JPS5887432A - Color management system - Google Patents

Abstract

PURPOSE:To realize an efficient color management system based on a visual decision, by a method wherein a system comprises a color measuring device, which measures a color of a color sample and converts it into an electric signal, and a device which can compute and store a color coefficiency being capable of reproducing and displaying a color. CONSTITUTION:A color measuring device 1 measures a color of a color sample S and converts it into an electric signal. An operational processor 2, which is constituted so as to perform a given operation of each of a collection, a reference, and an inspection mode, consists of a computer controller 2a and a memory 2b. An input device 3 performs operations to specify a mode and to input a necessary data. A color display unit 4, which, if a color coefficiency is inputted, composes a color corresponding to a color coefficiency to display it in a display picture, consists of a color controller 4a which receives a color coefficiency from the operational processor 2 to transmit a control signal for a specific display, and a filter color display unit 4b which displays a color, corresponding to the control signal, on a screen serving as a display picture.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention is directed to the production of various color materials (designated by dyeing factories, etc.).
This article relates to a nine-colored tube slipper system suitable for workers who need to finish products.

Traditionally, in dyeing factories, there were many repeat orders that required dyeing to the same color as the previous Kumame Nine Colors.
In some cases, color management is performed in which the obtained product is searched and compared with nine color samples for final evaluation.

However, the huge number of roundings that occur for each color sample stripe patch poses a huge problem in terms of storage space and retrieval. Besides, for example Combiator color! Mechanization using Tsutengu also has the following problems. In other words, even if the color difference is the same, according to the meat I1 judgment, there is a
Differences due to differences in I broad, crystal, film, metal surface, etc., and roofing due to the form of the substrate, etc., cause the p-color bats to be extremely hot and less likely to be present. Therefore, color management is essential for the final Kti ratio judgment.

In response to this current situation, Akira Hontaka provides a color management system that is completely considered, is based on visual judgment, is highly efficient, and does not require storage space.

That is, the present invention provides a color management system for retrieably storing color samples for dyeing, etc., which includes a color toning device that converts one color of a color sample into an electric signal, and a toning device that converts one color of a color sample into an electric signal, and a color adjusting device that converts the color of the color sample into an electric signal in response to an armpit electric signal. Re-31111I! It is equipped with an arithmetic processing device that calculates and stores color coefficients that can be displayed, and a color display device that receives the color coefficients and reproduces and displays the colors corresponding to the color coefficients in an improved display image. The first invention is a color management system in which the colors of the color sample are stored as pre-color scheme coefficients and reproduced and displayed on the display screen of the public display device when necessary. The second invention is a color management system characterized in that the color of the test object is displayed on the same screen of a color display device together with the color sample stored in the first invention, and the test object can be compared and evaluated with the color sample. It is.

The above-mentioned invention was made by focusing on the recent advances in one-color technology and filter function.

Hereinafter, details of the present invention will be explained with reference to the drawings.

The first figure of joy is the invention! This is the overall explanation of the iI koji example, and the second
The figure is an explanatory diagram of a display image iI of a color display device, which is an example of a scissor display.

In the figure, reference numeral 1 denotes a round color toning device that keeps the color of the color sample 8 constant, and uses a commercially available O-part color adjusting needle. Therefore, the details are omitted, but the spectral reflectance of eight nine-color samples was set up like an omniscient O, and the spectral reflectance was converted into an electrical signal and output.

The goose is a calculation section layer device that is configured to perform the predetermined operations of acquisition, stock inspection, and inspection described later. It consists of a circular storage device using the capital.

E is an input device for rounding such as specifying the mode O and inputting necessary data, and various commercially available input devices such as E and I can be applied.

4 is a color display device which, when a predetermined color coefficient is input, synthesizes a color corresponding to the armpit color coefficient and displays it on the display screen Km; upon receiving the color coefficient from the arithmetic processing unit 2, displays the predetermined color. A force for emitting a control signal for the 2-control station 41 and a combination of 9 filters according to the wrinkle control signal are used to synthesize white light and display a color according to the color coefficient on a screen, which is a display screen. It consists of a filter force 2 and an indicator 4b. In addition, the combination of filters corresponds to three color stimulus values, yellow and red.

