KR101490333B1 - PH test device using light transmittancy - Google Patents

Abstract

The present invention relates to an apparatus and a method for measuring pH using light transmittance, and more particularly, to a method and apparatus for measuring a pH using light transmittance, The present invention relates to an apparatus and method for measuring pH using light transmittance capable of measuring and analyzing the amount of transmitted light.
The present invention relates to a method and apparatus for guiding a surrounding light source to a white light through a digital color optical sensor, and a method of measuring a pH of the white light by transmitting a part of light through the reagent, The PH information is stored in the storage unit.

Description

Technical Field [0001] The present invention relates to an apparatus and a method for measuring pH using light transmittance,

The present invention relates to an apparatus and a method for measuring pH using light transmittance, and more particularly, to a method and apparatus for measuring a pH using light transmittance, The present invention relates to an apparatus and method for measuring pH using light transmittance capable of measuring and analyzing the amount of transmitted light.

In general, the main component of a living body is an electrolytic solution, and the pH of a living body fluid is an important index that determines its biochemical characteristics.

Therefore, more precise measurement of 0.01 pH or less is desired. The logarithm of the inverse number of the hydrogen ion concentration in the solution is referred to as pH, and in the case of pure water, it is defined as 7. The acid and alkali are represented by numerical values of 0 to 14 on the basis of this.

pH is a field that is actively used in various fields such as engineering and chemistry. The acidity or basicity of a solution can be expressed as the concentration of hydrogen ions, which is called the power of the hydrogen ion.

In other words, pH is a numerical value indicating the degree of acidity and basicity of a substance, and the dissociation concentration of hydrogen ions is taken as the reciprocal of the logarithm and defined using logarithm.

The activity of hydrogen ions in aqueous solution is represented by the dissociation constant (Kw = 1.011 × 10-14) and the interaction of other ions, and the neutral aqueous solution has a pH value of 7 due to the dissociation constant.

That is, when the pH is lower than 7.0, 25 ° C is referred to as the reference temperature, it is said to be acidic.

An acid-based indicator is a substance that identifies the characteristics (acidity, neutrality, basicity) of a substance by changing its color depending on the acidity of the substance.

The range of color change of the pH indicator is limited and varies with the type of indicator. Acid-base indicators are generally large organic molecules that are themselves weak acids or weak bases, and in order for the substance to be used as an indicator, the colors of acid and base should be different. The choice of indicator depends on the pH range.

Precise measurement of pH has become a widely used field for various pH studies. Several types of pH sensors have been developed. pH measurement methods include pH indicators and pH meters using glass electrodes.

Although the pH meter is a device that accurately measures hydrogen ion concentration, the electrodes of the pH meter are very vulnerable to impact and have a disadvantage of being damaged even if hit a little. The glass electrode must be immersed in distilled water at all times so that the glass electrode is not dried.

The pH meter is not only difficult to measure but also difficult to store, and it takes much time and takes a lot of time.

In order to secure these shortcomings, other methods are being sought in Korea. One of them is a microcomputer pH measurement system, which is developed to solve the analysis error which can not be corrected simultaneously with other data by reducing the hassle of continuously recording by the human force in the measurement of the digital pH meter.

However, this method is easy to maintain accuracy, continuity, and recordability, but since it uses an analog pH meter, it is also immersed in the standard solution to make basic adjustments. Since the amplifier is amplified by using OP AMP, it is necessary to set the maximum voltage. Since the error is reduced by adjusting the amplification factor, the pH system itself uses the analog method. Therefore, the A / D conversion must be performed. There is a possibility that

Another method, the pH test paper, is paper made by infiltrating the indicator into the filter paper. When the pH test paper is immersed in the solution, the solution reacts with the indicator on the paper. Since the color after the reaction depends on the hydrogen ion concentration of the solution, The pH of the solution can be determined by observing the color change and comparing it with the standard discoloration table.

