JP2010190630A - Measuring device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a measuring device for improving the working efficiency of a user during calibration. <P>SOLUTION: This measuring device measures a specific physical quantity in measuring liquid and displays it on a display section 4, and, during calibration, displays information about the calibration on the display section 4 to allow the user to operate the execution of the calibration. During the calibration, the display section 4 simultaneously displays a measured value taking key 4f for indicating the taking of a measured value of calibration liquid, and a trend graph 4g of the measured value of the calibration liquid. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a measuring apparatus, and more specifically, measures a specific physical quantity in a measuring solution and displays it on a display unit. At the time of calibration, information on calibration can be displayed on the display unit so that a user can perform a calibration operation. It relates to the measuring device.

  FIG. 8 is a diagram showing an example of a display screen of the display unit 100 of the conventional dissolved oxygen meter. In the upper left part of the screen, the measurement value (main measurement signal display 100a) of the dissolved oxygen amount of the measurement liquid L is displayed in large letters, and the temperature of the measurement liquid L (auxiliary signal display 100b) is displayed below it. . Further, the display unit 100 is configured by a touch panel, and menu items, command items, operation keys, and the like are displayed according to the situation, and various operations can be performed by the user by the user's touch input. In the example of FIG. 8, four operation keys of a home key 100c, a back key 100d, an arrow key 100e, and an enter key 100f are displayed in a vertical line on the right side of the display screen 110.

  It is necessary to calibrate the dissolved oxygen meter periodically to maintain the measurement accuracy. In calibration of a dissolved oxygen meter, a calibration solution with a known amount of dissolved oxygen (0% or 100%) is usually measured, and the measured value obtained at this time is taken into the dissolved oxygen meter to obtain the correct value (ie, calibration). Value).

FIG. 9 is a diagram showing a display screen at the time of calibration. (A) and (b) are calibration screens, and (c) is a trend graph screen.
When the measurement of the calibration liquid is started, a calibration screen as shown in FIGS. 9A and 9B is displayed on the display unit 100. Three commands of “Show trend graph”, “Adjust now”, and “Quit without adjusting” are displayed on the calibration screen, and any command is selected by the user touching the arrow key 100e. In FIG. 9A, the “Adjust now” command 100g for instructing the acquisition of the measurement value is selected. When the user touches the enter key 100f in this state, the selected command is executed, and the dissolved oxygen meter starts taking in the measured value of the calibration solution.

  By the way, since the measurement of the amount of dissolved oxygen uses an electrochemical reaction, it takes time until the measured value is stabilized. For this reason, there is a demand for the user to confirm whether or not the measured value is stable when the measured value of the calibration liquid is taken in.

  The “Show trend graph” command 100 h is a command for switching the display unit 100 to a trend graph screen of measured values. As shown in FIG. 9B, the user selects this command 100h and touches the enter key 100f to check whether or not the measurement value is stable. Then, the entire display unit 100 is switched to a trend graph screen as shown in FIG. 9C, and a trend graph 100i from the start of measurement of measured values is displayed. The user confirms whether or not the measured value is stable with reference to the trend graph 100i.

  On the trend graph screen, an operation key 100j for switching the display unit 100 to the calibration screen of FIG. 9B is prepared. When the user confirms the trend graph 100i, the user touches the operation key 100j to return to the original calibration screen. When the user determines that the measurement value is stable, the user performs the acquisition of the measurement value. If it is determined that the measured value is not stable, wait for a while and then switch to the trend graph screen again to check whether the measured value is stable.

  In this way, the calibration screen has an operation key to switch to the trend graph screen, and the trend graph screen has an operation key to return to the calibration screen so that the calibration screen and the trend graph screen can be moved back and forth. Makes it possible to properly determine the timing for taking in measured values.

  Patent Document 1 below describes a measuring instrument calibration operation method for a water distribution monitor that switches between a calibration screen and a trend graph screen on a graphic operation panel during calibration.

Japanese Patent Laid-Open No. 08-193990

However, in the conventional dissolved oxygen meter as described above, it is necessary to alternately display the calibration screen and the trend graph screen, and the screen switching operation is complicated.
In addition, since the trend graph screen cannot be referenced at the same time when the measured value is captured, the user does not change the measured value from the last confirmation of the trend graph until the measured value is captured. If you are worried about this, you will return to work, such as displaying a trend graph again just in case.

