JPH07245715A - Color image processor - Google Patents

Abstract

PURPOSE:To further improve a color reproducibility accuracy by setting a masking matrix again through the optional setting of an operator. CONSTITUTION:An RGB luminance signal is converted into a density signal Y'M'C' by a logarithmic transformation section 1. A level discrimination section 6 decides whether or not the level of the density signal Y'M'C' is higher than a level of a reference density 32. When the decision indicates a negative result, the level discrimination section 6 controls a switch 8 to switch density signals Y, M, C from a color correction section 2 to a gradation modulation section 4, and when the discrimination indicates an affirmative result, to a gradation modulation section 3. On the other hand, in the case of the negative discrimination, a matrix constant A2 from a table 7 is selected, and in the case of the affirmative discrimination, a matrix constant A1 from the table 7 is selected. Then the color correction section 2 executes matrix arithmetic operation by using the selected matrix constant to generate the density signal YMC. A printer engine 5 implements printing based on the density signal YMC.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color image processing apparatus for performing adaptive color correction.

[0002]

2. Description of the Related Art Conventionally, a fixed process is performed for color correction of a color printer.

To increase the gradation dynamic range, the electrophotographic method uses dot diameter modulation when the density is high, and area modulation when the density is low.

[0004]

However, if dot diameter modulation and area modulation are used together to increase the dynamic range, the color reproduction method differs depending on the modulation method.
It was impossible to optimize both dot diameter modulation and area modulation at the same time.

An object of the present invention is to provide a color image processing apparatus which can solve the above problems and further improve the color reproduction accuracy.

[0006]

[Means for Solving the Problems]

1) A color image processing apparatus according to the present invention includes a color correction unit for performing color correction based on image density, a dot diameter modulation unit for dot diameter modulation, an area modulation unit for area modulation, and the image density. When the image density is higher than the reference density as a result of comparison by the comparing means for comparing with the predetermined reference density, the density signal from the color correcting means is switched to the dot diameter modulating means side to change the image density. Is lower than the reference density, a switching means for switching the density signal from the color correcting means to the area modulating means side is provided.

2) In the color image processing apparatus described in 1) above, the color correction means stores the matrix constant, and the matrix obtained from the storage means according to the comparison result by the comparison means. An arithmetic means for performing a matrix operation on the image density before color correction using a constant is provided.

3) In the color image processing apparatus described in 1) above, the color correction means uses a look-up table that associates an image density with an image density to be converted, and an image density before color correction. And an interpolating means for interpolating the image density obtained from the look-up table.

[0009]

[Action]

1) In the color image processing apparatus according to the present invention, the comparison unit compares the image density with a predetermined reference density, and if the comparison result shows that the image density is higher than the reference density, the density signal from the color correction unit is used as a dot signal. When the image density is lower than the reference density, the density signal from the color correcting means is switched to the area modulating means by the switching means.

2) In the color image processing apparatus described in 1) above, the color correction means uses the matrix constant obtained from the storage means in accordance with the comparison result by the comparison means, and uses the matrix density for the image density before color correction. Matrix calculation is performed by the calculation means.

3) In the color image processing apparatus described in 1) above, the color correction means interpolates the image density obtained from the look-up table with respect to the image density before color correction by the interpolation means.

[0012]

Embodiments of the present invention will now be described in detail with reference to the ground.

<First Embodiment> FIG. 1 shows a first embodiment of the present invention. In FIG. 1, reference numeral 1 is a logarithmic converter, which converts the input RGB luminance signal into a density signal Y'M'C '. Reference numeral 2 denotes a color correction unit as a calculation means, which performs a masking process on the density signal Y'M'C 'from the logarithmic conversion unit 1 to generate a density signal YMC. That is, in the color correction unit 2,

[0014]

[Equation 1]

The matrix operation of is performed. 7 is a table as a storage means,

[0016]

[Outer 1]

The table 7 and the color correction section 2 constitute color correction means. Reference numeral 3 is a gradation modulation unit for performing dot diameter modulation. Reference numeral 4 is a gradation modulation unit for performing area modulation such as dither. Reference numeral 6 denotes a level discriminator, which serves as a comparison means and has a density Y'M 'from the logarithmic variable 1
C'is compared with a predetermined reference value, and a control signal corresponding to the comparison result is output. Reference numeral 8 is a switch as a switching means, and according to the control signal from the level discriminating unit 6, Y, M and C from the color correcting unit 2 are provided to either the gradation modulating unit 3 side or the gradation modulating unit 4 side. It is to switch. 5 is a print engine.

Next, the operation will be described.

The RGB luminance signal input through the input terminal is converted into the density signal Y'M'C 'by the logarithmic conversion unit 1 and output to the color correction unit 2 and the level discrimination unit 6.

By the level discriminating section 6, the concentration Y'M'C '
Is compared with the reference concentration 32. As a result of comparison, 0 ≦
When Y ′, M ′, C ′ ≦ 32, the level discriminator 6
By controlling the switch 8 to switch the density signals Y, M and C from the color correction section 2 to the gradation modulation section 4, and 32 <Y ′,
If M ′, C ′ ≦ 255, the level discriminating unit 6 controls the switch 8 to switch the density signals Y, M, C from the color correcting unit 2 to the gradation modulating unit 3.

On the other hand, as a result of comparison by the level discriminator 6, if 0≤Y ', M', C'≤32, then from the table 7

[0022]

[Outside 2]

Then, using the respective matrix constants, the color correction section 2 performs a matrix operation to generate density signals Y, M and C. Printing is performed by the print engine 5 based on the density signals Y, M, and C.

