JP5377983B2 - measuring device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a measuring device capable of obtaining outline of a measured value in a short time without enlarging the device, and displaying the measured value in detail as the need arises. <P>SOLUTION: This measuring device includes a measuring part for measuring an electric parameter (for example, a resistance value) relative to a measuring object, and a control part for displaying a measured value based on a measurement result by the measuring part on a display part in terms of a numerical value. The control part allows a display part to display a measured value in a first display mode for displaying to the third decimal place when the measurement result is within a measured value range (within the range not less than 0.090 M&Omega; and not more than 0.200 M&Omega;) specified beforehand, allows the display part to display the measured value in a second display mode for displaying only to the second decimal place when the measurement result is lower than a lower limit value (0.090 M&Omega;) of the measured value range, and allows the display part to display the measured value in a third display mode for displaying only to the first decimal place when the measurement result exceeds an upper limit value (0.200 M&Omega;) of the measured value range. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a measurement apparatus that displays a measurement value based on a measurement result as a numerical value on a display unit.

  As this type of measuring apparatus, a digital insulation resistance meter (hereinafter also simply referred to as “resistance meter”) that digitally displays a measured value is disclosed in Japanese Patent No. 2929760. This ohmmeter is provided with a digital display unit for displaying measured values as numerical values (4-digit segment display) and a bar graph display unit for displaying measured values in a bar graph. In this case, with this type of ohmmeter, a certain amount of time has passed since the measurement of the resistance value (display of the measured value) until the display value below the decimal point in the measured value can be accurately displayed. Takes time. For this reason, immediately after the start of measurement, the lower display value of the measurement value fluctuates (the lower display value of the measurement value fluctuates little by little), making it difficult to read (understand) the measurement value.

  On the other hand, in this resistance meter, in addition to the normal display of the measured value on the digital display unit, as an example, the measured value is displayed on the bar graph display unit with an accuracy of about 1/10 of the measured value displayed on the digital display unit. The configuration is adopted. Specifically, with this ohmmeter, the measured value is displayed in detail on the digital display up to the display value below the decimal point, and the bar graph display unit is measured with a bar corresponding to the value above the decimal point. A configuration that displays a summary of values is adopted. As a result, with this ohmmeter, the measured value can be obtained by referring to the bar graph display section even when the display value below the decimal point in the measured value displayed on the digital display section fluctuates immediately after the start of measurement. It is possible to grasp the outline of.

Japanese Patent No. 2929760 (page 1-4, Fig. 2-4)

  However, the conventional resistance meter has the following problems. That is, in the conventional ohmmeter, a bar graph display unit for enabling an overview of the measurement value and a digital display unit for enabling a detailed measurement value to be grasped are separately provided in the display unit. . Therefore, since a large display unit having a wide display area for displaying two of the bar graph display unit and the digital display unit is necessary, the conventional ohmmeter has a problem that the apparatus main body is enlarged. There is. Moreover, in the conventional ohmmeter, it is trying to grasp | ascertain the outline | summary of a measured value by a bar graph display in a short time. However, in reality, it is difficult to read the bar graph display that displays the measured value due to the lighting state of a very small bar, so it is difficult to instantaneously grasp the outline of the measured value There is also.

  In this case, as a usage form of this type of measuring device (resistance meter), for example, whether the measurement object has a resistance value equal to or higher than a reference value defined by the standard (for example, “0.1 MΩ”) ”Is used. In such a usage pattern, when the measured value greatly exceeds the reference value (for example, when the resistance value is less than 0.5 MΩ), the measured value is, for example, “0.489 MΩ” or “0.491 MΩ”. Any of the above (no matter what the second decimal place or the third decimal place is), the standard is still satisfied, so wait until the display value below the decimal point settles Even if not, the inspection (measurement process) can be terminated at the time when the upper display value is displayed, assuming that the resistance value is equal to or higher than the reference value.

  However, for users who are unfamiliar with the measurement process using this type of device, the measured value is “0.4 MΩ or more in the state where the display values of the second decimal place and the third decimal place in the above example are staggered. It is difficult to grasp for a moment. For this reason, in order for an unfamiliar user to recognize that the object to be measured has a resistance value greater than or equal to the reference value by looking at the display on the digital display unit, as a result, detailed measurement is performed on the digital display unit. As long as the time it takes for the value to be displayed (the time it takes for the inexperienced user to instantly grasp the measured value when the lower display value of the measured value is settled) There is a current situation that takes time.