For example, if the pH test paper is cut into an appropriate length and put in and out of the solution, if the color of the part contacting with the solution changes to orange, this solution is an acidic solution of about pH 4.

If the color of the pH test strip is full, this solution is neutral. It has the advantage of simple and quick measurement of pH, but the error range of pH test paper is about 0.2 ~ 0.5 pH and its accuracy is low.

In addition, the color change of the pH test paper is more sure to be observed immediately after immersing it in the solution, and it is preferable to place the pH test paper in a place without light, which is also time-consuming and difficult to store.

Another method is to use indicators. Like the pH test paper, the pH value is measured using the principle that the color of the indicator changes in the discoloration range.

In order to distinguish the discolored color of the indicator, a method of measuring the pH using a spectrophotometric method and an equi-absorbance point is being sought. The spectrophotometric method can be measured by standard buffer method. However, since the absorbance is measured by adding the indicator accurately to the standard buffer solution, it is troublesome, and there is a high possibility that an error occurs when the standard solution and the ion intensity are different.

In addition, there is a disadvantage in that it is not easy to operate because it is necessary to measure the absorbance of the sample itself, make the sample alkaline, measure the pH after making the measurement, and then measure the absorbance of the sample itself.

However, it is necessary to keep the length of the liquid layer at the absorption wavelength constant. It is difficult to calculate the absorbance by the general public, and the absorbance is also measured by the spectrometer Expensive equipment is required using a quartz cell and the pH of the solution must be maintained at a constant ionic strength.

A common drawback of the various methods described above is that it is difficult to keep, time dependent, and difficult to calculate.

Especially, the pH meter which is the most widely used and used globally is not only time consuming to measure but also requires a lot of hands and the measurement is possible only with the standard solution. A pH measurement method using an optical method capable of precise measurement of 0.01 or less, which is easy, simple and time-wise to secure these shortcomings, is presented.

The pH indicator is the most widely used method to measure the concentration of hydrogen ions. However, it has a disadvantage in that the user's subjective measurement method is included only by eyes, and the minute discoloration range can not be measured by eyes or measurement error is large.

An indicator is a reagent used to determine a certain state in a chemical reaction. Indicators are mainly used to determine the neutralization point while titrating, or to know the concentration of hydrogen ions. Indicators are substances that show a noticeable change as the pH of the solution changes. Some of these indicators are color-coded and others are fluorescence or luminescence. In some cases, the solution becomes turbid or precipitate is formed. The most widely used of these is the indicator that changes color.

The types of indicators vary widely and vary at different points in time. The most commonly used indicator is an acid-base indicator, and the acid-base indicator has a different color depending on the pH (hydrogen ion index). Acid base indicators are themselves weak acids or weak bases. If you drop one or two drops of the weak acid indicator in the acid solution, the hydrogen attached to the indicator will not fall off.

This is because there are many hydrogen ions in the solution. However, if a small amount of a basic substance is added to this solution, the concentration of hydrogen ions in the solution will be reduced, so that the hydrogen attached to the indicator will dissociate and the number of molecules present in the ion state will increase. As the acidity of the solution changes, the number of indicator molecules that change the molecular structure increases, and when the molecular structure changes, the color of the molecule also changes.

When the RGB value is measured, it is possible to distinguish the difference of the pH value below 0.01 and to measure the pH value which changes easily by the temperature. You can also see the approximate change in wavelength by calculating the wavelength with the measured RGB values.

In order to solve the above-described problems, the present invention is characterized in that in order to transmit different amounts of light according to the color of a substance, each different indicator used in a pH measuring method is mixed in a solution, The present invention also provides an apparatus and method for measuring pH using light transmittance capable of distinguishing pH in a pH discoloration section by using a difference in degree of transmission between the pH and the pH.

The present invention is based on the principle that a color change appears in a discoloration section of a sample, and a light which does not affect the sample is irradiated, and the amount of light transmitted through the optical element is measured and analyzed to determine the pH. and an object of the present invention is to provide a pH measuring apparatus and a method thereof.

