JP4681311B2 - Color arrangement rule generation method, apparatus for implementing the method, program, and recording medium recording the same - Google Patents

Description

  The present invention relates to a color arrangement rule generation method, an apparatus for executing the method, a program, and a recording medium on which the method is recorded, and in particular, by a color arrangement based on the correlation between color brightness and vividness without depending on hue, The present invention relates to a color arrangement rule generation method for creating a natural or artificial impression by color arrangement for manipulating impressions such as feeling and artificial feeling, an apparatus for implementing this method, a program, and a recording medium recording the same.

Color is an element deeply related to human behavior, and the color setting of a product greatly affects sales. Color is an area of great interest because the color of goods owned by an individual enriches the life of the person with it and represents the personality of that individual. In particular, the importance of color coordination, that is, the color arrangement technology of multiple colors, is being sought from the recent purchasing trend of trying to create a style of one's own color by harmonizing with the goods that he already owns. .
In order to perform a color arrangement in which a plurality of colors harmonize, a material that presents a color sample of a plurality of colors grouped as an example of the color arrangement is created. This is called a color chart.

  The idea about color harmony has been discussed in the past, and many coloration rules have been created for harmonizing coloration. Specific examples include the theory of harmony by Chevreul, a researcher of the Gobelins weaving, and the Moon-Spencer harmony theory that tries to quantitatively express the harmony of colors. These are intended to find a certain rule in the relationship of colors that seem to be harmonious, and are numerical values defined in color solids that quantitatively represent color changes, such as the Munsell color system. It is a color scheme rule using. On the other hand, there is a color system created for the purpose of color harmony so that it can be used as a color chart that can perform harmonious color schemes, such as the Ostwald color system and PCCS (Japan Color Research Color Scheme). However, these colors are primarily intended to “harmonize” a plurality of colors, and whether or not the colors are harmonized is based on an empirical sense. And if you don't have knowledge of each color scheme, Munsell color system, Ostwald color system and many other color schemes, you can't use the color scheme rules, and only apply within the color systems that the rules support. There is a problem that it cannot be performed (see Non-Patent Document 1).

  On the other hand, there are a color arrangement rule and a color chart based on an image generated when a plurality of colors are arranged. This is a development from past psychological research that changes the warmth / coolness and heavy / lightness depending on the hue, and extracts the image when combining multiple colors by means of the semantic differential (SD) method. To create. Color schemes and color charts are classified according to image words such as “moist”, “refreshing”, “revolutionary”, and “behavioral”. As an example, the color chart of Nippon Color Design Laboratory is composed of 160 words. The color to be arranged is specified by three elements of color (hue, brightness, vividness) (see Non-Patent Document 2).

  However, as a problem, the color arrangement method classified by the image word has an enormous number of color arrangements because the image changes depending on the hue such as warm color and cold color. Also, the impression may change slightly depending on the culture and time. In addition, there is a possibility that one of the paired image words, for example, “quiet” and “lively”, is treated as a negative impression or is difficult to select. When a pair of image words has a negative nuance, when a pair of image words is difficult to imagine, it is difficult to make a color scheme other than the color scheme examples belonging to the word. For example, the opposite of “sophisticated” has a bad meaning of “not refined” (see Non-Patent Document 3), and the opposite of “ecological tone” is difficult to imagine. In addition, it is not easy to record because the designation of the color to be arranged is designated by each value of the three elements of color (hue, brightness, vividness).

These conventional color schemes are used not only for color designation of many products such as clothes and interiors, but also for color matching of personal clothes, makeup, etc. due to recent strong interest in colors. Has been. However, regarding color harmony, there is still no absolute color scheme, and many color schemes are being studied.
Color Coordination Basics, pp. 80-87, Tokyo Chamber of Commerce and Industry, Tokyo Chamber of Commerce published Color scheme image chart, p. 42, published by Haruyoshi Nagumo, Graphic Inc. Color scheme image chart p.118, published by Haruka Nagumo, Graphic Inc.

  In recent years, there has been an increasing demand not only for the color of articles owned but also for the color of cosmetics, the color of hair, and the like associated with the body. Many people want to use natural shades or shades that emphasize them. Also, in the past, impressions involving emotions such as “refreshing image” and “adult image” were emphasized, but recently “looks more natural” and “artificial (more embedded) More complex and visual effects are required, such as “It looks like” and “Three-dimensional”. However, even though there are coloring rules that take into account the emotions and impressions that arise from color combinations, there are currently no systematic coloring rules that take into account visual effects.

