JP2021056171A - Optical analyzer and analysis method - Google Patents

Abstract

To provide an optical analyzer that displays dependent data on two parameters with good visibility.SOLUTION: An optical analyzer 1 is equipped with an image display device 10 for two-dimensionally displaying data having first, second and third parameters, and comprises: a data acquisition unit 11 for acquiring the value of each data as a first, a second and a third parameter value when obtained; a display color determination unit 13 for determining a display color that corresponds to a color among those having been determined so as to successively change the value of the third parameter acquired by the data acquisition unit 11 in correspondence to the successive changes of the values; and a two-dimensional graph display unit 14 for displaying the plurality of data, showing the first parameter value of each data in the two-dimensional area of the screen as a first coordinate value, showing the second parameter value as a second coordinate value, and showing a third parameter value corresponding to the first and second parameter values in the display color at a position corresponding to the first and second coordinates.SELECTED DRAWING: Figure 1

Description

The present invention relates to an optical analyzer including an image display device that displays data having values depending on two parameters on a screen as a graph, and an optical analysis method.

In various measurements, data that changes with the passage of time from a reference time is acquired, and the data is displayed as a graph on a display. When these data are, for example, a wavelength spectrum (same for wave number spectrum and frequency spectrum) in a spectroscopic measuring device, data having values depending on two parameters of time and wavelength (in the case of wavelength spectrum) can be obtained. Since each such data can be represented as a point in the three-dimensional space, it can be displayed as a three-dimensional graph as a whole. However, since only a two-dimensional image can be displayed with a normal image display device, how to display the entire image of a graph having three-dimensional attributes on a two-dimensional screen so that the user can easily understand it. The question is whether to do it.

In Non-Patent Document 1, for the purpose of capturing chemical changes occurring in a sample, measurement by Fourier Transform Infrared Spectroscopy (FTIR) is repeated at predetermined time intervals, and the x-axis is time, y. It is described that a three-dimensional graph having a wavelength on the axis and an absorbance on the z-axis is displayed by shifting the wavelength spectrum for each time on the same two-dimensional screen to represent the entire three-dimensional graph. As a result, all the wavelength spectra for each time are displayed on the same two-dimensional screen. Therefore, from the value of each curve when the y-axis coordinates are specific values, the change in the intensity of absorbance at a specific wavelength that occurs with the passage of time can also be visually recognized on the screen, and the sample is based on this. It is possible to determine the change in the chemical bond that occurred in.

"Time course measurement of vinyl chloride resin adhesive by FTIR", March 12, 2013, Shimadzu Corporation, [Search on May 20, 2019], Internet <URL: https://solutions.shimadzu.co .jp / cgi / ac? cmd = 1 & url = / solnavi / s / apl / a-news / 1 / a / a455.htm>

Since the graph of Non-Patent Document 1 displays spectrum information in three dimensions, if the number of curves displayed on the screen increases, the visibility as a whole deteriorates, and the wavelength spectrum is distinguished by time. It becomes difficult to visually recognize the change in the intensity of absorbance at a specific wavelength with the passage of time. That is, there is a limit due to problems such as visibility when displaying data having a total of three or more parameters that depend on two parameters in three dimensions.

An object to be solved by the present invention is to provide a data display device and a method capable of displaying data having values depending on two parameters with good visibility.

The optical analyzer according to the present invention, which has been made to solve the above problems, is
It is provided with an image display device that displays a plurality of data having a first parameter related to time, a second parameter, and a third parameter depending on the values of the first parameter and the second parameter on a two-dimensional screen. There,
A data acquisition unit that acquires the value of each data as the value of the first parameter, the value of the second parameter, and the value of the third parameter when the data is obtained.
A display color that determines the display color, which is the corresponding color among the colors defined so that the value of the third parameter acquired by the data acquisition unit is continuously changed in response to the continuous change of the value. The decision department and
The plurality of data are displayed by displaying the value of the first parameter of each data in the two-dimensional area on the screen as the value of the first coordinate, the value of the second parameter as the value of the second coordinate, and the first. It is provided with a two-dimensional graph display unit that displays the value of the parameter and the value of the third parameter corresponding to the value of the second parameter at the positions corresponding to the first coordinate and the second coordinate in the display color.

Here, "continuously changing" means that the color continuously changes in any one or more of the three elements of color, hue, saturation, and lightness.

