JPH0373694A - Color difference matrix circuit - Google Patents

Abstract

PURPOSE:To optionally adjust color reproducibility by dividing the 1st and 2nd color difference signals respectively into two positive and negative partial color difference signals, amplifying these four divided signals by optional amplification factor, mutually adding the amplified signals to obtain two composite color difference signals. CONSTITUTION:The 1st and 2nd color difference signal composing circuits 14, 16 respectively amplify and output respective color difference signals R-Y, B-Y. In the color difference matrix circuit 8, these color difference signal composing circuits 14, 16 are not used only for the amplification of color difference signals. In the 1st color difference signal composing circuit 14 for composing a color difference signal R-Y, the component of the other color difference signal B-Y is added to the color difference signal R-Y. In the 2nd color difference signal composing circuit also 16, the components of partial color difference signals (R-Y)<+>, (R-Y)<-> are added to compose the color difference signal B-Y. The colors of a video signal expressed by the composed color difference signals R-Y, B-Y are optionally adjusted up to their phases.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a color difference matrix circuit, and particularly to a technique for improving color reproducibility of a color difference matrix device used in a color video camera or the like.

[Prior Art] FIG. 10 is a block diagram of a conversion block from a color difference signal to a chroma signal in a conventional color video camera. 1st
Referring to Figure 0, the conventional conversion block converts the color difference signal R-Y
and a color difference matrix circuit 40 for inputting the color difference signals B-Y, amplifying and outputting each independently, and balanced modulation of the first color-specific carrier wave fscI by the color difference signal R-Y amplified by the color difference matrix circuit 40. A balanced modulator MODI for outputting the second color carrier fs by the color difference signal B-Y amplified by the color difference matrix circuit
It includes a balanced modulator MOD2 for balanced modulating c2, and an adder circuit 18 for adding the outputs of the balanced modulators MODI and MOD2 and outputting the result as a chroma signal.

The conventional color difference matrix circuit 40 receives the color difference signal RY from the RY signal input terminal 24 and uses a gain control amplifier (GC) to set the level of the color difference signal to an arbitrary value.
A) G which is connected to 36 and the B-Y signal input terminal 34 and is used to set the signal level of the color difference signal B-Y to an arbitrary value.
Contains CA38.

From the R-Y signal input terminal 24 to the color difference signal matrix circuit 4
The color difference signal R-Y inputted to 0 is gain-adjusted by the GCA 36 and inputted to the balanced modulator MODl. The balanced modulator MODI balance-modulates the first color-specific carrier wave fscI with the color difference signal RY. B-Y signal input terminal 3
The color difference signal B input from 4 to the color difference matrix circuit 40
-Y is gain adjusted by the GCA 38 and input to the balanced modulator MOD2. The balanced modulator MOD2 has a second
The color-specific carrier wave fsc2 is balanced-modulated by the color difference signal B-Y. The outputs of the balanced modulators MODI and MOD2 are mixed by an adder circuit 18 and output as a chroma signal.

[Problem 8 to be solved by the invention] In the conventional color difference matrix circuit, the levels of the two color difference signals R-Y and B-Y are controlled by two gain control amplifiers provided independently. All I can do is do it. Regarding color vectors represented by color difference signals amplified for each color difference signal, only the aspect ratio can be changed. Therefore, it is difficult to freely set the color reproducibility in the obtained video signal, and there is a problem that the desired color reproducibility cannot be achieved.

Therefore, an object of the present invention is to provide a color difference matrix circuit that can freely adjust color reproducibility in an obtained video signal.

[Means for Solving the Problems] A color difference matrix circuit according to the present invention receives a first color difference signal as input, and generates a first partial color difference signal consisting only of positive components of the first color difference signal and a negative component. a first color difference signal dividing means for outputting a second partial color difference signal consisting of only a positive component of the second color difference signal; a second color difference signal dividing means for outputting a third partial color difference signal consisting of a negative component and a fourth partial color difference signal consisting only of negative components; first color difference signal synthesis for outputting a first composite color difference signal by amplifying the signal, the third partial color difference signal, and the fourth partial color difference signal at arbitrary amplification factors and adding them together; means, the first partial color difference signal, the second partial color difference signal, the third partial color difference signal, and the fourth partial color difference signal are each amplified at arbitrary amplification factors and added. and second color difference signal synthesis means for outputting two combined color difference signals.

