JP2007218607A - Measuring device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a measuring device capable of rapidly and easily inputting a set value used for sorting parts. <P>SOLUTION: The measuring device comprises a storage section 6 capable of storing set value data Ds showing a plurality of set values, an arithmetic control section 4 for determining a prediction equation based on the plurality of set values and calculating a predetermined prediction value using the prediction equation, and an operation section 5 for correcting the prediction value. The arithmetic control section 4 determines the corrected value obtained by correcting the prediction value by the operation of the operation section 5 as a new set value different from the plurality of set values shown by the set value data Ds. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a measuring apparatus configured to be able to set a setting value used for selecting parts, for example.

As this type of measuring device, an IC tester current measuring device disclosed in Japanese Patent Laid-Open No. 9-80114 is known. This IC tester current measuring device includes a measurement circuit (Iddd measurement circuit and Iddq measurement circuit in the publication), a measurement value memory circuit, a reference value memory circuit, and a comparator (a low side comparator and a high side comparator in the publication). It has. In this IC tester current measurement device, the measurement circuit measures the current value of the power supply current (Iddp and Iddq in the publication) supplied to the DUT, and the measurement value memory circuit measures the power supply current measured by the measurement circuit. Save the current value. The reference value memory circuit stores a set value of a comparison reference value input from the outside. On the other hand, the comparator compares the current value of the power supply current stored in the measurement value memory circuit with the comparison value based on the comparison reference value. Thereby, the user determines the quality of the DUT based on the comparison result (corresponding to the comparison determination result in the publication). By the way, a general measuring device such as a current measuring device of this IC tester is an operation configured to be able to input a value corresponding to the operation amount for inputting a set value such as the above-mentioned comparison reference value. And a display unit for displaying each set value so that the set value being input can be confirmed. In this case, the user sets a desired setting value to be input after setting a desired setting value among the values (for example, “0”) displayed on the display unit as an initial value of each setting value to a changeable state. By operating the operation unit by the operation amount corresponding to the difference between the initial value and the initial value, it is possible to input a desired value for each setting value.
Japanese Patent Laid-Open No. 9-80114 (page 2-4, FIGS. 1 and 2)

  However, the conventional measuring apparatus has the following problems. That is, in the conventional measuring apparatus, since the set value is not predicted, a numerical value of 0 is preset as the initial value of the set value. Therefore, the user has to repeatedly operate the up / down key, for example, the number of times corresponding to the value so that the numerical value becomes 0 to a desired setting value. There is a problem that the input operation is complicated.

  The present invention has been made in view of such problems, and a main object of the present invention is to provide a measuring apparatus capable of quickly and easily inputting set values used for part selection and the like.

  In order to achieve the above object, the measuring apparatus according to claim 1 is configured to determine a prediction formula based on the storage section configured to be capable of storing a plurality of set values, and to use the prediction formula. An arithmetic control unit that calculates a predetermined predicted value, and the arithmetic control unit determines the predicted value as a new set value different from the plurality of set values.

  According to a second aspect of the present invention, there is provided a measuring device configured to store a plurality of setting values, determine a prediction formula based on the plurality of setting values, and use the prediction formula to determine a predetermined prediction value. And an operation unit for correcting the predicted value, and the operation control unit determines the corrected value corrected by the operation of the operating unit as the plurality of set values. Are determined as different new set values.

  According to a third aspect of the present invention, in the measurement device according to the second aspect, when the operation unit corrects the predicted value, the rotation operation type dial outputs an operation signal corresponding to the rotation operation amount. The arithmetic control unit corrects the predicted value to the correction value based on the operation signal output from the rotary operation type dial.

  The measuring device according to claim 4 is the measuring device according to any one of claims 1 to 3, wherein the arithmetic control unit stores the prediction formula as an n-order equation in the storage unit. The order and coefficient of the prediction formula are determined so that the plurality of set values that have been set are the solutions.

