JPH1155540A - Method and device for generating luminance image and recording medium recording this method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To convert a natural image into a normal luminance image and to output a luminance image that makes the distinction of different color areas clear on an artificial image by providing an image classifying means which classifies color images into the natural image and the artificial image. SOLUTION: A frequency distribution generating part 102 calculates the number of colors which have pixel values that are the same or close to a color image in an image accumulating part 101 in color space. An image classifying part 103 classifies the input color image into either a natural image or an artificial image based on a result of the part 102. A color space transforming part 104 transforms each pixel value on RGB space to an image that is classified as the artificial image in the part 103 into a value on color space that corresponds to human perception. As for an image that is classified to the natural image in the part 103, a luminance image is generated by allocating a luminance level to each pixel value in accordance with the gradation reproductive range of an output device.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and apparatus for generating a luminance image which converts a color image into a luminance image and outputs the luminance image to an output device such as a facsimile or a printer which has a small number of gradation representations. It is about media.

[0002]

2. Description of the Related Art In general, a color image often represents the color of each pixel in the image by a combination of R (red), G (green), and B (blue). In that case, the conventional luminance image generation device generates a luminance image by converting each pixel value of the input color image into a luminance component Y based on Expression (1).

[0003] Y (x, y) = 0.299 R (x, y) +0.587 G (x, y) +0.114 B (x, y) (1) where R (X, y), G (x, y) and B (x, y
y) is each R (red) at the coordinates (x, y) on the image,
Pixel values of G (green) and B (blue) components, and Y (x, y)
Represents a luminance component at the same coordinates. “·” Represents a product.

[0004]

In the luminance conversion based on the equation (1), even if the colors, that is, the combinations of (R, G, B) are different, there are cases where the luminance components match or are close to each other. There is a problem that it becomes difficult to distinguish the different color areas on the luminance image. In particular, in an image including a color character or a figure drawn by a person, a problem arises in that it is difficult to interpret the contents of the luminance image as the conversion result. It should be noted that for a natural image, performing a conversion according to the equation (1) can provide a luminance image that does not cause discomfort.

Further, when a color image is converted into a luminance image and output to a device such as a facsimile which expresses a plurality of gradations in two types of white and black, the number of binary gradations is expressed by the color image. When the number of gradations of the luminance component Y is smaller than the number of gradations, there is also a problem that the gradation in the low luminance or high luminance part cannot be sufficiently represented.

FIG. 3A shows an example of the former. The input image of FIG. 3 shows a "Yokosuka R & D center" on a background where the color gradually changes from left to right and from white to blue.
Is superimposed and displayed at the center.
FIG. 3A shows a result of converting this image into a luminance image based on the above-described equation (1). In this example, the character becomes partially unclear because the luminance components of the character and the background are the same. It is shown.

According to the present invention, a natural image is converted into a normal luminance image within the gradation expression range of the output device, and an artificial image is converted into a luminance image when converting the natural image into a luminance image. It is an object of the present invention to provide a method and apparatus for outputting a luminance image in which different color regions can be clearly distinguished according to a range, and a recording medium on which the method is recorded.

[0008]

In order to solve the above-mentioned problems, the present invention provides an image classification means for classifying a color image into a natural image and an artificial image, and a luminance image according to a gradation expression range of an output device. A luminance image generating means for outputting, and a color space dividing means for dividing a color space into a plurality of partial spaces for an image classified as an artificial image are used.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a luminance image generating apparatus according to the present invention will be described in detail with reference to the drawings.

In FIG. 1, reference numeral 101 denotes an image storage unit;
2 is a frequency distribution creating unit, 103 is an image classifying unit, 104 is a color space converting unit, 105 is a color space dividing unit, and 106 is a luminance image generating unit. FIG. 2 is a flowchart showing a processing flow.

