JP2020024627A - Electronic appliance, operand input method to electronic appliance and program - Google Patents

Abstract

To provide an electronic appliance, operand input method to the electronic appliance and program allowing for inputting an operand more easily.SOLUTION: An electronic appliance 1 in the present invention comprises numeric value input means that inputs a basic operand and a first multiple value that is a value a first multiple operand that is a multiple of the basic operand is divided by the basic operand by user operation, operator input means that inputs an operator by user operation, and separation means that separates an input of the basic operand from an input of the first multiple value by an input of the operator.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an electronic device, a method of inputting the number of operations to the electronic device, and a program.

  In general, there are two types of medicines handled at prescription pharmacies, such as a boxed state in which a plurality of continuous packages are packed in a box (hereinafter, the boxed state is also referred to as a box) and an individual taken out of the box. There are a state of the continuous body and a state of a rose in which the continuous body is separated.

In the case of a tablet or capsule, for example, the continuous package is formed by packaging a plurality of tablets or capsules in a PTP (press through package).
Further, in the case of the dust, it is packaged by SP (strip package), and more specifically, is a sheet in which a plurality of bags each having a predetermined amount of the dust are connected.

  At a prescription pharmacy, a pharmacist prepares a required number of medicines by combining a box, a continuous body and a rose in accordance with the prescription in order to deliver the medicine to the patient, and delivers the prepared medicine to the patient. become.

  Here, a box (42 medicines) in which 14 sets of continuous medicines containing three medicines are packed in a box, a continuous medicine pack (3 medicines) containing three medicines, A case in which a pharmacist prepares 100 medicines according to a prescription by combining a rose (the number of medicines is 1) in which a continuous package is separated into one medicine state will be described. You will ask how many bodies you need.

  Specifically, the pharmacist uses a calculator to divide 100, which is the number of required drugs, by 42, which is the number of drugs in the box, to obtain 2.38. Check that there are many in three, and prepare two boxes.

  Subsequently, the pharmacist uses a calculator to subtract the number 84 of the medicines for the two prepared boxes from the number 100 of the necessary medicines, and finds that the remainder (insufficient) is 16 and obtains this. Divide the shortage medicine number 16 by 3 which is the number of medicines in the continuous body to obtain 5.33..., And confirm that the number of continuous medicine bodies is small and the number of medicines is large and the number of medicines is large. Prepare a continuous body.

  Finally, the pharmacist uses a computer to subtract the number of medicines for the five prepared continuous packages 15 from the number of medicines for the shortage, and the remainder (insufficient) is one. And prepare one rose.

  As a computer suitable for such a calculation, Patent Literature 1 discloses a calculation result obtained by dividing an operand (for example, the number of required medicines 100) by an operation number (the number of medicines in a box 42). (The number of boxes 2) and the remainder (16), and the remainder (16) can be used as the operand (shortage 16) for the next calculation. There is disclosed a computer which divides by the number of medicines in the body 3), performs an operation, and obtains a quotient (the number of continuous bodies 5) and a remainder (the number of roses 1) in a series of operations.

JP 2015-219730 A

  By the way, the continuous body and the box as described above are merely examples, and the number of medicines in one continuous body and the number of the continuous body contained in the box are determined depending on the type of the medicine. The number may differ, and there are many types of drugs prescribed at prescription pharmacies and the like.

  For this reason, it is difficult to memorize how many medicines are contained in one continuous package and how many medicines are contained in one box for each medicine. When inputting the number, if the pharmacist does not know the number of drugs included in one continuous body and the number of drugs included in one box, the pharmacist first counts the number of drugs included in the continuous body, and In addition to calculating the number of medicines, the calculation is performed such that the counted number is multiplied by the number of continuous bodies contained in the box to obtain the number of medicines in the box, The emergence of a computer (hereinafter, also referred to as an electronic device) capable of easily inputting the number of operations is required.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide an electronic device capable of more easily inputting the number of operations, a method of inputting the number of operations to the electronic device, and a program.

In order to achieve the above object, the present invention is grasped by the following configurations.
The electronic device according to the present invention is configured such that a basic operation number and a first multiple value which is a value obtained by dividing a first multiple operation number which is a multiple of the basic operation number by the basic operation number are operated by a user operation. Numerical input means for inputting, operator input means for inputting an operator by a user operation, separating means for separating input of the basic operation number and input of the first multiple value by inputting the operator, Is provided.

  According to the present invention, it is possible to provide an electronic device capable of more easily inputting the number of operations, a method of inputting the number of operations to the electronic device, and a program.

