KR20200025687A - System and method for measuring environmental pollutants or disease tracers using smart device - Google Patents

Abstract

According to the present invention, a system and a method for measuring environmental pollutants or disease tracers using a smart device can conveniently measure environmental pollutants or disease tracers at a site by a colorimetric analysis method using a portable smart device by photographing a material to be analyzed and extracting colors by the smart device to compare and analyze the extracted colors of the material to be analyzed and colors of standard samples. Also, according to the present invention, the system and the method for measuring the environmental pollutants or disease tracers using the smart device can measure the concentrations of environmental pollutants or disease tracers by matching concentrations and colors of a first state and a second state of the standard samples by the smart device to set color changes in accordance with changes in concentration of the standard sample and allow extracted colors of a material to be analyzed to correspond to the aspects of the set changes in concentration of the standard samples.

Description

System and method for measuring environmental pollutants or disease markers using smart devices {SYSTEM AND METHOD FOR MEASURING ENVIRONMENTAL POLLUTANTS OR DISEASE TRACERS USING SMART DEVICE}

The present invention relates to a system and method for measuring environmental pollutants or disease markers, and more particularly, to a system and method for measuring environmental pollutants or disease markers using smart devices.

Colorimetric analysis is an assay that quantifies a substance by comparing its color, concentration and hue with a standard. Colorimetric analysis may use solid or gaseous coloring, but generally a solution is used. Specifically, there are a method of comparing the concentration of the solution color, a method of comparing the color tone of the solution, photoelectric colorimetric analysis to electrically compare the amount of light.

First, in the method of comparing the concentration of the color of the solution, using a colorimeter, the concentration of the substance is calculated by calculating the point where the concentration of the color is the same as the standard solution by adjusting the liquid layer of the solution. As a standard material, a solution having a known concentration is used as the substance to be detected. When standard chemicals are easily changed or discolored, alternative standards such as colored glass or colored paper may be used.

In addition, by comparing the color tone of the solution, various standard solutions of known concentration are placed side by side, and among them, the most similar to the sample is found. The above is a method of comparing with the naked eye, and there are other photoelectric colorimetric methods in which the amount of light to be measured is compared with an electrical signal. This is a quantitative analysis by measuring the absorbance of light of a specific wavelength by various photochromic colorimeters and comparing it with the absorbance of a standard solution.

That is, the colorimetric analysis method is a comparative analysis based on the color of the material to be compared, it is analyzed directly with the naked eye, or using an analysis equipment that can perform colorimetric analysis. In the method of comparing and determining with the naked eye of the user, the result of the determination is influenced by the visual difference and the proficiency of the individual's color recognition, and there is a problem that the fine density is difficult to determine and an error may occur. Therefore, when a high degree of accuracy of the results is required, various colorimetric analyzers are used.

However, since such a colorimetric analysis equipment is expensive equipment, it requires additional cost burden on the user, and also has a disadvantage in that the place of use is limited due to lack of portability. In addition, the colorimetric analysis device may be used only by a user who has been trained more than a predetermined precision analysis device, there is a lack of ease of use, there is also a problem that the general public cannot easily use. Therefore, the advantages of colorimetric analysis are easy and economical barriers to obtaining results.

Meanwhile, with the recent rapid development and dissemination of smart devices, modern people show characteristics of personalization and self-management. With increasing interest in health, there is a growing demand for individuals to directly measure environmental pollutants or disease markers, such as the purchase and use of fine dust detectors and radiometers.

As the prior art related to the present invention, Korean Patent Publication No. 10-2009-0049355 (name of the invention: a measuring device for analyzing a biological material using a colorimetric method, publication date: May 18, 2009), Korean Patent Publication No. 10-2009-0038476 (Inventive Name: Colorimetric Titration Measurement System and Method, Publication Date: April 20, 2009).

The present invention has been proposed to solve the above problems of the conventionally proposed methods, the smart device photographs the material to be analyzed and extracts the color, and compares the color of the extracted analysis material and the color of the standard sample Therefore, to provide a system and method for measuring environmental pollutants or disease markers using smart devices, which can conveniently measure environmental pollutants or disease markers by colorimetric analysis in the field using portable smart devices. do.