The optical analysis method according to the present invention
A method having a plurality of steps of displaying a plurality of data having a first parameter related to time, a second parameter, and a third parameter depending on the values of the first parameter and the second parameter on a two-dimensional screen. There, the multiple steps
A data acquisition step of acquiring the value of each data as the value of the first parameter, the value of the second parameter, and the value of the third parameter when the data is obtained.
A display color that determines a display color that is a corresponding color among the colors that are determined to continuously change the value of the third parameter acquired in the data acquisition step in response to the continuous change of the value. The decision process and
The plurality of data are displayed by displaying the value of the first parameter of each data in the two-dimensional area on the screen as the value of the first coordinate, the value of the second parameter as the value of the second coordinate, and the first. This is a two-dimensional graph display step of displaying the value of the parameter and the value of the third parameter corresponding to the value of the second parameter at the positions corresponding to the first coordinate and the second coordinate in the display color.

According to the present invention, among the colors defined so that the value of the first parameter and the third parameter having a value depending on the second parameter are continuously changed in response to the continuous change of the value. By displaying at the position of the first coordinate corresponding to the value of the first parameter and the second coordinate corresponding to the value of the second parameter in the two-dimensional area on the screen with the corresponding display color of. The values of the three parameters can be displayed with good visibility.
In addition, the purpose of the conventional optical analyzer is to measure the absorbance and transmittance of the measurement sample, and real-time performance is rarely required, but unlike laser illumination equipment and laser processing equipment, light output is output in real time. The present invention can be applied to an apparatus that needs to be monitored. Furthermore, the present invention can be applied to the quality control of the device in the manufacture of the optical device.

The schematic which shows one Embodiment of the data display device which concerns on this invention. The schematic diagram which shows the structure of the memory of the data temporary storage part 12 used for the data display device of this embodiment. The flowchart which shows the operation of the data display apparatus of this embodiment, and one Embodiment of the data display method which concerns on this invention. This is an example of a two-dimensional graph showing the time change of the intensity with respect to a plurality of wavelengths displayed on the display, and shows the state (a) immediately after the start of measurement and the state (b) after a certain time has passed from the start of measurement. The figure which shows. An example of a second two-dimensional graph displayed on a display, which shows a state (a) immediately after the start of measurement and a state (b) after a certain amount of time has passed from the start of measurement. The figure which shows an example of the whole image displayed on a display. A flowchart showing a data display method of a modified example.

An embodiment of the optical analyzer and the optical analysis method according to the present invention will be described with reference to FIGS. 1 to 7.

(1) Configuration of One Embodiment of the Optical Analyzer According to the Present Invention FIG. 1 is a schematic view showing the configuration of the optical analyzer 1 according to the embodiment of the present invention. The optical analyzer 1 includes a spectroscopic measurement device 20 and a data display device 10 that displays data acquired by the spectroscopic measurement device 20. In FIG. 1, as an example of the spectroscopic measurement device 20, the light 90 to be measured is separated by a diffraction grating 21 and the intensity of the separated light 90 for each wavelength is detected by the light detector 22. The photodetector 22 is a one-dimensional arrangement of a plurality of photodetector elements 221. Light having a different wavelength is incident on the photodetector 22 for each photodetector 221 (position in the photodetector 22) by being separated by the diffraction grating 21. Each photodetector 221 detects the intensity of the light incident on it and sends out an electric signal corresponding to the intensity. Therefore, the electric signal for each photodetector 221 indicates the intensity for each wavelength of the light 90 incident on the photodetector 22.

The data display device 10 includes a data acquisition unit 11, a data temporary storage unit 12, a display color determination unit 13, a two-dimensional graph display unit 14, a second two-dimensional graph display unit 15, a display 16, an input unit 17, and data storage. It has a unit 18 and a control unit (not shown) that controls each unit.

The data acquisition unit 11, the display color determination unit 13, the two-dimensional graph display unit 14, and the second two-dimensional graph display unit 15 are embodied by the CPU (central processing unit) and software of the computer main body 19. The functions of each of these parts will be described later together with the operation of the data display device 10.