FIG. 2 is a plan view of the electronic device according to the first embodiment of the present invention. FIG. 2 is a block diagram of the electronic device according to the first embodiment of the present invention. FIG. 2 is a diagram illustrating an outline of a symbol table of the electronic device according to the first embodiment of the present invention. FIG. 5 is a diagram for explaining operations and operations of the electronic device based on a specific example of the first embodiment according to the present invention. It is a figure for explaining a 2nd embodiment concerning the present invention.

Hereinafter, embodiments for carrying out the present invention (hereinafter, referred to as “embodiments”) will be described in detail with reference to the accompanying drawings.
The same elements are denoted by the same reference numerals throughout the description of the embodiments.

(1st Embodiment)
FIG. 1 is a plan view of an electronic device 1 according to a first embodiment of the present invention.
FIG. 2 is a block diagram of the electronic device 1 according to the first embodiment of the present invention.
As can be seen from FIG. 1, the electronic device 1 according to the first embodiment is a so-called electronic desk calculator (calculator).

As shown in FIGS. 1 and 2, the electronic device 1 includes an operation unit 10, a display unit 20, a recording medium reading unit 30 (see FIG. 2), a storage unit 40 (see FIG. 2), and a CPU 50 (see FIG. 2). 2) and a data bus 60 (see FIG. 2).
Each of the operation unit 10, the display unit 20, the recording medium reading unit 30, and the storage unit 40 is connected to the CPU 50 by a data bus 60.
As shown in FIG. 1, the electronic device 1 also includes a power generation unit 70 having a solar panel.

  As shown in FIG. 1, the operation unit 10 is a part for performing various operations by a user, and includes a number input unit 11 operated when inputting a numerical value and the like, and an operator for specifying a type of operation. And a result display instructing unit 13 (“=” key) for displaying the operation result on the display unit 20.

  Further, the operation unit 10 includes a clear unit 14 (“AC” key) for clearing data and the like stored in the storage unit 40 during the display of the display unit 20 and the calculation process. 1 also functions as a power input operation unit for turning on the power.

That is, when the “AC” key is pressed while the power of the electronic device 1 is off, the power of the electronic device 1 is turned on. When the power is on, the electronic device 1 functions as the clear unit 14.
The power supply is automatically turned off when the operation unit 10 is not operated for a predetermined time or more.

  The keys of the operator input unit 12 and the keys of the number input unit 11 are used for purposes other than specifying an operator and a number, which will be described later.

  The display unit 20 is a unit that performs display according to the operation of the operation unit 10 and includes, for example, a liquid crystal display panel.

  The recording medium reading unit 30 is a reading unit for reading data or the like recorded on a recording medium M (for example, a USB memory or the like) detachably connected to the connection port.

The storage unit 40 includes a ROM, a RAM, and the like. The ROM stores a calculation processing program for causing the CPU 50 to perform various processes as a computer.
The RAM not only stores data that need to be temporarily stored in the calculation process, but also data (symbol table) for symbols that are displayed together with the calculation results on the display unit 20, which will be described later. It is remembered.

  The CPU 50 is a control unit that controls the overall control of the electronic device 1 according to a calculation processing program and the like stored in the storage unit 40.

  The data bus 60 is a transmission path for performing data communication between each unit (the operation unit 10, the display unit 20, the recording medium reading unit 30, and the storage unit 40) and the CPU 50.

  In the electronic device 1 having the above-described configuration, a more detailed description will be given with reference to an example in which a quotient operation (also referred to as a quotient calculation) is actually performed using a plurality of operation numbers. .

  As an example, when a pharmacist prepares 200 medicines according to a prescription at a prescription pharmacy or the like, a number of continuous containers are stored in a box (sometimes simply called a box) containing the medicines. When the user does not know whether the container is stored or how many medicines the serial package has, the user can use the electronic device 1 of the present embodiment to set the required number of boxes and the necessary number of boxes. It is assumed that a calculation is performed to determine the number of continuous bodies and the required number of roses.

  In the case of a drug, the continuous package is often manufactured by a heat sealing method, and is called a heat in a prescription pharmacy or the like, and thus may be called a heat in the following description.

First, the user (pharmacist) presses the “AC” key shown in FIG. 1 to turn on the power of the electronic device 1.
Then, the decimal point key (“·” key) of the number input unit 11 is continuously pressed for, for example, three seconds or more.

  As described above, when the decimal point key (“·” key) is pressed for a long time, the CPU 50 determines that the menu has been selected, and makes the symbol table stored in the storage unit 40 accessible. .

FIG. 3 is a diagram showing an outline of the symbol table.
As shown in FIG. 3, in the symbol table, names (symbols) corresponding to a plurality of quotients and remainders of calculation results when performing calculations using a plurality of calculation numbers in each business type are prepared in advance. You can select the appropriate one from among them.
How the symbols are actually displayed on the display unit 20 will be described later with reference to FIG.