  According to the measuring apparatus of claim 1, the calculation control unit calculates a predetermined predicted value using a prediction formula determined based on a plurality of set values and determines the predicted value as a new set value. Thus, the predicted value can be calculated using a prediction formula that matches the increasing / decreasing tendency in which the value of the set value input in the past changes, so that the predicted value can be brought close to the desired set value. Therefore, it is possible to input a desired set value quickly and easily as compared with a conventional apparatus that performs an input operation from 0 as an initial value to a desired set value.

  According to the measuring apparatus of claim 2, the calculation control unit calculates a predetermined predicted value using a prediction formula determined based on a plurality of set values, and the corrected corrected value is corrected by the operation unit. By determining the value as a new set value, when the value to be input as the set value does not match the calculated predicted value, it is only necessary to correct the predicted value calculated as a value close to the desired set value. A new set value can be set. In addition, when the value to be input as the set value matches the predicted value, the correction of the predicted value can be made unnecessary. For this reason, compared with the above-mentioned conventional measuring apparatus, the operation amount at the time of inputting a set value can be reduced. As a result, a desired set value can be input quickly and easily.

  Further, according to the measuring device of claim 3, the rotary operation type dial outputs an operation signal corresponding to the rotational operation amount, thereby performing an operation of pressing a predetermined number of times in order to input a desired set value. Compared to the up / down key, etc. that cannot correct the predicted value unless it is repeated, the predicted value can be corrected simply by rotating the rotary operation type dial, so that the predicted value can be corrected quickly and easily. As a result, a desired set value can be input quickly and easily.

  Furthermore, according to the measurement apparatus of claim 4, when the calculation control unit determines the prediction formula as an n-order equation, the prediction formula is set so that a plurality of set values stored in the storage unit are taken as solutions. By determining the order and coefficient, it is possible to calculate the predicted value using a prediction formula that matches the increasing / decreasing tendency of the setting value input in the past, so a value closer to the desired setting value can be obtained. As a result of being able to calculate as a predicted value, a desired set value can be input more quickly and easily. In this case, by determining the quadratic equation or the cubic equation as the nth order equation, the coefficient of the prediction formula can be determined quickly and easily.

  Hereinafter, the best mode 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 drawings.

  The measuring device 1 is a device that is used to measure the resistance value of a measurement object and to select (for example, rank) the measurement object based on the measured resistance value, for example, as shown in FIG. , Measuring unit 2, A / D converter 3, calculation control unit 4, operation unit 5, storage unit 6 and display unit 7. In this case, the measuring device 1 is configured to be able to set a plurality of ranks R for determining a resistance value range for ranking the resistance value of the resistor 100 as a measurement object, and the measured resistance value of the resistor 100 is It is configured to be able to determine which one of the plurality of ranks R belongs to.

  The measuring unit 2 includes a voltage source 2a, an operational amplifier 2b, and a resistor 2c having a resistance value Rs. In this case, the voltage source 2a supplies, for example, a constant voltage having a voltage value Vs to the resistor 100 via the resistor 2c. The A / D converter 3 performs an analog-digital (A / D) conversion on the output signal S1 output from the operational amplifier 2b to generate a digital signal S2 and output it to the arithmetic control unit 4.

  The arithmetic control unit 4 determines the resistance value (Ω) of the resistor 100 based on the voltage value indicated by the digital signal S2 output from the A / D converter 3, the resistance value Rs of the resistor 2c, and the output voltage Vs of the voltage source 2a. ) Is calculated. Further, the arithmetic control unit 4 executes rank setting processing 20 shown in FIG. 3 in order to set a plurality of ranks R used for ranking the resistance values of the resistors 100. In this case, when the setting value Sl that defines the lower limit of the predetermined range in each rank R and the setting value Su that defines the upper limit are input using the operation unit 5, the arithmetic control unit 4 Set value data Ds indicating Sl, Su (hereinafter also referred to as “set value S” when not distinguished) is stored in the storage unit 6.