[Operation] The first color difference signal dividing means divides the first color difference signal and outputs a first partial color difference signal consisting only of positive components and a second partial color difference signal consisting only of negative components. do. The second color difference signal dividing means receives the second color difference signal, and the second color difference signal splitting means receives the second color difference signal.
A third partial color difference signal consisting only of positive components of the color difference signal and a fourth partial color difference signal consisting only of negative components are output.

The first color difference signal synthesis means and the second color difference signal synthesis means each independently generate a first partial color difference signal, a second partial color difference signal, a third partial color difference signal, and a fourth partial color difference signal. The signals are amplified by an arbitrary amplification factor and added, and outputted as a first composite color difference signal and a second composite color difference signal, respectively.

[Embodiment] FIG. 1 is a block diagram showing a color difference matrix circuit 8 according to the present invention and a part of its peripheral circuits. Referring to FIG. 1, a color difference matrix circuit 8 according to the present invention has an R-
It is connected to the Y signal input terminal 24, and converts the color difference signal R-Y into a partial color difference signal (R-Y)+ consisting of only its positive component and a partial color difference signal (RY)- consisting only of its negative component. The R-Y signal dividing circuit 10, which is an example of a first color-difference signal dividing means for dividing and outputting the signal, is connected to the B-Y signal input terminal 34, receives the color-difference signal B-Y, and outputs the B-Y signal. a second color difference signal dividing means for dividing and outputting a partial color difference signal (B-Y)+ consisting of only positive components and a partial color difference signal (B-Y)- consisting only of its negative components; It is connected to the B-Y signal dividing circuit 12 as an example, the R-Y signal dividing circuit 10 and the B-Y signal dividing circuit 12, and four partial color difference signals (RY)'' (RY)-( B-Y
)" (B-Y)- to produce a composite color difference signal R-Y
a first color difference signal synthesis circuit 14 for outputting R-
It is connected to the Y signal division circuit 10 and the B-Y signal division circuit 12, and outputs four partial color difference signals (R-Y).
)-(B-Y) + (B-Y)- and outputs a composite color difference signal B-Y.

The output of the first color difference signal synthesis circuit 14 is a balanced modulator MOD.
Connected to I. The output of the second color difference signal synthesis circuit 16 is connected to a balanced modulator MOD2. A first color-specific carrier wave fsel is supplied to the balanced modulator MODl. The balanced modulator MOD2 has a second color-specific carrier f. 2
is supplied. The outputs of the balanced modulators MODI and MOD2 are both connected to an adder circuit 18.

The first color difference signal synthesis circuit 14 includes the R-Y signal division circuit 1
0 for amplifying the partial color difference signal (R-Y); and a gain control amplifier 0CA2 connected to the RY signal dividing circuit 10 for amplifying the partial color difference signal (R-Y). Gain control amplifier 0CA2 and
The partial color difference signal (B
-Y) Gain control amplifier for amplifying 0
CA2, a gain control amplifier 0CA2 connected to the B-Y signal dividing circuit 12 and for amplifying the partial color difference signal (B-Y), and a gain control amplifier 0CA.
2, an adder circuit 20 connected to GCA2, GCA3, and GCA4 for adding their outputs and outputting the result to the balanced modulator MODI.

The second color difference signal synthesis circuit 16 includes the B-Y signal division circuit 1
A gain control amplifier GCA5 is connected to the B-Y signal dividing circuit 12 and is connected to the gain control amplifier GCA5 for amplifying the partial color difference signal (B-Y)-. control amplifier 0CA2,
It is connected to the R-Y signal splitting circuit 10 and outputs a partial color difference signal (R
-Y) Gain control amplifier for amplifying 0
CA2, a gain control amplifier 0CA2 connected to the R-Y signal dividing circuit 10 and for amplifying the partial color difference signal (R-Y), and a gain control amplifier GCA.
5, an adder circuit 22 connected to GCA6, GCA7, and GCA8 for adding their outputs and outputting the result to balanced modulator MOD2.