More specifically, when a menu is selected by holding down the decimal point key (“·” key), the contents of the pharmacy corresponding to the top row of the symbol table are displayed on the display unit 20.
That is, the display unit 20 indicates that the symbol of the number of boxes is displayed for the quotient 1, the symbol of the number of heats is displayed for the quotient 2, and the symbol of rose is displayed for the remainder.

  The example to be described below is a pharmacy, which is a content that calculates the quotient 1 (the number of boxes), the quotient 2 (the number of heats), and the remainder (rose), and corresponds to the top row of this symbol table. If the decimal point key ("." Key) is pressed again while the contents of the pharmacy to be performed are displayed on the display unit 20, this content is applied to a plurality of quotients and surnames (symbols) corresponding to the calculation results. Will be done.

  If a pharmacy in the symbol table has been previously selected by selecting a menu, the pharmacy has been stored, so that the operation of selecting this menu is unnecessary.

  On the other hand, in a shipping company, a predetermined number of products are collected on pallets (also referred to as small packages), and the products are handled in a form in which predetermined numbers of pallets are collected (also referred to as large packages). When preparing a predetermined number of products, the names of bulk, pallets (small packages), and sets (large packages) are often used, and employees of the shipping company use multiple operation numbers. When performing the calculated remainder remainder, the contents of the transportation corresponding to the second row from the top of the symbol table may be selected.

More specifically, when the menu is selected, an addition key (“+” key), which is a key of the operator input unit 12 for inputting an addition operator, is located next to the symbol table. It functions as a key for performing an operation of moving to the data of.
Therefore, as described above, when the content of the pharmacy is displayed on the display unit 20, pressing the addition key (“+” key) corresponds to the second row from the top of the symbol table. The contents of the transportation to be performed are displayed on the display unit 20, and in that state, the decimal point key (“•” key) may be pressed as in the previous case.

  When the contents of the transportation are displayed on the display unit 20, when the subtraction key (“−” key), which is the key of the operator input unit 12 for inputting the subtraction operator, is pressed, the pharmacy is re-entered. Is displayed on the display unit 20.

  When the contents of the appropriate symbol are not included in the contents prepared in advance in the symbol table, as shown in FIG. 3, the symbol table contains the contents of the symbol so that the user can create the contents of the corresponding symbol. New items are also prepared.

  That is, a new creation is displayed on the display unit 20, and a cursor displayed on the display unit 20 in this state is operated by a multiplication operator key ("x" key) which is an operator input unit 12 key for inputting a multiplication operator. ) And a division operator key (“÷” key), which is an operator input unit 12 key for inputting a division operator, and a number input key of the number input unit 11 is operated to create a symbol. It can be carried out.

  The hiragana displayed above the number input keys of the number input section 11 indicates hiragana that can be input with the number input keys in order to create a symbol, and is converted to kanji. To do so, the user can operate the result display instruction unit 13 (“=” key).

  For this reason, for example, it is possible to cope with a case where a completely different name (symbol) from the prepared one is desired to be displayed on the display unit 20 together with the calculation result, or a case where there is a quotient 3 or later. .

Assuming that the above-mentioned preparation has been performed, the operation and operation of the electronic device 1 when performing the calculation corresponding to the case described above will be described below with reference to FIG.
FIG. 4 is a diagram for explaining the operation and operation of the electronic device 1 based on a specific case.
FIG. 4A is a diagram showing the operation contents of the operation unit 10 and the display contents of the display unit 20 according to the operation, and FIG. 4B is a flowchart for explaining the operation of the electronic device 1. It is.

When the user turns on the power of the electronic device 1 by pressing the “AC” key shown in FIG. 1 when the power is off, the operation of the flowchart shown in FIG. 4B is started.
Then, when the power is turned on, the CPU 50 proceeds to step S10, where the user operates the “×” key following the “AC” key operation shown in the operation 1 in FIG. It is determined whether the “number-set mode” is selected.

Then, if step S10 is NO, CPU 50 determines whether another operation has been performed (step S20), and if step S20 is YES, the process further proceeds to step S21, where CPU 50 performs an operation based on the other operation. , Etc., and returns to step S10 again.
For example, as an example of other processing, there is a menu selection by long-pressing the decimal point key (“·” key) described above.

  When step S20 is NO, the CPU 50 proceeds to step S30, determines whether or not the time during which no operation is performed has passed a predetermined time, and if the predetermined time has elapsed (step S30: YES) ), The CPU 50 performs a process of turning off the power of the electronic device 1 (step S31), and the operation of this flowchart ends, and if step S30 is NO, the process returns to step S10 again.