In addition, the present invention, the smart device matches the density and the color of the first state and the second state of the standard sample, respectively, to set the color change in accordance with the change in the concentration of the standard sample, and set the color of the extracted analysis target material It is another object of the present invention to provide a system and method for measuring environmental pollutants or disease markers using smart devices that can measure concentrations of environmental pollutants or disease markers in response to changes in concentrations of standard samples.

Measurement system of environmental pollutants or disease markers using a smart device according to the characteristics of the present invention for achieving the above object,

As a measuring system,

A colorimetric method that compares the color of a standard sample with the analyte, and includes smart devices for measuring environmental pollutants or disease markers.

The smart device,

An imaging module for photographing the analysis target material;

A color extraction module which processes the image photographed by the photographing module and extracts a color of the analysis target material; And

It comprises a colorimetric analysis module for comparing and analyzing the color extracted from the color extraction module with the color of the standard sample.

Preferably,

The photographing module displays a color detection area on a driving screen of the smart device,

The color extraction module may extract a color of the color detection area.

Preferably, the color extraction module,

The color of the material to be analyzed may be extracted as an RGB value.

Preferably, the colorimetric analysis module,

The R value of the standard sample may be compared with the R value of the analyte.

Preferably,

The photographing module photographs the standard sample,

The color extraction module extracts the color of the standard sample,

The apparatus may further include a standard sample setting module for setting a color of the extracted standard sample.

More preferably,

Further comprising an input module for receiving the concentration of the standard sample,

The standard sample setting module is set by matching the concentration of the input standard sample and the color of the extracted standard sample,

The colorimetric analysis module may analyze the concentration of environmental pollutants or disease markers through color comparison.

Even more preferably,

The input module receives the first concentration and the second concentration of the standard sample,

The photographing module photographs a first state and a second state of the standard sample,

The color extraction module may extract a first color by processing an image photographing the first state of the standard sample, and extract a second color by processing an image photographing the second state of the standard sample.

Even more preferably, the standard sample setting module,

The first color and the second color extracted with respect to the standard sample may be matched with the first density and the second density, respectively, to set the color change according to the concentration change.

Even more preferably, the standard sample setting module,

The color change according to the change of the concentration of the standard sample may be set using the first color, the first density, the second color, and the second density on a two-dimensional plane having color as one axis and density as another axis. .

Even more preferably, the standard sample setting module,

The color change according to the concentration change may be set as a linear function.

Method for measuring environmental pollutants or disease markers using a smart device according to the characteristics of the present invention for achieving the above object,

As a measuring method,

Smart devices that measure environmental pollutants or disease markers using colorimetric methods that compare the color of analyte with a standard sample,

(2) collecting an image of the analysis target material photographed by a photographing module;

(3) extracting a color of the analysis target material by processing the collected image; And

(4) characterized in that it comprises the step of comparing the color extracted in the step (3) with the color of the standard sample.

Preferably, the smart device,

Displaying a color detection area on a driving screen of the imaging module;

In the step (3), it is possible to extract the color of the color detection area from the collected image.

Preferably, in step (3),

The color of the material to be analyzed may be extracted as an RGB value.

Preferably, in step (4),

The R value of the standard sample may be compared with the R value of the analyte.

Preferably, before step (4),

(1) The method may further include setting a color of the standard sample.

More preferably, the step (1) is,

(1-1) setting a first state of the standard sample;

(1-2) setting a second state of the standard sample; And

(1-3) using the first state and the second state of the standard sample may include setting the color change according to the change in concentration of the standard sample.

Even more preferably, the step (1-1) is

(1-1-1) receiving a first concentration which is a concentration of a first state of the standard sample;

(1-1-2) collecting an image photographing a first state of the standard sample photographed by the photographing module; And

(1-1-3) extracting a first color by processing an image photographing the first state of the standard sample,

Step (1-2),

(1-2-1) receiving a second concentration which is a concentration of a second state of the standard sample;

(1-2-2) collecting an image photographing a second state of the standard sample photographed by the photographing module; And

(1-2-3) extracting a second color by processing an image photographing the second state of the standard sample.

