JP2744512B2 - Card reading method and card transaction processing device - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for reading a card having a magnetic stripe and a card transaction processing apparatus using the method, and more particularly, to a magnetic stripe by artificially inserting a card. And a card transaction processing device for reading magnetic data.

(Prior Art) Recently, a card transaction processing apparatus capable of performing transaction processing by using various cards having a magnetic stripe has been put to practical use.

FIG. 8 is an external perspective view of the card transaction processing device. In FIG. 8, the card transaction processing device 1 includes a keyboard 2, a display unit 3, a printing unit 4, a card insertion unit 5, and a pin pad 6.

The keyboard 2 is arranged on the front upper surface of the apparatus and has a plurality of keys for data input. The display unit 3 is composed of a display device including a liquid crystal display for displaying operation guidance and input data of the device. The printing unit 4 includes a thermal printer device for printing transaction slips and the like. The card insertion unit 5 is used by an attendant to artificially insert and withdraw a card, and has a data reading unit including a magnetic head and the like and a card position detection unit as described later. The pin pad 6 is an operation unit for inputting a personal identification number and the like, and is connected to the device 1 by a cable 6a.

In the card transaction processing device 1 having the above configuration,
When an IC card having a magnetic stripe is inserted into the card insertion unit 5 after the power is turned on, the data reading unit reads the magnetic data of the magnetic stripe in response to the insertion operation, and sends the magnetic data to a storage unit (not shown). When the IC card is completely inserted into the card insertion portion, a contact is brought into contact with a terminal portion of the IC card, and the IC data is read and similarly sent to a storage unit (not shown). In this state, when the attendant operates the keyboard 2 and presses a transaction instruction key related to magnetic data, a corresponding operation procedure is displayed on the display unit 3. When the clerk further inputs predetermined data with the keyboard 2 in accordance with the operation procedure, a communication control unit (not shown) transmits the data to the center device, performs predetermined data processing on the center device side, and notifies the end of the processing. Therefore, the printing unit 4 operates to print the transaction slip. Thus, the transaction processing for the magnetic data is completed. When a transaction instruction key related to IC data is pressed, the operation procedure is similarly displayed on the display unit 3, and the data is transmitted to the center device. Then, transaction processing relating to the IC data is executed, and a transaction slip is printed.

9 to 11 show a cross-sectional view, a plan view, and a perspective view of the card insertion section 5. FIG.

The card insertion section 5 includes a casing 10 and an insertion port 11 including a U-shaped recess 10a is formed on the front side of the casing 10. Further, card guide grooves 12, 12 communicating with the insertion slot 11 are provided inside the opposing side walls of the casing 10, respectively. A magnetic head 13 is disposed inside the casing 10 on the side of the insertion opening 11. The magnetic head 13 is attached to the lower surface of the distal end of a lever 14, the base of the lever 14 is rotatably pivotally supported, and the substantially central portion thereof is a coil spring 15.
Is pressed downward. When the card is not inserted, the lever 14 is pressed by the coil spring 15 and abuts on the stopper member 16. Therefore, the tip of the magnetic head 13 is positioned at substantially the same height as the guide groove 12. Insertion detection lever below the magnetic head 13
17 are arranged. The insertion detecting lever 17 is formed in a substantially S-shape, and is rotatably supported at the center thereof. Below the one end extending below the insertion detection lever 17, a limit switch 18 for detecting insertion of a card is provided. This limit switch 18 is usually an insertion detection lever.
17 is rotated clockwise by the elastic force of the coil spring 19, and the contact 18a is pushed down by one end thereof, so that the contact 18a is held in the OFF state. On the other hand, when the card is inserted, the other end of the insertion detecting lever 17 is pushed down, and one end thereof is separated from the contact 18a as shown in FIG. 9 and the contact 18a protrudes.
Turns on to output the insertion detection signal. Insertion opening of casing 10
A contact 20 is provided in the interior away from 11. The contact 20 is attached to the lower surface of the distal end of the completion detection lever 21, and the base of the completion detection lever 21 is pivotably supported. The end of the completion detection lever 21 is supported by a coil spring 22, and a pair of contact pieces 23, 2
4 extends downward. Below these contact pieces 23 and 24, limit switches for detecting the completion of card insertion
25 are arranged. When the card is not inserted, the completion detecting lever 21 is rotated clockwise in FIG. 9 by the elastic force of the coil spring 22, so that the limit lever 25 a is switched off by the switching lever 25 a by the contact piece 24. When the completion detection lever 21 rotates counterclockwise as indicated by an arrow when a card is inserted or abutted, the limit switch 25 outputs a completion detection signal because the switching lever 25a is turned ON by the contact piece 23. .