Then, following the operation of the "AC" key shown in the operation 1 of FIG. 4A, the operation of the "x" key is performed, and when step S10 becomes YES, the processing of the calculation using the plurality of calculation numbers Be started.
Note that the operation of the “x” key is performed following the operation of the “AC” key, and the processing of the calculation using a plurality of calculation numbers (also referred to as “number-set mode”) is started. As shown in FIG. 4A, a display indicating that the “number-set mode” is selected is displayed on the upper left of the display unit 20.

  When step S10 is YES, first, the CPU 50 proceeds to step S11 to execute a process of storing the input operand in the operand memory of the temporary storage area provided in the RAM of the storage unit 40 by the user. Execute.

  Specifically, every time the user operates the number input unit 11 to input a number, the input number is displayed on the display unit 20 and the input number is recorded in the operand memory. Be executed.

  For example, in this case, as shown in operation 2 of FIG. 4A, the user operates the number input unit 11 to input “2”, “0”, and “0” (that is, input “200”). ) Is performed, the number is displayed on the display unit 20 in the order, and “200.” is displayed according to the input of “200”, and the operand memory displays the number. “200” is stored in the order, and a numerical value “200” (a numerical value corresponding to the number of medicines to be prepared) is stored.

Here, “.” (Dot) in the display content “200.” on the display unit 20 indicates the position of the numerical value being input.
Regarding this “.”, The same applies to the case where another number is input by the number input unit 11, and the description thereof will be omitted.
The registration of the number in the operand memory is performed until step S12 becomes YES.

Then, when the user performs an operation of the “÷ remainder” key for specifying the remainder calculation (see operation 3 in FIG. 4A), step S12 becomes YES, and the CPU 50 proceeds to step S13 to execute the basic calculation by the user. An input of a number (also referred to as a basic operation number) will be accepted.
Note that when the user performs an operation of a “÷ remainder” key for designating a quotient remainder calculation (see operation 3 in FIG. 4A), as shown in FIG. "Remainder" is displayed so that the operator can visually recognize that the quotient remainder operation has been designated.

  As described above, in this case, the user (pharmacist) does not know how many heats (continuously packed bodies) are stored in the box (box) and one heat ( Since the user does not know how many medicines are collected in one continuous body), the user first opens the box, takes out one heat, and has how many medicines the heat has. The user operates the number input unit 11 to input the number of the medicine.

For example, when 14 medicines are collected in one heat, the user operates the number input unit 11 to display “1” and “4” as shown in operation 4 in FIG. Since the input is performed (that is, the input of “14”), the CPU 50 causes the display unit 20 to display the numbers in the order, and displays “14.” in accordance with the input of “14”.
Since “14” is the number of medicines included in one heat, the number is displayed on the display unit 20 as shown in operation 4 of FIG. "14." is displayed at the display of the number.

Further, the CPU 50 stores “14” in the basic operation number memory of the temporary storage area provided in the RAM of the storage unit 40 in that order, and stores the basic operation number “14” (the number of drugs having heat) in that order. Record.
Here, the reason why the input operation number is called a basic operation number will be described later.
The registration of the number in the basic operation number memory is executed until step S14 becomes YES.

  Then, as shown in operation 5 of FIG. 4A, following the input of the basic operation number, the operation of the multiplication operator key (“×” key) of the operator input section 12 for inputting the multiplication operator is performed. When this is performed, as described above, step S14 becomes YES, and the CPU 50 performs a process of accepting (accepting) a multiple (multiple value) (process of step S15) with that as a delimiter.

  The multiple is a multiple of the number of medicines contained in one box (box) as compared to the medicine of one heat, that is, a multiple operation number (multiple of the basic operation number) which is a multiple of the basic operation number. Here, the value is a value obtained by dividing the first multiple operation number described later) by the basic operation number, and corresponds to the number of heats contained in one box (box).

  As described above, the user opens the box (box), takes out one heat, and counts how many medicines are collected in that heat. The number of heats remaining in the parentheses) is counted, and the number obtained by adding 1 is the numerical value to be input here.

  For example, if there are two heats remaining in the box (box), the user operates the number input unit 11 to input “3” as shown in operation 6 in FIG. Will be done.

Then, the CPU 50 causes the display unit 20 to display the input number “3” as the process of step S15.
Since the number (numerical value) input here is the number of heats (number of pairs), the display unit 20 displays the number of pairs as shown in operation 6 in FIG. "3." is displayed at the display of the number of sets.

Further, the CPU 50 stores “3” in the multiple memory of the temporary storage area provided in the RAM of the storage unit 40, and records the multiple “3” for calculating the number of operations described later.
That is, in the present embodiment, the input of the operator (multiplication operator) by the operation of the operator input unit 12 following the input of the basic operation number (“14”) by the operation of the number input unit 11 is used as a delimiter. This is an input procedure for inputting a multiple (“3”) for obtaining the number of operations to be described later by the operation of the unit 11.

