JP6846004B2 - Computers, arithmetic processing methods and programs - Google Patents

Description

The present invention relates to a computer, an arithmetic processing method and a program, and more particularly to an electronic computer having a remainder calculation function, an arithmetic processing method and a program.

Conventionally, an electronic desk calculator (so-called calculator) having a function of calculating and displaying a remainder (division calculation function) in a division (division) calculation process is known. When executing a division calculation with a calculator, in general, after inputting the divisor, enter the division key for setting the division calculation, then enter the divisor, and press the calculation execution key (=). By performing the input operation, one division calculation is executed, and the quotient and the remainder value, which are the calculation results, are displayed simultaneously or individually on the display panel.

As for the method of input operation and the method of displaying the calculation result in the remainder calculation, for example, as shown in Patent Document 1, the division, the division key, and the divisor are sequentially input, and then the quotient key is input to display the division. There is also known a calculator that applies a method in which only the quotient value is displayed on the panel and only the remainder value is displayed on the display panel instead of the quotient value by inputting the remainder key.

Japanese Unexamined Patent Publication No. 06-202990

A calculator having a division calculation function as described above has the following problems when the result of the division calculation (quotient or remainder) is used for yet another calculation.

For example, assuming that 24 bottles containing 72 tablets are put in one box, 10000 tablets are calculated by dividing 10000 by 72 when determining how many boxes, how many bottles, and how many tablets will be. After that, a series of arithmetic processes for calculating the value of the quotient further divided by 24 are executed. Specifically, first, by performing the calculation of the formula (111) in which 10000 is divided by 72, the quotient (= 138) and the remainder (= 64), which are the calculation results, are displayed on the display panel. Since these calculation results are used for the next calculation, they are temporarily saved by the memory function of the calculator or the user takes notes.
10000 ÷ 72 = 138 remainder 64 ... (111)

Next, the quotient (= 5) and the remainder (= 18), which are the results of a series of arithmetic processing, are calculated by dividing the value of the quotient of the above equation (111) by 24, which is saved or noted. ) Is displayed on the display panel.
138 ÷ 24 = 5 remainder 18 ... (112)

In this way, a plurality of solutions can be derived such that 10000 tablets are 5 boxes, 18 bottles, 64 tablets, and so on. Here, in a conventional general calculator in which at least one of the operators +, ×, and ÷ cannot be displayed, the display capacity is limited, and it is difficult to display the solutions of a plurality of operations at once. Even if multiple solutions are displayed, the relationship between multiple units such as how many bottles are contained in one box and how many tablets are contained in one bottle and the corresponding multiple solutions is not specified, and each solution is displayed. It was difficult to understand the meaning of the displayed solution.

Therefore, it is an advantage of the present invention to provide a computer, an arithmetic processing method, and a program that can be displayed on a display unit in an easy-to-understand form.

The computer according to the present invention
An input unit that accepts inputs of the first number, the second number, and the third number,
A display unit including a first display area capable of displaying integers and a second display area capable of displaying fractions, and a display unit.
Based on said third number more said first number and said second number of input has been received and the input unit, the first value by performing a first arithmetic processing using the first number as the first divisor And the arithmetic processing unit that acquires the second value by executing the second arithmetic processing using the second number as the second divisor.
The first number received by the input unit is displayed on either the molecular part or the denominator part of the second display region of the display unit, and the input is received by the input unit. The number is displayed on any other portion of the molecular portion and the denominator portion of the second display region of the display unit, and the first value calculated by the first arithmetic processing in the arithmetic processing unit is used as the first value. A display control unit that displays the one portion of the second display area and displays the second value calculated by the second arithmetic processing in the arithmetic processing unit on the other partial of the second display area. When,
Have.

According to the present invention, it can be displayed on the display unit in an easy-to-understand form.

It is an external view which shows one Embodiment of the computer which concerns on this invention. It is a block diagram which shows an example of the functional structure of the computer which concerns on one Embodiment. It is a figure which shows the example of the display form in the display part applied to the computer which concerns on one embodiment. It is a flowchart which shows an example of the arithmetic processing method of the computer which concerns on one Embodiment. It is an operation state diagram which shows an example of the key input operation and display operation in the arithmetic processing method which concerns on one Embodiment.

Hereinafter, the computer, the arithmetic processing method, and the program according to the present invention will be described in detail by showing embodiments.
(Electronic computer)
FIG. 1 is an external view showing an embodiment of a computer according to the present invention, and FIG. 2 is a block diagram showing an example of a functional configuration of the computer according to the present invention. FIG. 3 is a diagram showing an example of a display mode in the display unit applied to the computer according to the present embodiment.