On the other hand, the IC card 26 has a magnetic stripe 27
And 20 terminal portions 28 to be abutted.

When the staff inserts the IC card 26 having the magnetic stripe 27 from the insertion slot 11 in the card insertion section 5 having the above configuration, the IC card 26 is guided by the guide grooves 12, 12, and the magnetic head 13 is coiled by the upper surface thereof. The lever 17 is lifted against the elastic force of 15, and abuts against the other end of the insertion detection lever 17 to rotate the lever 17 in the counterclockwise direction indicated by the arrow. Accordingly, the limit switch 18 is turned on to supply an insertion detection signal to a control unit (not shown) of the device 1. As a result, the control unit operates the magnetic head 13, so that the magnetic data of the magnetic stripe 27 is read by the magnetic head 13 with the insertion of the IC card 26.

When the IC card 26 is further inserted and the leading end abuts on the base of the completion detection lever 21, the lever 21 rotates counterclockwise as indicated by an arrow, and the switching lever 25a is moved by the contact piece 23 as shown in FIG. Since the switching is made in the ON direction, a completion detection signal of card insertion is output from the limit switch 25. Thereby, the control unit stops the operation of the magnetic head 13 and ends the reading of the magnetic data. When the completion detection lever 21 rotates, the contact 20 comes into contact with the terminal portion 28 of the IC card 26, so that the power is connected to the IC card 26, and the data input / output terminal of the IC card 26 and the control unit are connected. Connected.

In this manner, the read magnetic data of the magnetic stripe 27 and the IC data read from the IC memory of the IC card are sent to the data processing unit of the device 1, and whether the data is valid or invalid is determined by a parity check or the like. . And
If the magnetic data is determined to be invalid, an IC card
The user instructs the display unit 3 to pull out the IC card 26 from the card insertion unit 5, and when the IC card 26 is pulled out, instructs to insert the IC card 26 again to insert the card 26.

(Problems to be Solved by the Invention) By the way, in a device such as a card transaction processing device described above, in which a clerk artificially inserts a card into a card insertion portion and pulls out the card, the magnetic data of the magnetic stripe of the card is inserted into the card. Because the method is read while moving, if the insertion is temporarily stopped when the card is inserted, or if the insertion speed fluctuates significantly, the magnetic data is read because the magnetic data is read with some data missing from the magnetic stripe. Therefore, the card insertion and withdrawal operations have to be repeated to read the magnetic data again, which is very troublesome.

Since the card is pulled out at a relatively constant speed when the card is pulled out, the magnetic data of the magnetic stripe is also read at the time of pulling out. However, since the withdrawal speed often fluctuates for an inexperienced person or the like, it is similarly difficult to stably read magnetic data, and the card insertion and withdrawal operations have to be repeated.

The present invention has been made to solve such a problem, and an object of the present invention is to provide a method and a card transaction processing device capable of stably reading magnetic data of a magnetic stripe of a card.

(Means for Solving the Problems) In a card reading method according to the present invention, a card having a magnetic stripe is artificially inserted into a card insertion portion, and magnetic data of the magnetic stripe is read by a data reading portion at the time of insertion. When it is determined that the magnetic data read at the time of insertion is invalid, the magnetic data is read in the reverse direction by the data reading unit when the card is pulled out, and the read magnetic data is inverted.