Note that the process of step S15 is executed until step S16 becomes YES.
Therefore, when the number to be input is 2 or more, the input number is sequentially displayed on the display unit 20 and the number input to the multiple memory is also displayed, as described in step S13. It will be recorded sequentially.

  Then, as shown in operation 7 of FIG. 4A, when the user operates the result display instruction unit 13 (“=” key), step S16 becomes YES, and the CPU 50 proceeds to step S17. The quotient operation is executed based on the numerical values “200”, “14”, and “3” stored in the operand memory, the basic operand memory, and the multiple memory.

  Specifically, first, the CPU 50 determines the number of medicines having a heat (basic operation number “14”), which is a basic unit of medicine contained in a box (box) stored in the basic operation number memory, and , The number of heats contained in the box (box) stored in the multiple memory (multiple “3”), and the number of medicines in the box (box) is determined. An operation number (also referred to as a first operation number or a first multiple operation number) based on the box is obtained.

  That is, the CPU 50 executes the calculation of “14 × 3”, obtains the number of medicines in the box (box) (“42”), and acquires this as the first operation number of the remainder calculation.

Then, the CPU 50 performs an operation of dividing the operand “200” stored in the operand memory by the first operand “42” to obtain a quotient 1 and a remainder 1.
For example, in this case, the quotient 1 is “4” and the remainder 1 is “32”.

Subsequently, the CPU 50 performs an operation of dividing the remainder 1 “32” by the basic operation number “14” to obtain the quotient 2 and the remainder 2 corresponding to the number of roses.
For example, in this case, the quotient 2 is “2” and the remainder 2 is “4”.
Note that this remainder 2 is a final remainder, and may be simply referred to as “remainder” hereinafter.

  When the quotient remainder calculation is executed as described above, the CPU 50 proceeds to step S18, and displays the quotient 1 (“4”) and the quotient 2 on the display unit 20 as shown in operation 7 of FIG. ("2") and the remainder ("4") are displayed, and symbols ("number of boxes", "number of heats", and "roses") indicating units are displayed above them.

  As described above, in the “number-set mode” of the present embodiment, the input of the number of operations can be performed simply by counting and inputting the number of medicines having heat and the number of heats in a box (box) in accordance with the input procedure. Since it is completed, the input of the number of operations can be performed very easily.

  In addition, following the input of the basic operation number (the number of medicines having heat), the input of the multiple is performed by operating the multiplication operator key ("x" key) for inputting the multiplication operator. .

  This multiple is used in an operation for calculating an operation number based on a box (box) (basic operation number “14” × multiple “3”), and a multiplication operator is added to an instruction to input the multiple. When the key (“×” key) is used, the concept of the key to be operated (“×” key) matches the concept of the numerical value (multiple) input thereafter, so that the user can intuitively understand the operation content. It is easy to operate.

  In addition, as described above, it is possible to select a menu by long-pressing the decimal point key (“•” key) and input to change the symbol displayed together with the calculation result. Unit display can be performed, and the calculation result can be easily understood.

(2nd Embodiment)
Next, a second embodiment will be described with reference to FIG.
The second embodiment is different from the above-described “number-set mode” in that the number of operations is fixed (locked), the quotient calculation is repeated, and the operation can be performed for different operands. The other points are the same as in the first embodiment.
Therefore, in the following, differences from the first embodiment will be mainly described, and description of the same points as the first embodiment may be omitted.

FIG. 5 is a diagram for explaining the second embodiment according to the present invention. As in FIG. 4 described above, FIG. 5A shows the operation contents of the operation unit 10 and the display unit 20 corresponding to the operation. FIG. 5B is a flowchart for explaining the operation of the electronic device 1.
Here, as in the previous case, the description will be made based on a specific case.

Specifically, as an example, the first operation is an operation for preparing 200 medicines, which is the same as in the first embodiment.
Then, in this case, a calculation for preparing 330 drugs is performed as a second calculation.

  As shown in FIG. 5B, when the power is turned on, the CPU 50 makes a determination in steps T10, T30, and T40 corresponding to steps S10, S20, and S30 in FIG. 4B described above. Is going.

  Then, when step T30 becomes YES, the CPU 50 executes the process of step T31 corresponding to step S21 of FIG. 4B described above, and when step T40 becomes YES, the CPU 50 of FIG. The process of step T41 corresponding to step S31 is performed, and the operation of this flowchart ends.

  On the other hand, when operation 1 in FIG. 5A (the same operation as operation 1 in FIG. 4A) is performed by the user, step T10 becomes YES, and CPU 50 executes the process of step T11.

