JPH05111047A - Automatic white balance correcting device - Google Patents

Abstract

PURPOSE:To always execute optimum white balance correction independently of the quantity of incident light. CONSTITUTION:A noise level detecting circuit 15 detects noise levels included in color difference signals (R-Y signal (g), B-Y signal (f)) from an AGC control voltage (q) outputted from an AGC circuit included in a process circuit 3 and outputs a noise level value (r). AB-Y suppression judging circuit 16 compares the value (r) with a B-Y start value (k), and when the value (r) is larger, outputs a B-Y suppression signal (s). A B-Y signal suppressing circuit 18 reduces the gain of the B-Y signal (f) based upon the signal (s) and reduces a noise component included in the signal (f) so that a noise component included in a B-Y signal integrated value (i) is smaller than the value (k). Similar processing is applied also to the R-Y signal (g) by means of an R-Y suppression judging circuit 17 and an R-Y signal suppressing circuit 19.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic white balance correction device used in an image pickup device or the like.

[0002]

2. Description of the Related Art As is well known, the color temperature of a light source is important when taking an image using a color image pickup device. Since the human eye has chromatic adaptation according to the illumination, a white subject looks white even if the color temperature of the light source changes. However, an imaging device such as a color camera has the highest sensitivity at a specific color temperature,
Since color reproduction can be obtained, when the color temperature of the light source changes, the color appearance of the subject becomes unbalanced according to the color temperature. For example, when the color temperature of the light source is higher than the color temperature set for the camera, the image taken looks bluish because the proportion of light of short wavelength is high, and when the color temperature of the light source is lower, Since the proportion of long-wavelength light is high, it looks reddish. Therefore, it is necessary to match the characteristics of the camera with the characteristics of the human eye, and even if the color temperature of the light source changes, it is necessary to correct R = G = B when a white subject is imaged. This is generally called white balance correction, and what is automatically controlled is called auto white balance correction.

FIG. 2 shows a conventional automatic white balance correction apparatus. In FIG. 2, 1 is an image sensor, 2 is a color demodulation circuit, 3 is a process circuit, and 4 is an encoder. Reference numeral 5 is a BY integration circuit that integrates the BY signal, 6 is an RY integration circuit that integrates the RY signal, and 7 is a BY that determines whether or not to perform white balance correction in the BY direction. A Y start determination circuit 8 is a variable resistor for setting a start value in the BY start determination circuit 7, both ends of which are connected to the power supply and the ground. Reference numeral 9 is an RY start determination circuit for determining whether or not to perform white balance correction in the RY axis direction, and 10 is a variable resistor for setting a start value in the RY start determination circuit 9. 11 is a B control signal generating circuit for outputting a B signal gain control signal,
Reference numeral 12 is an R control signal generation circuit that outputs an R signal gain control signal, 13 is a B signal gain control circuit, and 14 is an R signal gain control circuit. Further, a is a video signal output from the image sensor 1, b is a G signal output from the color demodulation circuit 2, c is an R signal output from the color demodulation circuit 2 and passed through the R signal gain control circuit 14, and d is Output from color demodulation circuit 2 B
B signal passed through the signal gain control circuit 13, e is a luminance signal generated by the process circuit 3, f is a BY signal generated by the process circuit 3, and g is an RY signal generated by the process circuit 3. , H is the video signal output from the encoder 4, i is the BY signal integration value, j is the RY signal integration value, k is the BY start value, l is the RY start value, and m is the B- The BY signal integrated value determined and output by the Y start determination circuit 7, n is the RY signal integrated value determined and output by the RY start determination circuit 9, and o is B
Signal gain control signal, p is R signal gain control signal.

