JPH0119197B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an electronic register that performs registration processing based on pre-stored price data.

[Conventional technology]

Conventionally, as shown in, for example, Japanese Utility Model Application Publication No. 55-74941, unit prices were preset for each department.
Some products allow registration processing based on preset unit prices simply by operating departmental keys.

[Problem to be solved by the invention]

Although such an electronic register has the advantage of speeding up the registration process, when selling products in a certain number of departments as a set, it is necessary to operate a plurality of department keys, respectively. Examples of products that sell multiple products as a set include set meals at restaurants and set services at beauty salons. In stores like this,
Although the departments to be entered for each set are determined, each department key must be operated individually, making key operations cumbersome and prone to operational errors. Also, since the registration process takes time,
There was a drawback that the service to customers deteriorated.

An object of this invention is to combine multiple pieces of data including prices of products specified at the time of registration by classification, and to automatically perform registration processing for each piece of combined data when a specific key is pressed. The purpose is to simplify key operations.

[Means to solve the problem]

A first storage means (addresses 01 to 0A of memory 5, etc.) that stores at least product price data and is designated at the time of classification registration; a second storage means that stores a plurality of codes that designate this first storage means; Storage means (memory 5 address
0B to 14, etc.), a specific key (such as the MS key on the input section 6) that specifies this second storage means, reads a code in the second storage means when this specific key is operated, and specifies it using this code. and calculation means (CPU 1, etc.) that performs registration processing for each code based on the price data in the first storage means.

Note that the words in brackets are added for reference in order to clarify how the above-mentioned means are embodied in the embodiments.

[Effect]

The first storage means stores at least price data of products, and is designated at the time of classification registration. A plurality of codes specifying the first storage means are stored in the second storage means. A code in the second storage means is read out when a specific key designating the second storage means is operated, and registration is based on price data in the first storage means designated by this code. Processing is performed for each code by the arithmetic means.

Therefore, key operations during registration can be simplified.

〔Example〕

Hereinafter, one embodiment will be described based on FIGS. 1 to 9.

FIG. 1 shows a schematic system configuration diagram of an electronic register. Reference numeral 1 indicates a CPU, and this CPU 1 provides R/W to an input control section 2, a display control section 3, a print control section 4, and a memory 5 via a control bus CB. signal,
A chip designation signal is output, and a control signal output from the print control section 4 is input. Further, the CPU 1 communicates with each of the control units 2, 3,
4 and the memory 5. In addition, the CPU 1 inputs data from the input buffer IN via the data bus DB, and also inputs data from the display control unit 3.
It outputs data to a display buffer DI provided in the print buffer DI and a print buffer PR provided in the print control section 4, and also exchanges data with the memory 5.

The input control section 2 inputs a timing signal to the input section 6.
KP is output, and when a key operation is performed in the input section 6, the timing signal KP is selected in response to the key operation and is input to the input buffer IN as a key input signal KI. Further, the display control section 3 outputs the digit signal DG and the segment signal SG obtained by decoding the data of the display buffer DI to the display section 10 to display amount data and the like. The print control unit 4 also includes a print position signal of a print drum (not shown) provided in the print unit 8.
A print drive signal HD generated by matching TP with data in the print buffer PR is sent to the print unit 8. Then, the printing unit 8 prints amount data and the like on the recording paper according to the print drive signal HD.

FIG. 2 shows the operation panel of the input section 6, which includes a number key 9, a department key 10, and a cash key.
In addition to CA, etc., there are also multi-set keys described later.
MS and multi-reset key MR are provided respectively. In addition, input section 6 includes REG (registration) and SET1.
A mode switch 11 is provided for specifying each mode such as (setting 1) and SET2 (setting 2).

Further, FIG. 3 shows the format of the memory 5, in which the storage areas designated by row addresses 01, ~0A, are associated with departments 1~10, respectively.
The unit price of that department and the total sales of that department are stored there. Also, line address 0B~14,
A plurality of row addresses of the respective departments are stored in each storage area designated by , and each storage area is referred to as multi-department 1 to multi-department 10. further line address
In the storage area after 15, the input data is classified by transaction and stored as a total by transaction.

Next, the operation of this invention will be explained. When setting unit prices for departments 1 to 10, after setting the mode switch 11 to the "SET1" mode, input unit prices for each department as shown in FIG. At this time, each time the department key is operated, the operation according to the flow shown in FIG. 5 is executed. That is, in executing step _S1 , the key code input by the departmental key operation is converted into a line address specifying the corresponding storage area of the memory 5 and written into the X register. Next, the process moves to step _S2 , and A is selected according to the number set immediately before the section key operation.
The unit price data written in the register is transferred to the storage area M(x) of the memory 5 specified by the address in the X register. Then step
Moving on to the execution of _S3 , the unit price data in the A register is transferred to the printing buffer PR, and printed on recording paper in the printing section 8. Similarly, unit price data is stored in the corresponding storage area of the memory 5, and the unit price data and department number are printed on recording paper as shown in FIG.