  If step T10 is YES, a display indicating that "number-set mode" has been selected is displayed on the upper left of the display unit 20, as in the first embodiment. Since the mode is fixed (locked), the display of “K number-set mode” with “K” indicating the mode is performed.

  Further, in the second embodiment, since the operation is started from the input of the basic operation number, the number is also displayed on the display unit 20.

  The process in step T11 is the same as step S13 in FIG. 4B, and detailed description is omitted, but operation 2 in FIG. 5A similar to operation 4 in FIG. Is performed by the user, the display on the display unit 20 is performed in the same manner as described above, and the basic operation number "14" is recorded in the basic operation number memory.

The process of step T11 is performed until step T12 becomes YES, and this step T12 is the same as step S14 of FIG. 4B.
If step T12 is YES, the process proceeds to step T13, but this step is also the same as step S15 in FIG. 4B, and FIG. 5A similar to operation 6 in FIG. Is performed by the user, the same display as described above is displayed on the display unit 20, and the multiple value "3" is recorded in the multiple memory.

Then, as shown in operation 5 of FIG. 5A, when the user operates the “÷ remainder” key for specifying the remainder calculation, step T14 becomes YES, and the CPU 50 proceeds to step T15 to perform the basic calculation. The first operation number is obtained based on the numerical value “14” of the basic operation number stored in the number memory and the numerical value “3” of the multiple stored in the multiple memory. The numerical value “42” is stored in the first operation number memory in the storage area.
That is, the CPU 50 stores the operation number group including the basic operation number and one or more multiple operation numbers including at least the first multiple operation number in the temporary storage area in the RAM of the storage unit 40 in the processing so far. Let it.

  Note that when the user operates the “÷ Remainder” key for designating the remainder operation, the input relating to the operation number has been completed, and thus the process of obtaining the first operation number is performed as described above. Since the next process is the input process of the operand, the display on the display unit 20 is set to “0.”, and the display of “total number” indicating that the operand is input is displayed. Is being done.

  Further, similarly to the first embodiment, “÷ remainder” is displayed at the upper right of the display unit 20 so that it can be visually recognized that the quotient remainder operation has been designated (the operation in FIG. 5A). (Refer to the display on the display unit 20 corresponding to No. 5.)

Subsequently, the CPU 50 proceeds to step T16 to display the input number on the display unit 20 and store it in the operand memory of the storage unit 40. The process of step T16 is also performed in FIG. Is the same as the process in step S11.
Also in this case, as shown in the operation 6 of FIG. 5A, the same operation as the operation 2 of FIG. 4A is performed, so that the numerical value “200” is recorded in the operand memory. Done.
Note that the process of step T16 is performed until step T17 becomes YES.

Then, as shown in operation 7 of FIG. 5A, when the user operates the result display instruction unit 13 (“=” key), step T17 becomes YES, and the CPU 50 proceeds to step T18. The quotient calculation is executed based on the numerical values “200”, “14”, and “42” stored in the operand memory, the basic operand memory, and the first operand memory.
Note that the quotient remainder operation is the same as described above, and as a result of the execution of the quotient remainder operation, the quotient 1 is “4”, the quotient 2 is “2”, and the remainder is “4”.

  Subsequently, the CPU 50 proceeds to Step T19, performs the same processing as Step S18 in FIG. 4 of the first embodiment, and proceeds to Step T20.

Then, if the user's operation following step T17 is an operation of the clear unit 14 (“AC” key), the CPU 50 determines that the determination of step T20 is YES, and sets a plurality of operation numbers (basic operation The basic operation number of the number memory and the operation number of the first operation number memory are cleared, and the process returns to step T10 again.
At this time, the multiple of the multiple memory and the operand of the operand memory are also cleared, and the display on the display unit 20 is displayed in the same state as when the power is turned on.

  On the other hand, if the user's operation following step T17 is an operation of the number input unit 11, the CPU 50 determines NO in step T20, proceeds to step T21, and resets (clears) only the operand memory. Proceed to step T16.

  Then, as shown in operation 8 of FIG. 5A, when the input of “330” is performed by operating the number input unit 11, the CPU 50 stores “330” in the operand memory, and When the user operates the result display instructing unit 13 (“=” key) as shown in operation 9 of (A), step T17 becomes YES, and the CPU 50 proceeds to step T18 to execute the operand memory. The quotient calculation is executed based on the numerical values “330”, “14” and “42” stored in the basic operation number memory and the first operation number memory.

  In this calculation, the quotient 1 is “7”, the quotient 2 is “2”, and the remainder is “8”. After the calculation in step T18, the process proceeds to step T19, and the display content displayed on the display unit 20 is The display on the display unit 20 shown at the operation 9 in FIG.