Visual effects such as “look more natural” and “look more artificial” are achieved by specific color selection and coloration techniques, but choose the right color scheme from the vast number of color combinations. This is difficult to achieve unless there is a person who has special training or who does not have knowledge in the current situation and can use many colors. . Many people rely on sense and experience to do this.
The present invention provides a color scheme based on the correlation between the brightness and vividness of the color without depending on the hue, and creates any natural or artificial impression by a color scheme that manipulates the impression of natural and artificial feeling. The present invention provides a color arrangement rule generation method that can be applied to a system, an apparatus that implements the method, a program, and a recording medium on which the program is recorded.

Claim 1: a value indicating the value and vividness showing the hue, and the upper limit value and the lower limit value brightness of the color chart, in correlation negative correlation or a positive correlation between brightness and vividness a correlation value that indicates whether there is, obtains the number of colors of the color chart, different values of the period from a value indicating a hue corresponding to the white of the monitor to a value indicating the hue and the acquisition of the color chart Acquire only the number of colors as the coordinate value of the hue, and acquire the different values between the value indicating the vividness corresponding to the white color of the monitor and the value indicating the acquired vividness, as many as the number of colors in the color chart. The brightness coordinate value is obtained, and different values between the lower limit value and the upper limit value of the brightness are obtained as the brightness coordinate values by obtaining the number of colors of the color chart, and the correlation coefficient value is positive. To show the correlation of Combining the hue coordinate value, the vividness coordinate value, and the brightness coordinate value so that the hue and brightness are also in the order of decreasing hue when arranged in ascending order, the hue, vividness, and brightness are combined. When a series of pairs is generated and the correlation coefficient value indicates a negative correlation, when the vividness is arranged in ascending order, the hues are arranged in ascending order and brightness is arranged in descending order. The coordinate value, the coordinate value of the vividness, and the coordinate value of the brightness are combined to generate a series consisting of a set of hue, vividness, and brightness, and the set of hue, vividness, and brightness is converted into RGB. A color arrangement rule generating method for presenting a series of RGB values obtained as a color chart was constructed .

Further, according to claim 2: a color characteristic input unit 1 that acquires the value indicating the value and vividness showing a hue, a brightness characteristic input unit 3 to set the upper limit and lower limit of the brightness of the color chart, It obtains the correlation coefficient values indicating how correlation between the brightness and vividness is a negative correlation or a positive correlation, and the impression characteristic input unit 2 for obtaining the number of colors of the color chart, monitor Different values between the value indicating the hue corresponding to white and the value indicating the acquired hue are obtained by the number of colors of the color chart as the coordinate value of the hue, and the vividness corresponding to the white of the monitor Different values between the value indicating the brightness and the acquired value indicating the vividness are acquired as the brightness coordinate values by the number of colors of the color chart, and between the lower limit value and the upper limit value of the brightness. Different values of the color When the number of colors in the chart is acquired and used as the coordinate value of brightness, and the correlation coefficient value indicates a positive correlation, when the vividness is arranged in ascending order, the hue and brightness are also in the order of decreasing. The hue coordinate value, the vividness coordinate value, and the brightness coordinate value are combined to generate a series composed of a set of hue, vividness, and brightness, and the correlation coefficient value has a negative correlation. When the vividness is arranged in ascending order, the hue coordinate value, the vividness coordinate value, and the brightness coordinate value are set such that the hue is in ascending order and the brightness is in increasing order. in combination, the color rule calculation unit 4 for generating a sequence consisting of a set of hue and saturation and brightness, the sequence of RGB values obtained by converting a set of the hue and saturation and brightness to the RGB as the color chart Presenting color We configured the coloring rule generating apparatus and a chart output unit 5.