  Further, in the rank setting process 20, when the setting values S for a plurality of (for example, two) ranks R are input, the arithmetic control unit 4 performs a predetermined prediction based on the input setting values S. A prediction formula F for calculating the values El and Eu is determined. Here, the predicted value El is a value obtained by predicting the lower limit set value S1 of the new rank R different from the input rank R, and the predicted value Eu is the upper limit set value Su of the new rank R. This is the predicted value. Further, the arithmetic control unit 4 determines the order De and the coefficient Co of the prediction formula F so that the set value S for each rank R is the solution. In this case, the arithmetic control unit 4 determines the nth order equation as the prediction formula F when the number of ranks R to which the set value S is input is (n + 1). For example, when the number of ranks R to which the set value S is input is two, the arithmetic control unit 4 determines the degree De of the prediction formula F to be “1”, and the number of ranks R to which the set value S is input is In the case of three, the degree De of the prediction formula F is determined to be “2”. When the number of ranks R is four or more, the degree De of the prediction formula F can be determined to be “2”.

  Further, the arithmetic control unit 4 causes the display unit 7 to display the calculated predicted values El and Eu as candidates for the set values Sl and Su in the predicted value display process 40 shown in FIG. In this case, when the displayed predicted value E is corrected to the desired correction value M by the operation unit 5, the arithmetic control unit 4 determines the correction value M as the new set value S for the rank R. In addition, when the displayed predicted value E is not corrected, the arithmetic control unit 4 determines the predicted value E as a set value S for a new rank R. At this time, the arithmetic control unit 4 causes the storage unit 6 to store setting value data Ds indicating the determined new setting value S.

  As shown in FIG. 2, the operation unit 5 includes a jog dial 5a corresponding to the rotary operation type dial according to the present invention, and a confirmation key 5b. The jog dial 5a receives an operation signal So corresponding to the amount of rotational operation when the set number N of rank R ("rank number" in the figure) and the set value S are input and when the predicted value E is corrected. Is output to the arithmetic control unit 4. On the other hand, the confirmation key 5b is operated when confirming each value input using the jog dial 5a, and outputs an operation signal So to that effect to the arithmetic control unit 4. The storage unit 6 is configured to be able to store set value data Ds under the control of the arithmetic control unit 4. Under the control of the arithmetic control unit 4, the display unit 7 has an input screen P (see FIG. 2) on which the set number N of rank R and each set value S can be input, the measured resistance value of the resistor 100, and the resistance 100 A result display screen (not shown) capable of displaying the rank R to which the resistance value belongs is displayed.

  Next, the overall operation of the measuring apparatus 1 will be described with reference to the drawings.

  First, the arithmetic control unit 4 executes a rank setting process 20 shown in FIG. Here, the lower limit set values Sla, Slb, Slc, Sld from the A rank Ra to the D rank Rd are set to “0Ω, 200Ω, 400Ω, and 600Ω” and the upper limit set values Sua, Sub, Suc, Sud. An example in which is set to “100Ω, 400Ω, 600Ω and 700Ω” will be specifically described. In this case, in the rank setting process 20, the arithmetic control unit 4 first displays the input screen P (see FIG. 2) on the display unit 7. In addition, on the input screen P at this stage, as shown in the figure, “0” as an initial value of each value is displayed at an input portion where the set number N or the set value S is not input, and first, A cursor (an underline below the input portion of the set number N in the figure) is displayed at the input location of the set number N as an inputable item. At this time, the user operates the jog dial 5a by a predetermined rotational operation amount to change the value (display value) displayed at the input position of the set number N from the initial value to a desired set value (in this case, “4”). ), The set number N is fixed to “4” by operating the enter key 5b. At this time, the jog dial 5a outputs an operation signal So corresponding to the rotational operation amount to the arithmetic control unit 4, and the enter key 5b decides the value of the input location where the cursor is (in this case, the set number N). The operation signal So to the effect is output to the arithmetic control unit 4. Thereby, the arithmetic control unit 4 sets the set number N with the current cursor to “4” based on the operation signal So output from the jog dial 5a (step 21), and also displays the display as shown in FIG. The unit 7 is controlled to move the cursor to the position of the next input item (in this case, the lower limit set value Sla of the A rank).