Even more preferably, in the step (1-3),

The first color and the second color extracted with respect to the standard sample may be matched with the first density and the second density, respectively, to set the color change according to the concentration change.

Even more preferably, in the step (1-3),

The color change according to the change of the concentration of the standard sample may be set using the first color, the first density, the second color, and the second density on a two-dimensional plane having color as one axis and density as another axis. .

Even more preferably, in the step (1-3),

The color change according to the concentration change may be set as a linear function.

According to the measurement system and method of environmental pollutants or disease markers using the smart device proposed in the present invention, the smart device photographs the material to be analyzed and extracts the color, the color of the extracted analysis target material and the color of the standard sample By comparative analysis, environmental pollutants or disease markers can be measured by colorimetric method conveniently in the field using portable smart device.

In addition, according to the measurement system and method of the environmental pollutant or disease marker using the smart device proposed in the present invention, the smart device matches the concentration and color of the first state and the second state of the standard sample, respectively, The color change according to the change in the concentration of, and the concentration of the environmental pollutant or the disease marker can be measured in response to the concentration change pattern of the set standard sample color of the extracted analysis target material.

1 is a view showing the configuration of a measurement system of environmental pollutants or disease markers using a smart device according to an embodiment of the present invention.
2 is a diagram illustrating colorimetric analysis.
3 is a view showing a detailed configuration of a smart device in the measurement system of environmental pollutants or disease markers using the smart device according to an embodiment of the present invention.
4 is a view illustrating an example of a screen of a smart device on which an imaging module is driven in a measurement system of environmental pollutant or disease marker using a smart device according to an embodiment of the present invention.
5 is a view illustrating an example of a screen of a smart device displaying a color extraction result in a measurement system of an environmental pollutant or disease marker using a smart device according to an embodiment of the present invention.
6 is a view illustrating a color change according to a change in concentration of a standard sample set in a standard sample setting module in a measurement system of an environmental pollutant or disease marker using a smart device according to an embodiment of the present invention.
7 is a view showing a flow of a method for measuring environmental pollutants or disease markers using a smart device according to an embodiment of the present invention.
8 is a view showing a detailed flow of step S100 in the method for measuring environmental pollutants or disease markers using a smart device according to an embodiment of the present invention.
9 is a view showing the detailed flow of step S110 in the method for measuring environmental pollutants or disease markers using a smart device according to an embodiment of the present invention.
10 is a view showing a detailed flow of step S120 in the method for measuring environmental pollutants or disease markers using a smart device according to an embodiment of the present invention.
11 is a view taken of seven samples of different BPA concentrations.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. However, in describing the preferred embodiment of the present invention in detail, if it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, the same reference numerals are used throughout the drawings for parts having similar functions and functions.

In addition, throughout the specification, when a part is 'connected' to another part, it is not only 'directly connected' but also 'indirectly connected' with another element in between. Include. In addition, the term 'comprising' a certain component means that the component may further include other components, not to exclude other components unless specifically stated otherwise.

1 is a view showing the configuration of a measurement system of environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention. As shown in FIG. 1, the measurement system of an environmental pollutant or disease marker using the smart device 100 according to an embodiment of the present invention may include a smart device 100 and a server 200. It may be configured to include more.

That is, in the present invention, the smart device 100 captures an analysis target material and extracts a color to compare and analyze the color of the extracted analysis target material and the color of a standard sample, thereby using the portable smart device 100. Conveniently on site, colorimetric analysis can be used to measure environmental contaminants or disease markers. According to an exemplary embodiment, when much data processing is required for image processing or colorimetric analysis, the smart device 100 may communicate with the server 200 through a network.

The network may be a wired network such as a local area network (LAN), a wide area network (WAN), or a value added network (VAN), a mobile radio network, a satellite network, It may include all kinds of wireless networks such as Wireless Broadband Internet (WIBRO), High Speed Downlink Packet Access (HSDPA), and the like.