As shown in FIGS. 1 and 2, the computer 100 according to the present invention is applied to an electronic desk calculator (calculator) having a four-rule calculation function and a fraction calculation function. A display unit 120, an arithmetic processing unit 130, a memory unit 140, and a power supply unit 150.

As shown in FIG. 1, the key input unit 110 has a numeric keypad (1 to 9, 0, 00, decimal point) and calculation keys (+,-, ×, ÷, ÷ remainder, =) for performing four rules. Of the memory function keys (M +, M-, MR, MC) for saving or reading numbers, the plus / minus switching key (+/-), and the numbers displayed on the display unit 120, only the smallest digit is deleted. A delete key, a percentage key (%), and a clear key (C, AC) for clearing numbers are arranged. The ÷ remainder key is used to display the quotient and remainder in division, or to perform another division using the remainder from division, which will be described later.

Further, in the key input unit 110, in addition to the above-mentioned basic keys used for the four rules calculation, the fraction calculation function key 112 used for the fraction calculation, a specific calculation other than the fraction, and a specific numerical value are displayed. A specific calculation function key (× 10, × 1/10, inverse number, π) for performing the calculation, and a digit setting key (quotient digit) for setting the number of digits at the time of calculation are arranged.

The fraction calculation function key 112 includes an integer key for setting the input of the integer part in the mixed fraction display, a fraction key for setting the input for the fraction display, a fraction fraction switching key for switching between the fraction display and the fraction display, a mixed fraction display and an improper fraction. A mixed fraction improper fraction switching key for switching the display, and a reduction key (reduction) for reducing the input or calculated fraction and displaying it are arranged.

As shown in FIG. 1, the display unit 120 has a plurality of display areas 122 and 124 (two locations on the left and right in the figure) on one display panel, and each display area 122 and 124 has a 7-segment type display element. They are arranged in a predetermined arrangement. Specifically, the display unit 120 has a configuration corresponding to an integer display, a decimal display, and a fraction display, and the display area 122 on the left side of the drawing includes an integer (including an integer part of a mixed number) and a fraction. Only one display element having a predetermined number of digits (4 digits in the figure) is arranged so that a decimal number can be displayed. On the other hand, in the display area 124 on the right side of the drawing, a fraction can be displayed, and an integer (including an integer part of a mixed number) or a number 0 to 9 as a decimal can be displayed as in the display area 122. .. In the case of fractional display in the display area 124, a plurality of digits (up to 4 digits each in the figure) are displayed in two columns, the numerator portion in the upper row and the denominator portion in the lower row, and integer display or decimal display is performed. In the case of, numbers having the same size and shape as the display area 122 are displayed in one row (not shown). Further, between the display elements of the numerator portion and the denominator portion, a segment element of a horizontal bar serving as a fractional line (or a vinculum) separating the two is arranged.

As a display form in the display unit 120, for example, as shown in FIG. 3A, a display area 124 corresponding to a fractional display is used, and a number as a numerator is displayed in the upper row and a denominator is displayed in the lower row. A number is displayed, and a horizontal bar that serves as a fractional line is displayed between the two, so that a true fraction or an improper fraction is displayed.

Further, as another display form, for example, as shown in FIG. 3B, an arbitrary number of digits is used by using the display area 122 corresponding to the integer display and the display area 124 corresponding to the fractional display and the integer display. An integer of (8 digits or less here) is displayed. In this case, in the display region 124, the segment element on the lower side of the display element of the upper molecular portion (lower half including the horizontal bar in the center of the 7-segment display) and the upper side of the display element of the lower denominator portion (7). An integer of an arbitrary number of digits (up to 4 digits) is displayed by combining the segment element of the horizontal bar (upper half including the horizontal bar at the center of the segment display) and the segment element of the horizontal bar which is a fractional line.

Further, as still another display form, for example, as shown in FIG. 3C, the display area 122 corresponding to the integer display and the display area 124 corresponding to the fractional display and the integer display are used as described above. A band fraction consisting of an integer part and a fraction part, which is a combination of the displays of FIGS. 3A and 3B, is displayed.

Each display form as described above is applied when the user inputs a key of the key input unit 110 including the fraction calculation function key 112 or when presenting the result of the calculation, and is applied to the present embodiment. The display unit 120 applied to the above has a display function that is effective not only when performing four rules of calculation using ordinary integers but also when performing various calculations including fractions.