FIG. 2 is a more detailed circuit diagram of the RY division circuit 10. Referring to FIG. 2, the R-Y signal dividing circuit 10
A clamp circuit 26 for clamping the retrace period of the color difference signal R-Y input from the Y signal input terminal 24, and a clamp circuit 26 connected to the output of the clamp circuit 26, consisting of only the positive components of the color difference signal R-Y. A positive signal output circuit 28 for extracting and outputting the partial color difference signal (R-Y)+, and a partial color difference signal (R-Y)- consisting of only the negative components of the color difference signal R-Y from the output of the clamp circuit 26. and a negative signal output circuit 30 for extracting and outputting the negative signal.

The clamp circuit 26 responds to the clamp pulse input from the clamp pulse input terminal 32 to output the color difference signal RY.
It includes a transistor Q1 and a capacitor C1 for clamping the retrace period of the circuit. Capacitor C2 is for stabilizing the clamp potential (determined by R1 and R2) of the emitter of transistor Q1. Positive signal output circuit 28
is a clip circuit consisting of transistor Q2 and transistor Q3. A positive signal output is output from resistor R3. Negative signal output circuit 30 is a clip circuit consisting of transistors Q4 and Q5. A negative signal output is output from resistor R4. Positive signal output circuit 28, negative signal output circuit 30
are both connected to power source B. The resistor R2 and the resistor R1 have a reference potential (
(equal to the clamp potential).

The operation of the color difference matrix circuit 8 according to the present invention will be explained with reference to FIGS. 1 and 2. The color difference signal RY is R-
The signal is input from the Y signal input terminal 24 to the RY signal dividing circuit 10 . After the blanking period of the color difference signal R-Y is clamped by the clamp circuit 26, the color difference signal R-Y is input to the positive signal output circuit 28 and the negative signal output circuit 30. The positive signal output circuit 28 cuts the negative component of the color difference signal RY and outputs a partial color difference signal (RY)+ consisting only of positive components.

The negative signal output circuit 30 cuts the positive part of the color difference signal R-Y to generate a partial color difference signal (R-Y) consisting only of negative components.
Output -.

The B-Y signal dividing circuit 12 is configured similarly to the R-Y signal dividing circuit 10, and receives the color difference signal B-Y from the B-Y signal input terminal 34 and divides the partial color difference signal (B-Y) into and a partial color difference signal (B-Y)-.

In the first color difference signal synthesis circuit 14, the gain control amplifier GCAI adjusts the level of the partial color difference signal (RY) and outputs it to the adder 20. The gain control amplifier GCA2 adjusts the level of the partial color difference signal (RY)- and outputs it to the addition circuit 20. The gain control amplifier GCA3 adjusts the level of the partial color difference signal (B-Y)+ and outputs it to the addition circuit 20. The gain control amplifier GCA4 adjusts the level of the partial color difference signal (B-Y)- and outputs it to the addition circuit 20. Note that the gain control amplifiers GCA3 and GCA4 are amplifiers that can change the signal level from positive polarity to zero through negative polarity. The adding circuit 20 adds each input signal and outputs the sum to the balanced modulator MODI. First color difference signal synthesis circuit 1
The signal output from 4 is a newly rearranged composite color difference signal RY.

On the other hand, the second color difference signal synthesis circuit 16 similarly performs the following operation. The gain control amplifier GCA5 adjusts the level of the partial color difference signal (B-Y) and outputs it to the addition circuit 22. gain control amplifier G
CA6 adjusts the level of the partial color difference signal (B-Y)- and outputs it to the addition circuit 22. gain control amplifier GC
A7 adjusts the level of the partial color difference signal (RY)+ and outputs it to the addition circuit 22. gain control amplifier GCA
8 adjusts the level of the partial color difference signal (RY)- and outputs it to the addition circuit 22. In addition, gain control amplifier G
CA7 and GCA8 are amplifiers that can change the signal level from positive polarity to zero through negative polarity. The addition circuit 22 adds the input signals and generates a composite color difference signal B-
Y is output to the balanced modulator MOD2.

The composite modulator MODI outputs the first signal by the composite color difference signal RY.
The color-specific carrier wave f*C+ is modulated and output to the adder circuit 18. The second balanced modulator MOD2 has a composite color difference signal B-Y
The second color-based carrier wave fffC2 is modulated and output to the adder circuit 18. The addition circuit 18 adds the modulated color-specific carrier waves ESC+ and f*c2 and outputs the result as a chroma signal.