  On the other hand, reduce the number of digits displayed after the decimal point in the measured value (round down, round down, or round up the displayed value on the lower side) and instantly grasp the outline of the measured value even for inexperienced users. It is conceivable to adopt a configuration in which the measurement value is displayed so that the measurement value can be displayed. However, for example, when the actual resistance value is “0.099 MΩ”, it is determined that the measurement object does not satisfy the standard, and when the resistance value is “0.101 MΩ”, the measurement object. Therefore, when the actual resistance value is close to the reference value, it is necessary to display the display value on the lower side after the decimal point in detail.

  The present invention has been made in view of such problems, and can display the measurement values in detail as necessary while allowing an overview of the measurement values to be grasped in a short time without incurring an increase in the size of the apparatus. The main object is to provide a measuring device to obtain.

In order to achieve the above object, a measuring apparatus according to claim 1 includes a measuring unit that measures an electrical parameter of a measurement object, and a control unit that displays a measured value based on a measurement result of the measuring unit as a numerical value on a display unit. When the control unit displays the measurement value on the display unit, the control unit determines whether or not the measurement result is within a predetermined measurement value range, and the measurement value When it is within the range, the measurement value is displayed in the first display mode that displays up to the Nth decimal place (N is a natural number), and when the measurement result is below the lower limit value of the measurement value range, The measurement value is displayed in the second display mode that displays only up to the decimal place M (M is an integer equal to or less than (N-1)), and the measurement result exceeds the upper limit value of the measurement value range. sometimes, decimal L level (L is, (M -1) the following integer ) In a third display mode for displaying only before displaying the measured value. Incidentally, the state of the to have you in the present invention "to display only the decimal to the 0 position" means a condition for displaying the measured values only integer part no point or fractional part.

  According to a second aspect of the present invention, in the measurement apparatus according to the first aspect, the control unit causes the display unit to display the measured value right-justified.

  Moreover, the measuring apparatus of Claim 3 in the measuring apparatus of Claim 1 or 2 alert | reports so that it can specify whether the said control part is displaying the said measured value by the said 1st display mode. .

According to the measurement apparatus of claim 1, when displaying the measurement value on the display unit, it is determined whether or not the measurement result is within a predetermined measurement value range, and the measurement result is within the predetermined measurement value range. The measured value is displayed on the display unit in the first display mode that displays up to the Nth decimal place when within, and only up to the Mth decimal place when the measurement result is below the lower limit value of the measured value range. The measurement value is displayed on the display unit in the second display mode to be displayed, and the measurement value is displayed in the third display mode that displays only up to the Lth decimal place when the measurement result exceeds the upper limit value of the measurement value range. By displaying on the display unit, when the measurement result of the measurement unit is, for example, a value close to the reference value defined in the standard (within the measurement value range), the first decimal number is displayed up to the Nth decimal place. The measurement value is displayed in the display mode, and the measurement result of the measurement unit is significantly different from the above reference value. When the value is below the lower limit of the measurement value range or exceeds the upper limit of the measurement value range, the number of digits displayed after the decimal point is displayed up to the Nth decimal place. Since the measured value is displayed in the second display mode or the third display mode less than the one display mode, the conventional resistance in which two display areas of the digital display unit and the bar graph display unit are separately provided in the display unit Unlike the meter, it does not cause an increase in the size of the measuring device, and when the measurement result of the measurement object is close to the reference value, the measurement value can be displayed in detail and the detailed measurement value can be grasped. At the same time, when the measurement result of the measurement object is far from the reference value, the displayed approximate number (an outline of the measurement value) can be read instantaneously.

  According to the measuring apparatus of claim 2, the measured value is displayed on the display unit in the second display mode or the third display mode by displaying the measured value right-aligned on the display unit. The measured value can be read more reliably and more easily than the state in which an unnecessary space is generated on the right side (between the “measured value” and the symbol indicating “unit”) (the state where no right-alignment is displayed).

  Moreover, according to the measuring apparatus of Claim 3, it displays by a 2nd display mode or a 3rd display mode by alert | reporting identifiable whether the measured value is displayed by the 1st display mode. In the state where the measured value is displayed on the part, whether the displayed measured value is a measured value based on the measurement results up to the decimal place M and the decimal place L, or the detailed obtained to the decimal place N or less It is possible to intuitively recognize whether the outline of the measured value is displayed by numerical values up to M decimal places and L decimal places.