Further, in the present embodiment, in addition to the case where the above-mentioned normal calculation is performed, when a series of arithmetic processes including the division calculation is performed, in addition to the numbers indicating the final result of the arithmetic processing, a series of arithmetic operations are performed. The numbers input by the key input unit 110 for processing and the numbers indicating the calculation results obtained in the middle of the calculation process are displayed in the display area 122 corresponding to the integer display of the display unit 120, and the fractional display and the integer display. By using the display area 124 corresponding to the above, simultaneous display is performed in a form imitating the band fractions that are distinguished from each other.

The arithmetic processing unit 130 has a processor or a computer, executes a predetermined program stored in the memory unit 140, executes a calculation according to an operation by the key input unit 110, and displays the calculation result on the display unit 120. Display in a predetermined form. Here, when the arithmetic processing unit 130 performs the four-rule calculation using ordinary integers, for example, as shown in FIG. 3B, the arithmetic processing unit 130 covers both the display area 122 and the display area 124 of the display unit 120. It is used to control the numbers input by the key input unit 110 and the results of the executed calculations to be sequentially displayed as integers.

Further, when the arithmetic processing unit 130 performs a calculation including a fraction, for example, as shown in FIGS. 3 (a) and 3 (c), if only a true fraction or an improper fraction is calculated, the display area 124 is displayed. It is used to control the numbers input by the key input unit 110 and the results of the executed calculations to be sequentially displayed as fractions or integers. Further, if the calculation includes a mixed number, the arithmetic processing unit 130 uses only the display area 124 or the display area 122 and the display area 124 to sequentially display the input numbers and calculation results as fractions and integers. To control.

Further, when the arithmetic processing unit 130 performs a series of arithmetic processing including the remainder calculation, the arithmetic processing unit 130 displays an input number, a final result, and a number indicating a calculation result obtained in the middle of the arithmetic processing. The display area 122 and the display area 124 of the unit 120 are used to control the integer portion and the fractional portion (molecular portion and denominator portion) to be simultaneously displayed in distinct forms. The specific arithmetic processing and display form will be described in detail later.

The memory unit 140 is a RAM (Random) that stores data of numbers input by operating the key input unit 110, numbers displayed on the display unit 120 by operating the memory function keys, and numbers obtained by arithmetic processing. It has at least a part or all of an Access Memory) and a ROM (Read Only Memory) in which an arithmetic program or the like is stored. Further, the memory unit 140 stores data generated during the arithmetic processing in the arithmetic processing unit 130 and numerical data to be displayed on the display unit 120. At least a part of the memory unit 140 may be built in the arithmetic processing unit 130.

In addition to the primary battery and the secondary battery, the power supply unit 150 includes a solar cell panel 152 that receives room light and natural light to generate electricity, and supplies drive power to each part of the computer 100.

(Computer arithmetic processing method)
Next, the arithmetic processing method and the program in the computer according to the present embodiment will be described with reference to the drawings.
FIG. 4 is a flowchart showing an example of a calculation processing method of the computer according to the present embodiment. Further, FIG. 5 is an operation state diagram showing an example of a key input operation and a display operation in the arithmetic processing method according to the present embodiment.

The arithmetic processing method according to the present embodiment is applied to a case where a computer having the above-described configuration executes a series of arithmetic processes including a remainder calculation by executing a specific program in the arithmetic processing unit 130. Will be done. Such a series of arithmetic processes is realized by a special program, unlike a program in which ordinary four-rule arithmetic operations and fractional calculations are executed independently.

In the present embodiment, as a specific example of a series of arithmetic processes including the division calculation, "If there are 72 tablets in one bottle and 24 bottles in one box, 10,000 tablets can be stored in how many boxes. The case of calculating "how many bottles and how many tablets will the remainder be?" Will be described. Such a series of arithmetic processes are effectively applied when prescribing a drug, packing a product or a part in a box, or the like.

In the arithmetic processing method according to the present embodiment, for example, as shown in the flowchart of FIG. 4, the user first sequentially inputs each number that is a divisor in a series of arithmetic processing by the key input unit 110 (step S102). Specifically, for example, as shown in FIG. 5A, the user uses the key input unit 110 in the order of "÷ remainder", "÷ remainder", "M +", "7", "2", and "M +". By performing the key operation, the arithmetic processing unit 130 displays "72", which is the first divisor (first number), in the upper numerator part of the display area 124 of the display unit 120, and saves it in the memory unit 140. To do.