The data temporary storage unit 12 is a volatile memory included in the computer main body 19, and is a storage medium for temporarily storing data in order to operate the data display device 10 of the present embodiment. FIG. 2 is a schematic diagram showing the structure of the memory of the data temporary storage unit 12. In this memory, as will be described later, the data acquisition unit 11 obtains light intensity data for n wavelengths at m timings (time) based on the electric signals transmitted by the n photodetector 221s. , N in the horizontal direction and m in the vertical direction (vertical and horizontal can be interchanged) are stored in individual storage units arranged in a matrix (n and m are both natural numbers).

On the other hand, the data storage unit 18 is a hard disk drive (HDD) included in the computer main body 19, and stores data even after a series of operations of the data display device 10 is completed, and analyzes the data. It is provided so that A storage device such as a solid state drive (SSD) may be used for the data storage unit 18 instead of the HDD.

The display 16 has a screen for displaying various information including a two-dimensional graph and a second two-dimensional graph. Here, in the two-dimensional graph, a plurality of light intensity data (third parameter) relating to the light intensity detected by the light detector 22 is displayed in a display color defined as described later corresponding to the value of the data. In this graph, the time (first parameter) is set to the x coordinate (first coordinate) and the wavelength (second parameter) is set to the y coordinate (second coordinate).

On the other hand, the second two-dimensional graph shows the relationship between time and light intensity by displaying the time when the wavelength has a predetermined value at the x-coordinate and the light intensity data at the y-coordinate. It is a graph. In the second two-dimensional graph, the wavelength may have a plurality of predetermined values, and the relationship between time and light intensity may be indicated by different colors and / or symbols for each of the predetermined values. Further, as a second two-dimensional graph, the wavelength and the time are exchanged, and points, symbols, etc. are displayed at positions where the wavelength is the x-coordinate and the light intensity data is the y-coordinate when the time has a predetermined value. Thereby, the relationship between the wavelength and the intensity of light may be shown. In any case, in the second two-dimensional graph, one of the first parameter and the second parameter is set as the first coordinate of the second two-dimensional graph, and the third parameter is changed as the value of the parameter changes. We will pay attention to the change in the value of the parameter. In the following, the parameter that is the first coordinate of the second two-dimensional graph is referred to as the "target parameter of interest", and the other parameter, that is, the parameter that is fixed to a predetermined value in the second two-dimensional graph is ". It is called "fixed target parameter".

The second two-dimensional graph display unit 15 may be omitted so that the second two-dimensional graph is not displayed on the screen.

(2) Operation of the optical analyzer of the present embodiment and one embodiment of the optical analysis method according to the present invention Using FIG. 3, the operation of the optical analyzer 1 of the present embodiment and the operation of the data display device 10 can be performed. I will explain mainly. The operation of the optical analyzer 1 corresponds to one embodiment of the optical analysis method according to the present invention. FIG. 3 is a flowchart showing the operation of the data display device 10 in the optical analyzer 1 of the present embodiment. Here, a case where data of the light intensity detected by each photodetector element 221 of the photodetector 22 is acquired at a predetermined time interval δt will be described.

First, the user starts the operation of the data display device 10 by performing a predetermined operation using the input unit 17. First, the control unit sets the value of the time t, which is the first parameter, to the initial value "0" (step S1). Hereinafter, until the value of time t is changed in step S7 described later, the data is processed assuming that the time indicated by the value of t has elapsed from the start of the operation at that time. The present invention is not limited to starting the operation of the display unit by the operation of the user. For example, the data display device 10 is received from the control unit to notify that the operation of the data display device 10 is started. May start the operation of.

Next, the data acquisition unit 11 receives the electric signal transmitted by each photodetector 221 of the photodetector 22, and acquires the value of the light intensity for each photodetector 221 based on the intensity of the electric signal. (Step S2). Since light having a different wavelength is incident on each photodetector 221 as described above, the value of the light intensity for each photodetector 221 indicates the light intensity for each wavelength of the detected light. The data acquisition unit 11 sets the value for each acquired light intensity (third parameter) together with the value of the time (first parameter) at this time and the value of the wavelength (second parameter) corresponding to the intensity of each light. It is stored in the data temporary storage unit 12 and stored in the data storage unit 18.

Next, the display color determination unit 13 acquires the value of the intensity of each light stored in the data temporary storage unit 12 and determines the display color corresponding to the value of the intensity of each light (step S3). Here, the display color is one of the three elements of color, hue, saturation, and lightness, or one of the three elements of the color when the value is continuously changed within the range of the value of the acquired light intensity. Set so that multiple changes continuously. As a result, one corresponding display color is determined without omission for each obtained light intensity. The term "continuously" includes the case where the color changes stepwise as the value of the light intensity changes. Further, since only the brightness may be continuously changed, the display color may be determined by the shade of black and white (gray scale).