1 is a block diagram of a measuring device 1. FIG. It is explanatory drawing for demonstrating the display aspect of the measured value by the measuring apparatus. It is a flowchart of the measured value display process 10. It is a display screen figure in the state where the measured value is displayed by the 1st display mode in the present invention. It is a display screen figure of the state which is displaying the measured value by the 2nd display mode in this invention. It is a display screen figure of the state which is displaying the measured value by the 3rd display mode in this invention.

  Hereinafter, embodiments of a measuring apparatus according to the present invention will be described with reference to the accompanying drawings.

  First, the configuration of the measuring apparatus 1 will be described with reference to the attached drawings.

  A measuring apparatus 1 shown in FIG. 1 is an example of a measuring apparatus according to the present invention, and includes a measuring unit 2, an operating unit 3, a display unit 4, a storage unit 5, and a control unit 6. Various electrical parameters such as values, current values, and resistance values are measured, and the measurement values based on the measurement results can be displayed numerically. The measurement unit 2 includes a power supply unit, a current / voltage detection circuit, an A / D conversion circuit, an arithmetic circuit, and the like (not shown). The measurement unit 2 measures electrical parameters of the measurement object X according to the control of the control unit 6. Measurement data D1 (an example of “measurement result” in the present invention) is output. In the following description, an example of measuring the resistance value of the measuring object X will be described as an example in order to facilitate understanding of the present invention. Further, in practice, a test lead (measuring cable) or the like for connecting the measuring object X and the measuring unit 2 to each other is provided, but illustration and description thereof are omitted.

  The operation unit 3 includes a changeover switch or the like (not shown) for switching the measurement mode of the measurement apparatus 1 and the measurement range of the measurement process performed by the measurement unit 2 and outputs an operation signal corresponding to the switch operation to the control unit 6. Since the measurement mode and the measurement range switching operation and the processing executed by the measurement unit 2 and the control unit 6 in accordance with the operation are well known, explanations thereof will be given to facilitate understanding of the present invention. Omitted. As an example, the display unit 4 is configured by an LCD panel, and displays a measurement value based on the measurement result of the measurement unit 2 as a numerical value under the control of the control unit 6 as described later. In addition, although the measurement apparatus 1 provided with the display part 4 for displaying a measured value is mentioned as an example and demonstrated, the structure which displays a measured value on the indicator as an external apparatus is also employable. The memory | storage part 5 memorize | stores the display procedure data D0 comprised by the information regarding each display mode of the measured value range in this invention and the measured value range in this invention.

  In this case, as an example of the display procedure data D0, as shown in FIG. 2, the resistance value of the measurement object X measured by the measurement unit 2 (“measurement result” in the present invention) is 0.090 MΩ or more and 0.0. When it is within a range of 200 MΩ or less (an example of the “predetermined measurement value range” in the present invention), a display mode that displays up to the third decimal place (an example of “N = 3”) (the “first” in the present invention) Measured value is displayed on the display unit 4 and the measured resistance value of the measurement object X falls below the lower limit of the above range (in this example, “0.090 MΩ”). Is displayed with a smaller number of display digits after the decimal point than the display in the first display mode (display up to the third decimal place), and the display in the third display mode (decimal number Display digits after the decimal point Display the measured value on the display unit 4 in a display mode (display mode (an example of “second display mode” in the present invention) that displays only up to the second decimal place (example of “M = 2”)), When the measured resistance value of the measurement object X exceeds the upper limit value (in this example, “0.200 MΩ”), only the first decimal place (example of “L = 1”) is used. Information indicating that the measurement value is displayed on the display unit 4 in the display mode (an example of “third display mode” in the present invention) to be displayed is recorded.

  The display procedure data D0 is generated based on the above range and display mode defined by the manufacturer of the measuring apparatus 1 according to various standards as an example. The “measured value range” and the number of display digits after the decimal point for each display mode can be arbitrarily set by the user of the measuring apparatus 1 prior to the start of the measurement process. The control unit 6 controls the measuring device 1 as a whole. Specifically, the control unit 6 controls the measurement unit 2 to execute measurement of electrical parameters for the measurement object X, and executes a measurement value display process 10 shown in FIG. 3 as will be described later. Then, based on the measurement data D1 output from the measurement unit 2, the measurement value data D2 for displaying the measurement value on the display unit 4 is generated. Moreover, the control part 6 displays the measured value based on the measurement result by the measurement part 2 by a numerical value by outputting the produced | generated measured value data D2 to the display part 4. FIG.