Then, for example, as shown in FIG. 5B, the user performs a key operation in the order of "÷ remainder", "M +", "2", "4", and "M +" by the key input unit 110, thereby performing the calculation. The processing unit 130 displays "24", which is a second divisor (second number), in the lower denominator portion of the display area 124 of the display unit 120, and stores it in the memory unit 140.

That is, in the present embodiment, by sequentially inputting the numbers to be divisors, each divisor is collectively input before executing the calculation related to the series of arithmetic processing, and the input first divisor is input. And the second divisor are individually displayed in the upper and lower rows with a horizontal bar serving as a fractional line in the center of the display area 124 so that the user can easily distinguish them by looking at the display unit 120. As described above, in the present embodiment, the display function applied to the existing computer is used to distinguish individual numbers.

Here, in the present embodiment, when inputting each divisor, the "÷ remainder" key is operated one to several times in advance, and the "M +" key is operated before and after the number to be input. Specifically, by pressing the keys "÷ remainder" and "÷ remainder" twice before inputting the first divisor "72", the first divisor "72" is the divisor of the second quotient. Recognize that the second divisor "24" is the divisor of the first quotient by pressing the key "÷ remainder" once before inputting the second divisor "24", and divisor "72". The range of the divisors "72" and "24" is set by inputting the keys "M +" before and after the input of "24".

In this way, the arithmetic processing unit 130 is in the calculation mode for executing a series of arithmetic processing including the division calculation by performing a special key operation different from the case of executing the normal four-rule calculation and the fractional calculation. , And, it is determined that a divisor is input in the calculation mode, and the input number is displayed in the form of a fraction in the upper and lower rows of the display area 124 of the display unit 120. By performing the input operation shown in FIG. 5 (b) before the input operation shown in FIG. 5 (a), the second divisor "24" is displayed first, and the input shown in FIG. 5 (a) is continued. Even when the operation is performed, the same calculation result as above may be obtained. In addition, by setting in advance so that it is recognized as a mode in which multiple quotient operations are performed by continuously inputting the keys "÷ remainder" and "M +", the quotient of the mth time (m is an integer of 2 or more) Even if it is a divisor, the operation of pressing the key "÷ remainder" before inputting the divisor may be performed only once. In this case, enter in the order of the lower divisor (here, "72", "24") or the order of the higher divisor (here, "24", "72"). Just do it.

Next, the user inputs a number to be a divisor in a series of arithmetic processes by the key input unit 110 (step S104). Specifically, for example, as shown in FIG. 5C, the user performs a key operation in the order of "1", "00", "00", and "÷ remainder" by the key input unit 110 to perform arithmetic processing. The unit 130 displays the divisor "10000" in the integer portion of the display area 122 and the display area 124 of the display unit 120, and stores it in the memory unit 140.

In this way, in the divisor input operation, first enter the keys "÷ remainder" and "M +", then enter the key "M +" after the divisor input to complete the divisor input, and then the key "÷ remainder" or By entering a numerical value without entering "M +", that numerical value can be regarded as a division number, and by entering "÷ remainder" at the end, the range of the division number is determined and multiple stages of remainder display are displayed. It is confirmed that the division of is performed. When inputting the division number, the "÷ remainder" key may be input a plurality of times after the division number is input.

That is, as in the case of collectively inputting the divisors described above, the arithmetic processing unit 130 performs the division result and the remainder by performing a special key operation different from the case of executing the normal four-rule calculation or the fractional calculation. In the calculation mode for executing a series of arithmetic processes including the division calculation to be displayed, it is determined that the divisor has been input, and the input numbers are displayed in the display area 122 and the display area 124 of the display unit 120 in the form of integers. Display with. Here, the input divisor "10000" is different from the method of distinguishing the first and second divisors displayed in the upper and lower rows in the form of a fraction as described above, and the divisor display area of the display unit 120 is displayed. It is distinguished from these divisors by being displayed in the form of an integer or a decimal, for example, in the central region. As described above, in the present embodiment, the display area of the display unit 120 is such that the divisor and the divisor input for executing a series of arithmetic processes can be easily distinguished by looking at the display unit 120. Using 122 and the display area 124, the integer part and the fractional part (numerator part and denominator part) are distinguished from each other and are simultaneously displayed in a form imitating a mixed number.

Then, by inputting the above-mentioned divisor and divisor, the following plurality of calculations (equations (11) to (13)) are sequentially executed (step S106). The plurality of calculations shown below may be executed by the user inputting the calculation execution key (=) of the key input unit 110, for example, as shown in FIG. 5D.