The present invention relates to a method and apparatus for guiding a surrounding light source to a white light through a digital color optical sensor, and a method of measuring a pH of the white light by transmitting a part of light through the reagent, The PH information is stored in the storage unit.

In one embodiment, the color filters mounted on the digital color photosensor are red, blue, and green color filters.

In one embodiment, the four red, green and blue color filters are arranged in an array type, and a photodiode is incorporated in the color filter.

In one embodiment, the light incident on the photodiode after passing through the Red, Green, and Blue color filters is converted into a color coordinate system to obtain wavelengths and purity values of numerical values of red, blue, and green colors analyzed .

In one embodiment, the color coordinates are transformed into the color coordinate values used in cie 1931.

In one embodiment, the Red, Blue, and Green color values are converted to cie_lab, cmy values.

In one embodiment, the Red, Blue, and Green color values are represented by values x and y calculated from two values X, Y, and Z in the CIE XYZ color space through Equation 1 to Equation 3 below.

[Equation 1]

&Quot; (2) "

&Quot; (3) "

In one embodiment, the Red, Blue, and Green color values are X, Y, and Y in the CIE xyY color space, which is a color space. .

&Quot; (4) "

&Quot; (5) "

The present invention relates to a measuring device for measuring RGB information of a color; Converting means for storing data through analog-to-digital conversion in a signal measured through the measuring means, and changing the value through a fitting to a value between 0 and 255; And CIE 1931 with the stored information to calculate coordinate values such as Lab, CMYK, RGB, XYZ, and Yxy.

In one embodiment, the dominant wavelength and purity are calculated based on the coordinate values calculated through the calculation means.

In one embodiment, RGB values of the RGB information of the color are extracted, but other external lights or light sources are blocked, only white light is injected, only the light from the used light source is detected, The color coordinate value is detected.

The present invention relates to a method and an apparatus for generating a white light by introducing a surrounding light source into a white light through a digital color light sensor; The white light passing through the reagent and partially transmitting the light; The transmitted light includes numerical values of red, blue, and green colors obtained by digitizing light incident on a photodiode through a color filter. And storing the Red, Blue, and Green color information in a storage unit.

In one embodiment, the Red, Blue, and Green color values are represented by values x, y calculated from two values X, Y, and Z in the CIE XYZ color space through Equations 1 to 3.

In an exemplary embodiment, the Red, Blue, and Green color values are X, Y, and Y in the CIE xyY color space, which is a color space. .

The present invention provides a method of measuring color information, comprising the steps of: measuring RGB information of a color through measurement means; Converting means for storing data through analog-to-digital conversion in a signal measured through the measuring means, and changing the value to a value between 0 and 255 through fitting; And calculating the coordinate values of Lab, CMYK, RGB, XYZ, and Yxy by applying the CIE 1931 with the stored information to the CIE 1931.

In one embodiment, the method further comprises calculating a dominant wavelength and a purity based on the coordinate values calculated through the calculation means.

In one embodiment, RGB values of the RGB information of the color are extracted, but other external lights or light sources are blocked, only white light is injected, only the light from the used light source is detected, And detecting a color coordinate value through the color coordinate value.

In the pH measuring method according to the present invention, the pH can be measured with only a small amount of the solution, and the pH to be analyzed can be easily measured in a non-contact manner.

Also, according to the present invention, there is an advantage that there is no loss of the sample because the analyzing method using the light amount does not affect the sample.

According to the present invention, it is possible to develop a device at a much lower price than a currently available spectrometer by using an LED and a simple optical device.

According to the present invention, the present invention can be applied to color discrimination of pH indicator, color discrimination of fruits, discrimination of skin color and discrimination of degree of skin pigmentation, which are areas where color should be judged.

According to the present invention, there is an advantage that the pH concentration of the indicator can be analyzed using a small-sized analyzer instead of an expensive analyzer such as a spectrometer or a color limiter.

According to the present invention, even minute changes can be confirmed.