The operation of the conventional automatic white balance correction apparatus configured as described above will be described below. First, the image signal a is output from the image sensor 1 and sent to the color demodulation circuit 2. Here, the video signal a is decomposed into three kinds of color signals of R, G and B, and the G signal b is converted into the process circuit 3
R signal c and B signal d are sent directly to the process circuit 3 through the respective gain control circuits 14 and 13.
Then, in the process circuit 3, the R, G, B signals c, b, d are converted into a luminance signal e and a color difference signal (RY signal g, BY signal f) and sent to the encoder 4. Then, the encoder 4 converts the video signal into an NTSC format video signal h and outputs it.

The R- output from the process circuit 3
The Y signal g is input to the RY integrating circuit 6 and integrated by the RY integrating circuit 6 to become an RY signal integrated value j. This R
The −Y signal integrated value j is input to the R control signal generation circuit 12 through the RY start determination circuit 9, and the R signal gain control signal p is output from the R control signal generation circuit 12 to obtain the R signal gain. Control circuit 1
The R signal gain is controlled by 4 so that the RY signal integrated value j output from the RY integrating circuit 6 becomes zero. This is because the video signal a has a property that the average value of a large number of screens and a screen for a long time becomes almost white (achromatic color), so that the RY signal integrated value j should be zero. R
If the signal gain is controlled, the white balance is corrected.

Now, the RY start determination circuit 9 will be described. If the white balance correction is always performed, the circuit reacts to a slight change in incident light, and the correction stability of the white balance correction deteriorates. Therefore, this RY start determination circuit 9
By comparing the RY signal integrated value j with the start value 1 and starting the white balance correction only when the RY signal integrated value j exceeds the start value 1, a minute operation of white balance correction is performed. To improve the correction stability.

Further, B- output from the process circuit 3
Similar control is performed for the Y signal f. In this way, the color signal gain is controlled so that the integrated values j and i of the RY signal g and the BY signal f become zero, and the white balance is corrected.

[0008]

However, in the above-described conventional configuration, when the amount of light incident on the image pickup device 1 becomes small, the AGC circuit in the process circuit 3 operates to increase the signal gain, and therefore the signal gain increases. The noise level increases.
Especially when the amount of incident light is zero, the effect appears remarkably,
In the BY and RY start determination circuits 7 and 9, the integrated value of the noise level may exceed the start values k and l, and at that time, the white balance correction is applied to the noise, and thus the circuit operation. May become unstable and the circuit may run out of control. In order to avoid this, the start values k and l may be increased so that the integrated value of the noise level does not exceed the start values k and l. However, when the amount of incident light is large, the white balance correction error is large. There is a problem of becoming.

An object of the present invention is to solve the above-mentioned conventional problems and to provide an automatic white balance correction apparatus capable of always performing optimum white balance correction when the amount of incident light is large or small.

[0010]

An automatic white balance correction apparatus according to the present invention comprises a noise level detecting means for detecting a noise level value included in a color difference signal, and a noise level value detected by the noise level detecting means is a reference value. And a color difference signal suppressing unit that reduces the gain of the color difference signal according to the color difference suppression signal so that the noise component included in the integrated value of the color difference signal is equal to or less than the reference value. Is provided.

[0011]

According to the configuration of the present invention, the noise level value included in the color difference signal is detected, the color difference suppression signal is output when the noise level value exceeds the reference value, and the color difference signal corresponding to the color difference suppression signal is output. By lowering the gain so that the noise component included in the integrated value of the color difference signal is below the reference value, if the reference value is set to the normal incident light level,
It is possible to always perform optimum white balance correction when the amount of incident light is large or small, without the circuit operation becoming unstable due to the amount of incident light or the error in white balance correction increasing.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing the circuit configuration of an automatic white balance correction apparatus according to an embodiment of the present invention. In FIG. 1, an image sensor 1, a color demodulation circuit 2,
Process circuit 3, encoder 4, BY signal integration circuit 5, RY signal integration circuit 6, BY start determination circuit 7, variable resistor 8 for setting BY start value, RY start determination circuit 9 , RY Variable resistor 1 for setting the start value
The 0, B control signal generation circuit 11, R control signal generation circuit 12, B signal gain control circuit 13, and R signal gain control circuit 14 are the same as those in the conventional example shown in FIG.

