JPH0728415B2 - White balance adjustment device - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a white balance adjusting device for a color video camera.

2. Description of the Related Art A conventional white balance adjusting device is disclosed in, for example, Japanese Patent Laid-Open No. 56-4993. FIG. 5 shows the configuration of this conventional white balance adjusting apparatus, and 27 is a conversion circuit C for converting light incident from a subject into external color temperature information. Reference numeral 1 is an image sensor, and 2 is an amplifier. Reference numeral 28 is an RB color signal controller that adjusts the gain of the RB color signal using the output of the conversion circuit C1. The conventional white balance adjustment device configured as described above uses the external color temperature information obtained from the conversion circuit 27 to calculate the gain of the RB color signal as RB
By controlling with the color signal controller 28, white balance adjustment is performed so that the ratio of the color signals RGB indicating the white portion of the subject becomes 1: 1: 1 which is the ratio of the data indicating white.

Another conventional white balance adjusting device is disclosed in, for example, Japanese Patent Laid-Open No. 60-180394. FIG. 6 shows the configuration of this conventional white balance adjusting apparatus, in which 1 is an image sensor, 2 is an amplifier, and
Is a color process processing circuit, 30 and 31 are level detection circuits, 1
7 is an AND circuit. Reference numeral 32 is a white balance control circuit. In the conventional white balance adjusting device configured as described above, the level detectors A (30) and B (31) and the AND circuit 17 cause the luminance signal Y to be a predetermined level or higher and the chroma signal C to be A low-saturation state that is lower than a predetermined level different from the above is determined, and only in this state, the white balance control circuit 33 causes the color process processing circuit 29 to
Use the output of to adjust the white balance.

Problems to be Solved by the Invention However, in the above conventional technique, the conversion circuit C2
If there is a difference in the spectral characteristics and the temperature characteristics between 7 and the image sensor 1, a difference will occur between the detected color temperature and the actual color temperature, and an error will occur in white balance adjustment. Further, since the output of the conversion circuit C27 is directly used for control, the conversion circuit C27
In addition, considerable accuracy is required, and the cost tends to be high. Further, in the above-mentioned conventional technique, since the detection thresholds of the level detection circuits 30 and 31 are constant, even if the magnitude of the chroma signal is measured, the subject itself does not respond to a large change in color temperature. It becomes difficult to measure the saturation of the white balance, and the followability of the white balance adjustment with respect to the color temperature is deteriorated.

Means for Solving the Problems In order to solve the above problems, the present invention provides an external colorimetric circuit for obtaining external color temperature information, and a size of a color signal indicating a low saturation part from the external color temperature information or A conversion circuit that calculates data representing this and the output of the conversion circuit are used to detect a color signal portion having an imaging color signal close to the magnitude of the color signal indicating the low saturation portion of the subject, and to detect the color of the subject. The color data when a white subject is imaged is determined to be white by using a determination circuit that determines a low-frequency portion, an average circuit that averages color signals only when the determination is made, and the output of the average circuit. This is a configuration including a color signal control circuit that controls the color signal so that the data becomes the data shown.

With the above-described configuration, the present invention performs white balance adjustment using the color signal of the low-saturation portion of the subject, so that external measurement can be performed compared to when the output of the external color measurement circuit is used for direct control. Does not require the accuracy of the color circuit. Therefore, an external colorimetric circuit can be realized at low cost. In addition, in the determination circuit that extracts the low-saturation portion of the subject, the determination reference is changed according to the external color temperature information to correct the captured color temperature information indicating the low-saturation portion of the subject, and the Accurate low saturation determination is possible even with changes. As a result, the followability of the white balance adjustment with respect to the color temperature does not decrease. Therefore, all the above problems will be solved.

Embodiments Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of a white balance adjusting apparatus according to an embodiment of the present invention, in which 1 is an image sensor, 2 is an amplifier,
Reference numeral 3 is an external colorimetric circuit for obtaining external color temperature information, 4 is a conversion circuit connected to an amplifier for obtaining imaging color temperature information from a video signal,
Reference numeral 5 is a determination circuit for determining a low saturation portion of the subject from the external color temperature information and the captured color temperature information, and 6 is connected to the determination circuit 5 and the amplifier 2 and is provided only when the low saturation portion of the subject is determined. An averaging circuit for averaging color signals, 7 is an averaging circuit 6
Is a color signal control circuit that controls a color signal by using the output of FIG.

FIG. 2 is a block diagram of the white balance adjusting device in the first embodiment of the present invention. In FIG. 2, 1 is an image sensor, 2 is an amplifier, and 8 is a process processing circuit A for obtaining an RGB signal. 9,10,11 are RGB respectively
It is a signal variable gain amplifier. Reference numeral 5 is a determination circuit A for determining the low chroma portion of the subject, and 3 is an external colorimetric circuit for measuring the external color temperature. Reference numeral 20 is a luminance signal processing circuit, 17 is an AND circuit, 21 is a level detection circuit, and 15 is a conversion circuit A that generates a necessary parameter when determining low saturation from color temperature information. 12,13,14 are RGB signal averaging circuits, 18,
Reference numeral 19 is a divider, and 25 and 26 are sample and hold circuits.