  In this case, the user determines that the lower limit set value Sla (0Ω) to be input next matches the initial value (0Ω), and operates the enter key 5b without operating the jog dial 5a. To set the set value Sla to “0Ω”. At this time, the arithmetic control unit 4 controls the display unit 7 in accordance with the operation signal So output from the confirmation key 5b to move the cursor to the next input item (in this case, the upper limit set value Su of A rank). Move to the position. Here, the user determines that the upper limit set value Sua (100Ω) to be input does not match the initial value, and operates the jog dial 5a by a predetermined rotational operation amount to display the set value Sua. Is increased from the initial value to a desired set value (100Ω in this case), and then the set key Su is operated to fix the set value Sua to “100Ω”. In response to this, the arithmetic control unit 4 controls the display unit 7 to move the cursor to the position of the next input item (in this case, the lower limit set value Slb of the B rank). In this case, the arithmetic control unit 4 sets each set value Sla, Sua to “0Ω” and “100Ω” based on the operation signal So output from the jog dial 5a (step 22). Subsequently, the arithmetic control unit 4 stores the set value data Dsa of A rank Ra indicating the set values Sla and Sua in the storage unit 6 (step 23).

  Next, the arithmetic control unit 4 determines whether or not two or more set values S1 and Su for the rank R have been set (step 24). At this stage, since only the set value data Dsa of A rank Ra is set, the calculation control unit 4 stands by until the next set values Slb and Sub are input. Run again. At this time, as shown in FIG. 5, the user operates the jog dial 5a and the enter key 5b in the same manner as described above to set the set values Slb, Sub (in this case, 200Ω and 400Ω). At this time, the jog dial 5a and the enter key 5b operate in the same manner as described above, and output each operation signal So to the arithmetic control unit 4. Thereby, the arithmetic control unit 4 sets the set values Slb and Sub to “200Ω” and “400Ω”, respectively, based on the operation signal So output from the jog dial 5a (step 22). Subsequently, the arithmetic control unit 4 causes the storage unit 6 to store the set value data Dsb of the B rank Rb indicating the set values Slb and Sub (step 23). In this case, since the set value data Dsa and Dsb of the A rank Ra and the B rank Rb are stored in the storage unit 6, the calculation control unit 4 sets the set values S1 and Su of two or more ranks R in step 24. It is determined that it has been set, and the predicted value display process 40 shown in FIG. 6 is executed (step 25).

  In the predicted value display process 40, the calculation control unit 4 receives the set values S of the two ranks R, so the set values S of the input ranks R (that is, the settings stored in the storage unit 6). The order De of the prediction formula F is determined to be “1” so that the set value S indicated by the value data Ds is a solution (step 41), whereby the prediction formula F is converted to a linear equation (in this case, y = ax + b). ). In this equation F, the dependent variable (in this case, y) indicates the set value S, and the independent variable (in this case, x) is the rank value corresponding to the set value S (A rank Ra is “1”). , B rank Rb is “2”, C rank Rc is “3”, and D rank Rd is “4”). Subsequently, the arithmetic control unit 4 determines the coefficients Co of the prediction equations Fl and Fu so that the inputted set value S of the rank R is a solution (step 42). In this case, since the lower limit set values Sla and Slb (0Ω and 200Ω) are input for the two ranks Ra and Rb, the arithmetic control unit 4 predicts the prediction formula Fl so that both the set values Sla and Slb are the solutions. The coefficient Co (in this case, a and b) of (y = ax + b) is determined. Specifically, the arithmetic control unit 4 substitutes each set value Sla, Slb and the corresponding rank value (“1” or “2”) into the dependent variable and the independent variable of the prediction formula Fl for each rank. Thus, two equations (“0 = a + b” and “200 = 2a + b”) having the coefficient Co as an unknown are determined, and the coefficient Co is determined by solving simultaneous equations composed of the determined two equations. In this case, since the coefficient Co is “a = 200, b = −200”, the arithmetic control unit 4 determines the prediction formula Fl as “y = 200x−200” using the determined degree De and the coefficient Co. .