  Next, a resistance value measurement process using the measurement apparatus 1 will be described with reference to the drawings.

  When using this measuring apparatus 1, for example, when performing an inspection “whether the measuring object X has a resistance value equal to or higher than a reference value (“ 0.1 MΩ ”as an example) defined in the standard). First, in a state where the measurement unit 2 is connected to the measurement object X, the operation unit 3 is operated to start a resistance value measurement process. At this time, the control unit 6 controls the measurement unit 2 according to the control signal from the operation unit 3 to measure the resistance value of the measurement object X. In response to this, the measurement unit 2 outputs the measurement result (resistance value in this example) for the measurement object X to the control unit 6 as measurement data D1. On the other hand, the control unit 6 starts the measurement value display process 10 shown in FIG. 3 with the output of the measurement data D1 from the measurement unit 2. In this measurement value display processing 10, the control unit 6 determines the measurement value based on the display procedure data D 0 in which the measurement data D 1 output from the measurement unit 2 (measurement result for the measurement object X) is stored in the storage unit 5. It is determined whether or not the value is within a range (in this example, a range of 0.090 MΩ to 0.200 MΩ) (step 11).

  At this time, as an example, when the measurement data D1 indicates a value of “0.101 MΩ” (an example of “when the measurement result is within the measurement value range”), the control unit 6 displays the display procedure data D0. Accordingly, the measurement value data D2 for displaying the measurement value based on the display procedure data D0 in the display mode displaying up to the third decimal place is generated and output to the display unit 4. At this time, as shown in FIG. 4, a detailed measurement value 21 of “0.101 MΩ” is right-justified and displayed on the display unit 4 (step 12). In this case, the measurement apparatus 1 is not limited to the above example, and when the value indicated by the measurement data D1 is in the range of 0.090 MΩ or more and 0.200 MΩ or less, that is, the measurement result by the measurement unit 2 is standard. The measured value 21 is displayed on the display unit 4 in a display mode in which up to the third decimal place is displayed when the value is close to the reference value determined in. Therefore, based on the measured value 21 displayed on the display unit 4, it is possible to accurately determine whether or not the measurement object X satisfies the standard (whether or not it has a resistance value greater than or equal to the reference value). It has become.

  On the other hand, when the value of the measurement data D1 is a value outside the above measurement value range (step 11) and, for example, the measurement data D1 indicates a value of “0.075 MΩ” (“the measurement result is in the measurement value range”). An example of “when the value is below the lower limit value”: Step 13), in accordance with the display procedure data D0, the control unit 6 displays the measured value based on the display procedure data D0 only to the second decimal place. Measurement value data D <b> 2 for display is generated and output to the display unit 4. At this time, the control unit 6 generates measurement value data D2 by rounding down the value of the third decimal place or less in the measurement result “0.075 MΩ”. At this time, as shown in FIG. 5, the measured value 21 of “0.07 MΩ” is displayed right-justified on the display unit 4 (step 14). In this case, since the measurement value data D2 is generated by rounding down the value of the third decimal place, the value of the third decimal place or less in the measurement data D1 (measurement result) sequentially output from the measurement unit 2 fluctuates. Even if it is, the measured value 21 displayed on the display unit 4 can be instantaneously read because the value below the third decimal place is not displayed.

  Further, the control unit 6 can specify that the rounded display value after the decimal point (display value of the third decimal place) in the measurement result by the measurement unit 2 is rounded down and the approximate value of the measurement value is displayed (this book). In the invention, it is possible to specify that the measured value is displayed in a display mode that is not the “first display mode”), and as an example, the notification display 22 that “approximate number is being displayed” is displayed blinking (step 15). Thereby, the user who has seen the notification display 22 knows that the measured value 21 is an approximate number of actual measured values. In this case, the measurement apparatus 1 is not limited to the above example, and when the value indicated by the measurement data D1 is less than 0.090 MΩ, that is, the measurement result by the measurement unit 2 is a standard defined by the standard. When the value is greatly below, the measured value 21 is displayed on the display unit 4 and the notification display 22 is flashed in a display mode in which only the second decimal place is displayed. Therefore, the measurement value 21 displayed on the display unit 4 is an approximate number, and whether or not the measurement object X satisfies the standard (in this example, it does not have a resistance value greater than the reference value). Can be grasped instantly.