Further, the card transaction processing device of the present invention comprises a card insertion unit for artificially inserting and removing a card having a magnetic stripe, a data reading unit for reading magnetic data from the magnetic stripe when inserting a card, and an effective unit for reading the read magnetic data. A card transaction processing device including magnetic data determining means for determining invalidity, wherein when the read magnetic data is determined to be invalid by the magnetic data determining means, the magnetic stripe is controlled by controlling the data reading section when the card is pulled out. And a data inverting unit for inverting the magnetic data read from the reverse direction.

(Operation) In the card reading method of the present invention, the magnetic data of the magnetic stripe is read when the card is inserted, and if the read magnetic data is valid, it is used for data processing as it is. If the read magnetic data is invalid, the magnetic data is read again in the reverse direction when the card is pulled out, inverted and converted into correct magnetic data, and then its validity / invalidity is determined.

Therefore, the magnetic data can be read again by a single insertion and withdrawal of the card, so that the magnetic data can be stably read and repeated insertion and withdrawal operations of the card can be prevented.

Further, in the card transaction processing device of the present invention, when the magnetic data determining means determines that the magnetic data read at the time of inserting the card is invalid, the reverse reading instructing means controls the data reading section at the time of removing the card to control the magnetic stripe. Read the data from the opposite direction.

The data inverting unit inverts the magnetic data read in the reverse direction and converts the magnetic data into normal magnetic data.

Therefore, the magnetic data can be read again by a single insertion and withdrawal of the card, so that the magnetic data can be stably read and repeated insertion and withdrawal operations of the card can be prevented.

(Example) Hereinafter, an example of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a block diagram of a card transaction processing device according to the present invention.

In FIG. 1, reference numeral 30 denotes a main control unit (CPU) for controlling the entire apparatus. The keyboard 30, the display unit 3, the printing unit 4, and the storage unit 32 are connected to the CPU 30 via a bus 31. . The keyboard 2 is used for inputting various data.
The display unit 3 is composed of a liquid crystal display or the like for displaying operation guidance and input data of the apparatus. The printing unit 4 includes a thermal printer device for printing transaction slips and the like. The storage unit 32 is used to store magnetic data, IC data, and the like determined to be valid. The CPU 30 has a bus 3
The communication control unit 33 is connected via 1. The communication control unit 33 is connected to the center device 35 via a communication line 34, and sends data and the like stored in the storage unit 32 to the center device 35 and receives data and the like sent from the center device 35. Used to do.

This card transaction processing device includes a card insertion unit 5. Since the card insertion section 5 has the same configuration as that shown in FIGS. 9 to 11, its description is omitted.
The data reading section 36 provided in the card insertion section 5 has a magnetic head 13 shown in FIG. 9, a mechanism section such as a lever 14 for supporting the magnetic head 13, a contact 20, and a supporting mechanism section for the contact 20. ing. The card position detecting section 37 provided in the card inserting section 5 has limit switches 18 and 25, an insertion detecting lever 17, and contact pieces 23 and 24, and the like.

Now, the card transaction processing device of the present invention has a data processing unit 38.
Is further provided. The data processing unit 38 is a data reading unit
It comprises a buffer memory 39 for temporarily storing magnetic data read by the 36 magnetic heads 13, a data inverting unit 40, a switching unit 41 and a data checking unit 42. Data inversion section
Numeral 40 is used to invert the magnetic data read in the reverse direction by the magnetic head 13 when the IC card 26 is pulled out and convert it into the same bit string as the magnetic data to be read when the IC card 26 is inserted. It has. The switching unit 41 is formed by a gate circuit, and is controlled to be switched by the CPU 30, and selectively outputs either the magnetic data in the buffer memory 39 or the magnetic data from the data inverting unit 40. The data check unit 42 is used to determine whether the transmitted magnetic data is valid or invalid, and performs a parity check and the like. Also, this data check unit 42
When the IC data of the IC card 26 is sent from the CPU 30, a parity check and the like are similarly performed to determine whether the IC data is valid or invalid.