  Further, since the upper limit set values Sua and Sub (100Ω and 400Ω) are input for the two ranks Ra and Rb, the arithmetic control unit 4 uses the prediction formula Fu so as to solve both the set values Sua and Sub. The coefficient Co is determined. In this case, the arithmetic control unit 4 operates in the same manner as the above operation, and uses two equations (“100 = a + b” and “400 = 2a + b”) based on both the set values Sua, Sub and the corresponding rank values. The coefficient Co is determined by solving the simultaneous equations formed. In this case, since the coefficient Co is “a = 300, b = −200”, the arithmetic control unit 4 determines the prediction formula Fu as “y = 300x−200” using the determined degree De and the coefficient Co. .

  Next, the arithmetic control unit 4 calculates the predicted values El and Eu of the rank Rc not set using the prediction formulas Fl and Fu (step 43). In this case, the arithmetic control unit 4 substitutes the value of the rank Rc that has not been set (in this case, “3”) for the independent variable of the determined lower limit prediction formula Fl (y = 200x−200). “400Ω” is calculated as Elc. Further, the arithmetic control unit 4 calculates “700Ω” as the predicted value Euc by substituting the value of the unset rank Rc into the independent variable of the determined upper limit prediction formula Fu (y = 300x−200). Subsequently, the arithmetic control unit 4 controls the display unit 7 to display the calculated predicted values El (400Ω) and Eu (700Ω) of the calculated rank Rc on the input screen P as shown in FIG. Step 44), the predicted value display process 40 is terminated.

  In this case, the user determines that the lower limit set value Slc of C rank Rc to be input next matches the displayed predicted value Elc, and presses the enter key 5b without operating the jog dial 5a. The set value Slc is fixed to “400Ω” by operating. In response to this, the calculation control unit 4 controls the display unit 7 to move the cursor to the position of the next input item (in this case, the upper limit set value Suc of the C rank). Next, the user determines that the upper limit set value Suc (600Ω) to be input next does not match the displayed predicted value Euc (700Ω), and operates the jog dial 5a to set the set value Suc. Is corrected from the predicted value Euc to the desired set value (in this case, 600Ω), and then the corrected value Muc (see FIG. 8) obtained by correcting the predicted value Elc is determined as the set value Suc. In response to this, the arithmetic control unit 4 controls the display unit 7 to move the cursor to the position of the next input item (in this case, the D rank lower limit set value Sld). Thus, the lower limit set value Slc can be set without operating the jog dial 5a because the predicted value Elc and the set value Slc match, and the upper limit set value Suc can be set in the vicinity of the set value Suc. Setting is possible only by correcting the predicted value Euc. For this reason, the operation amount of the jog dial 5a when setting the setting values Slc and Suc becomes extremely small as compared with inputting the setting values Slc and Suc by correcting the initial value.

  Next, the arithmetic control unit 4 determines whether or not the operation signal So is output from the jog dial 5a (step 26). In this case, since the operation signal So is output before the predicted value Euc is determined, the arithmetic control unit 4 outputs the operation signal So based on the operation signal So output from the jog dial 5a. A corrected value Muc (600Ω) in which the predicted value Euc of the C rank Rc where the cursor is located is corrected is calculated (step 27). In this case, the arithmetic control unit 4 determines the predicted value Elc (400Ω) as the set value Slc and also determines the correction value Muc (600Ω) as the set value Suc (step 28). Subsequently, the calculation control unit 4 stores the set value data Dsc of the C rank Rc indicating the set values Slc and Suc in the storage unit 6 (step 29). Next, the arithmetic control unit 4 determines whether or not the set value data Ds of the set number N (four in this case) is stored in the storage unit 6 (step 30). In this case, since the set value data Dsa to Dsc from the A rank Ra to the C rank Rc are stored, the arithmetic control unit 4 executes the predicted value display process 40 in step 25 again.