The smart device 100 may measure environmental pollutants or disease markers by colorimetric analysis that compares the color of the standard sample and the analyte. Here, the smart device 100 may be a portable device such as a smart phone, a tablet PC, a smart glass, a smart watch, and the like. In addition, the smart device 100 may be installed and run an application for the implementation of the system and method for measuring environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention. In this case, the application may be software that is custom developed according to the form or operating system of the smart device 100, and in some embodiments, may be provided as a software as a service (SaaS). Detailed configuration of the smart device 100 will be described in detail later with reference to FIG. 3.

The server 200 may allow connection of the smart device 100 through a network, and transmit and receive various signals and data to enable measurement of environmental pollutants or disease markers. In particular, when a large amount of information processing is required by allowing the process to be processed through the server 200, it is possible to enable smooth processing, and may provide software in the form of SaaS to the connected smart device 100.

2 is a diagram illustrating colorimetric analysis. As shown in A of FIG. 2, the AuNP solution has a reddish color of gold nano and then changes to a blue color when it meets NaCl solution. As shown in FIG. 2B, when the aptamer solution is mixed with gold nanoparticles, the aptamer does not change to a blue-based color even when the aptamer meets the NaCl solution. Using this property, as shown in C of FIG. 2, after mixing the analyte to be measured and the aptamer, and then mixing the gold nano, NaCl according to the extent to which the remaining aptamer is combined with the gold nano, The extent to which the manna changes to blue varies, so the concentration of the analyte can be measured.

In the present invention, by using the principle of the colorimetric analysis method, by extracting and analyzing the color of the solution, it is possible to measure the concentration of environmental pollutants or disease markers included in the analyte.

3 is a diagram showing the detailed configuration of the smart device 100 in the measurement system of environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention. As shown in FIG. 3, the smart device 100 of the measurement system of an environmental pollutant or disease marker using the smart device 100 according to an embodiment of the present invention includes a photographing module 120 and a color extraction module ( 130) and a colorimetric analysis module 150, and may further include an input module 110 and a standard sample setting module 140.

The input module 110 may receive a concentration of a standard sample. That is, the concentration of the standard sample having known concentration may be input through the input module 110. The input module 110 may display a concentration input popup on the screen of the smart device 100 to request concentration input of a standard sample, and receive the concentration at a specific value through a keypad or a microphone.

The imaging module 120 may photograph an analysis target material. The photographing module 120 may be implemented as a camera provided in the smart device 100, and automatically recognizes the lighting conditions of the surroundings, and adjusts the image to an optimal brightness to increase color extraction performance of the analyte. Can be obtained. In addition, according to an embodiment, a specific filter may be used to photograph an analyte.

On the other hand, the photographing module 120 may display a color detection area on the driving screen of the smart device 100. Since the image photographed by the photographing module 120 may include various images, the color detection region may be displayed to accurately capture the analysis target material in the color detection region.

4 illustrates an example of a screen of the smart device 100 in which the photographing module 120 is driven in the measurement system of an environmental pollutant or disease marker using the smart device 100 according to an embodiment of the present invention. Drawing. As shown in Figure 4, in the measurement system of environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention, the screen of the screen of the smart device 100, the imaging module 120 is driven The color detection area can be indicated by a green circle in the center. The user may take a picture by adjusting the material to be analyzed in the color detection area by using the smart device 100.

The color extraction module 130 may extract the color of the analysis target material by processing the image photographed by the photographing module 120. In particular, the color extraction module 130 may extract the color of the color detection area. That is, as shown in FIG. 4, the color of the portion corresponding to the color detection region may be extracted from the plurality of test tube images included in the captured image. Meanwhile, the color extraction module 130 may extract a color of an analysis target material as an RGB value, and in some embodiments, may extract the color as a CMYK value.

5 is a diagram illustrating a screen of the smart device 100 displaying the color extraction result in the measurement system of environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention. As shown in Figure 5, in the measurement system of environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention, the color extracted module 130 extracts the color R, G, Each can be represented by a B value and the color can be charted. On the screen as shown in FIG. 5, the extracted color values and charts may be checked using the smart device 100 and may be retaken.