When the calculation example shown in the present embodiment is executed, the calculation shown in the equations (111) and (112) is sequentially executed in the general calculator as described above. On the other hand, in the present embodiment, since the two division calculations are continuously executed, the arithmetic processing unit 130 is input in step S102 as shown in the following equation (11). The first and second divisors are multiplied (step S106), and the calculation result (product) is stored in the memory unit 140 (step S108). Here, the result of multiplying the first divisor "72" shown in the equation (11) by the second divisor "24" corresponds to the number of tablets in one box.
72 x 24 = 1728 ... (11)

Next, the arithmetic processing unit 130 executes a division calculation that divides the divisor input in step S104 by the value of the product calculated by the equation (11), as shown in the following equation (12). Step S106), the calculation result (second quotient and second remainder) is stored in the memory unit 140 (step S108). Here, in the result of dividing the divisor "10000" shown in the equation (12) by the result of multiplying the first divisor "72" and the second divisor "24", the number of boxes containing the tablets containing the tablets. “5” corresponds to the second quotient, and the number of surplus tablets “1360” that is insufficient to fill the 6th (second quotient + 1) box corresponds to the second surplus.
10000/1728 = 5 remainder 1360 ... (12)

That is, in the present embodiment, a plurality of calculations for obtaining the final result (quotient) of a series of arithmetic processes by dividing the divisor by the product of the divisors collectively input ((111) described above). Equation and (corresponding to equation (112)) are executed together. In such an arithmetic processing method, in an operation in which a remainder calculation is continuously executed or an operation in which a division calculation and a normal division are continuously executed, the divisor is calculated by multiplying the divisor of each calculation (product). It is based on the equivalent of the division operation.

Next, in step S110, the arithmetic processing unit 130 determines that the series of operations has not been completed if the remainder of the second (a) is equal to or greater than the divisor of the first (first (a-1)). The result is No, and the process proceeds to step S114. If it is less than the first divisor, it is determined that the series of operations has been completed, the result is Yes, and the process proceeds to step S112. Here, since the second remainder "1360" in the equation (12) is equal to or greater than the first divisor "72", the process proceeds to step S114. In step S114, a shifts to step S106 with a as (a-1).

As a result, as shown in the following equation (13), the arithmetic processing unit 130 divides the value of the second remainder calculated in the equation (12) of step S108 by the first divisor for the division calculation. It is executed (step S106), and the calculation result (quotient and remainder) is saved in the memory unit 140 (step S108). Here, in the result of dividing the second remainder "1360" of the calculation of the formula (12) shown in the formula (13) by the first divisor "72", the sixth (second quotient + 1) box is satisfied. The number of bottles filled with excess tablets "18" corresponds to the first quotient, and the number of bottles too large to fill the (first quotient + 1) first quotient ""64" corresponds to the first remainder.
1360 ÷ 72 = 18 remainder 64 ... (13)

Then, when the next divisor is not set, or when the first remainder is less than the next divisor even if the next divisor is set, the arithmetic processing unit 130 ends a series of arithmetic processing (step). Yes) of S110, the process proceeds to step S112.

In this way, when the division is repeated a times (a is an integer of 2 or more), and the _{divisor DE a} , the divisor DS _a , the quotient Q _a , and the remainder R _a of the a, the first division is (14). It becomes according to the formula.
DE _a = (DS _a × DS _(a-1) × ・ ・ ・ × DS ₂ × DS ₁ ) × Q _a + R _a・ ・ ・ (14)

In the second division in step S106 performed by changing a to (a-1) in step S114, the remainder R _{a of} the a is set as the divisor DE _(a-1) of the (a-1) (15). It becomes according to the formula.
R _a = DE _(a-1)
= (DS _(a-1) × DS _(a-2) × ・ ・ ・ × DS ₁ ) × Q _(a-1) + R _(a-1)・ ・ ・ (15)
Every time this becomes No in step S110, a is reduced by one in step S114, and the calculation in step S106 is repeated.

Next, as shown in FIG. 5D, for example, the arithmetic processing unit 130 is a quotient value which is a calculation result obtained by the calculations (Equations (11) to (13)) sequentially executed in the above-mentioned arithmetic processing. "5" is displayed in the integer part of the display area 122 and the display area 124, and the remainder values "18" and "64" are displayed in the upper numerator part and the lower denominator part of the display area 124, respectively. (Step S112).