The configuration and function of each section will be described in order with reference to FIGS. <Image Storage Unit>: 101 The image storage unit 101 stores a color image, a luminance image, and an image generated in the process of creating the luminance image. <Frequency distribution creating unit>: 102 The frequency distribution creating unit 102 calculates the number of colors having the same or similar pixel values in the color space for the color image in the image storage unit 101 (see FIG. 2 202 and 206). The color space used here is RGB or XYZ
Color space such as Munsell, CIELUV, CIELAB
Color space corresponding to human perception such as Y, L
Any space may be used as long as the space is a numerical value of a color, such as a luminance axis such as ^* and two-dimensional chromaticity coordinates such as xy and u'v '. The result of the frequency distribution creating unit 102 is transferred to the image classifying unit 103 or the color space dividing unit 105. <Image Classification Unit>: 103 The image classification unit 103 classifies the input color image into one of a natural image and an artificial image based on the result of the frequency distribution creation unit 102 (see the image classification 203 in FIG. 2). The determination at the time of classification is performed based on the ratio of the maximum frequency to the total number of pixels. That is, when the maximum value of the frequency distribution occupies a certain percentage or more of the total number of pixels, the image is regarded as an artificial image, and the others are regarded as natural images. <Color space conversion unit>: 104 The color space conversion unit 104 converts each pixel value in the RGB space of the image classified into the artificial image in the image classification unit 103 into a value in a color space corresponding to human perception. (Refer to the color space conversion 205 in FIG. 2). The color space corresponding to human perception includes, for example, an HVC space and an HSI space that represent colors by three attributes of hue, saturation (or saturation), and lightness (or intensity), such as the Munsell color system. , HSV space, or a uniform color space such as CIELV or CIELAB.

After the image data after the color space conversion is transferred to the image storage unit 101, the frequency distribution creating unit 102 creates a frequency distribution in a color space corresponding to human perception. <Color space division unit>: 105 The color space division unit 105 divides the color space corresponding to human perception into a plurality of subspaces based on the result of the frequency distribution creation unit 102 (see FIG. 207 and integration 208 of subspaces with a small number of pixels). The processing of the color space dividing unit 105 will be described below.

<1> A data range of a luminance component and a color component is obtained from the frequency distribution, and a range (L _th , C _th ) of the luminance component and the color component that can be regarded as the same color is determined. <2> to detect the maximum value of the frequency distribution, around the color corresponding to the maximum value, the luminance component and a color look-component, L _th, C _th
Pixels having colors included in the range are assigned the same identifier to form a partial space.

<3> The operation of <2> is similarly performed for pixels for which an identifier has not been set, and identifiers are assigned to all pixels, so that the color space can be changed to a plurality of partial spaces having different identifiers. To divide.

<4> When the number of pixels included in one partial space is small, the image is integrated with a different partial space having a similar luminance component in the color space. The color space is divided into a plurality of subspaces by the operations from <1> to <4> described above.

The result of the color space division unit 105 is transferred to the luminance image generation unit 106. <Luminance Image Generation Unit>: 106 The luminance image generation unit 106 generates a luminance image for each of the natural image and the artificial image, and transfers the result to the image storage unit 101 (see FIG. Assignment 204 and brightness level assignment 20 for each subspace
9).

For an image classified as a natural image by the image classification unit 103, a luminance image is generated by assigning a luminance level to each pixel value according to the gradation reproduction range of the output device as follows. (Refer to the luminance level assignment 204 for each pixel value in FIG. 2).

First, RG at the coordinates (i, j) of the image
The pixel value on the B space is calculated by the luminance component Y
(I, j). Next, the maximum value Y _max of the luminance component
And a minimum value Y _min , and an output value Y ′ (i, j) of luminance is obtained according to the expression (2) according to the gradation expression range of the output device (here, Y ₁ or more and Y ₂ or less). .

Y ′ (i, j) = scale · (Y (i, j) −Y _min ) + Y ₁ scale = (Y ₂ −Y ₁ ) / (Y _max −Y _min ) ... (2) For images classified as artificial images, the color space division unit 1
At 05, a brightness image is generated by allocating the same brightness level to the colors contained in the same subspace (see brightness level allocation 209 for each subspace in FIG. 2).

First, for colors included in the same subspace, an order is assigned to the subspace based on their color components or luminance components. Next, according to the gradation expression range of the output device, the order assigned to each subspace is converted into a luminance level based on the following equation (3). Equation (3) shows a case where the order is assigned in ascending order of the luminance (the higher the luminance, the greater the order number).