  An object of the present invention is to provide a measuring apparatus that eliminates the conventional problems and improves the workability of the user during calibration.

In order to achieve such a problem, the invention described in claim 1
In the measuring device that measures the specific physical quantity in the measurement liquid and displays it on the display unit, and at the time of calibration, displays information related to the calibration on the display unit to enable the user to perform calibration.
The display unit is characterized by simultaneously displaying a measurement value acquisition key for instructing acquisition of the measurement value of the calibration liquid and a trend graph of the measurement value of the calibration liquid at the time of calibration.

The invention described in claim 2
The measuring apparatus according to claim 1,
An operation key that is always displayed on the display unit during measurement and calibration is used as the measurement value import key.

The invention according to claim 3
The measuring apparatus according to claim 1 or 2,
The display unit is further characterized by simultaneously displaying numerical values of measured values of the calibration liquid.

The invention according to claim 4
In the measuring apparatus in any one of Claims 1-3,
The trend graph is characterized in that the display scale of at least one of the measurement value axis and the time axis is set for each type of calibration.

The invention described in claim 5
In the measuring apparatus in any one of Claims 1-4,
The trend graph is characterized in that the display range of at least one of the measurement value axis and the time axis is set for each type of calibration.

The invention described in claim 6
In the measuring apparatus in any one of Claims 1-5,
The trend graph is characterized in that the center value of the measurement value axis is set according to the type of calibration.

The invention described in claim 7
In the measuring apparatus in any one of Claims 1-6,
The display unit is composed of a touch panel.

According to the invention of claim 1,
At the time of calibration, the display unit simultaneously displays a measured value import key that instructs to import the measured value of the calibration fluid and a trend graph of the measured value of the calibration fluid. In addition, the trend graph can be referred to, and the workability of the user at the time of calibration can be improved.

According to the invention of claim 2,
Since the operation keys that are always displayed on the display unit during measurement and calibration are used as measurement value acquisition keys, it is not necessary to increase the display around the trend graph, and the display contents on the display unit are easy to see.

According to the invention of claim 3,
Since the display unit displays the numerical value of the measured value of the calibration solution at the same time, it is possible to grasp not only the change of the measured value with time but also the accurate current value.

According to the invention of claim 4,
Since the trend graph has at least one of the measurement value axis and time axis display scales set for each type of calibration, the user can always display the trend graph with the optimal display scale regardless of the type of calibration. Can be referred to.

According to the invention of claim 5,
Since the trend graph has a display range for at least one of the measurement value axis and time axis set for each calibration type, the user can always display the trend graph in the optimal display range regardless of the calibration type. Can be referred to.

According to the invention of claim 6,
Since the center value of the measurement value axis is set according to the type of calibration in the trend graph, the user can always refer to the trend graph represented by the optimum center value regardless of the type of calibration.

According to the invention of claim 7,
Since the display unit is composed of a touch panel, the trend graph can be confirmed near the measurement value capture key, which is the part that the user directly operates, which can improve the workability of the user. it can.
Using the touch panel as the display unit is preferable in the measurement apparatus of the present invention in which the display of the measurement value capturing key and the display of the trend graph of the measurement value are performed simultaneously.

It is a block diagram which shows the Example which applied this invention to the dissolved oxygen meter. It is a figure which shows the external appearance of a dissolved oxygen meter. It is a figure which shows the example of a display at the time of the calibration of the display part 4. FIG. It is a figure which shows the example of a calibration setting screen. It is a figure which shows the operation | movement flow at the time of calibration of the dissolved oxygen meter of this invention. It is a figure which shows the example of a display of the display part 4 at the time of manual calibration. It is an example of the trend graph screen at the time of applying this invention to a pH meter. It is the figure which showed the structure of the dissolved oxygen meter as an example of the conventional measuring apparatus. It is a figure which shows the example of a display at the time of the calibration of the display part 110. FIG.

FIG. 1 is a block diagram showing an embodiment in which the present invention is applied to a dissolved oxygen meter.
The dissolved oxygen meter includes a sensor unit 1 immersed in the measurement liquid L, a main body 2 to which a measurement signal from the sensor unit 1 is input, an operation input unit 3 that receives various operations such as setting information input by a user, and dissolved oxygen. The display unit 4 is configured to display various screens such as measurement values of quantities, setting screens, and calibration screens.