Next, the two-dimensional graph display unit 14 displays the value of the intensity of each light acquired by the data acquisition unit 11 on the two-dimensional graph having the time value as the first coordinate and the wavelength value as the second coordinate. An electric signal is transmitted to the display 16 so as to display in the display color determined by the color determination unit 13. As a result, the two-dimensional graph is displayed on the display 16 (step S4).

Here, the display color can be displayed, for example, at a small point within a range that can be visually recognized by the user, or the time interval δt for acquiring data (time, wavelength, and light intensity) is on the x-axis side. The length of the side and the interval of the wavelength for which data is acquired may be displayed as a rectangle or a square having the length of the side on the y side. As an example of the latter, FIG. 4A shows a two-dimensional graph displayed on the display 16. At this point, a plurality of data are displayed for the wavelength, but only the data when the initial value is 0 is displayed for the time. As described in FIG. 4A, the x-axis may be displayed by a sampling number assigned for each time when the data is acquired, instead of the time. Further, the y-axis may be indicated by a number assigned to each photodetector element 221 instead of the wavelength. Although not shown in FIG. 4A, the y-axis may be displayed in wavenumber or frequency instead of wavelength.

Next, the second two-dimensional graph display unit 15 stores the time (attention target parameter) value and the light intensity value when _{the wavelength (fixed target parameter) has a predetermined value λ s as the data temporary storage unit 12.} An electrical signal is transmitted to the display 16 so as to be displayed on a second two-dimensional graph in which the time value is the first coordinate and the light intensity value is the second coordinate. As a result, the second two-dimensional graph is displayed on the display 16 (step S5). Here, when the wavelength has a plurality of predetermined values, the light intensity for each wavelength can be easily distinguished by displaying the second two-dimensional graph with different colors and / or symbols for each of the predetermined values. be able to. FIG. 5A shows an example in which a graph showing the relationship between time and light intensity values for each of the two wavelengths is displayed on one second two-dimensional graph. In this example, the data is shown by different symbols between the two wavelengths. At this point, only the value when the time is the initial value 0 is displayed.

As described above, a second two-dimensional graph in which the fixed target parameter is time and the attention target parameter is the wavelength may be displayed, or two types in which the fixed target parameter and the attention target parameter are interchanged with each other may be displayed. The second two-dimensional graph may be displayed together. In the second two-dimensional graph, it is not necessary to set the display color according to the value of the light intensity, and all may be the same color.

When the second two-dimensional graph display unit 15 is omitted in the data display device 10, step S5 is omitted and the process proceeds to the next step S6.

In step S6, the control unit determines whether or not a predetermined time δt has elapsed since the data was acquired, based on the time information obtained by the function of the clock possessed by the computer. If this determination is Yes, the process proceeds to step S7, and if No, step S6 is repeatedly executed until the predetermined time δt elapses (Yes).

In step S7, the value obtained by adding δt to the value of time t at that time is changed to a new value of time t. Then, it is determined whether or not _{the time t has passed the predetermined time t e} to complete the operation (step S8). If this determination is No, the process returns to step S2. Therefore, the operations of steps S2 to S7 are repeated until the determination is Yes in step S8. By such repeated operations, the data acquisition unit 11 acquires the light intensity value each time it reaches each of the plurality of predetermined times, and the display color determination unit 13 causes the data acquisition unit 11 to acquire the light intensity value. The display color is determined each time the display color is acquired, and the two-dimensional graph display unit 14 additionally displays data on the two-dimensional graph each time the display color determination unit 13 determines the display color (see FIG. 4B). In this way, the two-dimensional graph is updated (data is added) in real time while the light intensity is acquired. Therefore, the user can immediately see the obtained measurement data by the updated two-dimensional graph. Similarly, the second two-dimensional graph can be updated (data is added) each time a plurality of predetermined times are reached (see FIG. 5 (b)).

Then, when the determination in step S8 becomes Yes, a series of operations is completed.