That is, instead of the divisor and the divisor input by the user by the key input unit 110 shown in FIG. 5C, the calculation result obtained by the arithmetic processing is overwritten and displayed. As described above, in the present embodiment, the display area 122 of the display unit 120 and the display area 122 and the display unit 120 so that the user can easily distinguish the quotient and the remainder number as a result of the series of arithmetic processing by looking at the display unit 120 Using the display area 124, the integer part and the fraction part (numerator part and denominator part) are distinguished from each other and are simultaneously displayed in a form imitating a mixed number.

In the state where the result of the calculation process shown in FIG. 5D is displayed, the user inputs a specific key such as a calculation execution key (=) or a shift key of the key input unit 110, for example. By repeating the key input operation so that the display switches to the state in which the input divisor or divisor shown in 5 (c) is displayed, the display state in FIG. 5 (c) and the display in FIG. 5 (d) are displayed. It may switch between states.

As a result, the user can see the number displayed on the display unit 120 shown in FIG. 5 (d), and see that "10000 tablets is equivalent to 5 boxes containing 24 bottles containing 72 tablets. There are 18 bottles and 64 tablets that do not fill one bottle. "

In a conventional general calculator, when executing a series of calculation processes including division calculation, the result of the previously executed calculation is saved and read using the memory function, etc., and the calculation result for which a memo is taken is re-recorded. Since each calculation must be executed in order by inputting, there is a problem that the input operation is complicated and the work efficiency is poor. In addition, since only the final result of a part of a series of arithmetic processing (for example, the quotient and the remainder obtained by the above equation (112)) is displayed on the display panel, the number entered first can be confirmed. It was not possible to collectively confirm the results of the arithmetic processing including the calculation results in the middle (for example, the quotient and the remainder obtained by the above equation (111)).

On the other hand, in the present embodiment, since the user can first input the divisor and the divisor in a batch in a series of arithmetic processes, the input operation can be easily performed and the work efficiency can be improved. it can. In addition, the input history related to a series of calculation processes and the results including the calculation results in the middle are displayed simultaneously on the display unit in a form imitating a mixed number, so that the user can see these numbers and display the input history. And the calculation result can be easily recognized and understood.

(Modification example)
Next, a modification applicable to the computer and the arithmetic processing method shown in the above-described embodiment will be shown.

(1) In the above-described embodiment, the divisor input by the user is displayed in the numerator portion and the denominator portion in the upper part of the display area 124 of the display unit 120, respectively, and the divisor is displayed in the integer part of the display area 122 and the display area 124. The form displayed in is shown. Further, the quotient value that is the result of a series of arithmetic processing is displayed in the integer part of the display area 122 and the display area 124, and the remaining value is displayed in the numerator part and the denominator part of the lower part of the display area 124, respectively. showed that. The present invention is not limited to this display form, and the divisor or quotient value is displayed in the upper numerator portion or lower denominator portion of the display area 124, and the divisor or remainder value is displayed in the display area 122 and the display area 124. It may be the one displayed in the integer part of.

That is, using the display area 122 corresponding to the integer display of the display unit 120 and the display area 124 corresponding to the fractional display and the integer display, the numbers indicating the input history and the result of the arithmetic processing are distinguished from each other. Anything that is displayed at the same time will do. In particular, as shown in FIG. 5 (c), when the first divisor "72" is displayed in the numerator portion and the second divisor "24" is displayed in the denominator portion, corresponding to them, in FIG. 5 (d). When displaying such a quotient and a remainder, the relationship between the divisor and the quotient is the same in the display area 124 so that the first quotient "18" is displayed in the numerator part and the second quotient "5" is displayed in the denominator part. It is preferable to place it in a position when distinguishing and recognizing it. The first remainder "64" may be displayed anywhere on the display unit 120 as long as it is not the display area of the fractional portion. Similarly, the first divisor and the first quotient are displayed in the denominators in FIGS. 5 (c) and 5 (d), respectively, and the second divisor and the second quotient are shown in FIGS. 5 (c) and 5 respectively. Needless to say, the same effect can be obtained even if it is displayed on the molecular part in (d).

(2) Further, in the above-described embodiment, when executing a series of arithmetic processes including division calculation, first, numbers to be divisors are sequentially input, each divisor is input collectively, and then the divisor is used. Although the operation procedure (steps S102, S104) for inputting the numbers is shown, the present invention is not limited to this, and each divisor may be input collectively after inputting the division. .. Further, when executing a series of arithmetic processes including division calculation, the key operations for inputting numbers indicating divisors and divisors are limited to those shown in FIGS. 5A to 5C. Instead, if it is not the same as or confused with the key operation when executing normal four-rule calculation or fractional calculation (that is, the key operation that does not execute other existing calculation programs), it can be freely set and applied. be able to.