There are filters corresponding to the actual 311 and brightness, and each filter is connected to a pulse motor, so that each filter can be combined in any combination.

Therefore, as the color coefficient, it is sufficient that a filter set corresponding to 80 colors of the color sample can be set (this is referred to as "1 filter coefficient").

By the way, the above-mentioned arithmetic processing device 2 is a general purpose computer.

The following operations are performed in each search and inspection mode.

(1) In the acquisition mode, the electric signal of the color toning device 1 is mixed with the color 0 of the color sample S. ! 11111 required
A color coefficient is calculated in L1 via the three color stimulus values, and input device 3
The nine scissors input from the sample 8 are also stored in the storage device MblC@ next along with the search code of sample 8.

(2) When the search code KjiP is entered, the input device 1 is used to search for the 80 color coefficients of the color samples corresponding to the search code from 1 & Brass, output to the color display device 4, and output to the color display device 4. 4, 80 color samples are reproduced and displayed in a predetermined shape, for example, a rectangular shape, on the display screen P.

(3) In the inspection mode, the field color device 110 reads the electrical signal, and the test sample T is set from the wrinkle electrical signal.
At the same time as calculating the color coefficient of
Search for the 10 color coefficients of the wrinkle color sample from the color difference data, and calculate the upper and lower O gold #ilI color change coefficients from the nine color coefficients and the passed elf color difference data, and calculate these color coefficients. It outputs to the color display device 4. Then, as shown in the chart, the power 2 display device 4 displays the color of the test sample T according to the color coefficient of color T/11 and the upper and lower pass limit number of samples S based on the color sample S. The upper limit pass 1ilIIIL sample color 8- and the lower limit pass & 1 degree sample color 8 are displayed.

In this case, the force 2-display device 4 is one in which four sets of the above-mentioned filter mechanisms are provided and displayed on the same screen.

As described above, the collection of 80 color samples, retrieval, and color inspection of the nine products obtained are performed as follows.

In the case of mass acquisition, after setting the colorimeter IK color sample ♂ and specifying the acquisition mode from the input device 3, enter the search code for the color sample 8 and start it. The 80 color coefficients of the color samples are collected from the arithmetic processing device 2 into the storage device 2b. When the collection is completed, the arithmetic processing unit 2 outputs a completion message to an output device such as 90RT (not shown), so the next color sample St#Il1 is set in the color device L, and the input device 3 Enter the search code manually. Then, they are collected in the same way as before. Let's collect data one by one like this. Therefore, unlike the conventional method, there is no need to print the color sample 8 on a 41i tube for each leaf, and
Not only does it save space on the i-tube, but it's also easy to enter the search code, as it takes just a fist.

Next, in the case of a search, in this case, a search mode is designated from the input device 3, a desired search code is inputted, and the process is started. Immediately, the color of the color sample S corresponding to the search code is displayed by the arithmetic processing unit 2 on the color display 94 of the color display device 4. l! In case of inspection, visual comparison observation can be made as in the conventional method by displaying the test sample T on the display 1ii1iK4F and comparing it.

As described above, the system consisting only of the acquisition mode and the search mode, that is, the first aspect of the present invention, greatly improves the drawbacks of the conventional color tube H1p stem O, which is one-by-one.

Next, using the above-mentioned first invention, 9II! A case where an invention, that is, an inspection is included, will be explained.

In the case of solids, first, the test sample Tf, which has been collected from the product to be tested, is set in the gray color apparatus 1.

Then, specify the inspection mode from the input device 3, then input the search code of the color sample 8 to be wrinkled and, if necessary, the above-mentioned pass a discoloration difference data corresponding to the pass limit sample,
Let it start. Then, color display 1! 4b The O display screen PK is a large rectangle as shown in Figure 2, showing the color T' of the test sample T, and next to it is the standard and upper limit of passing 1.
The color S' of the 1M31 sample color 8H1 crystal standard color sample S and the color 8L of the standard shade medium lower limit pass @ direct appearance are displayed side by side. Therefore, the test sample T can be observed simultaneously with the standard color sample 8 as well as the upper and lower pass limit samples, which makes it possible to perform extremely accurate inspections and eliminate differences among inspectors.