Therefore, when the density is high, the dot diameter modulation is performed, while on the other hand, the area modulation is performed in the highlight portion where the density is low, and the gradation dynamic range is greatly improved.

<Second Embodiment> FIG. 2 shows a second embodiment of the present invention.

Compared with the first embodiment, this embodiment is as follows.
The color correction method is different. That is, in the first embodiment, by using the matrix constants selected from the table 7 according to the density, the color correction unit 2 performs the matrix operation on Y'M'C 'to obtain YMC. On the other hand, in the present embodiment, YMC corresponding to Y'M'C 'is LUT (l
ook up table) 21 and its YMC
The YMC deviated from is interpolated by the interpolating unit 22 and obtained.

The color correction method of this embodiment is a known method, and in the LUT 21, the number of bits required by the YMC corresponding to Y'M'C 'is less than the number of bits required to represent the entire Y'M'C' space. It is represented by a number. The interpolation in the interpolating unit 22 as the interpolating means is performed in advance in the Y'M'C 'space (see FIG. 3).
Is finely divided, and YMC data corresponding to the lattice point (that is, the vertex of each subcell) is mapped.
Then, the density deviated from the grid point can be obtained by calculation using the YMC data and the coordinates of the point of interest in the subcell. For example, the concentration D (O) at point O of one subcell shown in FIG.

[0028]

## EQU2 ## D (O) = (1-r ₃ ) (1-r ₁ ) (1-r ₂ ) D (p ₀ ) + (1-r ₃ ) r ₁ (1-r ₂ ) D (p ₁ ) + (1-r ₃ ) r ₁ r ₂ D (p ₂ ) + (1-r ₃ ) (1-r ₁ ) r ₂ D (p ₃ ) + r ₃ (1-r ₁ ) (1- r ₂ ) D (p ₄ ) ＋ r ₃ r ₁ (1-r ₂ ) D (p ₅ ) ＋ r ₃ r ₁ r ₂ D (p ₆ ) + r ₃ (1-r ₁ ) r ₂ D (p ₇ ) can be obtained from However, r represents the position of the target point in the subcell, and D (·) represents the density.

The RGB luminance signal input through the input terminal is converted into the density signal Y'M'C 'by the logarithmic conversion unit 1 and output to the LUT 21 and the level discrimination unit 6.

By the level discriminating unit 6, the concentration Y'M'C '
Is compared with the reference concentration 32 (see FIG. 3). As a result of comparison, if 0 ≦ Y ′, M ′, C ′ ≦ 32, the level discriminating unit 6 controls the switch 8 so that the density signals Y, M, and C from the interpolating unit 22 are changed to the gradation modulating unit. Switch to 4, 32
If <Y ′, M ′, C ′ ≦ 255, the level discriminating unit 6 controls the switch 8 to switch the density signals Y, M, and C from the interpolating unit 22 to the gradation modulating unit 3.

On the other hand, when the result of comparison by the level discriminator 6 is 0≤Y ', M', C'≤32, Y '
The YMC corresponding to M'C 'is taken out from the LUT 21, and the YMC deviated from the YMC is interpolated by the interpolating unit 22 to generate YMC (YMC corresponding to area modulation), 32 <Y', M ', C If ′ ≦ 255, then
The YMC corresponding to Y′M′C ′ is taken out from the LUT 21, and the YMC deviated from the YMC is interpolated by the interpolation unit 22.
To interpolate YMC (YM corresponding to dot diameter modulation
C) is generated. Then, the print engine 5 prints based on the density signals Y, M, and C.

Therefore, when the density is high, the dot diameter modulation is performed, while on the other hand, the area modulation is performed in the highlight portion where the density is low, and the gradation dynamic range is greatly improved.

[0033]

As described above, according to the present invention,
With the above configuration, the color reproduction accuracy can be further improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing a first embodiment of the present invention.

FIG. 2 is a block diagram showing a second embodiment of the present invention.

FIG. 3 is a diagram for explaining an interpolation method.

FIG. 4 is a diagram for explaining an interpolation method.

[Explanation of symbols]

 1 Logarithmic conversion unit 2 Color correction unit 3, 4 Gradation modulation unit 5 Print engine 6 Level discrimination unit 7 Table 21 LUT 22 Interpolation unit

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical display location H04N 1/46 B41J 3/00 A H04N 1/46 Z

Claims (3)

[Claims] 1. A color correction unit for performing color correction based on image density, a dot diameter modulation unit for dot diameter modulation, an area modulation unit for area modulation, and comparing the image density with a predetermined reference density. When the image density is higher than the reference density as a result of comparison by the comparing means, the density signal from the color correcting means is switched to the dot diameter modulating means side so that the image density is lower than the reference density. In this case, the color image processing apparatus is provided with a switching means for switching the density signal from the color correcting means to the area modulating means side. 2. The color correction means according to claim 1,
A storage unit for storing matrix constants; and a calculation unit for performing a matrix calculation on the image density before color correction using the matrix constants obtained from the storage unit according to the comparison result by the comparison unit. A color image processing device characterized by the above. 3. The color correction means according to claim 1,
A lookup table that associates image densities with image densities to be converted, and interpolation means that interpolates the image densities obtained from the lookup tables with respect to the image densities before color correction are provided. Color image processing device.