In the predicted value display process 40, the calculation control unit 4 receives the set values S of the three ranks R, and therefore the order De of the prediction formula F so that the set value S of the input ranks R is the solution. Is determined to be “2” (step 41), whereby the prediction formula F is determined to be a quadratic equation (in this case, y = ax ² + bx + c). Subsequently, the arithmetic control unit 4 determines the coefficients Co of the prediction equations Fl and Fu so that the inputted set value S of the rank R is a solution (step 42). In this case, since the lower limit set values Sla to Slc (0Ω, 200Ω and 400Ω) are input for the three ranks Ra to Rc, the arithmetic control unit 4 makes these set values Sla to Slc as solutions. A coefficient Co (in this case, a, b, and c) of the prediction formula Fl (y = ax ² + bx + c) is determined. Specifically, the arithmetic control unit 4 converts each set value Sla to Slc and each rank value (in this case, “1”, “2”, or “3”) into a dependent variable of the prediction formula Fl for each rank, and By substituting into the independent variable, three equations (“0 = a + b + c”, “200 = 4a + 2b + c” and “400 = 9a + 3b + c”) with the coefficient Co as an unknown are determined, and are composed of the determined three equations The coefficient Co is determined by solving the simultaneous equations. In this case, since the coefficient Co is “a = 0, b = 200, c = −200”, the arithmetic control unit 4 uses the determined degree De and the coefficient Co to calculate the prediction formula Fl as “y = 200x−200. Decided.

Further, since the upper limit set values Sua to Suc are input for the three ranks Ra to Rc, the arithmetic control unit 4 makes the prediction formula Fu so as to solve the set values Sua to Suc (100Ω, 400Ω and 600Ω). A coefficient Co of (y = ax ² + bx + c) is determined. In this case, the arithmetic control unit 4 operates in the same manner as the above operation, and three equations (“100 = a + b + c”, “400 = 4a + 2b + c”, “400”) based on the set values Sua to Suc and the values of the respective ranks. 600 = 9a + 3b + c ”) to determine the coefficient Co. In this case, since the coefficient Co is “a = −50, b = 450, c = 300”, the arithmetic control unit 4 uses the determined degree De and the coefficient Co to calculate the prediction formula Fu as “y = −50x ^2. + 450x + 300 ". In this way, by determining the order De and the coefficient Co of the prediction formula F so that the set value S is a solution, the prediction formula F that matches the increasing / decreasing trend in which the value of the set value S input in the past changes is obtained. Since the predicted value E can be calculated using the value, a value closer to the desired set value S is calculated as the predicted value E.

Next, the arithmetic control unit 4 calculates the predicted values Eld and Eud of the unset D rank Rd using the prediction formulas Fl and Fu, respectively (step 43). Specifically, the arithmetic control unit 4 determines the value of the D rank Rd as an independent variable of the determined lower limit prediction formula Fl (y = 200x−200) and the upper limit prediction formula Fu (y = −50x ² + 450x + 300). By substituting (“4” in this case), “600Ω” and “700Ω” are calculated as the predicted values Eld and Eud of the set values Sld and Sud. Subsequently, the arithmetic control unit 4 controls the display unit 7 to display the calculated predicted values Eld and Eud on the input screen P (step 44), as shown in FIG. finish.

  In this case, the user determines that the lower limit set value Sld of the D rank Rd to be input next matches the displayed predicted value Eld, and presses the enter key 5b without operating the jog dial 5a. Operate to set the set value Sld to “600Ω”. In response to this, the calculation control unit 4 controls the display unit 7 to move the cursor to the position of the next input item (in this case, the upper limit set value Su of D rank). Next, the user determines that the upper limit set value Sud and the displayed predicted value Eud match, and operates the enter key 5b without operating the jog dial 5a to set the set value Sud to “700Ω”. To confirm.

  In this case, the calculation control unit 4 determines that the operation signal So from the jog dial 5a is not output in step 26, and sets the predicted values Eld and Eud for each setting of the D rank Rd without executing step 27. The values Sld and Sud are respectively set (step 28). Subsequently, the arithmetic control unit 4 stores the set value data Dsd of the D rank Rd indicating the set values Sld and Sud in the storage unit 6 (step 29). Next, since the set value data Dsa to Dsd from the A rank Ra to the D rank Rd are stored, the arithmetic control unit 4 determines that the set value data Ds of the set number N is stored in step 30, The display of the input screen P is terminated and the rank setting process 20 is terminated.