According to the present invention, it is possible to obtain color coordinate values based on RGB data information and RGB data, to quantitatively judge or evaluate the pH, and to have a merit that it can be handled easily anywhere since it is small in size. And the degree of dyeing of the dye, the degree of coating, and the like can be analyzed in real time

According to the present invention, there is an advantage that the pH concentration of the indicator can be analyzed using a small-sized analyzer, not an expensive analyzer such as a spectrometer or a color limiter. It also has the advantage of being able to identify even minor changes.

According to the present invention, it is possible to obtain color coordinate values based on RGB data information and the RGB data, to quantitatively judge or evaluate the pH, and to have a merit that it can be handled easily anywhere since it is small in size. The degree of dyeing of the dyes, and the degree of coating can be analyzed in real time.

1 is a schematic diagram schematically illustrating an experimental method according to the present invention.
2 is a view showing a configuration according to the present invention.
3 is a simplified schematic diagram of a sensor used in the experiment according to the present invention.
FIG. 4 is a view schematically showing a process of converting R, G and B values obtained through the sensor according to the present invention into color coordinates in order to find wavelength and purity.
5 is a view illustrating RGB fitting steps and the like according to the present invention.
6 is a graph showing the results of phenolphthalein experiment according to the present invention.
7 is a graph showing the results of a BTB experiment according to the present invention.
8 is a graph showing the results of the methyl orange experiment according to the present invention.
9 is a graph showing a phenolphthalein test result according to the present invention.
10 is a graph showing a result of methyl orange experiment according to the present invention.
11 is a graph showing a result of a BTB experiment according to the present invention.

In the present invention, a method of measuring pH using absorption and transmission of light is presented. Experiments were carried out using a small - sized color sensor. The data were analyzed by measuring the transmittance of the light and applied to an international standard method called cie1931 to analyze the optical characteristics of the indicator using pH - dependent indicator characteristics.

As shown in FIG. 1, the present invention includes a digital color light sensor 10 for guiding an ambient light source to a white light source 18, a white light source 18 for transmitting a part of light through a reagent, The light is incident on the photodiode 34 through the color filter 16 of the PH liquid solution 14 in the cuvette to measure the pH and the PH information is stored in the storage unit of the computer 20, Is displayed.

That is, as shown in FIG. 2, in the present invention, firstly, the white LED 31 is turned on by the PH indicator 32, the color filter device 33, the photodiode 34, the A / D converter 35, Is transmitted and stored.

Specifically, an experiment according to an embodiment of the present invention analyzes red, green, and blue light signals by analyzing optical characteristics by adding an indicator to a pH solution, and detects the color coordinates by applying the red, green, and blue light signals to 1931, And the purity was detected.

The pH measurement method using the optical method described herein is a method of accurately expressing the pH value by the color change indicated by putting a specific indicator into a solution of an unknown pH value, which is stored in a storage section.

Table 1 shows the kinds of indicators used in the experiment according to one embodiment of the present invention. Indicators used three representative indicators with varying ranges of acidity, neutrality, and basicity.

Methyl orange indicator with basal discoloration range, BTB indicator with discoloration range near neutral, and phenolphthalein indicator with acid discoloration range were used. The indicator has its own acidity. Also, there is a distinctive color change in the discoloration range.

The indicators used were phenolphthalein, methyl orange, BTB and solution. First, phenolphthalein solution is an indicator to distinguish acid and base. It is colorless in acidic solution and is used in acid / base titration because it is red in basic solution of pH 9 or more. The triphenylmethyl-based materials containing phenolphthalein are generally colorless when they are bonded to four atoms having different carbon atoms (acid forming), and when the basic molecule OH- is added to this indicator, it is combined with H + contained in phenolphthalein H2O is formed and combined with the other three atoms, and the molecule changes to a planar structure. In this case (base molding), it is reddish.