  As described above, in the second embodiment, the operation using the plurality of operands can be repeatedly performed until the input (instruction) for clearing the plurality of operands from the storage unit 40 by the operation of the clear unit 14. When the quotient operation with the same operation number is repeatedly performed, it is not necessary to repeatedly perform the operation of inputting the operation number, and the operability is improved.

  Further, in the second embodiment, prior to the input of the operand, input relating to the operand is performed. However, the input procedure of the numerical value relating to the operand is the same as that of the first embodiment. This is the same in that the input of the number of operations can be performed very easily because the operation is followed.

Although the electronic device 1 of the present invention has been described based on the specific embodiments, the present invention is not limited to the above specific embodiments.
For example, the electronic device 1 may be a combination of the first embodiment and the second embodiment.

  Specifically, in the first embodiment, the selection of the “number-set mode” by the user is selected by the operation of the “X” key following the operation of the “AC” key. In the second embodiment, the same operation is performed. “K number-set mode” for fixing the number of operations was selected, but either selection was added to the operation of the “×” key following the operation of the “AC” key, and further, “×” Assuming that the selection is made by adding a partially different operation so as to be selected by performing a key operation, it is possible to distinguish which is selected, so that the first embodiment and the second embodiment are performed. Even if both forms are combined, no problem occurs.

Also, in the first embodiment, although briefly mentioned, the number of operations is not limited to the two operations of the basic operation and the first operation, and may be three or more operations. .
Even in such a case, if the input of the number of operations is performed by inputting a number other than the basic number of operations as a multiple, as described above, the number is simply counted and the number is input as a multiple. Often, the input operation can be facilitated.

  For example, in the case where the number of medicines included in the drug continuous package (heat) is 14, the small box contains two continuous packages (heat), and the large box contains three small boxes, Following the input of the basic operation number by the operation of the number input unit 11 (input of the number “14”), the number of operations by the operation of the number input unit 11 A multiple is input (the number of heats in a small box is “2”), and a multiple is input (a number of small boxes in a large box is “3”) to operate the number input unit 11. The multiple may be input repeatedly as many times as necessary (the number of times equal to the number of operations excluding the basic operation number).

  By inputting a multiple in this way, the number of drugs (basic operation number) of the drug enclosure (heat), which is the most basic unit, ie, the basic operation number, is a multiple ( The second operation number "28" can be obtained by multiplying the number of heats "2" in the small box, and further, the second operation number "28" is a multiple (the number of small boxes "3" in the large box). ) Can be obtained to obtain the first operation number “84” which is the largest operation number.

  That is, if the multiple input is performed in this manner, the operation numbers (second operation number, first operation number) are the operation numbers (basic operation number, second operation number) according to the immediately preceding input. It is obtained by multiplying by a multiple (2 times, 3 times).

  In the above-described first and second embodiments, “.” Is added to the numerical value being input to indicate the position of the numerical value being input, but this may be omitted. Good.

  As described above, the present invention is not limited to the specific embodiments, and various modifications and improvements are also included in the technical scope of the present invention. It is clear from the description of the claims.

In the following, the inventions described in the claims first attached to the application form of this application are appended.
The item numbers of the claims described in the supplementary notes are as set forth in the claims originally attached to the application form of this application.
<Claim 1>
Numerical input means for inputting a basic operation number and a first multiple value which is a value obtained by dividing a first multiple operation number which is a multiple of the basic operation number by the basic operation number, by a user operation;
Operator input means for inputting an operator by user operation,
Separating means for separating the input of the basic operation number and the input of the first multiple value by the input of the operator;
Electronic equipment provided with.
<Claim 2>
The apparatus further includes an operation unit that performs an operation based on the input basic operation number and the first multiple value,
The calculating means calculates the first multiple operation number by calculating a value obtained by multiplying the basic operation number by the first multiple value;
The electronic device according to claim 1.
<Claim 3>
The numerical value input means enables a user to input a second multiple value which is a value obtained by dividing a second multiple operation number which is a multiple of the first multiple operation number by the first multiple operation number,
The operator input means can also separate the input of the first multiple value and the input of the second multiple value by inputting the operator by a user operation.
The electronic device according to claim 1.
<Claim 4>
An arithmetic unit that performs an arithmetic operation based on the input basic arithmetic number, the first multiple value, and the second multiple value,
The calculating means obtains the first multiple operation number by calculating a value obtained by multiplying the basic operation number by the first multiple value, and calculates the second multiple operation number in the first multiple operation number. Calculating the second multiple operation number by calculating a value obtained by multiplying the numerical value;
The electronic device according to claim 3.
<Claim 5>
A storage unit that stores an operation number group including the basic operation number and one or more multiple operation numbers including at least the first multiple operation number;
A clear unit that issues an instruction to clear the operation number group stored in the storage unit by a user operation;
With
If the clear instruction has not been issued, it is possible to repeatedly execute the operation based on the stored operation number group,
The electronic device according to claim 2.
<Claim 6>
The arithmetic means includes, for the operand, a plurality of quotients and one remainder based on each of the basic operand and one or more multiple operands including at least the first multiple operand. Quotient operation for
A display unit for displaying a result of the remainder calculation,
Symbol display means for displaying a symbol representing a unit corresponding to each of the plurality of quotients and the one remainder, when a result of the remainder operation is displayed on the display unit;
The electronic device according to claim 2, further comprising:
<Claim 7>
The apparatus further includes symbol changing means for changing the displayed symbol according to a user operation.
The electronic device according to claim 6.
<Claim 8>
The operator is a multiplication operator,
The electronic device according to claim 1.
<Claim 9>
A numerical input step of inputting a basic operation number and a first multiple value which is a value obtained by dividing the first multiple operation number which is a multiple of the basic operation number by the basic operation number, by a user operation;
In the numerical value input step, an operator input step of inputting an operator by a user operation,
In the numerical value input step, a separating step of separating the input of the basic operation number and the input of the first multiple value by inputting the operator,
Input method including.
<Claim 10>
For electronic devices,
Numerical input means for inputting a basic operation number and a first multiple value which is a value obtained by dividing a first multiple operation number which is a multiple of the basic operation number by the basic operation number, by a user operation;
Operator input means for inputting an operator by user operation,
Separating means for separating the input of the basic operand and the input of the first multiple value by the input of the operator;
Program to execute the process as