Next, the card reading method of the present invention will be described together with the operation of the card transaction processing apparatus of the present invention based on the operation flowcharts of FIGS. 1, 5 to 7.

First, when the apparatus is turned on, the CPU 30 controls the display unit 3 to display a card insertion instruction (step 1). Thereby, the attendant inserts the IC card 26 into the card insertion section 5.
(Step 2), as shown in FIG.
The magnetic head 13 of the data reading unit 36 is pushed up by the upper surface of the insertion end of the card 26 and comes into contact with the magnetic stripe 27. At the same time, the insertion detection lever 17 of the card position
Since the card 26 is pushed down by the lower surface and rotated counterclockwise, the contact 18a of the limit switch 18 protrudes.
Therefore, an insertion detection signal is output from the limit switch 18, and this signal is supplied to the CPU 30. Upon receiving this signal, the CPU 30 controls the magnetic head 13 to start operation. Therefore, the magnetic data of the magnetic stripe 27 is read by the magnetic head 13 in accordance with the insertion of the IC card 26 (step 3).

When the IC card 26 is further inserted and its tip abuts on the completion detection lever 21, this lever 21 rotates counterclockwise, and the contact piece 23 switches the switching lever 25a of the limit switch 25 in the ON direction. . Therefore, an insertion completion detection signal is output from the limit switch 25, and this signal is supplied to the CPU 30. When the CPU 30 receives this signal,
It is determined that the insertion of the IC card 26 has been completed (step 4),
The reading operation of the magnetic head 13 is stopped, and the reading of the magnetic data of the magnetic stripe 27 is terminated.

The read magnetic data is sequentially stored in the buffer memory 39 of the data processing unit 38 (step 5). When magnetic data is stored in the buffer memory 39, the CPU 30
By controlling the gate circuit of 41, the magnetic data of the buffer memory 39 is sent directly to the switching unit 41, and supplied to the data check unit via this switching unit 41. The data check unit 42 determines whether the magnetic data is valid or invalid (step 6).
FIG. 2 is a diagram showing a magnetic data storage area in the buffer memory of the data check unit 42. This storage area
B _1, B ₂ ... and a memory area indicated by B _n. on the other hand,
The magnetic data has a data structure from the first character (1C) to the Nth character (NC), and each character is m
A vertical parity bit and a horizontal parity bit are added to the bit data. Then, in the memory area B ₁ first character (first 1C), the memory area B ₂ second character (a 2C), the memory area B ₃ ... B _n third character (Third
C)... Each of the Nth character (NCth) is stored.

FIG. 6 is an operation flowchart showing the magnetic data determination process (step 6) of the data check unit 42.

That is, when storing magnetic data (first 1C~ second NC) data check unit 42 in the memory area B ₁ ... B _n, firstly, the memory area
Storing the first character of B ₁ (the first 1C) in the register, performing vertical parity check (step 20). Error (error) if there is no (step 21) stores second character memory region B ₂ (the second 2C) in the register, performing vertical parity check (step 22). If there is no error, a vertical parity check of the third character (3C)... Nth character ((NC)) of the memory areas B ₃ ... B _n is performed (step 24). Next, a horizontal parity check is performed (step 26).

If there is no error in the magnetic data, the data check unit 42
The CPU 30 notifies the U30 that there is no error, the CPU 30 determines that the magnetic data is correct (step 7), fetches the magnetic data from the buffer memory of the data check unit 42, stores the magnetic data in the storage unit 32, and executes a transaction process. (Step 8). In this transaction processing, the CPU 30 transmits predetermined data through the communication control unit 33 and the communication line 34 based on the company code, the password, the transaction selection data, and the like indicated by the magnetic data, and the transaction instruction data input by the keyboard 2. To the center device 35. Since the center device 35 performs predetermined data processing and notifies the end together with the print data, the CPU 30 activates the printing unit 4 to print and issue a transaction slip, thereby terminating the transaction process relating to the magnetic data.