  The main body 2 includes a measurement circuit 2a that processes a measurement signal from the sensor unit 1, a control unit 2b that performs various controls such as calculation of dissolved oxygen amount and acquisition of measurement values during calibration, and a calibration setting unit 2c that holds settings related to calibration. It is composed of Further, the temperature of the measurement liquid L measured by a temperature sensor (not shown) is input to the main body 2.

  The measurement circuit 2a receives the measurement signal from the sensor unit 1, converts it into a digital signal, and outputs it to the control unit 2b. The control unit 2b calculates the dissolved oxygen amount of the measurement liquid L based on the input measurement signal and the temperature of the measurement liquid L, and displays it on the display unit 4.

  FIG. 2 is a diagram showing the appearance of the dissolved oxygen meter of this example. Items other than the sensor unit 1 are housed in one case 10, and the display unit 4 is installed on the front surface of the case 10. Furthermore, the operation input unit 3 is integrally formed with the display unit 4 as a touch panel. The sensor unit 1 is connected to the main body 2 in the case 10 via a cable 11 and a cable gland 12 provided at the lower part of the case 10.

The display unit 4 displays not only the measured value of the dissolved oxygen amount but also menu items, command items, operation keys, and the like according to the situation, and allows the user to perform various operations by touch input of the user.
In the example of FIG. 2, the measured value of the dissolved oxygen amount (main measurement signal display 4a) of the measurement liquid L is displayed in large letters in the upper left part of the screen of the display unit 4, and the temperature of the measurement liquid L (auxiliary signal display) is displayed below it. 4b) is displayed. Further, on the right side portion of the screen of the display unit 4, four operation keys including a home key 4c, a back key 4d, an arrow key 4e, and an enter key 4f are displayed in a vertical line.

  The home key 4c has a function of switching the display content of the display unit 4 to the initial top page. The back key 4d has a function of returning the display content of the display unit 4 to the previous content. The arrow key 4e functions as a movement button and is used when scrolling the selection state of the command displayed on the display unit 4. The enter key 4f mainly functions as a determination button, and is used for executing a command in a selected state, confirming input contents, and the like.

  The operation keys 4 c to 4 f are always displayed on the display unit 4 in common regardless of measurement or calibration, and these operation keys 4 c to 4 f mainly function as the operation input unit 3.

  It is necessary to calibrate the dissolved oxygen meter periodically to maintain the measurement accuracy. The calibration of the dissolved oxygen meter is usually performed by measuring a calibration solution having a known dissolved oxygen amount (0% or 100%), taking the measured value obtained at this time into the main body 2, and comparing it with the calibration value. The use of a calibration solution having a dissolved oxygen content of 0% is referred to as zero calibration, and the use of a calibration solution having a dissolved oxygen content of 100% is referred to as span calibration. The calibration value is generally known for both zero calibration and span calibration. For example, in the case of span calibration, it is 8.26 [mg / l] at a liquid temperature of 25 ° C. In the present embodiment, description will be given by taking span calibration as an example.

  FIG. 3 is a diagram showing a display example of the display unit 4 at the time of calibration. (A) and (c) are calibration screens, and (b) is a trend graph screen.

  First, the user calls the calibration screen shown in FIG. On this calibration screen, commands of dissolved oxygen amounts “0%” and “100%” are displayed, and the user is allowed to select which calibration is performed. The user touches the arrow key 4e to select the command “100%” as shown in FIG. Thereafter, when the user touches the enter key 4f, the command of “100%” that has been selected is determined, and the calibration work of the span calibration is started.

  When the calibration work is started, the control unit 2b automatically switches the display unit 4 to the trend graph screen. (B) of FIG. 3 is an example of a trend graph screen, and shows a state in which less than 30 minutes have elapsed since the start of the calibration work.

  On the trend graph screen, there are four operation keys 4c to 4f, a trend graph 4g showing the change over time of the measured value of the calibration solution, a current value display (main signal display) 4h of the measured value, and a temperature display of the calibration solution ( Auxiliary signal display) 4i is displayed.

  The four operation keys 4c to 4f are displayed in the same size at the same position as the display position on the calibration screen of FIG.