In the first color difference signal synthesis circuit 14 and the second color difference signal synthesis circuit 16, the color difference signal R-Y.

B-Y are each amplified and output. However, in the color difference matrix circuit 8 according to the present invention, these color difference signal synthesis circuits do not merely amplify color difference signals. Color difference signal R-Y.

B-Y are respectively partial color difference signals (R-Y)” (R-Y)
- and a partial color difference signal (B-Y)''(B-Y)-, which are each independently amplified and then added.In addition, the first color difference signal that synthesizes the color difference signal R-Y is In the synthesis circuit 14, the component of the other color difference signal B-Y is added to the color difference signal R-Y.Similarly, in the second color difference signal synthesis circuit 16, the component of the other color difference signal B-Y is added to the color difference signal R-Y. In addition, not only the partial color difference signal (B-Y)" (B-Y)-, but also the partial color difference signal (R-Y)" (R-Y)-
components are added. As a result, the color of the video signal represented by the composite color difference signals RY and BY, which are obtained by combining these signals, can be freely adjusted up to its phase.

FIG. 3 is a schematic diagram showing a color vector plane and the vector representation of each color on the color vector plane. In this schematic diagram, the horizontal axis is the BY axis, and the vertical axis is the RY axis. Based on these two axes, the first quadrant to the
Four quadrants are formed. In Figure 3,
The bright spots of the vector representations of the six colors used in the color par signal are shown. The six colors are red (R),
Yellow (Ye), Green (G), Cyan (Cy), Blue (B)
and magenta (M g ). A feature of the color difference matrix circuit according to the present invention is that the position of the color vector typically represented by each of these colors is moved not only in distance (level) from both axes but also rotationally around the origin O. This means that it can be done.

FIG. 4 is a waveform diagram representing the color difference signal RY of a typical color par signal. In this waveform diagram, each pulse component represents yellow, cyan, green, magenta, red, and blue in order from the left. 5A is a waveform diagram showing the partial color difference signal (RY) divided by the R-Y signal dividing circuit 10, and FIG. 5B is a waveform diagram showing the partial color difference signal (RY) divided by the R-Y signal dividing circuit 10. It is a waveform diagram of signal (RY)-.

FIG. 6 is a waveform diagram of the color difference signal B-Y of the color par signal, which is the same as that shown in FIG. FIG. 7A shows the partial color difference signal (B-Y
)+ waveform diagram. Figure 7B shows the B-Y signal dividing circuit 1.
FIG. 2 is a waveform diagram of a divided color difference signal (B-Y)- which is divided and outputted according to FIG.

The color difference signal synthesis circuit 14.16 amplifies and adds each divided color difference signal shown in FIGS. 5A, 5B, 7A, and 7B at an arbitrary ratio, and generates a composite color difference signal R-YSB.
-Y respectively.

Figures 8A to 8D show the gain control amplifier GCA
1 is a schematic diagram of a color vector plane for showing the functions of GCA2, GCA5, and GCA6; FIG.

Referring to Figure 8A, gain control amplifier GCA
I is to adjust the distance of the color vectors in the first and second quadrants from the B-Y axis by amplifying and outputting the partial color difference signal (R-Y)+ with an arbitrary amplification factor. I can do it. Similarly, the gain control amplifier CGA2 controls the color vector B in the third and fourth quadrants.
- The distance from the Y axis can be adjusted. Referring to FIG. 8C, the gain control amplifier GCA5 is for adjusting the distance of the color vectors in the first and fourth quadrants from the RY axis.

Referring to Figure 8D, gain control amplifier GCA
6 is R of the color vector in the second and third quadrants
- This is for adjusting the distance from the Y axis.

FIGS. 9A to 9D are schematic diagrams of color vector planes for explaining the functions of gain control amplifiers GCA3, GCA4, GCA7, and GCA8, respectively. 9th
Referring to FIG. A, the gain control amplifier GCA3 has a function of rotating the bright spots of the color vector in the first and fourth quadrants of the color vector plane around the positive side of the BY axis. This is because the gain control amplifier GCA3 amplifies and adds the partial color difference signal (B-Y)+ to the composite color difference signal RY.