Next, the CPU 30 controls the display unit 3 to instruct removal of the card (step 9), and the attendant removes the IC card 26. When the IC card 26 is pulled out, as shown in FIG. 9, the completion detection lever 21 rotates clockwise, so that the switching lever 25a of the limit switch 25 is switched to the OFF direction, and the output of the completion detection signal stops. . As a result, the CPU 30 determines that the IC card 26 has been pulled out. When the IC card 26 is completely pulled out, the insertion detection lever 17 rotates clockwise and the output of the insertion detection signal of the limit switch 18 stops, so that the CPU 30 determines that the extraction of the IC card 26 is completed. Then, the process returns to step 1 and stands by for a new transaction process.

At this time, when the contact 20 comes into contact with the terminal section 28 when the IC card 26 is inserted, the power supply section 43 is connected to the IC card 26, and the CPU 30 is connected to the data input / output terminal.
Therefore, when the transaction by the IC memory is selected, the transaction processing based on the IC data is executed. Note that the IC data is supplied to the data check unit 42, and when it is determined that the data is invalid, the CPU 30 reads the IC data from the IC memory of the IC card 26 again and supplies the IC data to the data check unit 42.

By the way, in step 6, the data check unit 42
When notifying the U30 that there is an error, the CPU 30 determines that there is an error in the magnetic data read by inserting the card (step 7), and controls the display unit 3 to instruct removal of the IC card 26 (step 12). . With this instruction, the attendant pulls out the IC card 26 (step 13), and when the output of the completion detection signal of the limit switch 25 stops, the CPU 30 controls the magnetic head 13 of the data reading unit 36 to reverse the magnetic data of the magnetic stripe 27. Read from the direction (step 14). IC card 26
Is further removed, and the output of the insertion detection signal of the limit switch 18 stops, the CPU 30 determines that the removal of the IC card is completed (step 15), and stops the reading operation of the magnetic head 13.

The magnetic data read when the IC card 26 is pulled out is stored in the buffer memory 39 of the data processing unit 38 (step 16). Since the bit string of this magnetic data is read in the reverse direction, the CPU 30 A data inverting unit 40 which sends an operation signal to the buffer unit 39 to take in magnetic data from the buffer memory 39 and controls switching of the switching unit 41.
Is output to the data check unit 42.

Now, the magnetic data taken into the data inverting section 40 is
As shown in FIG. 3, the data is stored in a predetermined storage area of an internal buffer memory. That is, the storage areas are R ₁ , R ₂ , R ₃
... and a memory area indicated by R _n. On the other hand, since the magnetic data is read from the opposite direction, the reading order includes the Nth character (NC) at the beginning, and the following, the N-1th character (N-1C) and the N-2th character (N-2C)... The first character (1C) is arranged. Since the bit strings of the Nth to first characters are reversed, the most significant bit (MSB) and the least significant bit (LSB) are located oppositely. And the memory area R
_1, R ₂ ... to R _n N-th character (the NC), the N-1 character (the N-1C) ... first character (first 1C) are stored in this order.

FIG. 7 is an operation flowchart showing the magnetic data inversion processing (step 19) of the data inversion section 40.