The trend graph 4g is displayed in a large size at a position that does not overlap with the operation keys 4c to 4f and substantially at the center of the display unit 4 so that the user can easily see it.
The trend graph 4g is created with the horizontal axis representing the elapsed time from the start of calibration liquid measurement and the vertical axis representing the measured value. The display range of the horizontal axis is fixed at 30 minutes, and a scale of 4 m is provided at intervals of 10 minutes. The vertical axis is displayed in the range of ± 1.0 [mg / l] from the center value with a display scale of 1.00 [mg / l] with the calibration value of 8.26 [mg / l] as the center value of 4k. ing. On the vertical axis, auxiliary lines 4j are attached at the positions of the center value 4k and 9.26 [mg / l].

  The display range, display scale, and center value of the trend graph 4g are stored in advance in the calibration setting unit 2c. The control unit 2b automatically reads the setting information from the calibration setting unit 2c during the calibration operation, and creates the trend graph 4g according to the read setting.

  At the top of the trend graph 4g, a current value display 4h and a temperature display 4i are displayed in parallel. As a result, not only the change of the measurement value but also the latest measurement value and temperature can be grasped simultaneously on the same screen.

  In the trend graph screen of FIG. 3B, the enter key 4f is caused to function as a measurement value capturing key for capturing a measured value into the main body 2.

The user refers to the trend graph 4g displayed on the display unit 4 and confirms whether or not the measured value of the calibration liquid is stable at the present time. When the user determines that the measured value is stable, the user touches the enter key 4f. When the enter key 4f is touched, the control unit 2b starts to take in the measured value of the calibration solution and switches the display unit 4 to the screen shown in FIG.
That is, in the dissolved oxygen meter of the present embodiment, an instruction for taking in the measured value is made directly from the same screen as the trend graph 4g without shifting to another screen without the trend graph for taking in the measured value as in the conventional example. Done.

  The control unit 2b performs a short-time stability check when taking the measurement value of the calibration liquid. As shown in FIG. 3C, the display 4n displays a display 4n indicating that the stability check is being executed. In the stability confirmation, it is confirmed whether or not the change amount of the measured value within a predetermined time (several seconds to several tens of seconds) is within a predetermined reference value. By this stability check, it is possible to prevent an unstable measurement value from being taken in, which cannot be grasped only by the user viewing the trend graph.

  When the stability check of the measurement value is completed, the control unit 2b takes in the measurement value of the calibration solution. The control unit 2b matches the acquired measurement value with the calibration value, and then displays a message indicating that the calibration is completed on the display unit 4. This completes the calibration work.

  Depending on the content and type of calibration, there may be cases where the trend graph 4g is not required at the time of calibration, or the trend graph 4g is not desired due to user preference. Therefore, it is possible to select not to display the trend graph 4g according to the setting of the user.

  FIG. 4 is a diagram showing an example of the calibration setting screen. The calibration setting screen is prepared separately from the screen for actually executing calibration as shown in FIG. The calibration setting screen allows the user to set and change various items related to calibration. Prepare the item “Trend graph” in the calibration setting screen. The user calls this calibration setting screen on the display unit 4, and when the trend graph 4g is desired to be displayed during calibration, the item “Trend graph” is set to “Enable” and the trend graph 4g is not desired to be displayed during calibration. In this case, set it to “Disable”. The set contents are stored in the calibration setting unit 2c.

When “Trend graph” is set to “Enable”, the trend graph screen shown in FIG. 3B is displayed on the display unit 4 during the calibration operation.
On the other hand, when “Trend graph” is set to “Disable”, the trend graph 4 g is not displayed on the display unit 4, and the screen of FIG. 3A is continuously displayed. When the enter key 4f is touched again after the calibration work is started, the control unit 2b starts to take in the measured values, and the display unit 4 is switched to the screen shown in FIG.

FIG. 5 is a diagram showing an operation flow at the time of calibration of the dissolved oxygen meter of the present invention.
This flow starts when the user selects a command for shifting to some calibration operation.
In step S1, the control unit 2b confirms which type of calibration the user has selected. If span calibration is selected, the process proceeds to step S2.
In step S2, the control unit 2b checks whether the display setting of the trend graph is set to “Enable” or “Disable”. If the setting is set to “Enable”, the process proceeds to step S3. In step S3, the control unit 2b displays a trend graph screen on the display unit 4 with the start of the calibration work, and proceeds to step S4. On the other hand, if the display setting of the trend graph is set to “Disable” in step S2, the screen at the start of the calibration work is continuously displayed on the display unit 4, and the process directly goes from step S2 to step S4. move on.
In step S4, the control unit 2b confirms whether or not the measurement value import key is touched by the user. When the measurement value import key is touched, the process proceeds to step S5.
In step S5, the control unit 2b confirms whether or not the measurement value is stable. If it is determined that the measurement value is stable, the process proceeds to step S6. On the other hand, when it is determined that the measured value is not stable, the confirmation of stability is repeated.
In step S6, the control unit 2b takes the measurement value into the control unit 2b, and matches the measurement value taken in the next step S7 with the calibration value.
Finally, in step S8, the control unit 2b displays a calibration completion message on the display unit 4, and the calibration operation is completed.
When calibration other than span calibration is selected in step S1, operations similar to those in steps S2 to S8 are performed using setting information corresponding to the type of calibration.