The two-dimensional graph illustrated in FIG. 4 captures the time change due to a chemical change occurring in the sample by detecting, for example, the intensity of the light transmitted through the sample for each wavelength and determining the wavelength of the light absorbed by the sample. Can be used for Alternatively, the intensity of the light transmitted through the sample eluted from the column of the liquid chromatograph for each wavelength is detected for each time (retention time) to determine the components contained in the sample eluted from the column at each retention time. Can be used for

FIG. 6 shows an overall example of the image displayed on the display 16. In this example, three graphs are displayed on the screen. Of these, the graph displayed in the upper left part of the screen is a two-dimensional graph 31 in which the x-axis is time, the y-axis is wavelength, and the light intensity is shown in color. The graph displayed at the lower left of the screen is a second two-dimensional graph 32 in which the x-axis is time and the y-axis is light intensity. On the right side of the second two-dimensional graph 32, a wavelength input field 321 capable of inputting a plurality of wavelengths to be fixed values is provided. When the user inputs a numerical value of the wavelength into the wavelength input field 321 using the input unit 17, the relationship between the time and the light intensity at the wavelength is displayed in the second two-dimensional graph 32. In addition, in the wavelength input field 321, symbols and the like for distinguishing data in the second two-dimensional graph 32 (in this example, the line type of the line connecting the points) are displayed for each input wavelength. .. The graph displayed in the upper right part of the screen is a second two-dimensional graph 33 showing a spectrum in which the x-axis is the wavelength and the y-axis is the light intensity data at the time when this screen is displayed. At the lower right of the screen, a sampling rate input field 34 for inputting a numerical value of a predetermined time interval δt as a sampling rate is provided.

(3) Modification Example In the above embodiment, it has been described that the display of the two-dimensional graph is updated in real time while acquiring the light intensity from the photodetector 22, but the two-dimensional graph is displayed after all the light intensities are acquired. It may be created and displayed. An example of a data display method in the case of performing such a display will be described with reference to the flowchart of FIG. 7.

In this example, the data obtained by measuring the light intensity at each wavelength for each time is stored in the data storage unit 18 together with the combination of the time and wavelength values in advance. When the user performs a predetermined operation using the input unit 17, the data acquisition unit 11 acquires the data value of each light intensity from the data storage unit 18 together with the time and wavelength values corresponding to the data. (Step S11). The acquired data is stored in the data temporary storage unit 12.

The display color determination unit 13 acquires the value of each data stored in the data temporary storage unit 12 and determines the display color corresponding to the value of each data (step S12). Then, the two-dimensional graph display unit 14 displays an electric signal in the display color determined by the display color determination unit 13 on the two-dimensional graph in which the time value is the first coordinate and the wavelength value is the second coordinate. Is transmitted to the display 16 (step S13).

Further, the second two-dimensional graph display unit 15 _{acquires the time value and the light intensity value when the wavelength has a predetermined value λ s} from the data temporary storage unit 12, and obtains the time value in the first coordinate. , The electric signal is transmitted to the display 16 so as to be displayed on the second two-dimensional graph having the value of the light intensity data as the second coordinate (step S14).

By the above operation, the two-dimensional graph (and the second two-dimensional graph) of the data measured in advance is displayed on the display 16, and the operation is completed.

Note that step S14 may be omitted. Further, as in the above-mentioned example of updating the display in real time, the relationship between the wavelength and the light intensity at a predetermined time may be displayed as a second two-dimensional graph.

In addition, the data display device and the data processing method according to the present invention can be modified in various ways. For example, the combination of the second parameter and the third parameter is not limited to the above-mentioned wavelength and light intensity, and various combinations can be used.

[Aspect]
It will be understood by those skilled in the art that the above-described exemplary embodiments are specific examples of the following embodiments.

(Section 1)
The optical analyzer according to paragraph 1 is
It is provided with an image display device that displays a plurality of data having a first parameter related to time, a second parameter, and a third parameter depending on the values of the first parameter and the second parameter on a two-dimensional screen. There,
A data acquisition unit that acquires the value of each data as the value of the first parameter, the value of the second parameter, and the value of the third parameter when the data is obtained.
A display color that determines the display color, which is the corresponding color among the colors defined so that the value of the third parameter acquired by the data acquisition unit is continuously changed in response to the continuous change of the value. The decision department and
The plurality of data are displayed by displaying the value of the first parameter of each data in the two-dimensional area on the screen as the value of the first coordinate, the value of the second parameter as the value of the second coordinate, and the first. It is provided with a two-dimensional graph display unit that displays the value of the parameter and the value of the third parameter corresponding to the value of the second parameter at the positions corresponding to the first coordinate and the second coordinate in the display color.

