JPS5827545B2 - Transaction suspension processing method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a transaction interruption processing method for complex transactions and the like in a cash registration device that manages cash for monetary transactions in counter operations at bank branches and the like.

Recently, in counter operations at bank branches, etc., there is a "first line" process for money management such as money transfer, daily deposit and withdrawal calculations, and cash reconciliation, as well as slip processing and file updates at the center. A cash registration device that allows one person to perform all the second-line processing, so-called OTM (On-
1ine Tel 1ers Machine) is used.

As a result, customer service at stores has improved, and in-store operations have been streamlined.

Conventionally, transactions handled in the above-mentioned OTM are broadly divided into single transaction and compound transaction.

Here, a single transaction is a transaction in which the center file is updated only once for each batch input to the transaction counter memory.

For example, when depositing 12,000 yen in cash into savings account 1, in this case, in the transaction counter memory, the deposit item is 1-12. ooOJ as a breakdown,
Enter "1" in the denomination item (10,000 yen note) and "2" in the denomination item (1,000 yen note), and on the other hand, at the center, enter ``+12,000J calculation processing for account +-1'' in the file. conduct.

On the other hand, a compound transaction is a transaction in which the center file is updated two or more times for one batch input to the transaction counter memory.

For example, when depositing a check from our store with a face value of 15,000 yen (checking account Φ2) into a savings account -4F,1, in this case, the transaction counter memory records the account +2.
Enter the withdrawal 1'-150004 in the withdrawal item, and enter the deposit [15,000, J] into the account +1 in the deposit item, and also enter the breakdown in the bill type item (our store check). Enter the number of sheets “1” and the amount “15,000J”,
On the other hand, the center performs arithmetic processing of "1--15,000" for checking account #2 on file, and then updates the file on ordinary account-II-1 on file.

In this manner, in the case of a compound transaction, some operations, such as key-in operations for cash details, are omitted compared to the case where one transaction is simply performed multiple times.

A zero-proof check is performed after each transaction is completed for such single transactions and composite transactions.

That is, the transaction counter memory checks whether the difference between the deposit amount (or withdrawal amount) and the amount calculated from the cash details is zero.

In this case, the cash details indicate the number of denominations (10,000 yen notes, 5,000 yen notes, 1,000 yen notes, 500 yen notes) and the amounts of other coins.

If the result of this check is that the amount is not zero, a message such as "proof error" is displayed on a display, such as a plasma display device, as well as a deficiency or surplus amount.

In addition, in a compound transaction, even in the middle of the compound transaction, for example, if the file should be updated twice, it may be updated once.
After the first file update, if there is a momentary power outage, a cancel key is pressed, or there is an insufficient balance in the first file update, the compound transaction will be interrupted and, as a result, a zero-proof check will be performed. Sometimes.

However, in the conventional method described above, in the middle of a compound transaction, compared to a single transaction, some operations such as the key-in of cash details are omitted, so if the compound transaction is interrupted, almost no proof is obtained. do not have.

Therefore, if a zero-proof check is performed in this case, it will be determined that a bruf error has occurred, and a message such as ``Bruf Error'' will be displayed on the display, and each time the teller (teller) corrects the file at the center before proceeding with the transaction. As a result, there is a problem in that processing for suspending a complex transaction is delayed, leading to a decline in office efficiency and customer service.

The object of the present invention is to change the value of the transaction counter that has already been traded when the compound transaction is interrupted due to a momentary power outage, a key-in of the cancel key, or an insufficient balance when updating a file during the compound transaction. Based on the concept of inputting the cash details with special codes added using a reverse addition method, the proofs in the middle of a compound transaction are matched, and as a result, even if a zero-proof check is performed in the middle of a compound transaction, This eliminates blueprint errors and therefore eliminates the need for file corrections at the center, thereby speeding up the processing of interruptions in complex transactions.As a result, it increases office efficiency and improves customer service, which eliminates the problems with the conventional method described above. The point is to solve the problem.

The present invention will be explained below with reference to the drawings.

FIG. 1 is an external view of the OTM.

In FIG. 1, OTM1 includes a key group 11 consisting of data keys and function keys, a display device such as a plasma display device (FDP) 12 that displays data two-dimensionally, and a journal 13 that prints data one-dimensionally. , and a band scanner 14 for reading out the magnetically recorded portion of a bankbook or card.
The TM housing includes various control devices, arithmetic devices, storage devices, and the like.

Figure 2 shows an OTM that performs the complex transaction cancellation processing method of the present invention.
FIG.

In FIG. 2, data key 11-1 is, for example, O
It includes numerical data keys such as ~9°oo, ooo, and 1, and the numerical data keyed in using these data keys 11-1 is temporarily stored in the calculation buffer 21.