In addition, according to the embodiment, the color extraction module 130 of the measurement system of environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention, the image captured by the imaging module 120 Image processing tools such as noise removal, adjustment of brightness or saturation, etc. can be used. By using such an image processing tool, accurate color may be derived from an image.

On the other hand, when extracting the color of the analysis target material through the image processing, it is possible to accurately extract the color using a pre-trained artificial neural network. In this case, a deep neural network (DNN), a convolutional neural network (CNN), a recurrent neural network (RNN), or the like may be used as the artificial neural network to be used.

The standard sample setting module 140 may set the color of the extracted standard sample. In this case, the photographing module 120 photographs the standard sample, the color extraction module 130 extracts the color of the standard sample, and the standard sample setting module 140 extracts the color of the standard sample extracted by the color extraction module 130. Can be set. That is, the photographing module 120 and the color extracting module 130 may photograph and color extract the standard sample in addition to the analyte. In this case, the standard sample setting module 140 may set the color extracted from the image of the standard sample photographed in the same environment in which the analysis target material is photographed, so that an accurate colorimetric analysis result may be derived.

On the other hand, the standard sample setting module 140 may be set by matching the concentration of the input standard sample and the color of the extracted standard sample. More specifically, the input module 110 receives the first and second concentrations of the standard sample, the photographing module 120 captures the first and second states of the standard sample, and the color extraction module 130. ) May extract a first color by processing an image photographing the first state of the standard sample, and extract a second color by processing the image photographing the second state of the standard sample. The standard sample setting module 140 may match the first color and the second color extracted with respect to the standard sample with the first density and the second density, respectively, and set the color change according to the concentration change.

That is, the concentration (first density) of the initial state (first state) of the standard sample is input through the input module 110, and the first color is taken by the photographing module 120 to extract the first color. The initial state can be set. Next, the concentration of the final state (second state) of the standard sample (second concentration) is input through the input module 110, and the photographing module 120 captures the standard state of the final state to capture the second color. You can extract and set the final state.

The standard sample setting module 140 uses the first color, the first density, and the second color and the second concentration on a two-dimensional plane having color as one axis and density as another axis, to change the concentration of the standard sample. You can set the color change accordingly. In this case, the standard sample setting module 140 may set the color change according to the change in density as a linear function.

6 is a color change according to a change in concentration of a standard sample set in the standard sample setting module 140 of the environmental pollutant or disease marker measurement system using the smart device 100 according to an embodiment of the present invention. The figure is shown. As shown in FIG. 6, the standard sample setting module 140 of the measurement system of an environmental pollutant or disease marker using the smart device 100 according to an embodiment of the present invention, the X-axis concentration, Y-axis color After displaying the first state and the second state of the standard sample on a two-dimensional plane, a calibration curve may be set. That is, the first state and the second state are connected by a linear function to set a calibration curve, that is, a color change according to a change in density.

In particular, in the measurement system of environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention, since the colorimetric analysis using the characteristics of gold nano as shown in Figure 2, gold nano Using the red color of the standard sample setting module 140 may set the color change to the R value of the RGB value. In FIG. 6, the R value increases linearly as the concentration increases.

The colorimetric analysis module 150 may compare and analyze the color extracted by the color extraction module 130 with the color of the standard sample. More specifically, the colorimetric analysis module 150 may compare and analyze the R value of the standard sample and the R value of the analyte using the R value among the extracted RGB values. That is, in the graph as shown in Figure 6, knowing the RGB value of the color of the material to be analyzed can know the concentration. Using the function set by the standard sample setting module 140 as described above, the colorimetric analysis module 150 may analyze the concentration of environmental pollutants or disease markers through color comparison.

7 is a flowchart illustrating a method of measuring environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention. As shown in FIG. 7, in the method for measuring environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present disclosure, the method may include collecting an image of an analysis target material (S200). Extracting the color of the analysis target material by processing the extracted image (S300) and comparing and analyzing the extracted color with the color of the standard sample (S400), and setting the color of the standard sample. It may be implemented to further include (S100).