  Further, when the value of the measurement data D1 is a value outside the above measurement value range (step 11) and, for example, the measurement data D1 indicates a value of “0.489 MΩ” (“the measurement result is in the measurement value range”). An example of “when the upper limit value is exceeded”: Step 13), the control unit 6 displays the measurement value based on the display procedure data D0 in a display mode in which only the first decimal place is displayed according to the display procedure data D0. Measurement value data D2 for generating the data is generated and output to the display unit 4. At this time, the control unit 6 generates measurement value data D2 by rounding down the second decimal place value of the measurement result “0.489 MΩ”. At this time, as shown in FIG. 6, the measured value 21 of “0.4 MΩ” is displayed right-justified on the display unit 4 (step 16). In this case, since the measured value data D2 is generated by truncating the value below the second decimal place, the value less than the second decimal place in the measurement data D1 (measurement result) sequentially output from the measurement unit 2 fluctuates. Even if it is, the measured value 21 displayed on the display unit 4 can be instantaneously read because the value below the second decimal place is not displayed.

In addition, the control unit 6 displays the approximate number of the measurement values by rounding down the display values of the second decimal place and below (display values of the second decimal place and the third decimal place) in the measurement result by the measurement section 2. As an example, the notification display 22 that “approximate number is being displayed” is blinked and displayed as an example (to be able to specify that the measured value is displayed in a display mode other than the “first display mode” in the present invention) ( Step 17). Thereby, the user who has seen the notification display 22 knows that the measured value 21 is an approximate number of actual measured values. In this case, the measurement apparatus 1 is not limited to the above example, and when the value indicated by the measurement data D1 exceeds 0.200 MΩ, that is, the measurement result by the measurement unit 2 is the reference value determined by the standard. When it greatly exceeds, the measured value 21 is displayed on the display unit 4 and the notification display 22 is flashed in a display mode in which only the first decimal place is displayed. Therefore, the measurement value 21 displayed on the display unit 4 is an approximate number, and whether or not the measurement object X satisfies the standard (in this example, the resistance value is equal to or higher than the reference value). Can be grasped instantly.

  Thus, according to this measuring apparatus 1, when the measurement result (value of the measurement data D1) by the measurement unit 2 is within a predetermined measurement value range (in this example, 0.090 MΩ or more and 0.200 MΩ or less). The measured value is displayed on the display unit 4 in the first display mode displaying up to the third decimal place when the value is within the range, and the measurement result is the lower limit value of the above measured value range (in this example, 0.090 MΩ) The measured value is displayed on the display unit 4 in the second display mode in which only the second decimal place is displayed when the value is below the measurement value, and the measurement result is the upper limit value of the above measurement value range (in this example, 0. 200 MΩ), when the measured value is displayed on the display unit 4 in the third display mode that displays only the first decimal place, the measurement result of the measurement unit 2 (value of the measurement data D1) is For example, close to the standard value of “0.1MΩ” defined in the standard When it is a value (in this example, “in the range of 0.090 MΩ or more and 0.200 MΩ or less”), measurement is performed in a display mode (first display mode in the present invention) that displays up to the third decimal place. When the value 21 is displayed and the measurement result of the measurement unit 2 (value of the measurement data D1) is greatly deviated from the reference value (in this example, “below 0.090 MΩ”), Or, in the state of “exceeding 0.200 MΩ”, the display mode (second display mode or third mode in the present invention) displays only the second decimal place or the first decimal place. The measurement value 21 is displayed in the display mode), and therefore, unlike the conventional ohmmeter in which two display areas of the digital display unit and the bar graph display unit are separately provided in the display unit, the measurement apparatus 1 is increased in size. Without incurring the measurement object X When the measurement result is close to the reference value, the measurement value 21 can be displayed in detail to grasp the detailed measurement value, and when the measurement result for the measurement object X is far from the reference value, it is displayed. Approximate numbers can be read instantly.

  Moreover, according to this measuring apparatus 1, the measurement value 21 is displayed on the display unit 4 in the second display mode or the third display mode of the present invention by displaying the measurement value right-aligned on the display unit 4. , The measured value 21 can be read more reliably and more easily than the state in which an unnecessary space is generated on the right side of the measured value 21 (between the symbol indicating “measured value” and “unit”) (the state in which no right-alignment is displayed). .