(3) Further, in the above-described embodiment, the display area 122 and the display area 124 of the display unit 120 are used to display all the input divisors and divisors, and the result calculated by a series of arithmetic processes is displayed. Although the case of displaying all of them has been described, the present invention is not limited to this, and may display only arbitrary numbers among the input numbers and calculation results.

(4) Further, in the above-described embodiment, as an example of the arithmetic processing, a case where the division calculation is executed twice in succession has been described, but the present invention is not limited to this, and the division calculation is not limited to this. And, like ordinary division, it may be applied to the arithmetic processing in which the remainder calculation and the other four rules operations are continuously executed.

(5) Further, in the above-described embodiment, the key input unit 110 is a button-type hardware key, but the present invention is not limited to this, and a software key which is a virtual key on the display may be used.

Although some embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and the present invention is made by combining the configurations of the plurality of embodiments within a practicable range. It also includes the inventions described in the claims and the equivalent scope thereof.
The inventions described in the claims of the original application of the present application are described below.

(Additional note)
[1]
An input unit for inputting the first and second numbers,
In response to the input of the first number and the second number by the input unit, the first operation based on the first number and the second number and the first value calculated by the first operation were used. A second operation, an arithmetic processing unit that executes arithmetic processing including, and
A solution of the first operation and a solution of the second operation calculated by the calculation process in the calculation processing unit are provided with a first display area capable of displaying integers and a second display area capable of displaying fractions. A display unit that displays one of the numerator portion and the denominator portion of the second display region so as to distinguish one from the solution of the first operation and the other of the solution of the second operation.
Computer with.

[2]
The display unit uses the other of the solution of the first operation and the solution of the second operation calculated by the operation processing in the calculation processing unit as one of the solution of the first operation and the solution of the second operation. The computer according to [1], which is displayed in the other of the numerator portion and the denominator portion of the second display region or in the first display region so as to be distinguished from the above.

[3]
The first number and the second number are the first divisor and the second divisor, respectively.
The first operation and the second operation are the first division and the second division, respectively.
The first value is the first remainder calculated by the first division.
The computer according to [1] or [2], wherein the solution of the first operation and the solution of the second operation are the first quotient of the first division and the second quotient of the second division, respectively.

[4]
The display unit distinguishes the second remainder calculated by the second division from the first quotient and the second quotient together with the first quotient of the first division and the second quotient of the second division. The computer according to [3] to be displayed in.

[5]
An arithmetic processing unit that executes arithmetic processing including a first arithmetic and a second arithmetic using the first value calculated by the first arithmetic, and an arithmetic processing unit.
It has a first display area capable of displaying integers and a second display area capable of displaying fractions, and the first number and the first operation input for calculating the first operation and the second operation. Display displayed on one of the molecular part and the denominator part of the second display region so as to distinguish one of the second numbers input for calculating the above from the other of the first number and the second number. Department and
Computer with.

[6]
The display unit has the molecular portion of the second display region and the molecular portion so as to distinguish the other of the input first number and the second number from one of the first number and the second number. The computer according to [5], which is displayed on the other side of the denominator portion or in the first display area.

[7]
The first number and the second number are the first divisor and the second divisor, respectively.
The first operation and the second operation are the first division and the second division, respectively.
The computer according to [5] or [6], wherein the first value is a first remainder calculated by the first division.

[8]
The computer according to [7], wherein the display unit displays the divisor used for the first division together with the first divisor and the second divisor so as to distinguish them from the first divisor and the second divisor. ..

[9]
Enter the first and second numbers into the input section of the computer,
In response to the input of the first number and the second number by the input unit, the first operation based on the first number and the second number and the first value calculated by the first operation were used. Execute the second operation and the arithmetic processing including
The solution of the first calculation calculated by the calculation process and the second calculation are displayed on the display unit of the computer provided with the first display area capable of displaying integers and the second display area capable of displaying fractions. A computer arithmetic processing method for displaying one of the solutions of the above on one of the molecular part and the denominator part of the second display region so as to distinguish one of the solutions of the first operation from the other of the solution of the second operation. ..

[10]
A calculation process including the first calculation and the second calculation using the first value calculated by the first calculation is executed.
It is input to the display unit of the computer provided with the first display area capable of displaying integers and the second display area capable of displaying fractions in order to calculate the first operation and the second operation. The molecular portion of the second display region and so as to distinguish one of the first number and the second number input to calculate the first operation from the other of the first number and the second number. A computer arithmetic processing method that is displayed on one side of the denominator.