Claim 3 : A value indicating hue, a value indicating vividness, an upper limit value and a lower limit value of brightness of the color chart, and a correlation between brightness and vividness is a positive correlation or a negative correlation a correlation value that indicates whether the relationship, obtaining the number of colors of the color chart, different values of the period from a value indicating a hue corresponding to the white of the monitor to a value indicating the hue and the acquired, the acquired by the number of colors of the color chart to the coordinate values of the hue, the different values of the period from a value indicating a saturation corresponding to white monitor to a value that indicates the vividness that the acquired color of the color chart Is obtained as the coordinate value of the brightness, and different values between the lower limit value and the upper limit value of the brightness are obtained as the coordinate value of the brightness by obtaining the number of colors of the color chart, and the phase Positive correlation In the case of indicating the relationship, the hue coordinate value, the vividness coordinate value, and the brightness coordinate value are combined so that the hue and the brightness are in ascending order when the vividness is arranged in ascending order. When a series consisting of a combination of hue, vividness and brightness is generated and the correlation coefficient value shows a negative correlation, when the vividness is arranged in ascending order, the hue is in ascending order and the brightness is in descending order. The hue coordinate value, the vividness coordinate value, and the brightness coordinate value are combined to generate a series composed of a set of hue, vividness, and brightness, and the hue and vividness the sequence of RGB values obtained by converting the to brightness set to RGB to constitute a color scheme rule generation program for executing the steps you presented as the color chart to the computer.

According to a fourth aspect of the present invention, there is provided a recording medium on which the color arrangement rule generating program according to the third aspect is recorded.

  This invention is based on optical and physical conditions in the natural environment, and by manipulating the correlation between color brightness and vividness, it makes natural and artificial impressions unaffected by hue. Can produce. According to the present invention, it is possible to easily obtain a color arrangement rule that produces a visually natural impression or an artificial impression regardless of the change in the impression due to the difference in hue. This color arrangement rule is a rule that can be applied to an existing color system regardless of its type.

In a natural environment, due to the relationship between light and an object, light portions tend to be light in color and dark portions tend to be dark (colors become bright). This is caused by the presence of a portion that receives direct light and a portion that receives secondary light reflected from other surfaces.
Referring to FIG. 1, FIG. 1 (a) shows the brightness (brightness) and saturation (brightness) of some colors surrounded by a white frame in the natural image of FIG. 1 (b). It is a scatter diagram showing values. The vertical axis is saturation and the horizontal axis is luminance (cd / m ² ). The value on the vertical axis depends on CIE L ^* u ^* v ^* chromaticity coordinate values.

  In the white frame, which is a part of the natural image in FIG. 1B, a large number of white or bright yellow, dark yellow, and intermediate yellow areas are mixed. When this state is measured, as shown in FIG. 1A, generally, a result is obtained in which the relationship between brightness and vividness is a right-down correlation, that is, a negative correlation. At this time, many bright white, dark and dark (bright) colors, and intermediate colors are extracted from the image. In the case of FIG. 1, bright white, dark dark yellow, and intermediate colors are prominent. The present invention takes advantage of such optical facts to automatically generate color scheme rules and manipulate the impressions resulting from color schemes. First, when the color is set such that the light part is light in color and the dark part is dark, that is, a negative correlation between luminance and saturation, a correlation coefficient R = −1.0. This pattern looks more natural. This is because, as described above, there is a negative correlation between luminance and saturation in the natural environment, and this set of colors can be said to reconstruct the color distribution in the natural world. Because. On the contrary, the relationship between brightness and vividness was reversed, that is, the bright part is darker in color and the color is lighter in darkness, the positive correlation between luminance and saturation, the correlation When the colors with the number R = 1.0 are assembled, the natural impression as described above fades, and the human eye perceives it as a pattern illuminated by colored lighting, making it more artificial. An impression is brought about.

A method of creating this color pattern will be described with reference to FIG. FIG. 2A is a diagram for explaining the definition of saturation, and the distance from a certain color, red R to white W, is defined as saturation. The further away from white, the higher the saturation. The CIE 1931 (x, y) chromaticity diagram is used. FIG. 2B is a diagram showing the correspondence between saturation and luminance by the correlation coefficient.
Referring to FIG. 2A, the color of a certain point R is selected on the CIE 1931 (x, y) chromaticity diagram. Red circle R is selected. In the chromaticity diagram, when connecting from the R point to white (W) indicated by *, the chromaticity diagram has the same brightness, that is, an equiluminance surface, and therefore only the vividness of the color changes. Referring to (a) in FIG. 2B for explaining the change in saturation and luminance, the change in saturation (brightness) on the left side and the change in luminance (brightness) on the right side are represented by 7 at equal intervals. It is divided to correspond to its vividness and brightness. The saturation is shown as the saturation gradually decreasing from the highest bright red to the lowest white or gray achromatic color. The luminance is shown as a luminance that gradually decreases from the brightest white or gray to the lowest black. (B) in FIG. 2 (b) for explaining the correlation shows the case of a positive correlation (solid arrow) of R = 1.0 in which the level of vividness and the level of brightness match and are combined, and the vividness. This shows a case of a negative correlation (broken arrow) of R = −1.0 in which the height of brightness and the brightness are reversed.