In step S100, the smart device 100 may set the color of the standard sample. The detailed flow of step S100 will be described in detail later with reference to FIG. 8.

In operation S200, the smart device 100 may collect an image of the analysis target material photographed by the photographing module 120. The smart device 100 may display the color detection area on the driving screen of the photographing module 120.

In operation S300, the smart device 100 may process the collected image to extract a color of the analysis target material. In particular, in operation S300, the color of the color detection region may be extracted from the collected image. In operation S300, the color of the material to be analyzed may be extracted as an RGB value. In this case, step S300 may be processed by the color extraction module 130 of the smart device 100.

In step S400, the smart device 100 may compare and analyze the color extracted in step S300 with the color of the standard sample. More specifically, in step S400, the R value of the standard sample and the R value of the analyte may be compared and analyzed using the R value among the extracted RGB values. In this case, step S400 may be processed by the colorimetric analysis module 150 of the smart device 100.

8 is a diagram illustrating a detailed flow of step S100 in the method for measuring environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention. As shown in Figure 8, step S100 of the method for measuring environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention, setting a first state of the standard sample (S110) It may be implemented, including the step of setting a second state of the standard sample (S120) and the step of setting a color change according to the change of the concentration of the standard sample by using the first state and the second state of the standard sample (S130). .

In operation S110, the smart device 100 may set a first state of the standard sample. That is, after driving the application in the smart device 100 may set the first state of the standard sample. 9 is a diagram illustrating a detailed flow of step S110 in the method for measuring environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention. As shown in Figure 9, step S110 of the method for measuring environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention, the step of receiving a first concentration of the standard sample (S111) It may be implemented, including the step (S112) of collecting a photographed image of the first state of the standard sample and the step of extracting the first color of the standard sample (S113).

That is, the first module receives the first concentration, which is the concentration of the first state of the standard sample, through the input module 110 (step S111), and collects an image of the first state of the standard sample photographed by the photographing module 120. Next (step S112), the color extraction module 130 may extract the first color by processing an image photographing the first state of the standard sample (step S113). By this flow, concentration and color information of the first state of the standard sample can be obtained.

In operation S120, the smart device 100 may set a second state of the standard sample. 10 is a diagram illustrating a detailed flow of step S120 in the method for measuring environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention. As shown in Figure 10, step S120 of the method for measuring environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention, the step of receiving a second concentration of the standard sample (S121) It may be implemented, including the step (S122) of collecting a photographed image of the second state of the standard sample and the step (S123) of extracting the second color of the standard sample.

That is, a second concentration, which is a concentration of the second state of the standard sample, is input through the input module 110 (step S121), and an image of photographing the second state of the standard sample photographed by the photographing module 120 is collected. Next (step S122), the color extraction module 130 may process the image photographing the second state of the standard sample to extract the second color (step S123). By such a flow, concentration and color information of the second state of the standard sample can be obtained.

In operation S130, the smart device 100 may set the color change according to the change in concentration of the standard sample by using the first state and the second state of the standard sample. More specifically, in step S130, the first color and the second color extracted with respect to the standard sample may be matched with the first density and the second density, respectively, to set the color change according to the concentration change. Step S130 may be processed by the standard sample setting module 140 of the smart device 100.

Further, in step S130, the color change according to the change in the concentration of the standard sample using the first color, the first density, the second color, and the second density in a two-dimensional plane having the color as one axis and the density as another axis. Can be set. In particular, in step S130, as shown in FIG. 6, the color change according to the change in density may be set as a linear function.

Experimental Example

50 μl of 7 samples each having bisphenol A (BPA) concentrations of 0, 1, 10, 100, 1000, 10000, and 100000 ng / ml were prepared, and the BPA aptamer was 0.1 μM (50 each). Μl), AuNP was performed using 254 μM (stock concentration, 100 μl each), NaCl 0.5 M (50 μl each), and the final reaction time was 7 minutes.

FIG. 11 is a diagram illustrating seven samples having different BPA concentrations. That is, the sample which taken the density | concentration of BPA from 0, 1, 10, 100, 1000, 10000, and 100000 ng / ml respectively from the left side is image | photographed. Although there are differences in color, it is difficult to see the clear differences with the naked eye.