In addition, the function key 11-2 is used to input the calculation buffer 21 such as account, account number, denomination (10,000 yen, 5,000 yen, etc.), bill type (our check, other store's check), deposit, withdrawal, etc. It includes keys for processing several types of data, and control keys such as completion keys and compound keys.

The arithmetic control circuit 22 executes arithmetic instructions on the numerical data input through the data key 11-1 according to the function input through the function key 11-2, performs arithmetic processing, and stores the arithmetic results in the transaction counter memory. 24 and also controls other circuits of OTML.

This transaction counter memory 24 stores a plurality of counters, such as a deposit counter, a withdrawal counter, and a cash breakdown (10,000 yen,
5,000 yen, 1,000 yen, etc.) counter, ticket type (checks from our store, checks from other stores) counters, etc.

The balance counter memory 25 indicates the cumulative total of OTM1 transactions, and the contents stored in the transaction counter memory 24 that have undergone a zero-proof check are cumulatively added.

The line control circuit 23 is for reading directly between the OTM 1 and the center, and is used, for example, when updating files at the center.

When a compound transaction is interrupted, the inverse addition circuit 21 adds the cash breakdown corresponding to the value of the deposit counter or the value of the withdrawal counter (or the difference between the values of these counters) to the cash breakdown counter in the transaction counter memory 24. This is for inputting information to the user.

In this embodiment, there are three cases in which a composite transaction may be interrupted:

(1) If a file update impossible signal is sent to the arithmetic control circuit 22 via the circuit control circuit 23 due to insufficient funds or other reasons when updating a file at the center, (2) If the cancel key of the function key 11-2 is pressed (3) When a momentary power interruption is detected by the momentary power interruption detection circuit 26.

In such a case, the reverse addition circuit 27 sets the cash details in the cash details counter in the transaction counter memory 24, so that the contents stored in the transaction counter memory 24 can be proofed even in the middle of a complex transaction.

Next, the operation of the OTM shown in FIG. 2 will be explained using an example of a composite transaction.

FIG. 3 shows each counter in the transaction counter memory of FIG.

24-1 is a deposit counter, 24-2 is a withdrawal counter, 2
4-3 to 24-6 are cash breakdown counters that store the number of coins, each of which is 1. These are a 10,000 yen bill counter, a 5,000 yen bill counter, a 1,000 yen bill counter, and a 500 yen bill counter.

24-7 is also a cash breakdown counter that stores the amount of other coins, and 24-8 and 24-9 are counters that store the types of bills such as our store's checks and other store's checks, and they store the number of coins and the amount. Memorize both.

Note that other subject counters, figure number counters, etc. are omitted.

FIGS. 4A and 4B show an example of the contents of each counter in the transaction counter memory when a composite transaction is normally performed.

As a compound transaction, a customer pays a check from our store with a face value of 15,000 yen (
Assume that a deposit is made from current account II-21 to ordinary account Fist 1.

In this case, the teller updates the file for checking account +2 as a first step, and updates the file for savings account +2 as a second step.

By default, the function /
Key in the composite key 11-2 (this key remains in the key-in state).

First, in the first step, the subject ``Toza'' (key in the corresponding code) and the fourth item ``Φ1'' are keyed in using the data key 11-1 and the function key 11-2.

Next, data key 11-1 and function key 1
When "15000., J" is keyed in using the withdrawal key 1-2, "15000" is written in the counter 24-2 as shown in FIG. 4A.

Furthermore, data key 11-1, function key 1
When you key in the number of tickets ``1'' and the amount 1'-15000J using the number key of 1-2 and our ticket key, Figure 4A
As shown in , 1115000J is written to the counter 24-9.

Finally, when the completion key of the function key 11-2 is pressed in, the arithmetic control circuit 22 transfers the data to the line control circuit 23.
The message is transferred via the center, and the calculation of "-15000" is performed for the checking account Φ2.

As a result, if the file update is completed, the transaction counter memory 22 maintains the state shown in FIG. 4A.

Next, in the second step, the subject ``F9'' (key in the corresponding code) and the number 4 4I-1 are keyed in.

Furthermore, when l-15000j is keyed in using the data key 11-1 and the deposit key of the function key 11-2, the counter 24-1 is displayed as shown in FIG. 4B.
"15000" is written in.

After this, when the completion key of the function key 11-2 is pressed, the calculation control circuit 22 sends the data to the line control circuit 2.
The message is transferred via 3, and the center calculates ``+15000'' for the savings account +1.