  FIG. 3 is a diagram illustrating how colors change depending on whether the correlation between brightness and vividness is positive or negative. FIG. 3A shows a combination of colors having a positive correlation and a color combination having a negative correlation for blue. FIG. 3B shows a combination of colors having a positive correlation and a color having a negative correlation for green. Referring to FIG. 3 (b), when the hue is green, the negative correlation is composed of light white or gray, dark dark green, and intermediate green, and the positive correlation is light dark green and dark gray. And the middle green. Such a color relationship is constant regardless of the hue. Referring to FIG. 3A, when the hue is blue, the white color is a negative correlation with light white or gray, dark dark blue, and the intermediate blue color. It is a combination of bright and dark blue, dark gray and blue in the middle with positive correlation. When the correlation coefficients R = 1.0 and R = −1.0, the range of brightness and vividness of the colors in the pattern are equal. In this way, at R = −1.0, which is the strongest negative correlation, a combination of bright white or gray, dark and dark color (any hue) and intermediate colors thereof, on the other hand, positive At R = 1.0, which is the strongest correlation, a combination of a light and dark color, a dark gray color, and an intermediate color thereof.

  A pattern is completed when a plurality of colors created by manipulating the correlation coefficient are assigned to random positions. Such a pattern produces different impressions depending on the correlation coefficient. FIG. 4 is a diagram showing how the impression of the pattern changes depending on the correlation coefficient for red. Even if the same hue and the same brightness and vividness range, the set of colors shown in FIG. 4 (a) having a negative correlation and the set of colors shown in FIG. to differ greatly. The negative correlation in FIG. 4 (a) gives a natural impression as a change in the color of the object, and makes the presence of a natural shadow and depth. On the other hand, the positive correlation in FIG. 4B is an artificial, bright feeling, receives a mechanical and metallic impression, and looks like a flat surface with a light contrast.

FIG. 5 is a diagram showing how the pattern impression changes depending on the correlation coefficient, as in FIG. FIG. 5A is a diagram showing how the correlation changes for blue when the correlation is positive and negative, and FIG. 5B shows how the correlation changes for green when the correlation is positive and negative. Figure.
Therefore, a color arrangement rule is completed in which a combination of light white or gray to dark and dark colors gives a natural impression regardless of hue, and a combination of dark gray to light and dark colors gives an artificial impression.
The difference in impression due to the difference in correlation between brightness and vividness of the color is constant regardless of the type of color system. Therefore, it is possible to select and use a color that matches the rule of the present invention from the conventional color system. In other words, if you create a pattern that has a positive correlation between brightness and vividness, and selects a bright, vivid color, a darker gray, and an intermediate color from the color system in the same hue, Can produce a great impression. Conversely, creating a pattern that has a negative correlation and selects bright white or gray, a darker, brighter color, and an intermediate color in the same hue creates a more natural impression. can do.

A specific method of creating a color table (color chart) in accordance with this color arrangement rule will be described with reference to FIG. In the color chart to be created, the hue, brightness, and number of colors can be arbitrarily set.
Referring to FIG. 6, the color arrangement rule generating device of the present invention includes a color characteristic input unit 1, an impression characteristic input unit 2, a brightness characteristic input unit 3, a color arrangement rule calculation unit 4, and a color chart output unit 5. It is comprised by.
The color characteristic input unit 1 inputs a color characteristic of a hue characteristic value of an arbitrary color via a keyboard or other input device. The input values are x and y based on the CIE 1931 (x, y) chromaticity diagram chromaticity coordinate values. The CIE 1931 (x, y) chromaticity coordinate value is an index indicating the hue and vividness excluding the brightness among the three attributes (hue, brightness, and vividness) of the color.