[11]
It ’s a computer program,
Enter the first and second numbers into the input section of the computer,
In response to the input of the first number and the second number by the input unit, the first operation based on the first number and the second number and the first value calculated by the first operation were used. Execute the second operation and the arithmetic processing including
The solution of the first calculation calculated by the calculation process and the second calculation are displayed on the display unit of the computer provided with the first display area capable of displaying integers and the second display area capable of displaying fractions. Have the computer execute to display one of the solutions of the above on one of the molecular part and the denominator part of the second display region so as to distinguish one of the solutions of the first operation and the other of the solution of the second operation. Computer program.

[12]
It ’s a computer program,
A calculation process including the first calculation and the second calculation using the first value calculated by the first calculation is executed.
It is input to the display unit of the computer provided with the first display area capable of displaying integers and the second display area capable of displaying fractions in order to calculate the first calculation and the second calculation. The molecular portion of the second display region and so as to distinguish one of the first number and the second number input to calculate the first operation from the other of the first number and the second number. A computer program that causes a computer to display on one side of the denominator.

100 Computer 110 Key input unit 112 Fractional calculation function key 120 Display unit 122, 124 Display area 130 Arithmetic processing unit 140 Memory unit

Claims (5)

An input unit that accepts inputs of the first number (first divisor), the second number (second divisor), and the third number (divisor),
A display unit including a first display area capable of displaying integers and a second display area capable of displaying fractions, and a display unit.
Based on said third number more said first number and said second number of input has been received and the input unit, the first value by performing a first arithmetic processing using the first number as the first divisor an arithmetic processing unit (first quotient) acquires, obtains a second value (second quotient) is running a second arithmetic processing using the second number as a second divisor,
The first number received by the input unit is displayed on either the molecular part or the denominator part of the second display region of the display unit, and the input is received by the input unit. The number is displayed on any other portion of the molecular portion and the denominator portion of the second display region of the display unit, and the first value calculated by the first arithmetic processing in the arithmetic processing unit is used as the first value. A display that is displayed on the one portion of the second display area and that the second value calculated by the second arithmetic processing in the arithmetic processing unit is displayed on the other portion of the second display area. Control unit and
Computer with. The first operation and the second operation are the first division and the second division, respectively.
The first value is the first remainder calculated by the first division.
The computer according to claim 1 , wherein the solution of the first operation and the solution of the second operation are the first quotient of the first division and the second quotient of the second division, respectively. The display unit distinguishes the second remainder calculated by the second division from the first quotient and the second quotient together with the first quotient of the first division and the second quotient of the second division. The computer according to claim 2 to be displayed in. It is a method executed by the control unit of a computer.
The computer has an input unit that accepts inputs of a first number (first divisor), a second number (second divisor), and a third number (divided number), and a first display area and a fraction that can display integers. A display unit including a second display area capable of displaying, and
The control unit
Based on the first number, the second number, and the third number that have received input by the input unit, the first arithmetic processing using the first number as the first divisor is executed to execute the first calculation process, and the first value ( Acquired the first quotient)
The second arithmetic process using the second number as the second divisor is executed to obtain the second value (second quotient).
The first number received by the input unit is displayed on either the numerator portion or the denominator portion of the second display region of the display unit.
The second number that received the input by the input unit is displayed on any other portion of the numerator portion and the denominator portion of the second display region of the display unit.
The first value calculated by the first arithmetic processing is displayed on the one portion of the second display area.
A computer arithmetic processing method for displaying the second value calculated by the second arithmetic processing on the other portion of the second display area. It ’s a computer program,
The computer has an input unit that accepts inputs of a first number (first divisor), a second number (second divisor), and a third number (divided number), and a first display area and a fraction that can display integers. A display unit including a second display area capable of displaying, and
The program
Based on the first number, the second number, and the third number that have received input by the input unit, the first arithmetic processing using the first number as the first divisor is executed to execute the first calculation process, and the first value ( Acquired the first quotient)
The second arithmetic process using the second number as the second divisor is executed to obtain the second value (second quotient).
The first number received by the input unit is displayed on either the numerator portion or the denominator portion of the second display region of the display unit.
The second number that received the input by the input unit is displayed on any other portion of the numerator portion and the denominator portion of the second display region of the display unit.
The first value calculated by the first arithmetic processing is displayed on the one portion of the second display area.
A computer program that causes a computer to display the second value calculated by the second arithmetic processing on the other portion of the second display area.

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