When this file update is completed and the composite transaction key is released, the counters 24-1 to 24-1 of the transaction counter memory 24 are
24-1 is carried out, that is, (the value of the deposit counter 24-1 (the value of the withdrawal counter 24-2) is
-7 (value calculated from 7).

In the case shown in FIG. 4B, since the proof has been taken, the values of each counter in the transaction counter memory 24 are cumulatively added to the balance counter memory 25.

In this way, a zero-proof check is performed only once in a normal composite transaction.

Next, a case where the composite transaction is interrupted due to any of the reasons (1) to (3) described above will be described.

FIGS. 5A to 5C show an example of the contents of each counter in the transaction counter memory 24 when a compound transaction is interrupted.

As a compound transaction, as in the case above, the face value is 1500
Assume a case where a 0 yen check from our store (current account 4p2) is deposited into savings account #1, and a case where the composite transaction is interrupted after the file of current account +2 is updated as the first step.

In this case, after the first step is completed, see Figure 5A.
As shown in FIG. 4, the stored contents of the transaction counter memory 24 are the same as in the case of FIG. 4A.

Here, if the composite transaction is interrupted, the arithmetic control circuit 2
The inverse adder circuit 27 operates according to the signal from the power supply interruption detection circuit 26 or the signal from the power supply interruption detection circuit 26.

As a result, the inverse addition circuit 27 adds a value corresponding to the difference between the deposit counter 24-1 and the withdrawal counter 24-2 of the transaction counter memory 24 to the cash breakdown counters 24-3 to 24-7.
write to.

Therefore, in this case, the value of the withdrawal counter 24-2 is "150.
00" in the million yen ticket counter 24-3,
and ``1'' in the 5,000 yen bill counter 24-4 with special code x
Write with 9.

Therefore, even if a zero-proof check is performed after this, a bruef error will not occur.

Again, when the teller continues the compound transaction, he sets x9 in the transaction counter memory 24 before starting the second step operation.
A cancellation operation is performed for the cash breakdown counters 24-3 to 24-7 with symbols.

In this case, it is assumed that the teller is displaying the contents of the transaction counter memory 24 on the plasma display device 12.

After that, when the second step operation is performed in the same way as described above, the value in the transaction counter memory 24 becomes the same as in the case of FIG. 4B, as shown in FIG. 5C, and the composite transaction key is released. When the zero-proof check is performed, the proof has been taken, so the values of each counter in the transaction counter memory are cumulatively added to the balance counter memory 25.

In this way, even if the composite transaction is interrupted, the cash breakdown counters 24-3 to 24-7 are added to the deposit counter 2 by the reverse addition circuit.
4-1 or the amount corresponding to the value of the withdrawal counter 24-2 is written, so even if a zero-proof check is performed in the middle of a compound transaction, if other conditions are met, no blue error will occur. It will never occur.

In the above embodiment, "x9" was used as the special code used to write to the cash breakdown counter by the inverse addition circuit when a compound transaction is interrupted, but it goes without saying that other symbols can be used. .

According to the present invention, even if a compound transaction is interrupted, it is not necessary to correct the file update that was processed before the interruption occurs, and therefore, the compound transaction can be processed quickly, and as a result,
It can improve office efficiency and customer service, and is useful for solving the problems of the conventional methods mentioned above.

[Brief explanation of the drawing]

FIG. 1 is an external view of the OTM, FIG. 2 is a block circuit diagram of the OTM that performs the complex transaction cancellation processing method of the present invention, FIG. 3 is a diagram showing each counter of the transaction counter memory in FIG. 2, and FIG. Figures A and 4B are diagrams showing examples of the storage contents of the transaction counter memory when a compound transaction is successfully performed;
FIGS. A to 5C are diagrams showing an example of the contents stored in the transaction counter memory 24 when a compound transaction is interrupted. 1...OTM, 11...Group of keys, 11
-1...Data key, 11-2...
Function K, 12...Plasma display device, 13...Journal, 21...
... calculation buffer, 22 ... calculation control memory, 23 ... line control circuit, 24 ... transaction counter memory, 25 ... balance counter memory, 26... Momentary power interruption detection circuit, 27...
...Inverse addition circuit.

Claims (1)

[Claims] 1. Information indicating the transaction details input for each composite transaction involving multiple transaction processing units is stored in the transaction power rank memory, and the total of the stored contents for each transaction processing unit is compared and stored in the balance counter memory. In a money registration device that performs cumulative addition, a reverse addition means is provided, and when the composite transaction is interrupted at the end of a predetermined transaction processing unit, the reverse addition means adds the value of the deposit counter and the withdrawal counter of the transaction power rank memory. A transaction interruption processing method characterized in that the difference between the value and the value is input into a cash breakdown counter of the transaction counter memory.