KR0155838B1 - Back light compensation apparatus of video camera - Google Patents

Abstract

The present invention relates to a backlight compensation device of a video camera, and more particularly, to accurately compensate for backlight when a subject in a backlight state is photographed using a camcorder or a CCTV camera, and to affect the captured image by turning the backlight compensation switch on and off. The present invention relates to a video camera backlight compensation apparatus for minimizing a problem.

A backlight compensation apparatus for a video camera according to the present invention, comprising: a BLC pulse generator configured to set a BLC region; An aperture level setting unit that sets an opening degree of the aperture in association with a high luminance signal level of a portion where the light emitter is present in the BLC region; A BLC processor unit which selects and stores a luminance signal of a subject center region or an output luminance signal of the aperture level setting unit according to the level of a BLC pulse, and combines the stored luminance signals to perform aperture driving; And an aperture driving unit of an AI (Auto Iris) lens that adjusts the amount of light incident upon the output of the BLC processor.

As described above, according to the present invention, the aperture control signal is output based on the luminance level adjusted in association with the backlight intensity, so that the aperture is accurately driven according to the backlight state, thereby obtaining a clear image of the subject.

Description

Backlight Compensation Device for Video Cameras

FIG. 1 is a block diagram illustrating a back light compensation (BLC) device of a conventional video camera.

FIG. 2 is a circuit diagram of the aperture level setting unit when the BLC switch is turned off in the backlight compensation apparatus of FIG.

3 is a circuit diagram of the aperture level setting unit when the BLC switch is turned on in the backlight compensation apparatus of FIG.

4 is a configuration diagram of a BLC region generated in a BLC pulse generator to which both the prior art and the present invention can be applied.

5 is a block diagram illustrating a backlight compensation apparatus of a video camera according to the present invention.

6 is a circuit diagram of an aperture level setting unit in the backlight compensation apparatus of the video camera according to the present invention shown in FIG.

* Explanation of symbols for main parts of the drawings

The present invention relates to a backlight compensation device of a video camera, and more particularly, to accurately compensate for backlight when a subject in a backlight state is photographed using a camcorder or a CCTV camera, and to affect the captured image by turning the backlight compensation switch on and off. The present invention relates to a video camera backlight compensation apparatus for minimizing a problem.

When shooting a subject with a camcorder or CCTV camera (hereinafter referred to as a video camera), if there is a reflector reflecting the sun or sun light around the subject outdoors, or if there is a light emitter such as a bright light bulb indoors, the photographed subject will be bright. In contrast to the brightness of the luminous body or reflector, it appears unclear and dark.

As described above, the phenomenon in which the subject is not clear and dark is imaged due to a light emitter in which the luminance signal level incident on the CCD (Charge Coupled Device) of the video camera emits intense light. The level of the luminance signal becomes considerably higher than the level of the luminance signal reflected from the subject.

At this time, regardless of the luminance signal level reflected from the subject, the video camera enters the CCD by driving an AI (Auto Iris) lens or an ELC (Electric Level Control) aperture driving unit according to the high luminance level of the illuminant captured by the CCD. It will reduce the amount of light that goes into it.

Therefore, in the normal mode without the Back Light Compensation (BLC) procedure, the subject may not be clearly visible on the screen by narrowing the aperture and reducing the light more than the proper aperture adjustment according to the luminance signal (Y) level reflected from the subject. It will appear dark.

Hereinafter, a backlight compensation apparatus of a conventional video camera will be described in detail.

1 is a block diagram illustrating a backlight compensation apparatus of a conventional video camera.

The apparatus of FIG. 1 includes a CCD imaging unit 10, an imaging signal processing unit 12, a gain control unit 14, an aperture level setting unit 16, a BLC processor 18, a BLC pulse generator 20, and an aperture driver ( 22).

FIG. 2 is a circuit diagram of the aperture level setting unit when the BLC switch is turned off in the backlight compensation apparatus of FIG.

3 is a circuit diagram of the aperture level setting unit when the BLC switch is turned on in the backlight compensation apparatus of FIG.

2 to 3 include a power supply voltage Vcc, a resistor R1, a resistor R2, a BLC switch SW1, and an output 01 of an aperture level setting unit.

4 is a configuration diagram of a BLC region generated in a BLC pulse generator to which both the prior art and the present invention can be applied.

4 includes a captured image 1, a light emitter 2, a subject 3, a BLC area A, and a BLC area B. FIG.

The CCD imager 10 converts the image of the subject into an electrical image signal through the lens of the surveillance camera, and the image pickup signal processor 12 separates the luminance signal and the color signal through a sample and hold circuit (not shown) to process the signal. After that, it outputs to the gain control unit 14. The gain control unit 14 adjusts the level of the video signal according to the input level of the BLC processor unit 18 and outputs the video signal to the BLC processor unit 18.