In the smart device 100 in which the measurement system and method for measuring environmental pollutants or disease markers using the smart device 100 according to an embodiment of the present invention is implemented, an application developed for Android is executed and the concentration of BPA is increased. The sample was set to 0 as the first state of the standard sample and the sample at which the concentration of BPA was set to 100000 ng / ml was set as the second state of the standard sample, and then the concentration of BPA was set to 1, 10, 100, The measurement was performed using the sample set as 1000 and 10000 ng / ml as a measurement target material. The concentrations of BPA measured using the application were 1, 10, 100, 1000, and 10000 ng / ml, respectively.

As described above, according to the measurement system and method of environmental pollutant or disease marker using the smart device 100 proposed in the present invention, the smart device 100 captures an analysis target material and extracts color to extract the analysis. By comparing and analyzing the color of the target material and the color of the standard sample, it is possible to conveniently measure environmental pollutants or disease markers by colorimetric analysis using the smart device 100 which is easy to carry. In addition, according to the present invention, the smart device 100 matches the density and the color of the first state and the second state of the standard sample, respectively, to set the color change according to the change in the concentration of the standard sample, the extracted analysis target material The concentrations of environmental pollutants or disease markers can be measured in response to changes in the concentration of standard samples.

The present invention described above may be variously modified or applied by those skilled in the art, and the scope of the technical idea according to the present invention should be defined by the following claims.

100: smart device
110: input module
120: shooting module
130: color extraction module
140: standard sample setting module
150: colorimetric analysis module
200: server
S100: setting the color of the standard sample
S110: setting a first state of the standard sample
S111: receiving a first concentration of the standard sample
S112: collecting an image photographing the first state of the standard sample
S113: extracting the first color of the standard sample
S120: setting a second state of the standard sample
S121: receiving a second concentration of the standard sample
S122: collecting an image photographing the second state of the standard sample
S123: extracting the second color of the standard sample
S130: setting the color change according to the concentration change of the standard sample using the first state and the second state of the standard sample
S200: collecting an image of the material to be analyzed
S300: extracting the color of the analysis target material by processing the collected image
S400: comparing and analyzing the extracted color with the color of the standard sample

Claims (20)