By the way, the above-described calibration is calibration in a reference state such as a dissolved oxygen amount of 0% or 100%, and what calibration value is adjusted can be stored in advance in the control unit 2b.
On the other hand, calibration may be performed using a calibration solution that is not in the reference state. In this case, the user needs to set a calibration value to be adjusted. Hereinafter, such manual calibration will be described.

  FIG. 6 is a diagram illustrating a display example of the display unit 4 at the time of manual calibration. (A) is a calibration screen, (b) is a trend graph screen, (c) is a calibration value input screen, and (d) is input. It is a confirmation screen of a calibration value.

  The user calls up a calibration screen for selecting the type of calibration as shown in FIG. Prepare a “Manual Slope Cal.” Command to execute manual calibration on this calibration screen. When the user selects and determines this command, the manual calibration operation is started.

With the start of the manual calibration operation, the control unit 2b automatically switches the display unit 4 to the trend graph screen shown in FIG.
On the trend graph screen, as with the trend graph screen of FIG. 3B, the four operation keys 4c to 4f, the trend graph 4g showing the change over time of the measured value of the calibration liquid, and the current value display of the measured value (mainly Signal display) 4h, calibration liquid temperature display (auxiliary signal display) 4i are displayed. The trend graph 4g has a scale 4m, a center value 4k, and an auxiliary line 4j. FIG. 6B shows a state in which a little less than 30 minutes have elapsed since the start of the calibration work.

The user refers to the trend graph 4g displayed on the display unit 4 and confirms whether or not the measured value of the calibration liquid is stable at the present time. When the user determines that the measured value is stable, the user touches the enter key 4f. When the enter key 4f is touched, the control unit 2b confirms the stability of the measurement value and takes in the measurement value.
That is, even in manual calibration, the measurement value is instructed directly from the same screen as the trend graph 4g without shifting to another screen without the trend graph for capturing the measurement value as in the conventional example.

  Next, the control part 2b switches the display part 4 to the calibration value input screen shown to (c) of FIG. On the calibration value input screen, numerical value input keys 4p, numerical value input fields 4q, and operation keys 4c to 4f corresponding to “0” to “9”, “.”, “−” Are displayed. The user inputs the calibration value into the input field 4q using the numerical value input key 4p and touches the enter key 4f.

  When the enter key 4f is touched, the control unit 2b switches the display unit 4 to the confirmation screen shown in FIG. 6D, and displays the input calibration value on the confirmation display 4r. The user confirms the calibration value displayed on the confirmation display 4r, and executes an “Accept Data” command. The control unit 2b captures the calibration value of the confirmation display 4r and aligns the measurement value with the calibration value. This completes manual calibration.

This embodiment is configured as described above,
The display unit 4 simultaneously displays an enter key 4f for instructing the reading of the measured value of the calibration solution and the trend graph 4g of the measured value of the calibrating solution at the time of calibration, whereby the user instructs to take in the measured value. The trend graph 4g can be referred to instantly, and the user's workability during calibration can be improved.

  In the present invention, by providing a screen combining a trend graph screen and a screen called a “calibration screen” in the conventional example, it is possible to perform a calibration operation without causing the user to go back and forth between both screens. Thereby, the operation amount at the time of a user's calibration work reduces, and a user's burden can be reduced.

  In addition, since the enter key 4f that is always displayed on the display unit 4 during measurement and calibration is used as a measurement value capturing key, it is not necessary to increase the display around the trend graph 4g, and the display content of the display unit 4 is easy to see. .

  Further, since the display unit 4 displays the current value display 4h together with the trend graph 4g, it is possible to simultaneously grasp not only the state of the change in the measured value of the calibration solution but also the accurate current value.