The methyl orange used next is the acid base indicator which represents azo dye together with methyl red. Methyl orange is one of the azo dyes having a yellow azo group (-N═N-). In the basic solution, the azo group is maintained, but the structure changes as the hydrogen ion stuck in the acid solution. The material of the changed structure is red, so it becomes yellow in the basic solution, and becomes red when the acidity of the solution becomes stronger. More precisely, it has a color change range of pH 3.1-4.4, a red color at pH 3.1 and a yellow color at pH higher than 4.4.

The last used BTB solution [bromothymol blue] is an indicator that shows different colors in acidity, neutrality, and basicity. It is mainly used to confirm neutralization titration or photosynthetic reaction. The discoloration range is from pH 6 to pH 7.6. When the BTB solution is added to the neutral solution, the solution turns green. If the hydrogen ion is added to this solution as in the above indicator, the molecular structure changes and the color becomes yellow. When the basic solution comes in, the blue color appears.

The present invention has been made to solve the above-mentioned problems. This method can detect the change of the amount of very small sample by observing the light transmittance by the color change of the reagent. The present invention has the advantage of being non-contact and capable of detecting a specific wavelength while measuring the pH. This method measures the color change of the pH solution. This is because the light incident on the solution absorbs and diffuses light depending on the color of the solution, which changes the degree of the absorbed light. In this case, after passing through the red, green, and blue color filters having different transmission wavelengths, the light incident on the photodiode is digitized and analyzed.

The present invention relates to a system that can be measured in an objective and quantitative manner using an optical method in measuring information on pH. In addition, our goal is to quantitatively identify RGB color information. Based on the measured RGB information, it can be applied to cie1931 to find the wavelength and purity value for each indicator. The color information measuring device uses white light including light of all colors as a light source, and after the light of the light source passes through the color filter, three different colors passing through the filter are incident on the photodiode and analyzed.

The light emitted from the white light passes through the reagent, absorbs part of it according to the optical properties of the reagent, and partially transmits the light, which is transmitted through the photodiode. The A / D conversion of each light of different colors incident on the photodiode is performed to acquire data and analyze it to detect color information and color. It is a suggestion of analyzing information about color by obtaining RGB value and quantitatively analyzing the change of color such as pH in real time.

Returning to the beginning, Figure 1 is a schematic drawing of the experimental method. The sensor used in the experiment is designed to accurately induce color with a digital color photosensor 10 named tcs3414 (TAOS). The light source around the sensor is led to white light. White light passes through the reagent and some light is transmitted. The transmitted light passes through the color filter and enters the photodiode.

3 is a simplified schematic diagram of the sensor used in the experiment. The color filter mounted on the sensor is schematically shown with a color filter 16 of Red, Blue, and Green mounted thereon and schematically showing the experimental method. The sensors used in the experiment are array type with four red, green, and blue color filters (16), respectively, and each has a built-in PhotoDiode in the filter. The light source around the sensor is led to white light. White light passes through the reagent and some light is transmitted. The transmitted light passes through the color filter and enters the photodiode.

FIG. 4 is a view showing a process of converting R, G, and B values obtained through a sensor into color coordinates in order to find wavelength and purity. The obtained R, G, and B values are converted into the color coordinate values used in the cie 1931 (CIE 1931 standard colorimetric system). x, y, z, X, Y, Z, and so on. Also, it can be converted to cie_lab, cmy values, etc., and other color coordinate values other than R, G, B and Yxy color coordinates can be obtained and color information can be analyzed using other methods. Each color coordinate also has a different value. The capital letters X, Y, and Z represent approximate RGB values, and CMY is the value of cyan, magenta, and yellow. In particular, Yxy finds the color coordinates and applies it to cie1931 to detect the wavelength and purity of the color.

The CIE 1931 XYZ color space (or CIE 1931 color space) is one of the first mathematically defined color spaces based on studies of human color perception. The International Commission on Illumination (CIE) was enacted in 1931. Color space refers to a mathematical model that associates each of these three stimulus values with their respective colors. Among the various color spaces, CIE XYZ is a special color space that is fundamental to making such a color space because it is made by directly measuring human color perception. The color space represented by x, y, and Y is called the CIE xyY color space, and is often used for displaying colors.