Next, if you want to combine multiple departments 1 to 10 above and set them as multi-department, switch the mode switch 1.
3 to the "SET2" mode and operate the department keys of the departments to be combined as shown in FIG. 6, the operation according to the flow shown in FIG. 7 will be executed each time the department keys are operated.

That is, in executing step _S11 , the department key code input by the department key operation is converted into the row address of the department and written into the X register. Next, proceed to step _S12 ,
It is determined whether "1" is stored in the flag area F _S of the CPU 1, and if it is determined not, the process moves to step _S13 . "1" is stored in the flag area F _S when the multi-set key MS is operated immediately before the departmental key operation. In the execution of step _S13 , the contents of the Y register of CPU1 are changed to 2.
Carry up by one digit. Next, the process moves to step _S14 , where it is determined whether the contents of the most significant two digits _YMSD of the Y register are "0", and if it is determined not, the process moves to step _S15 . When executing step _S15 , the row address in the X register is the digit of the Y register.
Transferred to Y ₁ . Next, the process moves to step _S16 , where the unit price data stored in the storage area M(x) of the memory 5 designated by the row address in the X register is transferred to the A register. Next, the process moves to step _S17 , where the unit price data in register A and
The contents of the B register of CPU1 are added, and this sum is written to the B register. Next, the execution of the register ₁₈ is started, and the unit price data of the A register is printed on the recording paper in the printing section 8. If it is determined in step _S14 that the two most significant digits Y _MSD of the Y register are not "0", the process moves to step _S19 . In executing step _S19 , overflow processing is executed because the number of row addresses stored in the Y register exceeds the storage capacity of the Y register. Next, the process moves to step _S20 , where the Y register is down-loaded.

As described above, when the departmental keys are operated in the order shown in FIG. 6, steps _S11 to _S18 are repeatedly executed for each departmental key operation, and as a result, the unit price data corresponding to each department is "650"
"350" and "1600" are sequentially read out and printed on recording paper as shown in FIG. Along with this reading, each unit price data is sequentially added to the B register, and the total amount "2600" is stored.

After the departmental key operation, the multi-set key
When the MS is operated, "1" is set in the flag area F _S of the CPU 1. When the department key □2 is subsequently operated, it is determined in step _S12 that "1" has been set in the flag area F _S , and the process moves to step _S21 . When executing step _S21 , the row address in the X register is set to hexadecimal ``0A''.
(10 in decimal) is added, and the result of this addition is written to the X register. For example, since the row address of department 2 is "02", the row address of multi-department is "0C". Next, the process moves to step _S22 , where the row address of each department stored in the Y register is transferred to the storage area M(x) of the memory 5 specified by the row address in the X register as described above. is stored as. Then step
The process moves to execution of _S23 , and "0" is written in the flag area F _S. Next, proceed to step S24, and proceed to step _S24 .
The total amount in the register and the department number are printed on the recording paper along with a signal "P" indicating multi-department. Next, the process moves to step _S25 , where "0" is written to the contents of the B register.

After setting the unit price data in correspondence with the department keys and the multi-department data combining each department as described above, the mode switch 13 is set to the "REG" mode. Then, as shown in Figure 8, the multi-set key MS, department key □2
If the customer is operated in sequence to register multiple departments for the customer, the operation according to the flow shown in FIG. 9 will be executed when the department key is operated.

That is, in executing step _S31 , the department key code input by the department key operation is converted into a department address and written into the X register. Next, the process moves to step _S32 , where it is determined whether or not "1" indicating the operation of the multi-set key 11 is stored immediately before the flag area F _S.
If it is determined that the memory is present, the process moves to step _S33 . In executing step _S33 , "0A" is added to the row address of the X register, and the result of this addition is written to the X register. Next, the process moves to step _S34 , where the multi-department data in the storage area M(x) of the memory 5 specified by the row address in the X register is transferred to the Y register. Next, proceed to step _S35 , and write the lower two digits of the Y register.
The contents of Y _0,1 are transferred to the X register. Next, the program moves to step _S36 , where it is determined whether the contents of the X register are "00" or not. If it is determined not, it is determined that department data is stored, and the program moves to step _S37 . In executing step _S37 ,
Unit price data in storage area M(x) specified by the row address of the X register is transferred to the A register. Next, the process moves to step _S38 , where the unit price data in the A register is added to a predetermined area in the storage area M(x) for each department, and the unit price data in the A register is added to a predetermined storage area in the memory 5 for each transaction. In addition to the total addition, a subtotal addition is performed which is accumulated in the Z register of CPU1. Next, the process moves to step _S39 , where the unit price data in the A register is printed on the recording paper in the printing section 8. Next, the process moves to step _S40 , where it is determined whether or not "1" is stored in the flag area F _S. If "0" is stored, it is assumed that it is a normal department registration and the registration process is performed. If "1" is stored, it is multi-department registration and the process moves to step _S41 . In executing step _S41 , the contents of the Y register are incremented by two digits, and then the process returns to step _S35 . In step _S36 , the contents of the X register are "0".
If it is determined that the multi-department data transferred to the Y register has been completely registered and printed, the process moves to step _S42 . Step S ₄₂
In the execution of , "0" is written in the flag area F _S .