(Section 4)
The optical analysis method according to item 4 is
A method having a plurality of steps of displaying a plurality of data having a first parameter related to time, a second parameter, and a third parameter depending on the values of the first parameter and the second parameter on a two-dimensional screen. There, the multiple steps
A data acquisition step of acquiring the value of each data as the value of the first parameter, the value of the second parameter, and the value of the third parameter when the data is obtained.
A display color that determines a display color that is a corresponding color among the colors that are determined to continuously change the value of the third parameter acquired in the data acquisition step in response to the continuous change of the value. The decision process and
The plurality of data are displayed by displaying the value of the first parameter of each data in the two-dimensional area on the screen as the value of the first coordinate, the value of the second parameter as the value of the second coordinate, and the first. This is a two-dimensional graph display step of displaying the value of the parameter and the value of the third parameter corresponding to the value of the second parameter at the positions corresponding to the first coordinate and the second coordinate in the display color.

According to the optical analyzer according to the first item and the optical analysis method according to the fourth item, the value of the third parameter having the values depending on the first parameter and the second parameter corresponds to the continuous change of the value. The corresponding display color among the colors defined to continuously change, the first coordinate corresponding to the value of the first parameter and the value of the second parameter in the two-dimensional area on the screen. By displaying at the position of the second coordinate corresponding to, the value of the third parameter can be displayed with good visibility.

Here, the "first parameter regarding time" is the time when the data was obtained and the number of times the data was acquired when the data was acquired at a predetermined time interval, in addition to the time (from the reference time). It may be the indicated number (sampling number).

(Section 2)
The optical analyzer according to the second item is the optical analyzer according to the first item.
Each time the data acquisition unit reaches each of the plurality of predetermined times, the value of the third parameter is changed to the value of the first parameter and the value of the second parameter when the value of the third parameter is obtained. Get with the value of
The display color determination unit determines the display color each time the data acquisition unit acquires the value of the third parameter.
The two-dimensional graph display unit additionally displays the display color of the third parameter at the position each time the display color determination unit determines the display color.

(Section 5)
The optical analysis method according to the fifth item is the optical analysis method according to the fourth item.
In the data acquisition step, each time a plurality of predetermined times are reached, the value of the third parameter is used, the value of the first parameter when the value of the third parameter is obtained, and the second parameter. Get with the value of
In the display color determination step, the display color is determined each time the value of the third parameter is acquired in the data acquisition step.
In the two-dimensional graph display step, each time the display color is determined in the display color determination step, the display color of the third parameter is additionally displayed at the position.

According to the optical analyzer according to the second item and the optical analysis method according to the fifth item, data is additionally displayed on the screen each time a plurality of predetermined times are reached. Therefore, the display of the data can be updated in real time while acquiring the data.

(Section 3)
The optical analyzer according to the third item is the optical analyzer according to the first or second item.
Further, one of the first parameter and the second parameter is set as the target parameter of interest, the other is set as the fixed target parameter, and the fixed target parameter is predetermined among the values of the third parameter acquired by the data acquisition unit. Regarding the value of the third parameter, which is a fixed value of, the value of the parameter of interest in the second two-dimensional region other than the two-dimensional region on the screen is the first coordinate, and the value of the third parameter is the third. A second two-dimensional graph display unit for displaying at a position having two coordinates is provided.

(Section 6)
The optical analysis method according to the sixth item is the optical analysis method according to the fourth or fifth item.
Further, one of the first parameter and the second parameter is set as the target parameter of interest, the other is set as the fixed target parameter, and the fixed target parameter is predetermined among the values of the third parameter acquired in the data acquisition step. Regarding the value of the third parameter, which is a fixed value of, the value of the parameter of interest in the second two-dimensional region other than the two-dimensional region on the screen is the first coordinate, and the value of the third parameter is the third. It has a second two-dimensional graph display step of displaying at a position having two coordinates.

According to the optical analyzer according to the third item and the optical analysis method according to the sixth item, the change in the value of the third parameter accompanying the change in the parameter of interest of the two parameters is visually recognized in the second two-dimensional graph. It can be displayed with good quality. In the second two-dimensional graph, the data may be displayed in a single color.