Reference Signs List 1 electronic device 10 operation unit 11 number input unit 12 operator input unit 13 result display instruction unit 14 clear unit 20 display unit 30 recording medium reading unit 40 storage unit 50 CPU
60 data bus 70 power generation unit M recording medium

Claims (10)

Numerical input means for inputting a basic operation number and a first multiple value which is a value obtained by dividing a first multiple operation number which is a multiple of the basic operation number by the basic operation number, by a user operation;
Operator input means for inputting an operator by user operation,
Separating means for separating the input of the basic operation number and the input of the first multiple value by the input of the operator;
Electronic equipment provided with. The apparatus further includes an operation unit that performs an operation based on the input basic operation number and the first multiple value,
The calculating means calculates the first multiple operation number by calculating a value obtained by multiplying the basic operation number by the first multiple value;
The electronic device according to claim 1. The numerical value input means enables a user to input a second multiple value which is a value obtained by dividing a second multiple operation number which is a multiple of the first multiple operation number by the first multiple operation number,
The operator input means can also separate the input of the first multiple value and the input of the second multiple value by inputting the operator by a user operation.
The electronic device according to claim 1. An arithmetic unit that performs an arithmetic operation based on the input basic arithmetic number, the first multiple value, and the second multiple value,
The calculating means obtains the first multiple operation number by calculating a value obtained by multiplying the basic operation number by the first multiple value, and calculates the second multiple operation number in the first multiple operation number. Calculating the second multiple operation number by calculating a value obtained by multiplying the numerical value;
The electronic device according to claim 3. A storage unit that stores an operation number group including the basic operation number and one or more multiple operation numbers including at least the first multiple operation number;
A clear unit that issues an instruction to clear the operation number group stored in the storage unit by a user operation;
With
If the clear instruction has not been issued, it is possible to repeatedly execute the operation based on the stored operation number group,
The electronic device according to claim 2. The arithmetic means includes, for the operand, a plurality of quotients and one remainder based on each of the basic operand and one or more multiple operands including at least the first multiple operand. Quotient operation for
A display unit for displaying a result of the remainder calculation,
Symbol display means for displaying a symbol representing a unit corresponding to each of the plurality of quotients and the one remainder, when a result of the remainder operation is displayed on the display unit;
The electronic device according to claim 2, further comprising: The apparatus further includes symbol changing means for changing the displayed symbol according to a user operation.
The electronic device according to claim 6. The operator is a multiplication operator,
The electronic device according to claim 1. A numerical input step of inputting a basic operation number and a first multiple value which is a value obtained by dividing the first multiple operation number which is a multiple of the basic operation number by the basic operation number, by a user operation;
In the numerical value input step, an operator input step of inputting an operator by a user operation,
In the numerical value input step, a separating step of separating the input of the basic operation number and the input of the first multiple value by inputting the operator,
Input method including. For electronic devices,
Numerical input means for inputting a basic operation number and a first multiple value which is a value obtained by dividing a first multiple operation number which is a multiple of the basic operation number by the basic operation number, by a user operation;
Operator input means for inputting an operator by user operation,
Separating means for separating the input of the basic operation number and the input of the first multiple value by the input of the operator;
Program to execute the process as

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