In this embodiment, a noise level detection circuit (noise level detection means) 15, a BY suppression judgment circuit (comparison judgment means) 16, an RY suppression judgment circuit (comparison judgment means) 17, and a BY signal. Suppression circuit (color difference signal suppression means)
18 and RY signal suppressing circuit (color difference signal suppressing means) 1
9 is different from the conventional example, and these will be described below.

The noise level detection circuit 15 detects the noise level included in the color difference signals (RY signal g, BY signal f) from the AGC control voltage q output from the AGC circuit in the process circuit 3. Then, the noise level value r is output. The BY suppression determination circuit 16 compares the noise level value r with the BY start value (reference value) k, and if the noise level value r is larger, the BY suppression signal (color difference suppression signal) s. Is output to the BY signal suppression circuit 18.

The BY signal suppression circuit 18 lowers the gain of the BY signal f by the BY suppression signal s to reduce the BY signal f.
Is reduced so that the noise component included in the BY signal integration value i becomes smaller than the BY start value k. Similarly, for the RY signal g, the noise level value r output from the noise level detection circuit 15 and the RY start value (reference value) 1 are compared in the RY suppression determination circuit 17, and the determination is made. Output R-
The Y suppression signal (color difference suppression signal) t is the RY signal suppression circuit 1
When it is input to 9, the gain of g of the RY signal is lowered and RY is decreased.
The noise component included in the signal g is reduced so that the noise component included in the RY signal integration value j is smaller than the RY start value 1.

Thus, according to this embodiment, BY,
The noise components of the RY signal integrated values i, j are always BY, R
Since it becomes smaller than the -Y start value k, l, the automatic white balance correction circuit does not run away even when the amount of light incident on the image pickup apparatus 1 is very small, and it is possible to always realize optimum automatic white balance correction. .. In this embodiment, the signal processing system is described as the R, G, B signal processing method, but it is needless to say that the same effect can be obtained also in the automatic white balance correction apparatus using other signal processing methods. Absent.

[0017]

The automatic white balance correction apparatus of the present invention detects the noise level value included in the color difference signal,
When the noise level value exceeds the reference value, the color difference suppression signal is output, and the gain of the color difference signal is reduced according to this color difference suppression signal so that the noise component included in the integrated value of the color difference signal is below the reference value. Therefore, if the reference value is set to the normal incident light intensity level, the circuit operation will not become unstable due to the incident light intensity and the error of white balance correction will not increase, and the incident light intensity will always be high or low. Optimal white balance correction can be performed.

[Brief description of drawings]

FIG. 1 is a block diagram showing a circuit configuration of an automatic white balance correction apparatus according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a circuit configuration of a conventional auto white balance correction device.

[Explanation of symbols]

15 noise level detection circuit (noise level detection means) 16 BY suppression judgment circuit (comparison judgment means) 17 RY suppression judgment circuit (comparison judgment means) 18 BY signal suppression circuit (color difference signal suppression means) 19 R -Y signal suppressing circuit (color difference signal suppressing means) f BY signal (color difference signal) g RY signal (color difference signal) i BY signal integrated value j RY signal integrated value k BY start value ( Reference value) l RY start value (reference value) r Noise level value s BY suppression signal (color difference suppression signal) t RY suppression signal (color difference suppression signal)

Claims (1)

[Claims] 1. An automatic white balance correction device for integrating a color difference signal and controlling a gain of a color signal so that the integrated value becomes zero when the integrated value exceeds a reference value, and the automatic white balance correction device includes: Noise level detecting means for detecting a noise level value, a comparison determining means for outputting a color difference suppression signal when the noise level value detected by the noise level detecting means exceeds the reference value, and an integrated value of the color difference signal. An automatic white balance correction device, comprising: a color difference signal suppressing unit that reduces the gain of the color difference signal according to the color difference suppression signal so that the noise component included in is less than or equal to the reference value.