  Furthermore, according to this measuring apparatus 1, whether or not the measurement value is displayed in the first display mode is reported in an identifiable manner (in this example, the measurement value is displayed in the second display mode and the third display mode). Is displayed on the display unit 4), the measured value 21 is displayed on the display unit 4 in the second display mode or the third display mode of the present invention. In the state where “” is displayed, whether the displayed measurement value 21 is the measurement value 21 based on the measurement result only to the second decimal place or the first decimal place, or the detailed measurement obtained up to the third decimal place It is possible to intuitively recognize whether the summary of the value is displayed with numerical values only to the second decimal place and the first decimal place.

In addition, this invention is not limited to said structure. For example, the example in which “N”, “M”, and “L” in the present invention are respectively “3”, “2”, and “1” has been described, but each display mode in the present invention (the above “N”, “ M "and" L ") are not limited to this. Also, an example is described for right aligned displaying measurement values for each display mode, the present invention are not limited thereto, without right aligned displaying measurement values, to fix the display position of ". (Point)" It is also possible to adopt a configuration for displaying measured values.

  Even when these various configurations are employed, the measurement result of the measurement unit 2 (value of the measurement data D1) is, for example, a standard of “0.1 MΩ” defined by the standard, in the same manner as the measurement device 1 described above. When the value is close to the value, the measured value 21 is displayed in a display mode (first display mode in the present invention) that displays up to the Nth decimal place, and the measurement result of the measurement unit 2 (value of the measurement data D1) is When the display value is significantly different from the reference value, the display mode (the second display mode or the third display mode in the present invention) is smaller than the display mode in which the number of display digits after the decimal point is displayed up to the Nth decimal place. Since the measured value 21 is displayed, unlike the conventional ohmmeter in which two display areas of the digital display unit and the bar graph display unit are separately provided in the display unit, the measuring apparatus 1 is not increased in size, and , Measurement object X Together with the measurement results about the time is close to the reference value can grasp the detailed measurements when the measurement results of the measurement object X is far from the reference value can be read the approximate number that is displayed instantly.

  In addition, the measuring device 1 configured to notify whether or not the measurement value 21 is displayed in the first display mode by blinking the notification display 22 including the character string “approximate number is being displayed” is displayed. Although described as an example, the present invention is not limited to this, and instead of the notification display 22 described above, it is possible to specify whether or not the measurement value 21 is displayed in the first display mode in an identifiable manner. A configuration in which the indicator is turned on or off, or the measurement value 21 itself displayed in the first display mode or the measurement value 21 itself displayed in the second or third display mode is blinked or continuously displayed. It is also possible to employ a configuration for notifying whether or not the measurement value 21 is displayed in the first display mode. Even when such a configuration is adopted, in the state where the measurement value 21 is displayed on the display unit 4 in the second display mode or the third display mode in the present invention, in the same manner as the measurement device 1 described above, Whether the displayed measurement value 21 is the measurement value 21 based on the measurement result only to the second decimal place or the first decimal place, or a summary of the detailed measurement values obtained to the third decimal place or less It is possible to intuitively recognize whether the display is based on the numerical value of only the first place or the first decimal place.

DESCRIPTION OF SYMBOLS 1 Measuring apparatus 2 Measuring part 3 Operation part 4 Display part 5 Memory | storage part 6 Control part 10 Measurement value display process 21 Measured value 22 Notification display D0 Display procedure data D1 Measurement data D2 Measured value data X Measurement object

Claims (3)

A measurement apparatus comprising a measurement unit that measures an electrical parameter of a measurement object, and a control unit that displays a measurement value based on a measurement result of the measurement unit as a numerical value on a display unit,
When the measurement value is displayed on the display unit, the control unit determines whether or not the measurement result is within a predetermined measurement value range, and when the measurement value is within the measurement value range, N is the first display mode that displays up to a natural number), and when the measurement result is below the lower limit of the measurement value range, the Mth decimal place (M is (N -1) When the measurement value is displayed in the second display mode that displays only up to the following integer), and the measurement result exceeds the upper limit value of the measurement value range, the decimal place L (L is ( M- 1) A measuring apparatus that displays the measured value in a third display mode that displays only up to integers below.   The measurement device according to claim 1, wherein the control unit causes the display unit to display the measurement value right-justified.   The measurement apparatus according to claim 1, wherein the control unit notifies the user whether or not the measurement value is displayed in the first display mode.

Images