That is, the data inversion unit 40 Storing magnetic data read from the opposite direction in the memory area R ₁ ... R _n (first NC~ second 1C),
First, the first N characters of the memory region R _1, as shown in Figure 4, is stored in the setting register L _1. Next, in the N character setting register L ₁ (first NC), takes out each bit string in order from the most significant bit (MSB) is located at the lowest, and the most significant bit of the bit string taken out inversion register L ₂ least significant The bit is inverted and stored so as to be in the opposite position (step 30). Therefore, the inversion register L ₂ N-th
The character (No. NC) is converted into the original correct bit string and stored. Then, the inversion register L ₂ N-th
Storing character in the memory area S _n set in the buffer memory of the data inversion section 40 (step 31). Hereinafter, likewise the memory region R _2, R ₃ ... (N-1) th character of the R _n (the N
-1C), the N-2 character (the N-2C) ... stores a first character sequentially setting register L _1, the buffer memory in terms of the inverted bit sequence in inverted register L ₂ memory areas S
_{n-1, S n-2} ... stored in S ₁ (step 32-35). Therefore, the memory areas S ₁ to S _n are stored in the first character (the 1C) ~ N-th character (the NC) is reading order at the time of insertion, i.e. the correct bit string.

CPU30, upon determining that inversion processing of the magnetic data is completed (step 36), and outputs the transmission instruction to the data inversion section 40, thereby sending the magnetic data obtained by inverting from the buffer memory S ₁ to S _n to the data checking section 42. The data check unit 42 performs a parity check on the magnetic data in step 17 in the same manner as described above (steps 20 to 26), and notifies the CPU 30 of no error if there is no error in the magnetic data. CPU30
Determines that the magnetic data is valid (step 1)
8), the magnetic data is stored in the storage unit 32, and the transaction processing is executed (step 19). This transaction processing is the same as step 8.

Although the transaction processing of the IC card 26 having the magnetic stripe 27 has been described in the above embodiment, the present invention can be applied to a normal magnetic card having a magnetic stripe.

(Effect of the Invention) As described above, according to the present invention, when it is determined that the magnetic data of the magnetic stripe read at the time of inserting a card is invalid, the magnetic data is read from the opposite direction at the time of removing the card, and this magnetic data is read. Since the data is reversed, even if the magnetic data is invalid when the card is inserted, the magnetic data can be read again at the time of the pull-out operation to determine the validity / invalidity. Therefore, it is possible to provide a card reading method and a card transaction processing device capable of stably reading magnetic data of a card and preventing repetition of inserting / pulling-out operation of the card.

[Brief description of the drawings]

FIG. 1 is a block diagram of a card transaction processing device of the present invention, FIG. 2 is a diagram showing a magnetic data storage area when a card is inserted and read, FIG. 3 is a view showing a magnetic card storage area when a card is removed, and FIG. FIG. 5 is a diagram for explaining a reversal process of magnetic data, FIG.
FIG. 7 is an operation flowchart of a magnetic data determination process, FIG. 7 is an operation flowchart of a magnetic data inversion process, FIG. 8 is an external perspective view of a card transaction processing device, FIGS. It is a top view and a perspective view. 5 Card insertion part, 13 Magnetic head, 18, 25 Limit switch, 26 IC card, 27 Magnetic stripe, 30 CP
U, 36: data reading unit, 37: card position detecting unit, 38: data processing unit, 39: buffer memory, 40: data inverting unit,
41: switching unit, 42: data check unit.

Claims (2)

(57) [Claims] 1. A card reading method in which a card having a magnetic stripe is artificially inserted into a card insertion portion, and the magnetic data of the magnetic stripe is read by a data reading portion at the time of insertion. A card reading method, comprising: when the card is determined to be invalid, reading the magnetic data in a reverse direction by a data reading unit when the card is pulled out of the card insertion unit, and inverting the read magnetic data. 2. A card insertion unit for artificially inserting and removing a card having a magnetic stripe, a data reading unit for reading magnetic data from the magnetic stripe when the card is inserted, and validity / invalidity of the read magnetic data. A card transaction processing device comprising: a magnetic data determining unit for determining whether the read magnetic data is invalid by the magnetic data determining unit; and controlling the data reading unit when the card is pulled out to control the magnetic stripe. 1. A card transaction processing device comprising: a reverse reading instructing unit for reading magnetic data in the reverse direction; and a data reversing unit for reversing the magnetic data read in the reverse direction.