1 ... Optical analyzer 10 ... Data display device 11 ... Data acquisition unit 12 ... Data temporary storage unit 13 ... Display color determination unit 14 ... Two-dimensional graph display unit 15 ... Second two-dimensional graph display unit 16 ... Display 17 ... Input Unit 18 ... Data storage unit 19 ... Computer body 20 ... Spectral measuring device 21 ... Diffraction grating 22 ... Optical detector 221 ... Optical detection element 31 ... Two-dimensional graph 32, 33 ... Second two-dimensional graph 321 ... Wavelength input field 34 … Sampling rate input field 90… Optical

Claims (6)

It is provided with an image display device that displays a plurality of data having a first parameter related to time, a second parameter, and a third parameter depending on the values of the first parameter and the second parameter on a two-dimensional screen. There,
A data acquisition unit that acquires the value of each data as the value of the first parameter, the value of the second parameter, and the value of the third parameter when the data is obtained.
A display color that determines the display color, which is the corresponding color among the colors defined so that the value of the third parameter acquired by the data acquisition unit is continuously changed in response to the continuous change of the value. The decision department and
The plurality of data are displayed by displaying the value of the first parameter of each data in the two-dimensional area on the screen as the value of the first coordinate, the value of the second parameter as the value of the second coordinate, and the first. Optical analysis including a two-dimensional graph display unit that displays the value of the parameter and the value of the third parameter corresponding to the value of the second parameter in the display color at the position corresponding to the first coordinate and the second coordinate. apparatus. Each time the data acquisition unit reaches each of the plurality of predetermined times, the value of the third parameter is changed to the value of the first parameter and the value of the second parameter when the value of the third parameter is obtained. Get with the value of
The display color determination unit determines the display color each time the data acquisition unit acquires the value of the third parameter.
The two-dimensional graph display unit additionally displays the display color of the third parameter at the position each time the display color determination unit determines the display color.
The optical analyzer according to claim 2. Further, one of the first parameter and the second parameter is set as the target parameter of interest, the other is set as the fixed target parameter, and the fixed target parameter is predetermined among the values of the third parameter acquired by the data acquisition unit. Regarding the value of the third parameter, which is a fixed value of, the value of the parameter of interest in the second two-dimensional region other than the two-dimensional region on the screen is the first coordinate, and the value of the third parameter is the third. The optical analyzer according to claim 1 or 2, further comprising a second two-dimensional graph display unit that displays at a position having two coordinates. A method having a plurality of steps of displaying a plurality of data having a first parameter related to time, a second parameter, and a third parameter depending on the values of the first parameter and the second parameter on a two-dimensional screen. A data acquisition step in which the plurality of steps acquire the value of each data as the value of the first parameter, the value of the second parameter, and the value of the third parameter when the data is obtained.
A display color that determines a display color that is a corresponding color among the colors that are determined to continuously change the value of the third parameter acquired in the data acquisition step in response to the continuous change of the value. The decision process and
The plurality of data are displayed by displaying the value of the first parameter of each data in the two-dimensional area on the screen as the value of the first coordinate, the value of the second parameter as the value of the second coordinate, and the first. An optical analysis method, which is a two-dimensional graph display step of displaying a parameter value and a third parameter value corresponding to the second parameter value in the display color at positions corresponding to the first coordinate and the second coordinate. .. In the data acquisition step, each time a plurality of predetermined times are reached, the value of the third parameter is used, the value of the first parameter when the value of the third parameter is obtained, and the second parameter. Get with the value of
In the display color determination step, the display color is determined each time the value of the third parameter is acquired in the data acquisition step.
In the two-dimensional graph display step, each time the display color is determined in the display color determination step, the display color of the third parameter is additionally displayed at the position.
The optical analysis method according to claim 4. Further, one of the first parameter and the second parameter is set as the target parameter of interest, the other is set as the fixed target parameter, and the fixed target parameter is predetermined among the values of the third parameter acquired in the data acquisition step. Regarding the value of the third parameter, which is a fixed value of, the value of the parameter of interest in the second two-dimensional region other than the two-dimensional region on the screen is the first coordinate, and the value of the third parameter is the third. The optical analysis method according to claim 4 or 5, further comprising a second two-dimensional graph display step of displaying at a position having two coordinates.

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