Furthermore, since the colors are displayed under the same conditions, it is very easy to compare, and the ease of inspection is improved.

Although the present invention has been described above based on Examples, the present invention is not limited to such Examples.

A friend uses a spectrophotometric needle as a device to show the objects.
It goes without saying that the other four methods can also be applied.

Further, although the circle indicates a filter set 040 using a combination of filters as a color display device, it goes without saying that other color display devices such as color AT can also be applied. 1
However, when a display device is used, it is necessary to use a suitable color coefficient.

In other words, if the color coefficient is a combination of numerical values that can be used to reproducibly memorize the color of a sample such as a color sample, then the color coefficient can be calculated using a combination of numerical values that can be used to reproducibly memorize the color of a sample such as a color sample. It is necessary to consider the O configuration when selecting.

Also, you can display the data collection as a JI brass card, but if you collect it at the same time as the data collection and display it on the display device of the Nine Color Section 11kK, the collected data omM
, or because error correction is possible, p%m-data has a great umbrella effect on improving reimbursement.

Furthermore, as an inspection code, 40 is simply used for comparison, but when the inspection material itself is acquired as new color sample data, the color coefficients of the inspection material obtained during inspection are stored in the same way as in the acquisition mode. It is better to do this. By doing so, the acquisition work can be omitted.

Note that 9 indicates that a passing limit sample is displayed at the same time as a color sample, but the passing limit sample may be omitted depending on the case. In addition, as a method for inputting a passing AM sample, inputting color difference data from an input device has been shown, but it is also possible to collect 41L data in the same way as a color sample, or to obtain it by calculation. Saraki
The N display screen is also not limited to the one shown in the figure, and may be arbitrary, such as using a color sample as a background.

As explained above, the present invention uses a colorimeter to determine the color of the color sample, converts the wrinkle color into a coefficient that can be reproduced and displayed, and stores it in memory. All the shortcomings of the color management system were solved, and a ffi-like color management system was realized.

Moreover, since it is possible to memorize colors by converting them into numerical values,
It does not require a large-capacity storage device, and can be realized as a system using four small-scale Mitaro combinator systems, making it a very inexpensive system.

This? The present invention is very useful in color management.

[Brief explanation of the drawing]

Figure 1 is a block diagram of an embodiment of the present invention, and Figure 1 is an explanatory diagram of a picture (2) that appears on the inspection board of the embodiment. 1: 11 color storage: Computation section layer device 3: Input device 4: Color display device 8: Color sample! =Test sample

Claims (1)

[Claims] L In a color management system for storing color samples of dyed stone in a searchable manner, in order to brown the color of the color sample and convert it into an electrical signal - using a color device and a monochrome electrical signal. /II Calculation I to calculate and store the self-weight color coefficient by re-displaying the color sample O color
&mIIK, and a color display device that receives the color coefficient and reproduces and displays a color corresponding to the underarm color relationship on the display area, and stores and stores the color of the color sample as a color scheme coefficient and displays it automatically. A color management system is used to reproduce and display the 0th color of the color sample on the O display-11 on the color display device when necessary. i Zeng color scheme coefficient is white light color sample 01! The color management system according to claim 1 of the patent claim, which uses a filter coefficient to define the silver failure of the twirter for iK conversion. It is possible to store the color samples of the dye stains in a searchable manner, and to compare the colors of the test samples such as K11 products with the color samples. A color device that converts the color into an electric signal, and a scissors that receives the electric signal and converts the color again! an arithmetic processing device that calculates displayable color coefficients and stores at least the color coefficients of the color sample; and a processor that receives at least the color coefficients of each of the test sample and the color sample and displays the respective colors of the test sample and the color sample in the same manner. above? ! l
uml color display device, and is characterized in that it is possible not only to load a test sample on the one-color device but also to store and compare the nine-color sample and the test sample on one-iirm. m system. In addition to the above-mentioned color sample, the colors for the pass limit sample are also reproduced and displayed to improve the display image.
Color management system described in I-Kai 1.