When creating a color combination that produces a natural impression, the impression characteristic input unit 2 inputs a negative correlation R = −1.0 using a keyboard, and creates a color combination that produces an artificial impression. In this case, R = 1.0 of the positive correlation is input from the keyboard. Further, in the impression characteristic input unit 2, the number of colors of the color chart example that is actually output is input by the keyboard. The number of colors in the color chart is 2 or more. This value is set as step.
The brightness characteristic input unit 3 sets an upper limit and a lower limit of the brightness of the color of the color chart to be created. The brightness is set according to the brightness value. The luminance value matches the Y value of the CIEXYZ color system representing the brightness of the color with respect to the CIE 1931 (x, y) chromaticity coordinate value representing the color. Therefore, the color characteristic value can be expressed as (x, y, Y) from the X value, y value, and Y value, which are CIE 1931 (x, y) chromaticity coordinate values. These three values can be converted to RGB values and can be presented on a monitor. The upper limit value of the brightness input in the brightness characteristic input unit 3 is maxY, and the lower limit value of the brightness is minY. At this time, if the monitor gamut (color display range) is exceeded, input is performed again. Whether or not the gamut is exceeded is determined by the color arrangement rule calculation unit 4 described later.

The color arrangement rule calculation unit 4 determines the number of colors input in the impression characteristic input unit 2 between the x value and y value input in the color characteristic input unit 1 and the chromaticity coordinate value of the white point of the monitor (step ) To obtain equal CIE1931 (x, y) chromaticity coordinate values. Let the chromaticity coordinate value of the white point of the monitor be (xW, yW). If the CIE 1931 (x, y) chromaticity coordinate values of the changing color are x _k and y _k ,

It can be expressed as. As x ₁ , x ₂ , x ₃ ,..., the CIE 1931 (x, y) chromaticity coordinate value changes from white (achromatic) to the color specified in the color characteristic input unit 1 and the vividness of the color. Will increase.
On the other hand, the upper limit value (maxY) and the lower limit value (minY) of the brightness input in the brightness characteristic input unit 3 are equally divided by the number (step) of colors input in the impression characteristic input unit 2. go. Let Y _k be the changing brightness value.

It can be expressed as The brightness increases as Y ₁ , Y ₂ , Y ₃ ,.
The color attributes (color tone / brightness) obtained by Expression (1), Expression (2), and Expression (3) are combined. When the impression characteristic value input in the impression characteristic input unit 2 is R = 1.0, when the vividness is low, the brightness is low, and when the vividness is high so that the vividness and the brightness have a positive correlation. Combine to increase brightness. That is, (x ₁ , y ₁ , Y ₁ ), (x ₂ , y ₂ , Y ₂ ), (x ₃ , y ₃ , Y ₃ ), ..., (x _step , y _step , Y _step ) Combine three values with.
On the other hand, when negative correlation R = −1.0 is input to the impression characteristic input unit 2, the vividness is low but the brightness is high, and conversely when the vividness is high, the brightness is low. Combine with. That is, (x ₁ , y ₁ , Y _step ), (x ₂ , y ₂ , Y _{step -1} ), (x ₃ , y ₃ , Y _{step -2} ), ..., (x _step , y _step , Y ₁ ) Combine the three values so that

That is, when R = 1.0, which is a positive correlation, the brightness may be reversed and combined when R = -1.0, which is a negative correlation. The combination of colors created in this way has an artificial impression when the correlation is positive, and a natural impression when the correlation is negative. This is the color scheme rule.
Since the color created by this color arrangement rule can be presented on the monitor, it can be presented on the monitor constituting the color chart output unit 5. Since the color arrangement rule calculation unit 4 is calculated based on the CIE 1931 (x, y) chromaticity coordinate values, the color arrangement rule calculation unit 4 converts the values into RGB values for presentation on the monitor. This conversion also enables printing of a color chart by a printer.
The conversion formula from CIE1931 (x, y) chromaticity coordinate values to RGB values is as follows. First, the CIE 1931 (x, y) chromaticity coordinate value (x, y) and luminance value Y of each color created are converted into the CIE XYZ color system.

Three phosphors R, G, B and white CIE1931 (x, y) chromaticity coordinate values (xR, yR), (xG, yG), (xB, yB), (xW, yW) of the monitor presenting the stimulus Measure from there

(C is a determinant for calculation). Next, the white chromaticity coordinate values are converted into the CIE XYZ color system.

From these, the following equation is calculated (V is a value for calculation). C ⁻¹ is an inverse matrix of C.

(T is a determinant for calculation). The CIE XYW color system is converted into RGB values using T in equation (12) and the values in equations (4), (5), and (6). T ⁻¹ is an inverse matrix of T.