When the BLC switch SW1 is turned on when the subject 3 is clearly displayed on the image pick-up screen 1 due to the backlight, the BLC processor unit ( 18). When the pulse level of the BLC region output from the BLC pulse generator 20 is high, the BLC processor unit 18 is a BLC region A which is a portion set around the subject 3 in the captured image 1. Select to inject the luminance signal.

On the other hand, when the level of the pulse output from the BLC pulse generator 20 is low, the BLC processor 18 selects the BLC region B on the image pickup screen 1 and injects the luminance signal.

In the state where the BLC switch SW1 is turned off, the aperture level setting circuit output 01 is supplied with the power voltage Vcc of 5 volts as it is and is applied to the BLC processor unit 18, and the BLC processor unit 18 is turned off by the BLC switch. Recognize the state.

When the BLC switch SW1 is turned on, the output 01 of the aperture level setting unit 16 outputs 5 volts of the power supply voltage Vcc at a constant reference level voltage divided by the division resistors R1 and R2. Is applied to (18).

At this time, when the pulse level of the BLC pulse generator 20 becomes high, the BLC processor unit 18 injects the luminance signal level value obtained by selecting an image signal of the BLC region A in which the subject is in the backlight state on the entire captured screen. do.

In addition, when the pulse level of the BLC pulse generator 20 becomes low, the BLC processor 18 replaces an abnormally high luminance level signal of the BLC region B in which the sun or the bright light emitter is present, and sets the aperture level setting unit ( A value of a constant reference voltage level output by the voltage dividing resistors R1 and R2 with respect to the power supply voltage Vcc of 16) is introduced.

The inflow luminance level is combined by the BLC processor unit 18 to output an aperture control signal to drive the aperture driver 22 including an AI (Auto Iris) lens and an ELC (Electric Level Control).

Therefore, by replacing the abnormally high luminance signal region with a predetermined reference level and outputting the subject, the phenomenon in which the subject appears dark or unclearly on the monitor screen due to the influence of the surrounding strong light emitter can be reduced.

In the conventional backlight compensation apparatus, the backlight compensation function of the surveillance camera is operated when the BLC switch SW1 of the aperture level setting unit 16 is turned on. The output 01 of the iris level setting section 16 is output with a fixed voltage of 5 volts fixed to a constant reference level voltage divided by the division resistors R1 and R2.

Therefore, the luminance signal level value of the BLC area A centered on the subject 3 among the BLC areas on the screen is combined with a value obtained by replacing a high luminance level of the BLC area B, which is a part having a light emitting body, with a constant level. The aperture control unit 22 is driven by outputting an aperture control signal of the BLC processor 16 based on the voltage level. It is limited only to the fluctuation of the luminance signal level in the BLC area A at the center of the subject to drive the aperture, and the fixed voltage level when the BLC switch SW1 is turned on regardless of the brightness of the level value corrected in the BLC area B. Because of this output, precise backlight compensation is not achieved.

In addition, the brightness level on the screen changes significantly as the BLC switch is turned on and off even under normal lighting. As described above, when the BLC switch is turned on in normal lighting, the BLC processor 18 combines the luminance signal level value of the BLC region A with a fixed voltage level value without considering ambient lighting for the B region. This occurs because the aperture driver 22 is driven by outputting a control signal.

Accordingly, the present invention has been devised to solve the above problems, and outputs a constant reference level to the BLC area B, which is a part of the light emitting body on the screen, at the time of backlight compensation by linking the luminance level according to the brightness of the illumination. The present invention provides a backlight compensation device for a video camera that can precisely adjust the brightness level to compensate the backlight and to prevent the brightness of the monitor screen from being severely changed when the BLC switch is turned on or off.

In order to achieve the above object, a backlight compensation apparatus for a video camera according to the present invention includes: a BLC pulse generator configured to set a BLC region; An aperture level setting unit that sets an opening degree of the aperture in association with a high luminance signal level of a portion where the light emitter is present in the BLC region; A BLC processor unit which selects and stores a luminance signal of a subject center region or an output luminance signal of the aperture level setting unit according to the level of a BLC pulse, and combines the stored luminance signals to perform aperture driving; And an aperture driving unit of an AI (Auto Iris) lens that adjusts the amount of light incident upon the output of the BLC processor.

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

4 is a configuration diagram of a BLC region generated in a BLC pulse generator to which both the prior art and the present invention can be applied.

4 includes a captured image 1, a light emitter 2, a subject 3, a BLC area A, and a BLC area B. FIG.

5 is a block diagram illustrating a video camera backlight compensation apparatus according to the present invention.