Y ′ (i, j) = interval · Order (Index (i, j)) + Y ₁ interval = (Y ₂ −Y ₁ ) / (N−1) (1) 3) Here, N is the number of divisions of the color space, Index (i, j) is the identifier of the subspace to which the pixel value of the coordinates (i, j) belongs,
(k) is the order assigned to the subspace whose identifier is k, and Y ₁ and Y ₂ are the maximum value and the minimum value of the gradation expression range of the output device, respectively.

The present invention can also be realized by using a recording medium on which the processing according to the processing flow shown in FIG. 2 is recorded, and executing the processing based on the contents of the recording medium. it can. Therefore, the present invention includes the recording medium itself in the technical scope of the present invention.

[0023]

According to the present invention, the input color image is classified into a natural image and an artificial image based on the pixel value distribution of the color image, and in the case of the artificial image, the color space is divided into a plurality of partial spaces. By discretizing the color space and assigning luminance levels according to the gradation expression range of the output device,
Conversion to a luminance image can be realized without losing information of the input color image.

FIG. 3B shows an input image (an image in which a red character string “Yokosuka R & D Center” is superimposed and displayed on a background where the color gradually changes from white to blue) as in FIG. 3A. On the other hand, it is a result of conversion into a luminance image according to the present invention. In the luminance image according to the present invention, different luminance levels are assigned to the character area and the background area, so that the two can be easily distinguished.

[Brief description of the drawings]

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

FIG. 2 is a flowchart showing a processing flow of a luminance image generating method according to the present invention.

FIG. 3 is a diagram showing a difference in processing result between a conventional luminance conversion device and a luminance conversion device of the present invention.

[Explanation of symbols]

 101: Image storage unit 102: Frequency distribution creation unit 103: Image classification unit 104: Color space conversion unit 105: Color space division unit 106: Luminance image generation unit

Claims (3)

[Claims] An apparatus for converting a color image into a luminance image, comprising: a frequency distribution creating unit for creating a frequency distribution of pixel values in the color image; an input color image and a natural image based on the frequency distribution of pixel values. An image classification unit for classifying images, a color space conversion unit for converting a color space of a color image into a color space corresponding to human perception, and a color space into a plurality of subspaces based on a frequency distribution of pixel values. A color space dividing unit to be divided, and in the image classifying unit, when the image is classified into a natural image, a luminance level corresponding to a gradation expression range of an output device is assigned to each pixel value, and the image is classified into an artificial image A luminance image generating unit that generates a luminance image by assigning a luminance level according to the gradation expression range of the output device to each of the subspaces divided on the color space. Forming apparatus. 2. A method for converting a color image into a luminance image, comprising: a first processing step of creating a frequency distribution of pixel values for the color image; and a natural image and an artificial image based on the frequency distribution of pixel values. And a third processing step of assigning a luminance level according to the gradation expression range of the output device to each pixel value when the image is classified into a natural image by the second processing step. A fourth processing step of converting the color space of the color image into a color space corresponding to human perception when classified into an artificial image by the second processing step; A fifth processing step of creating a frequency distribution of pixel values for the color space that has been performed, and a color space obtained by the fourth processing step is divided into a plurality of subspaces based on the frequency distribution obtained by the fifth processing step. A sixth processing step of dividing; A seventh processing step of integrating a partial space with a small number of pixels with another partial space in the division result by the processing step, and a gradation expression of an output device for the partial space obtained by the seventh processing step An eighth processing step of assigning a luminance level according to the range. 3. A recording medium recording a process of converting a color image into a luminance image, the process comprising: a first process of creating a frequency distribution of pixel values for the color image; From the distribution, a second process of classifying the image into a natural image and an artificial image, by the second process, when classified into a natural image,
A third process of assigning a luminance level according to the gradation expression range of the output device to each pixel value, and by the second process, when classified into an artificial image,
A fourth process of converting the color space of the color image into a color space corresponding to human perception, and a fifth process of creating a frequency distribution of pixel values for the color space converted by the fourth process. A sixth process of dividing the color space by the fourth process into a plurality of subspaces based on the frequency distribution by the fifth process; and a subspace with a smaller number of pixels than the division result by the sixth process. And a seventh process of integrating a luminance level according to the gradation expression range of the output device with respect to the partial space obtained by the seventh process. A recording medium which records a process of generating a luminance image.