Expressions (4) to (13) are calculated for the values calculated in Expressions (1), (2), and (3), and colors based on the respective RGB values are presented on the monitor. Also, the CIE 1931 (x, y) chromaticity coordinate value and RGB value of the color are presented. An example of a color chart obtained as a result of the calculation is given in FIG. Such a result is generated in the color chart output unit 5.
Here, when the RGB value of the result of Expression (13) exceeds the monitor gamut, for example, when at least one of R, G, and B exceeds 255, the brightness characteristic input Assume that the re-input of the upper limit value maxY and the lower limit value minY of brightness is obtained in the unit 3.

  Judd, who studied the principles and principles common to many conventional color harmony theories, (1) as the principle of color harmony, (1) the principle of order, that is, the color selected by the regular relationship in the color space Harmonize, (2) familiarity principle, familiar relationships that are often seen in the natural environment seem to harmonize, (3) commonality principle, ie dominant elements such as hue and tone (4) The principle of clarity, and the fact that the colors can be clearly perceived (see Non-Patent Document 1). Traditional color harmony theory applies to one or more of these principles. This invention also applies to three of the principles (1), (2), and (3). Regarding (1), it has an order using a change in brightness and vividness obtained by linear calculation in the color space. (2) is derived from physical and optical characteristics in nature and is a familiar color scheme. Regarding (3), it is mentioned that the hue is constant and that it is defined as one kind of correlation. This invention has a scientific basis.

Hereinafter, specific application examples of the color arrangement rule of the present invention will be described.
Since this color arrangement rule is based on optical and physical laws that occur in the natural environment, the color pattern is suitable for giving a natural or artificial impression. From here, it is useful for color setting of cosmetics. Since cosmetics are in particulate form, they have the effect of mixing multiple colors. Referring to FIG. 8, this shows an eye shadow palette using the color scheme of the present invention. Eye shadows with both positive and negative correlations can be set and selected with a single color palette for both natural and artificial colors.

When applied to foundations, highlights, and shadows, the foundation color does not appear white and the natural texture of the face can be manipulated. This was a traditional makeup specialist, who could choose from a large number of makeup products for those with expertise, but if you make a single product that complies with these rules, many makeup amateurs will have a facial impression. Can be easily performed.
FIG. 9 shows the result of eye makeup in accordance with the color arrangement rule according to the present invention. FIG. 9A shows an example of a color scheme having a negative correlation. While this gives a more natural impression, FIG. 9B shows an example of a color scheme with a positive correlation, giving a more artificial, built-in impression.

  The color arrangement rule in the present invention can also be applied to the setting of the color of the wall tile. The visual effect according to the present invention is not related to the spatial position of the color to be arranged. Therefore, the visual effect of the present invention can be obtained even when random color arrangement is performed, and the impression of the wall surface can be manipulated. it can. In addition, the color design of clothing and various industrial products can add a new color axis “natural or artificial” or “adjust or make it stand out” to give a wider range of color schemes. . Nowadays, with the advance of computer graphics (CG) technology, it has become possible to create realistic images. However, as the CG image is obtained with more realistic quality, the calculation cost increases. In the data distribution on the Internet, the image distribution by the mobile phone, or the application in the mobile phone, the problem of the calculation cost and the image capacity becomes particularly large. Since the present invention can automatically derive the color scheme, it can produce a natural impression or an artificial impression, and can reduce the calculation cost.

A graph showing the brightness (luminance) and vividness (saturation) of colors in a natural image as a scatter diagram. The figure explaining defining the distance from red to white as a saturation, and making saturation and a brightness | luminance respond | correspond by a correlation coefficient. The figure explaining a mode that a color changes with the case where the correlation of brightness and vividness is positive and negative. The figure which shows a mode that the impression of a pattern changes with a correlation coefficient about red. The figure which shows a mode that the impression of a pattern changes with a correlation coefficient about blue and green. The figure explaining an Example. The figure explaining the example of the color chart produced by this invention. The figure which shows the eye shadow palette using the color scheme rule of this invention. The figure which shows the eye makeup using the color scheme rule of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Color characteristic input part 2 Impression characteristic input part 3 Brightness characteristic input part 4 Color scheme rule calculation part 5 Color chart output part

Claims (4)