However, when you operate the department key □2 mentioned above,
As shown in FIG. 8, unit price data of individual departments combined as multi-department data is printed on recording paper together with the department number, and further registration is executed for each department. After operating this department key □2,
If the unit price data "350" corresponding to the department □2 is not included in the amount billed to the customer, the operator continues to operate the multi-reset key MR and the department key □2. Then, after executing step _S31 , the process moves to step _S43 , and the flag area of CPU1 is
A check is made to see if “1” or “0” is stored in _FR , and the multi-reset key MR is pressed just before
is operated and if "1" is stored, the process moves to step _S44 . In executing step _S44 ,
Storage area M specified by the contents of the X register
Unit price data “350” of (x) is transferred to the A register. Next, the process moves to step S45, where the unit price data in the A register is subtracted from the total data in the storage area M(x), and the total by transaction is also subtracted from the total by transaction written in a predetermined storage area in the memory 5. The transaction-by-transaction total is subtracted, and the subtotal is subtracted from the subtotal data in the Z register of CPU1. Next, the process moves to step _S46 ,
The unit price data in the A register is printed on the printing unit 8 together with a "-" symbol as a deducted unit price. Then, following the operation of the department key □2, the cash key is pressed.
When the CA is operated, the subtotal data of the Z register is printed on the recording paper along with the "current" symbol. By the way, if you operate the department key alone,
Steps S ₃₁ , S ₃₂ , S ₄₃ , S ₃₇ to _{S 40} are executed in sequence, and only the registration according to the unit price data corresponding to the operated department is performed.

As described above, in this embodiment, after a multi-department has been registered, if you wish to deduct the unit price data of the departments included in the multi-department, you must operate the multi-reset key MR and the department key in sequence. Because unnecessary unit price data can be deducted by
This has the advantage of expanding the scope of use of multi-department registration.

Further, in the embodiment described above, only a storage area for storing total data for each department is provided, but in addition to this, a storage area for storing total data for multiple departments may be provided. In this way, total sales data for multiple departments can be printed out at the time of inspection and settlement, which can be useful for business management.

In addition, in the above embodiment, the multi-set key
Although multi-department registration is performed by operating the MS in combination with a departmental key, the present invention is not limited to this, and a configuration may also be provided in which a dedicated key for registering multi-department is independently provided. .

Furthermore, in the above embodiment, the case where departmental registration is performed using departmental keys as classification-based registration has been described, but this is not limited to this; registration using PLU keys can also be performed in the same way as multi-PLU. be.

〔Effect of the invention〕

According to this invention, an operator can register products classified into a plurality of categories by operating only a specific key. Therefore, key operations at the time of registration are very simple, so even in a busy store such as a beauty salon where a plurality of products are provided to customers, registration can be performed without making customers wait.

[Brief explanation of drawings]

Figures 1 to 9 show examples, Figure 1 is a schematic system configuration diagram, Figure 2 is a plan view of the input section, Figure 3 is a memory format diagram, and Figure 4 is a key for setting unit prices. Operation procedure diagram, the same figure is a printing state diagram,
Fig. 5 is a flowchart showing unit price setting operation, Fig. 6 is a key operation procedure diagram when setting multi-department, the same figure is a print state diagram, Fig. 7 is a flowchart showing multi-department setting operation, and Fig. 8 is a flowchart showing unit price setting operation. 9 is a key operation procedure diagram for multi-department registration, the same figure is a printing state diagram, and FIG. 9 is a flowchart showing department-specific and multi-department-specific registration processing. 1...CPU, 5...Memory, 6...Input section,
10... Department key group, 11... Multi set key.

Claims (1)

[Claims] 1. A first storage means that stores at least product price data and is designated at the time of classification registration; a second storage means that stores a plurality of codes that designate this first storage means; A registration process is performed based on a specific key specifying a storage means, and a code in the second storage means that is read out when the specific key is operated, and price data in the first storage means specified by this code. An electronic register comprising calculation means for each code.