4 is a chromaticity distribution chart of the CIE 1931 color space drawn using x and y variables. The curved boundary line of the outline corresponds to monochromatic light, and the wavelength of each monochromatic light is indicated by the nanometer. Note that the chromaticity distribution table is a table showing how the human eye responds to light with a particular wavelength and is not a means of directly representing the color of an object. This is because the color of the light source also affects the color of the object visible to the human eye. The chromaticity distribution table shows some interesting features of the CIE XYZ color space. The chromaticity distribution table represents all the colors seen in the average human eye. Therefore, Fig. 4 can be said to represent all the gums that are visible to human beings. The outer curve boundary is called the spectral location and corresponds to the color of monochromatic light. The bottom straight line is called the purple line. The color corresponding to this line is in the boundary position, but it can not be expressed by monochromatic light. The less saturated color is in the middle region, and there is white in the middle.

All colors in the visible light can be represented as positive x, y, z values. (And thus can also be represented by X, Y, Z values). If you randomly draw two points in this chart, all the colors that can be represented by mixing the two colors are on a straight line connecting the two points. In addition, all colors that can be represented by mixing three colors are in triangles of three points. (The same is true for multiple colors.) A color created by mixing two colors with the same amount is not in the middle of the two points. In other words, the distance on the xy color chart does not match the difference between the two colors. The color space in which the distance on the color space immediately indicates the color difference is the CIE L * u * v * (1960) color space or the CIE L * a * b * (1976) color space created later.

As can be deduced from the curvilinear space, there is no way to represent all the gums that can be seen by humans by mixing the three colors. This is because human vision is not a triangle. White exists at (x, y) = (1/3, 1/3) point.

Since the human eye has three color receptors, the distribution of all the visible light rays becomes a three-dimensional figure. However, the color can be divided into two elements, brightness and chromaticity. For example, white can be a light color, and gray can be represented in a darker form of the same white. White and gray have different brightness but the same color.

The CIE XYZ color space is designed such that the Y value is a value of brightness or illuminance. Therefore, as shown in the following equations (1) to (3), the chromaticity of a certain color can be expressed by the values x and y calculated from the two values X, Y, and Z.

The color space represented by x, y, and Y is the CIE xyY color space, and is often used for displaying colors. It is also possible to recalculate X and Z from x and y as shown in equations 4 and 5 below.

The present invention is a device having a purpose of transmitting information of pH by transmitting light. The device is intended to determine the characteristics of the color information of the indicator in an objective and quantified manner. In the case of additive mixing, RGB is composed, and when mixing amounts such as RGB, it becomes white according to the principle of additive mixing. According to the principle of additive mixing, all colors are composed of RGB, and all objects having a color are composed of a combination of RGB.

The present invention has the advantage that there are fewer restrictions than the above-mentioned devices. The apparatus is relatively small in size, and the apparatus is relatively simple since a prism or a diffraction grating is not inserted, and a separate image processor is not required, so that an image processing apparatus is not required.

According to an aspect of the present invention, there is provided an apparatus for measuring color information, comprising: measuring means for measuring RGB information of a color in analyzing color information; Conversion means for storing data through analog-to-digital conversion in a signal measured through the measurement means and changing the value to a value between 0 and 255 through fitting; and CIE 1931 for applying the stored information to Lab, CMYK, RGB , XYZ, Yxy, and the like. Further, the present invention aims to calculate the dominant wavelength based on the coordinate value calculated through the calculation means, and to find the purity.

In the system of the present invention, RGB values of color information are extracted, but other external lights or lights by the light source are completely blocked and only white light is injected, so that only the light in the used light source is detected, And detects a color coordinate value.

Therefore, phenolphthalein test results, BTB test results, methyl orange test results, phenolphthalein test results, methyl orange test results, and BTB test results are shown in FIGS. 6 to 11 through RGB fitting steps according to the present invention of FIG. The usefulness can be confirmed through the graph.