The video signal output from the image sensor 1 is amplified by the amplifier 2 and becomes the R signal, G signal, and B signal in the process processing circuit A8. On the other hand, the external color temperature information output from the external colorimetric circuit 3 includes the reference values K1 and K2 for low saturation determination in consideration of the color temperature by the conversion circuit A15, and the average white balance coefficient N _R , in the color temperature region. Converted to N _G , N _B. Judgment circuit A5
Are K1, K2, R signal, G signal, B signal, N _R , N _G , N _B ,
It is determined from the luminance Y whether the color saturation is low. Here, the judgment conditions are expressed by Expression 1 and Expression 2.

| N _R・ R−N _G · G | / Y <K1 (Formula 1) | N _B · B−N _G · G | / Y <K2 (Formula 2) When both Formula 1 and Formula 2 are satisfied , That is, color difference signal | N _R · R
When the value obtained by normalizing −N _G · G |, | N _B · B−N _G · G | with the luminance Y is smaller than certain predetermined levels K1 and K2, it is determined that the color saturation is low.

Here, the change in the reference value of the determination circuit A5 due to the external color temperature information will be described in more detail. FIG. 3 shows the relationship between the color difference signals BG and the color temperature when a white subject is imaged. Further, the relationship between the color difference signals R-G and the color temperature decreases monotonously, contrary to FIG. In this way, the color difference signal representing the low saturation of the subject itself changes depending on the color temperature. For example, in FIG. 3, the low saturation region D1 in the color temperature T _1, the low saturation region D2 in the color temperature T ₂ do not coincide.
However, since the color temperature and the low saturation area have a unique correspondence,
If the color temperature is known, the low saturation area of the color difference signal can be known, and the low saturation portion of the subject can be determined. Therefore, the low-saturation portion is determined as in Equations 1 and 2.

Next, when the luminance signal Y output from the luminance process circuit 20 is higher than a predetermined level, which is different from the above, the level detector 21 operates and the RGB averaging circuit 1 passes through the AND circuit.
Operate 2,13,14. In other words, Equation 1 and Equation 2 are satisfied,
Moreover, the RGB signals are averaged only when the luminance signal Y is equal to or higher than a predetermined level. Here, the reason why the limitation is set by the size of the luminance signal Y is that the accuracy of the white balance adjustment becomes low when the signal level is low, and even if this condition is not satisfied, the basic operation is not hindered. Further, instead of the luminance signal Y, another signal such as a G signal may be used.

As described above, the RGB signal of the low saturation part of the subject is extracted from the image data of one field, and the average value of each is calculated. ． To get From these, the signal ratios / and / are calculated by the dividers 18 and 19, and R.
It controls the gain of GB variable gain amplifiers 9, 10 and 11. This adjusts the white balance. On the other hand, the ratio detection circuit 22 is different in the ratio of the low saturation part of the subject from the above.
It is detected that it is above a certain predetermined level, and the sample and hold circuits 25 and 26 perform the sampling operation only when this is detected. When the ratio of the low saturation portion is small, the white balance adjustment error increases, but the white balance adjustment can be performed only when the error is small.

Further, the limiter circuits 23 and 24 limit when the signal ratio /, / values change greatly, and the limit values are given by the external colorimetric circuit 3 and the conversion circuit B16. Even if it does not exist, there is no problem in the basic white balance adjustment operation.

In the above operation, one field is one cycle, but a plurality of fields such as one frame may be one cycle. In addition, the white balance adjustment operation described above controls the RGB signal ratio of 1: 1: 1 as the target value when capturing a white subject, but the color difference signal after white balance adjustment is 0. You may control to.

FIG. 4 is a block diagram of a white balance adjusting apparatus according to the second embodiment of the present invention. The operation is to control so that the color difference signal becomes 0 when a white subject is imaged. In FIG. 4, 1 is an image sensor and 2
Is an amplifier, 3 is an external colorimetric circuit, 41 is a color difference signal RY, B-
A process processing circuit B for obtaining Y and a luminance signal Y. 35,3
6 is a variable gain amplifier, 42 is a judgment circuit B for judging the low saturation part of the object, 21 is a level detector, 17 is an AND circuit, and 22 is a ratio detection circuit. 33 and 34 are color difference signals R
-Y and BY average circuits, 23 and 24 are limiter circuits, and 25 and 26 are sample and hold circuits. Reference numeral 39 is a conversion circuit E which generates a necessary parameter when the judgment circuit B42 makes a low saturation judgment, and 40 is a conversion circuit F which gives the limit values of the limiter circuits 23 and 24. 37 and 38 are adders.