As a measuring system,
It includes a smart device 100 for measuring environmental pollutants or disease markers by colorimetric analysis method comparing the color of the standard sample and the analyte,
The smart device 100,
A photographing module 120 for photographing the analysis target material;
A color extraction module 130 for processing the image photographed by the photographing module 120 to extract a color of the analysis target material; And
Measurement of environmental pollutants or disease markers using the smart device 100, characterized in that it comprises a color analysis module 150 for analyzing the color extracted from the color extraction module 130 and the color of the standard sample. system.
The method of claim 1,
The photographing module 120 displays a color detection area on a driving screen of the smart device 100,
The color extraction module 130, characterized in that to extract the color of the color detection area, the system for measuring environmental pollutants or disease markers using a smart device (100).
The method of claim 1, wherein the color extraction module 130,
A system for measuring environmental pollutants or disease markers using a smart device (100), characterized in that the color of the analysis target material is extracted as an RGB value.
The colorimetric analysis module 150 of claim 1,
A system for measuring environmental pollutants or disease markers using a smart device (100), characterized in that the R value of the standard sample and the R value of the analyte are compared and analyzed using the R value among the extracted RGB values.
The method of claim 1,
The photographing module 120 photographs the standard sample,
The color extraction module 130, extracts the color of the standard sample,
System for measuring environmental pollutants or disease markers using a smart device 100, characterized in that it further comprises a standard sample setting module 140 for setting the color of the extracted standard sample.
The method of claim 5,
Further comprising an input module 110 for receiving the concentration of the standard sample,
The standard sample setting module 140 is set by matching the concentration of the input standard sample and the color of the extracted standard sample,
The colorimetric analysis module 150, characterized in that the analysis of the concentration of environmental pollutants or disease markers through color comparison, the measurement system of environmental pollutants or disease markers using the smart device (100).
The method of claim 6,
The input module 110 receives the first concentration and the second concentration of the standard sample,
The photographing module 120 photographs the first state and the second state of the standard sample,
The color extraction module 130 extracts a first color by processing an image photographing the first state of the standard sample, and extracts a second color by processing an image photographing the second state of the standard sample. Characterized in that, measuring the environmental pollutants or disease markers using the smart device (100).
The method of claim 7, wherein the standard sample setting module 140,
The first color and the second color extracted with respect to the standard sample is matched with the first density and the second density, respectively, characterized in that the setting of the color change according to the concentration change, environment using the smart device 100 Contaminant or disease marker measurement system.
The method of claim 8, wherein the standard sample setting module 140,
By using the first color, the first density, the second color, and the second density on a two-dimensional plane having color as one axis and density as another axis, setting the color change according to the change in density of the standard sample. Characterized in that, the system for measuring environmental pollutants or disease markers using the smart device (100).
The method of claim 9, wherein the standard sample setting module 140,
Measuring system of environmental pollutants or disease markers using the smart device 100, characterized in that the color change according to the concentration change is set as a linear function.
As a measuring method,
The smart device 100 for measuring environmental pollutants or disease markers by colorimetric analysis that compares the color of the standard sample and the analyte,
(2) collecting an image of the analysis target material photographed by the photographing module 120;
(3) extracting a color of the analysis target material by processing the collected image; And
(4) characterized in that it comprises the step of comparing the color extracted in the step (3) with the color of the standard sample, the environmental pollutant or disease marker measurement method using the smart device (100).
The method of claim 11, wherein the smart device 100,
A color detection area is displayed on a driving screen of the imaging module 120,
In the step (3), the color of the color detection region is extracted from the collected image, the method of measuring environmental pollutants or disease markers using the smart device (100).
The method of claim 11, wherein in step (3),
Method for measuring environmental pollutants or disease markers using the smart device 100, characterized in that for extracting the color of the analysis target material to the RGB value.
The method of claim 11, wherein in step (4),
The method of measuring environmental pollutants or disease markers using the smart device 100, characterized in that the R value of the standard sample and the R value of the analyte to be analyzed by using the R value of the extracted RGB value.
The method of claim 11, wherein before step (4),
(1) characterized in that it further comprises the step of setting the color of the standard sample, the method of measuring environmental pollutants or disease markers using the smart device (100).
The method of claim 15, wherein step (1) comprises:
(1-1) setting a first state of the standard sample;
(1-2) setting a second state of the standard sample; And
(1-3) comprising the step of setting the color change according to the change in the concentration of the standard sample using the first state and the second state of the standard sample, environmental pollutant using the smart device 100 Or measuring the disease marker.
The method of claim 16, wherein step (1-1)
(1-1-1) receiving a first concentration which is a concentration of a first state of the standard sample;
(1-1-2) collecting an image photographing a first state of the standard sample photographed by the photographing module 120; And
(1-1-3) extracting a first color by processing an image photographing the first state of the standard sample,
Step (1-2),
(1-2-1) receiving a second concentration which is a concentration of a second state of the standard sample;
(1-2-2) collecting an image photographing a second state of the standard sample photographed by the photographing module 120; And
(1-2-3) extracting a second color by processing an image photographing the second state of the standard sample, wherein the environmental pollutant or disease marker using the smart device 100 is extracted. How to measure.
The method according to claim 17, wherein in step (1-3),
The first color and the second color extracted with respect to the standard sample is matched with the first density and the second density, respectively, characterized in that the setting of the color change according to the concentration change, environment using the smart device 100 Method of measuring pollutant or disease markers.
The method according to claim 17, wherein in step (1-3),
By using the first color, the first density, the second color, and the second density on a two-dimensional plane having color as one axis and density as another axis, setting the color change according to the change in density of the standard sample. Characterized in that the method for measuring environmental pollutants or disease markers using the smart device (100).
The method according to claim 19, wherein in step (1-3),
Method for measuring environmental pollutants or disease markers using the smart device 100, characterized in that the color change according to the concentration change is set as a linear function.

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