Shows a value indicating the value and vividness showing the hue, and the upper limit value and the lower limit value of the brightness of the color chart, whether a negative correlation or the correlation between the brightness and vividness are positively correlated Obtain the correlation coefficient value and the number of colors in the color chart ,
Different values between the value indicating the hue corresponding to the white color of the monitor and the value indicating the acquired hue are obtained as the coordinate value of the hue by acquiring the number of colors of the color chart,
A different value between the value indicating the vividness corresponding to the white color of the monitor and the value indicating the acquired vividness is obtained as the coordinate value of the brightness by obtaining the number of colors of the color chart,
Different values between the lower limit value and the upper limit value of the brightness are obtained as the coordinate value of the brightness by obtaining the number of colors of the color chart,
When the correlation coefficient value indicates a positive correlation, the hue coordinate value, the vividness coordinate value, and the brightness are set so that the hue and brightness are also in the order of decreasing brightness when the vividness is arranged in ascending order. By combining with the coordinate value of the length, a series consisting of a combination of hue, vividness and brightness is generated,
When the correlation coefficient value indicates a negative correlation, when the vividness is arranged in ascending order, the hue coordinate value and the vividness coordinate are set such that the hue is in ascending order and the brightness is in increasing order. A sequence of hue, vividness and brightness is generated by combining the value and the coordinate value of the brightness,
A method for generating a color arrangement rule , wherein a series of RGB values obtained by converting a set of hue, vividness and brightness into RGB is presented as the color chart. A color characteristic input unit that acquires a value indicating the value and vividness indicating hue,
And brightness characteristic input unit for setting the brightness upper limit value and the lower limit value of the color chart,
Obtains the correlation coefficient values indicating how correlation between the brightness and vividness is a negative correlation or a positive correlation, and impressive characteristic input unit for obtaining the number of colors of the color chart,
Different values between the value indicating the hue corresponding to the white color of the monitor and the value indicating the acquired hue are obtained as the coordinate value of the hue by acquiring the number of colors of the color chart,
A different value between the value indicating the vividness corresponding to the white color of the monitor and the value indicating the acquired vividness is obtained as the coordinate value of the brightness by obtaining the number of colors of the color chart,
Different values between the lower limit value and the upper limit value of the brightness are obtained as the coordinate value of the brightness by obtaining the number of colors of the color chart,
When the correlation coefficient value indicates a positive correlation, the hue coordinate value, the vividness coordinate value, and the brightness are set so that the hue and brightness are also in the order of decreasing brightness when the vividness is arranged in ascending order. By combining with the coordinate value of the length, a series consisting of a combination of hue, vividness and brightness is generated,
When the correlation coefficient value indicates a negative correlation, when the vividness is arranged in ascending order, the hue coordinate value and the vividness coordinate are set such that the hue is in ascending order and the brightness is in increasing order. by combining the coordinate values of the value brightness, and color rule calculation unit for generating a sequence consisting of a set of hue and saturation and brightness,
The hue and you and a color chart output unit for presenting a set of vividness and brightness series of RGB values obtained by converting the RGB as the color chart distribution color rule generation apparatus. A phase indicating whether the correlation between the value indicating the hue, the value indicating the vividness, the upper limit value and the lower limit value of the brightness of the color chart, and the brightness and the vividness is a positive correlation or a negative correlation. Obtaining a relational value and the number of colors of the color chart ;
Different values between the value indicating the hue corresponding to the white color of the monitor and the value indicating the acquired hue are obtained as the coordinate value of the hue by acquiring the number of colors of the color chart ,
A different value between the value indicating the vividness corresponding to the white color of the monitor and the value indicating the acquired vividness is obtained as the coordinate value of the brightness by obtaining the number of colors of the color chart,
Different values between the lower limit value and the upper limit value of the brightness are obtained as the coordinate value of the brightness by obtaining the number of colors of the color chart,
When the correlation coefficient value indicates a positive correlation, the hue coordinate value, the vividness coordinate value, and the brightness are set so that the hue and brightness are also in the order of decreasing brightness when the vividness is arranged in ascending order. By combining with the coordinate value of the length, a series consisting of a combination of hue, vividness and brightness is generated,
When the correlation coefficient value indicates a negative correlation, when the vividness is arranged in ascending order, the hue coordinate value and the vividness coordinate are set such that the hue is in ascending order and the brightness is in increasing order. Combining a value and the coordinate value of the brightness to generate a series of pairs of hue, vividness and brightness;
Coloring rule generation program for executing the steps you presenting a sequence of RGB values obtained by converting a set of the hue and saturation and brightness to the RGB as the color chart to the computer. A recording medium on which the color arrangement rule generating program according to claim 3 is recorded.