For example, in the case of blue shown in the figure, the position of this vector can be moved in a direction parallel to the RY axis with the BY axis as the center. This movement is called axis correction. Note that the gain control amplifier GCA3 can control the level and polarity of the partial color difference signal (B-Y).

Similarly, referring to FIG. 9B, the yellow color vector is
By the function of gain control amplifier GCA4, B
- Rotated around the negative side of the Y axis. Referring to FIG. 9C, the color vector representing red is rotated around the positive side of the RY axis by the operation of gain control amplifier GCA7. Further, referring to FIG. 9D, the color vector corresponding to cyan, for example, is centered on the negative side of the RY axis, and the gain control amplifier GCA8
It is rotated by the action of

Therefore, the video signal obtained from the color difference matrix circuit 8 is controlled by the gain control amplifiers GCAI to GCA4 included in the first color difference signal synthesis circuit 14 and the gain control amplifiers GCA5 to GCA8 included in the second color difference signal synthesis circuit 16. The hue can be adjusted to your liking. In addition to adjusting the level within each quadrant of each color vector as in the past,
Since even the phase of the color vector can be freely controlled, the color reproducibility of the video signal can be freely adjusted using the color difference matrix circuit 8.

[Effects] As is clear from the above description, in the color difference matrix circuit according to the present invention, the first color difference signal and the second color difference signal are each divided into two positive and negative partial color difference signals.

These four divided signals are amplified by an arbitrary amplification factor and added together to obtain two composite color difference signals. These composite color difference signals can represent a new color vector that can be freely adjusted, including not only the level but also the phase, when compared with the color vector represented by the original color difference signal. As a result, the user can achieve desired color reproducibility in the resulting video signal. That is, it is possible to provide a color difference matrix circuit that can freely adjust the color reproducibility of the obtained video signal.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing the color difference matrix circuit and its surrounding elements according to the present invention, FIG. 2 is a circuit diagram of the R-Y signal dividing circuit, and FIG. 3 is a schematic diagram of the color vector plane. Figure 4 is a waveform diagram of the color difference signal R-Y, Figure 5A is a waveform diagram of the partial color difference signal (RY)+, and Figure 5B is a waveform diagram of the partial color difference signal (RY)-. 6 is a waveform diagram of the color difference signal B-Y, FIG. 7A is a waveform diagram of the partial color difference signal (B-Y)+, and FIG. 7B is a waveform diagram of the partial color difference signal (B-Y). )-, FIGS. 8A to 8D are schematic diagrams of color vector planes, and FIGS. 9A to 9D are schematic diagrams of color vector planes for representing phase changes of color vectors. Yes, and FIG. 10 is a block diagram of a conventional device. In the figure, 8 represents a color difference matrix circuit, 10 a R-Y signal dividing circuit, 12 a B-Y signal dividing circuit, 14 a first color difference signal synthesis circuit, and 16 a second color difference signal synthesis circuit. In addition, in the figures, the same reference numerals indicate the same or equivalent parts. ~' Fig. 2 Fig. 3 Fig. 8A Fig. 8B Fig. 88C Fig. 8D Fig. QA Fig. 48 Fig. 4 Fig. SA Fig. 5B Fig. 6 Fig. 7A Fig. Figure 10

Claims (1)

[Claims] (1) To input a first color difference signal and output a first partial color difference signal consisting only of positive components of the first color difference signal and a second partial color difference signal consisting only of negative components. a first color difference signal dividing means, which receives a second color difference signal different from the first color difference signal, and generates a third partial color difference signal consisting only of positive components of the second color difference signal; a second color difference signal dividing means for outputting a fourth partial color difference signal consisting only of components; the first partial color difference signal, the second partial color difference signal, and the third partial color difference signal; and the fourth partial color difference signal, each of which is amplified by an arbitrary amplification factor and added to each other to output a first combined color difference signal; a color difference signal, the second partial color difference signal, the third partial color difference signal, and the fourth partial color difference signal.
a second color difference signal for outputting a second composite color difference signal by amplifying and adding the partial color difference signals at arbitrary amplification factors.
A color difference matrix circuit including a color difference signal synthesis means.