value exists within a preset infrared wavelength value range, and the wavelength value of the light detected by the illuminance sensing unit has a wavelength value within the infrared wavelength value range. When the illuminance value is input and the illuminance value of the light is greater than the second reference illuminance value, supplying a current value corresponding to 50% of the current value supplied to the infrared LED light emitter to the infrared LED light emitter through the infrared LED light emitter. Infrared LED control device of surveillance camera system using wavelength recognition function of light. The method of claim 1,
The control unit
It is determined whether the wavelength value of the light exists within a preset visible light wavelength value range, and when the wavelength value is within the visible light wavelength value range, the illuminance value detected by the illuminance sensor is input, and the illuminance of the light is received. It is determined whether the value is larger than the preset reference value. If the illuminance value is greater than the first reference illuminance value while the wavelength value is within the visible light wavelength range, the current value is 150% larger than the current value supplied to the infrared LED light emitter. Infrared LED control device of the surveillance camera system using the wavelength recognition function of the light, characterized in that to supply the infrared LED light emitting unit through the infrared LED light emitting unit. delete The method of claim 1,
The control unit
An infrared LED control device of a surveillance camera system using a wavelength recognition function of light, characterized in that for supplying a current value corresponding to 150% of the current value supplied to the infrared LED light emitter to the infrared LED only for a predetermined time. 5. The method of claim 4,
Infrared LED control device of the surveillance camera system using the wavelength recognition function of the light, characterized in that the preset time is 10 seconds. (1) the control unit determining whether the wavelength value of the light input through the image processor is within the visible light wavelength value range; And
(2) The control unit determines whether the illuminance value input from the illuminance sensor is greater than the first reference illuminance value when the wavelength value of the light is within the visible light wavelength value range and is supplied to the infrared LED light emitter normally. Allowing a current value corresponding to 150% of the current value to be supplied to the infrared LED floodlight through the infrared LED floodlight driver.
Infrared LED control method of the surveillance camera system using a wavelength recognition function of light, characterized in that it comprises a. The method according to claim 6,
(1) the control unit determining whether the wavelength value of light incident through the image processor is within the infrared wavelength value range when the wavelength value of the light does not exist within the visible ray wavelength value range; And
(2) The control unit determines whether the illuminance value input from the illuminance sensor is greater than the second reference illuminance value when the incident light exists within the infrared wavelength value range, and if it is large, the current supplied to the infrared LED light emitter normally. Supplying a current value corresponding to 50% of the value to the infrared LED floodlight through the infrared LED floodlight driver;
Infrared LED control method of the surveillance camera system using the wavelength recognition function of the light made. The method according to claim 6,
The control unit further comprises the step of making the current value of 150% of the current value supplied to the infrared LED light emitter to the infrared LED light emitter only during a predetermined time period, characterized in that it further comprises Infrared LED Control Method of Camera System. The method of claim 8,
The predetermined time is 10 seconds infrared LED control method of the surveillance camera system using the wavelength recognition function of light.

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