  Next, the user sets the resistance 100 to be measured in the measurement unit 2. At this time, the voltage source 2a supplies a constant voltage to the resistor 100 via the resistor 2c, and the A / D converter 3 performs A / D conversion on the output signal S1 output from the operational amplifier 2b, thereby generating a digital signal. S2 is generated and output to the arithmetic control unit 4. In this case, as described above, the arithmetic control unit 4 determines the resistance value (Ω) of the resistor 100 based on the voltage value indicated by the digital signal S2, the resistance value Rs of the resistor 2c, and the output voltage Vs of the voltage source 2a. Is calculated. Next, the arithmetic control unit 4 reads the set value data Dsa to Dsd from the storage unit 6 and determines to which of the four ranks Ra to Rd indicated by the set value data Dsa to Dsd the resistance value of the resistor 100 belongs. Then, the determination result is displayed on the display unit 7. For example, when the measured resistance value of the resistor 100 is “500Ω”, the arithmetic control unit 4 controls the display unit 7 to display the resistance value, and the rank to which the resistance value belongs is C rank Rc (from 400Ω). (A range up to 600Ω) is displayed on the result display screen (not shown). As a result, the user selects the resistor 100 according to the displayed rank.

  Thus, according to this measuring apparatus 1, the arithmetic control unit 4 calculates the predetermined predicted value E using the prediction formula F determined based on the plurality of set values S, and sets the predicted value E to a new value. By determining the setting value S, the prediction value E can be calculated using the prediction formula F that matches the increasing / decreasing tendency of the setting value S input in the past. It can be brought close to the set value S. Therefore, the desired set value S can be input quickly and easily as compared with a conventional apparatus that performs an input operation so that the initial set value is 0 to the desired set value S.

  Further, according to the measuring apparatus 1, the calculation control unit 4 calculates the predetermined predicted value E using the prediction formula F determined based on the plurality of set values S, and the predicted value E is corrected by the operation unit 5. By determining the corrected value M as the new set value S, when the value to be input as the set value S does not match the predicted value E, the prediction is calculated as a value close to the desired set value S. A new set value S can be set only by correcting the value E. Further, when the value to be input as the set value S matches the predicted value E, the correction of the predicted value E can be made unnecessary. For this reason, compared with the above-mentioned conventional measuring apparatus, the operation amount at the time of inputting the set value S can be extremely reduced, so that the desired set value S can be input quickly and easily.

  Furthermore, according to this measuring apparatus 1, the jog dial 5a outputs an operation signal So corresponding to the rotation operation amount, and therefore, the operation of pressing a predetermined number of times to input a desired set value S must be repeated. Since the predicted value E can be corrected only by rotating the jog dial 5a as compared to an up / down key or the like that cannot correct the predicted value E, the predicted value E can be corrected quickly and easily. The desired set value S can be input quickly and easily.

  Further, according to this measuring apparatus 1, when the calculation control unit 4 determines the prediction formula F as an nth-order equation, the order De of the prediction formula F is set so that the set value S indicated by the set value data Ds is taken as a solution. By determining the coefficient Co and the coefficient Co, the predicted value E can be calculated using the prediction formula F that matches the increasing / decreasing tendency of the setting value S that has been input in the past. As a result of being able to calculate a closer value as the predicted value E, the desired set value S can be input more quickly and easily.