The CCD imager 30 converts the image of the subject into an electrical image signal through the lens of the surveillance camera, and the image pickup signal processor 32 processes the image signal through a sample and hold circuit not shown in the figure, and then gain control unit. Output to 34. The gain controller 34 adjusts the level of the video signal to match the BLC processor 38 and outputs the video signal.

When the subject is clearly displayed on the monitor screen under a backlight condition, when the BLC switch (not shown) is turned on, the BLC pulse generator 40 applies the pulses of the BLC region already set to the BLC processor 38. do. If the level of the pulse output from the BLC pulse generator 40 is high, the BLC processor 38 is the BLC processor 38 in the BLC region of the image pickup screen 1 shown in FIG. ) Luminance signal of area A, which is a part set at the center, is taken.

On the other hand, when the level of the pulse output from the BLC pulse generator 40 is low, the BLC processor 38 is a BLC which is a part of the BLC region of the image pickup screen 1 which is set around the subject 3. A high luminance signal level of the BLC region B, which is a part including the light emitter 2 such as the sun or an incandescent lamp except for the region A, may be equalized by the aperture level setting unit 36 according to the luminance level of the BLC region B. It is processed to the appropriate level of change and receives the output voltage level. Aperture driving unit at the brightness signal level summed up by combining the brightness level of BLC area A and the high brightness level of BLC area B by the aperture level setting unit 36 in the sum of the brightness signal levels. (42) is driven to perform stable backlight compensation.

In addition, when the BLC switch is turned off and the backlight compensation function is not performed in the video camera, the BLC processor 38 separates the BLC region according to the pulse level output from the BLC pulse generator 40 to select a luminance signal. Instead, the entire captured image signal is introduced as it is so that the aperture can be driven by the introduced signal.

The gain control section 34 adjusts the luminance signal level picked up by the CCD and then applies the image signal to the aperture level setting section 36 and the BLC processor section 38.

6 is a circuit diagram of an aperture level setting unit in the backlight compensation apparatus of the video camera according to the present invention shown in FIG.

The operation of the aperture level setting unit 36 in FIG. 6 is as follows.

The luminance signal Y1 output from the gain controller 34 passes only the AC component via the coupling capacitor C1. Resistors R3 and R4 divide the power supply voltage Vcc to provide a bias voltage of transistor Q1, and resistor R7 is a negative feedback resistor. The luminance signal Y1 is applied to the base of the transistor Q1 via the current limiting resistor R5 and outputs the luminance signal 02 from the collector resistor R6. Since the output luminance signal 02 is inverted in phase with the input luminance signal Y1 by 180 degrees, the higher the luminance level of the input luminance signal Y1 is, the lower the luminance level of the output luminance signal 02 becomes. In accordance with the luminance signal level of the region, the backlight is continuously converted to an appropriate voltage level at which backlight is corrected.

The BLC processor 38 outputs an aperture control signal by combining the luminance level of the BLC region A with the luminance level of the BLC region B, which changes in association with the light intensity of the light emitter, to output an aperture control signal 42. ).

Therefore, as described above, according to the present invention, the aperture control signal is output based on the luminance level adjusted in association with the backlight intensity, so that the aperture is accurately driven according to the backlight state, thereby obtaining a clear image of the subject.

In addition, compared to the conventional method in which an area outside the center of the subject is fixed at a fixed luminance level when the BLC switch is turned on, the present invention maintains the BLC switch under a normal illumination state because the region is maintained at an appropriate luminance level according to illumination. Provides a screen that maintains a constant luminance even when turned on or off.

Claims (3)

A backlight compensation apparatus of a video camera, comprising: a BLC pulse generator configured to set a BLC region; An aperture level setting unit that sets an opening degree of the aperture in association with a high luminance signal level of a portion where the light emitter is present in the BLC region; A BLC processor unit which selects and stores a luminance signal of a subject center region or an output luminance signal of the aperture level setting unit according to the level of a BLC pulse, and combines the stored luminance signals to perform aperture driving; And an aperture driving unit of an AI (Auto Iris) lens that adjusts the amount of light incident upon the output of the BLC processor. The backlight compensation apparatus of claim 1, wherein the aperture level setting unit is an inverter for inverting and outputting an input luminance signal level. The method of claim 1, wherein the aperture level setting unit comprises: a coupling capacitor (C1) for passing only the AC component of the incoming luminance signal; A transistor (Q1) for introducing the output of the coupling capacitor (C1) to the base through the current limiting resistor (R5); Bias resistors R3 and R4 connected to a power source and ground, respectively, and outputting a divided voltage to the base of the transistor Q1; A negative feedback resistor (R7) connected to the emitter of the transistor (Q1) and ground; And a collector resistor (R6) connected to the collector and the power supply of the transistor (Q1).