The video signal output from the image pickup device 1 is amplified by the amplifier 2 and becomes the color difference signals RY, BY and the luminance signal Y in the process processing circuit B42.

These color difference signals RY and BY, the luminance signal Y, the average white balance constants α and β in the color temperature region obtained by the external colorimetric circuit 3 and the conversion circuit E39, and the low saturation determination The determination circuit B42 determines the low saturation portion of the subject based on the threshold values K3 and K4. The conditions for the determination are represented by Equations 3 and 4.

(R−Y + αY) / Y <K3 (Formula 3) (B−Y + βY) / Y <K4 (Formula 4) When the conditions of the formulas 3 and 4 are satisfied and the luminance Y is equal to or higher than a predetermined level. The output of the AND circuit 17 causes the averaging circuits 33 and 34 to operate, and the color difference signal R of the low saturation part of the subject
-Y, BY are averaged. Then, when the low saturation portion of the subject is above a certain predetermined level, the sample and hold circuits 25 and 26 perform a sampling operation. These signals are used to control the gains of the variable gain amplifiers 35 and 36 to which the luminance signal Y is input, and the outputs are added to the color difference signals RY and BY using adders 37 and 38. As a result, the color difference signals RY and BY of the low saturation part of the subject can be controlled to be 0,
White balance adjustment is performed. Also, the limiter circuit
The operations of 23 and 24 are the same as those of the first embodiment, and basically there is no problem in the white balance adjusting operation even without them.
The same applies to the level detector for the luminance signal Y.

EFFECTS OF THE INVENTION As described above, according to the present invention, since the data of the color signal of the low saturation part of the subject is used, the white balance adjusting device of the above-mentioned prior art 1 which directly uses the external color temperature information. Compared with, even if the accuracy of the external color measurement circuit is low to some extent, accurate white balance adjustment is possible. Also, in addition to the imaging color temperature information, since external color temperature information is used,
Since the white balance can be adjusted even with a large change in color temperature, its practical effect is great in terms of cost and feasibility.

[Brief description of drawings]

FIG. 1 is a basic configuration diagram of the present invention, FIG. 2 is a block diagram of a first embodiment of the present invention, FIG. 3 is a conceptual diagram of low saturation judgment in the present invention, and FIG. 4 is a diagram of the present invention. Two
FIG. 5 is a block diagram of a first conventional white balance adjusting device, and FIG. 6 is a block diagram of a second conventional white balance adjusting device. 1 ... Image sensor, 2 ... Amplifier, 3 ... External colorimetric circuit,
4 ... conversion circuit D, 5 ... determination circuit, 6 ... averaging circuit,
7 ... Color signal control circuit, 8 ... Process processing circuit A, 9,
10,11 …… RGB variable gain amplifier, 12,13,14 …… RGB averaging circuit, 15 …… Conversion circuit A, 16 …… Conversion circuit B, 17 ……
AND circuit, 18, 19 ... Divider, 20 ... Luminance process circuit, 21 ... Level detector, 22 ... Ratio detection circuit, 23, 24
...... Limiter circuit, 25,26 …… Sample and hold circuit, 27 …… Conversion circuit C, 28 …… Color signal controller, 33,34…
... averaging circuit, 35, 36 ... variable gain amplifier, 37, 38 ... adder, 39 ... conversion circuit E, 40 ... conversion circuit F, 41 ... process processing circuit B, 42 ... determination circuit B.

Claims (5)

[Claims] 1. An external colorimetric circuit for obtaining external color temperature information, a conversion circuit for calculating the magnitude of a color signal indicating a low saturation portion or data representing this from the external color temperature information, and a conversion circuit for the conversion circuit. A determination circuit that uses the output to detect a color signal portion having an imaging color signal close to the size of a color signal indicating the low saturation portion of the subject and determine a low saturation portion of the subject;
An averaging circuit that averages the color signals only when the determination is made, and an output of the averaging circuit are used to control the color signals so that the color data when a white subject is imaged becomes white data. A white balance adjusting device comprising a color signal control circuit. 2. The white balance adjusting device according to claim 1, wherein the determination circuit also uses, as a determination reference, that the image pickup luminance information is within a predetermined level range. 3. A color signal control circuit determines an initial value of a control value of a color signal based on the external color temperature information or the imaging color temperature information, and when the subject has no low saturation portion, the color signal The white balance adjusting device according to claim 1, further comprising a circuit for holding the control value of 1. 4. The circuit according to claim 1, further comprising a circuit for operating the color signal control circuit by using the output of the averaging circuit only when the judgment by the judgment circuit is more than a predetermined ratio. The white balance adjusting device described in the item. 5. A color signal control circuit comprising: a limiting circuit for limiting a control range of a color signal; and a circuit for determining the limiting value based on external color temperature information or a color signal or a luminance signal. The white balance adjusting device according to claim 1.