Hereinafter, the analysis method according to the present invention will be described.

The present invention relates to a method and an apparatus for generating a white light by introducing a surrounding light source into a white light through a digital color light sensor; The white light passing through the reagent and partially transmitting the light; The transmitted light includes numerical values of red, blue, and green colors obtained by digitizing light incident on a photodiode through a color filter. And storing the Red, Blue, and Green color information in a storage unit.

In one embodiment, the Red, Blue, and Green color values are represented by values x, y calculated from two values X, Y, and Z in the CIE XYZ color space through Equations 1 to 3.

In an exemplary embodiment, the Red, Blue, and Green color values are X, Y, and Y in the CIE xyY color space, which is a color space. .

The present invention provides a method of measuring color information, comprising the steps of: measuring RGB information of a color through measurement means; Converting means for storing data through analog-to-digital conversion in a signal measured through the measuring means, and changing the value to a value between 0 and 255 through fitting; And calculating the coordinate values of Lab, CMYK, RGB, XYZ, and Yxy by applying the CIE 1931 with the stored information to the CIE 1931.

In one embodiment, the method further comprises calculating a dominant wavelength and a purity based on the coordinate values calculated through the calculation means.

In one embodiment, RGB values of the RGB information of the color are extracted, but other external lights or light sources are blocked, only white light is injected, only the light from the used light source is detected, And detecting a color coordinate value through the color coordinate value.

10: Digital color light sensor
12: Cuvette
14: PH Liquid Solution
16: Color filter
18: White light source
34: Photo diode
20: Computer
31: white LED
32: PH indicator
33: Color filter device
34: Photo diode
35: A / D converter
36: Detector

Claims (17)

A part of the white light emitted from the white light source passes through the reagent while the outside light or the light from the light source is blocked and the transmitted light passes through the color filter and enters the photodiode, And the pH information is stored in the storage unit,
Wherein the color filter is a color filter of Red, Blue, and Green, the four red, green, and blue color filters are arranged in an array type, a photodiode is disposed under the color filter, , And a blue color filter to convert the light incident on the photodiode to a color coordinate to find the wavelength and purity of the red, blue, Measuring device. delete delete delete The method according to claim 1,
Wherein the color coordinate is converted into a color coordinate value used in cie1931. The method according to claim 1,
Wherein the red, blue, and green color values are converted into cie_lab, cmy values. The method according to claim 1,
Wherein the red, blue and green color values are represented by values x and y calculated from two values X, Y and Z in the CIE XYZ color space by the following Equations (1) to (3) .
[Equation 1]

&Quot; (2) "

&Quot; (3) "

The method according to claim 1,
And X and Z are calculated from x and y through the following equations (4) and (5) in the CIE xyY color space where the Red, Blue, and Green color values are represented by x, y, PH measurement device using light transmittance.
&Quot; (4) "

&Quot; (5) "

delete delete delete Emitting white light from a white light source;
The white light passing through the reagent and partially transmitting the light;
The transmitted light passes through a color filter arranged in array type with four red, green, and blue colors, enters a photodiode under the color filter, converts red, green, and blue colors into red, Blue, Green Steps to represent the color in numerical order:
Converting the red, blue, and green colors into color coordinates to find the wavelength and purity of the numerical value;
Storing the Red, Blue, and Green color information in a storage unit;
And measuring the pH of the solution using the light transmittance. 13. The method of claim 12,
Wherein the red, blue and green color values are represented by values x and y calculated from two values X, Y and Z in the CIE XYZ color space by the following Equations (1) to (3) .
[Equation 1]

&Quot; (2) "

&Quot; (3) "

13. The method of claim 12,
And X and Z are calculated from x and y through the following equations (4) and (5) in the CIE xyY color space where the Red, Blue, and Green color values are represented by x, y, Measurement method of pH using light transmittance.
&Quot; (4) "

&Quot; (5) "

delete delete delete

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