  In addition, this invention is not limited to said structure. For example, although the example in which the predicted value E is calculated using the prediction formula F of the nth-order equation in which the order De and the coefficient Co are determined so that a plurality of setting values S are used as the solution has been described, the present invention is not limited thereto. For example, when three or more set values S are set, a prediction equation F of a linear equation that minimizes the sum of errors with respect to each set value S is determined using the least square method and the determined prediction A configuration in which the predicted value E is calculated using Formula F can also be employed. According to this configuration, since the predicted value E can be calculated with a simple prediction formula F, the predicted value E can be calculated quickly. In addition, the user determines which of the n-order equation in which the order De and the coefficient Co are determined so that a plurality of set values S are the solutions, and the linear equation determined by using the least square method is determined as the prediction formula F. It is also possible to adopt a configuration for selecting the above. According to this configuration, since the user can determine which equation is applied to the prediction formula F, a value closer to the desired set value S can be calculated as the predicted value E. Further, the example in which the set values S1 and Su are set in order from the A rank to the D rank has been described. However, the setting order is not limited to this, and a configuration that can be set in an arbitrary order may be employed.

  Furthermore, the structure which makes a user determine whether the predicted value E is calculated using the prediction formula F is also employable. According to this configuration, for example, the user inputs the set value S by correcting the initial value, rather than inputting the set value S by correcting the desired set value S and the predicted value E. When it is determined that the operation amount of the operation unit 5 is reduced, the operation amount of the jog dial 5a can be reduced by inputting the set value S by correcting the initial value. Further, in this example, the example of setting the upper and lower limit setting values Sl and Su that define a plurality of ranks R whose values increase together has been described, but the type of setting value in the present invention is not limited to this. For example, a set value is input as a positive deviation (for example, 10%, 20%, and 32%) with respect to a predetermined reference value, and as a negative deviation (for example, -5%, -12%, and -20%) When a set value is input, it is possible to set a new set value of positive and negative deviations by determining a prediction formula based on each set value and calculating the predicted value using the prediction formula. Similarly, when a set value is input as a plurality of deviations (for example, ± 10%, ± 20%, and ± 32%) that have the same positive / negative with respect to a predetermined reference value, the same operation as described above is performed. As a result, a new set value having a deviation different from the input set value can be calculated.

1 is a configuration diagram of a measuring device 1. FIG. 1 is a front view of a measuring device 1. FIG. 10 is a flowchart of rank setting processing 20. It is a display screen figure which shows the input screen P of the state into which the setting number N was input. It is a display screen figure which shows the input screen P of the state into which the setting value Sub was input. 10 is a flowchart of a predicted value display process 40. It is a display screen figure showing an example of input screen P in the state where predicted values Elc and Euc of rank Rc were displayed. It is a display screen figure which shows the input screen P of the state by which the correction value Muc which corrected the predicted value Euc was displayed. It is a display screen figure which shows the input screen P of the state into which the predicted value Eld and Eud were input.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Measuring apparatus 2 Measuring part 4 Operation control part 5 Operation part 5a Jog dial 6 Memory | storage part 8 Display part Co coefficient De Order Dsa-Dsd Setting value data Elc, Eld, Euc, Eud Predicted value Fl, Fu Predictive formula
Muc Correction value Sla ~ Sld, Sua ~ Sud Setting value

Claims (4)

A storage unit configured to be capable of storing a plurality of setting values; and an arithmetic control unit that determines a prediction formula based on the plurality of setting values and calculates a predetermined prediction value using the prediction formula;
The arithmetic control unit is a measuring device that determines the predicted value as a new set value different from the plurality of set values. A storage unit configured to be capable of storing a plurality of setting values; a calculation control unit that determines a prediction formula based on the plurality of setting values and calculates a predetermined prediction value using the prediction formula; and the prediction value And an operation unit for correcting
The arithmetic control unit is a measurement device that determines a corrected value obtained by correcting the predicted value by an operation of the operation unit as a new set value different from the plurality of set values. The operation unit includes a rotation operation type dial that outputs an operation signal corresponding to the rotation operation amount when correcting the predicted value,
The measurement apparatus according to claim 2, wherein the arithmetic control unit corrects the predicted value to the correction value based on the operation signal output from the rotary operation type dial.   The arithmetic control unit, when determining the prediction formula as an n-order equation, determines the order and coefficient of the prediction formula so that the plurality of setting values stored in the storage unit are used as a solution. The measuring apparatus according to any one of 1 to 3.

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