  Further, since the display unit 4 is configured with a touch panel, the user can check the trend graph 4g near the enter key 4f that is the operation input unit 3 when performing a calibration instruction. The workability can be improved.

  The center value of the trend graph 4g is appropriately set according to the type and content of calibration. In the span calibration of the present embodiment, the center value 4k is set to 8.26 [mg / l]. For example, in the case of zero calibration, it is automatically set to 0.0 [mg / l]. These central values are stored in advance in the calibration setting unit 2c, and the control unit 2b reads and uses corresponding setting information according to the type and content of calibration. Thereby, the user can always refer to the trend graph created with the optimum center value regardless of the type and content of the calibration.

Similarly, the display scale and display range of the trend graph 4g are appropriately set according to the type and content of calibration. In the span calibration of this embodiment, the display scale was set to 1.0 [mg / l] and the display range was set to the range of ± 1.0 [mg / l] from the center value. Is set to an appropriate value. The display scale and display range are stored in advance in the calibration setting unit 2c, and the control unit 2b reads out and uses corresponding setting information according to the type and content of calibration. Thereby, the user can always refer to the trend graph created with the optimal display scale and display range regardless of the type and content of calibration.
The display range, display scale, and center value may be configured so that the user can freely set them.

  Further, in this embodiment, when the trend graph display setting is set to “Disable”, the screen before the start of the calibration operation is continuously displayed on the display unit 4, but the calibration solution is being measured. You may display the message which shows.

  In this embodiment, the operation input unit 3 is formed integrally with the display unit 4, but the operation input unit 3 may be formed separately from the display unit 4. For example, the operation input unit 3 may be in the form of an operation button provided around the display unit 4.

  Moreover, although the present Example demonstrated the dissolved oxygen meter to which this invention was applied, the application object of this invention is not restricted to a dissolved oxygen meter. It is effective when applied to an apparatus using an electrochemical sensor that reacts relatively slowly over a period of several seconds to several tens of minutes. In addition to the dissolved oxygen meter, for example, a pH meter and a residual chlorine meter can be considered.

FIG. 7 is an example of a trend graph screen when the present invention is applied to a pH meter. A trend graph 4g ′ shown in FIG. 7 shows a state where calibration is performed using a standard solution of pH 7.0 for calibration.
In the trend graph 4g ′, the display range of the horizontal axis is fixed to 5 minutes, and a scale 4m ′ at 1 minute intervals is attached. The vertical axis of the trend graph 4g ′ displays the center value 4k ′ as 6.9 [pH], the display scale as 0.1 [pH], and the display range as ± 0.1 [pH] as the center value 4k ′. Has been.

  The center value 4k ′ is automatically set to an appropriate value for each standard solution. For example, when calibrating with a standard solution of pH 4.0, the center value 4k ′ is 4.0 [pH], and when calibrating with a standard solution of pH 9.0, the center value 4k ′ is 9.2 [pH]. Set to

DESCRIPTION OF SYMBOLS 1 Sensor part 2 Main body 2a Measurement circuit 2b Control part 2c Calibration setting part 3 Operation input part 4 Display part 4a Main measurement signal display 4b Auxiliary signal display 4c-4f Operation key 4g Trend graph 4h Current value display 4i Temperature display 10 Case 11 Cable 12 Cable gland

Claims (7)

In the measuring device that measures the specific physical quantity in the measurement liquid and displays it on the display unit, and at the time of calibration, displays information related to the calibration on the display unit to enable the user to perform calibration.
The measuring device is characterized in that, at the time of calibration, the measurement value capturing key for instructing the capturing of the measured value of the calibration solution and the trend graph of the measured value of the calibration solution are displayed at the same time.   The measurement apparatus according to claim 1, wherein an operation key that is always displayed on the display unit during measurement and calibration is used as the measurement value capturing key.   The measuring apparatus according to claim 1, wherein the display unit further displays a numerical value of the measured value of the calibration solution at the same time.   The measurement apparatus according to claim 1, wherein the trend graph has a display scale of at least one of a measurement value axis and a time axis set for each type of calibration.   The measurement apparatus according to claim 1, wherein the trend graph has a display range of at least one of a measurement value axis and a time axis set for each type of calibration.   6. The measuring apparatus according to claim 1, wherein the trend graph has a center value of a measurement value axis set in accordance with the type of calibration.   The measurement apparatus according to claim 1, wherein the display unit is configured by a touch panel.

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