JP2016071390A - Card reader - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a card reader that can read magnetic data on cards allowing only reading sensitivity of low sensitivity to read magnetic data, and allowing only reading sensitivity of high sensitivity to read the magnetic data, and can determine whether a card is the card capable of reading the magnetic data.SOLUTION: The card reader comprises: a first signal processing unit 14 to which an output signal of a magnetic head 4 to be arranged in one guide surface of a card passage groove is input; and a second signal processing unit 19 to which an output signal of a magnetic head 5 to be arranged in other guide surface of a card passage groove is input. With the card reader, a threshold with respect to a post-amplified output signal of the magnetic head 4 is set in the first signal processing unit 14 and a threshold with respect to a post-amplified output signal of the magnetic head 5 is set in the second signal processing unit 19 so that reading sensitivity of the magnetic data by the magnetic head 4 is higher than reading sensitivity of the magnetic data by the magnetic head 5.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a manual card reader that manually moves a card and reads magnetic data recorded on a magnetic stripe of the card.

  2. Description of the Related Art Conventionally, a manual card reader that reads a magnetic data recorded on a magnetic stripe of a card by manually moving the card is known (for example, see Patent Document 1). A card reader described in Patent Document 1 includes a magnetic head that reads magnetic data, a reproduction signal amplification circuit that amplifies the output signal of the magnetic head, and a waveform shaping circuit that shapes the waveform of the amplified signal amplified by the reproduction signal amplification circuit And a demodulation circuit that demodulates the shaped signal, and a CPU that controls the overall operation. Further, the card reader is configured such that when the waveform shaping circuit compares the amplified signal with a predetermined reading determination reference value, the waveform of the amplified signal cannot be shaped and the magnetic data cannot be read. Reference value changing means for changing the value is provided.

  In the card reader described in Patent Document 1, the reference value changing means is a sensitivity switching circuit, and the setting for low reading sensitivity of magnetic data (low sensitivity setting) and the reading sensitivity of magnetic data become high sensitivity. Switch the magnetic data reading sensitivity setting to the setting (high sensitivity setting). In the low sensitivity setting, the threshold value for the amplified signal is large, and in the high sensitivity setting, the threshold value for the amplified signal is small. Therefore, in the low sensitivity setting, it is possible to read the magnetic data even if the magnetic data recorded on the magnetic stripe includes a noise component. On the other hand, when the sensitivity is set, the magnetic data can be read even if the magnetic force of the magnetic data recorded on the magnetic stripe is weakened and the amplitude of the amplified signal is reduced.

  In the card reader described in Patent Document 1, normally, the sensitivity setting is low. If the magnetic data cannot be read when the magnetic data reading operation is performed, the sensitivity is changed to the high sensitivity setting. If the magnetic data cannot be read even if the magnetic data reading operation is performed again after the high sensitivity setting is changed, the setting is changed to the low sensitivity setting again. If data cannot be read, the setting switches alternately between the high sensitivity setting and the low sensitivity setting.

JP 2004-362177 A

  The card reader described in Patent Document 1 can read magnetic data with a low sensitivity setting but cannot read magnetic data with a high sensitivity setting (for example, a magnetic component recorded in a magnetic stripe includes a noise component). Or a card that can read magnetic data with a high sensitivity setting but cannot read magnetic data with a low sensitivity setting (for example, a card with a weak magnetic force recorded in a magnetic stripe) When the magnetic data is read by the card reader, even if the card is operated in the same manner, the magnetic data can be read and the magnetic data cannot be read alternately.

  In other words, this card reader can read magnetic data with a low sensitivity setting, but cannot read magnetic data with a high sensitivity setting, or it can read magnetic data with a high sensitivity setting but with low sensitivity. Whether magnetic data can be read each time the card is operated even if the same card is operated in the same way when trying to read the magnetic data of a card that cannot be read in the settings with a card reader The reading result changes. Therefore, in this card reader, there is a possibility that an error may occur in determining whether the card is a card that can read magnetic data or a card that cannot read magnetic data.

  Therefore, the object of the present invention is to read magnetic data of a card that can read magnetic data only with a low reading sensitivity and magnetic data of a card that can read magnetic data only with a high sensitivity reading sensitivity. It is another object of the present invention to provide a card reader that can appropriately determine whether the card can read magnetic data or the card that cannot read magnetic data.

  In order to solve the above problems, a card reader according to the present invention is a manual card reader that manually moves a rectangular card and reads magnetic data recorded on the magnetic stripe of the card. A card passage groove composed of an abutment surface that abuts one end surface in the hand direction and two guide surfaces that guide both sides of the card in the thickness direction of the card, and one of the two guide surfaces A first magnetic head that protrudes from the surface into the card passage groove and is disposed at a position where the magnetic stripe passes in the short direction of the card, and the card guide groove from the other guide surface of the two guide surfaces. A second magnetic head protruding inward and disposed at a position where the magnetic stripe passes in the short direction of the card, and a first signal to which an output signal of the first magnetic head is input And a second signal processing unit to which an output signal of the second magnetic head is input, and the read sensitivity of the magnetic data read by the first magnetic head is greater than the read sensitivity of the magnetic data read by the second magnetic head So that the threshold value for the output signal of the first magnetic head or the amplified output signal of the first magnetic head is set in the first signal processing unit, and the output of the second magnetic head is set in the second signal processing unit. A threshold for the signal or the output signal of the second magnetic head after amplification is set.

  The card reader according to the present invention includes a first magnetic head projecting from one guide surface of the two guide surfaces constituting the card passage groove into the card passage groove, and the other of the two guide surfaces. A second magnetic head protruding from the guide surface into the card passage groove. In the present invention, the output signal of the first magnetic head is input so that the read sensitivity of the magnetic data read by the first magnetic head is higher than the read sensitivity of the magnetic data read by the second magnetic head. The first signal processing unit sets a threshold for the output signal of the first magnetic head or the output signal of the first magnetic head after amplification, and the second signal processing unit receives the output signal of the second magnetic head. A threshold for the output signal of the magnetic head or the output signal of the second magnetic head after amplification is set.

  For this reason, in the present invention, even if the card can read magnetic data with a high reading sensitivity but cannot read magnetic data with a low reading sensitivity, the magnetic stripe contacts the first magnetic head. If the card is operated, the magnetic data on the card can be read. Further, even if the card can read magnetic data with a low reading sensitivity but cannot read magnetic data with a high reading sensitivity, the front and back of the card are arranged so that the magnetic stripe contacts the second magnetic head. If the card is operated with the opposite, the magnetic data on the card can be read. That is, according to the present invention, it is possible to read magnetic data of a card that can read magnetic data only with low reading sensitivity and magnetic data of a card that can read magnetic data only with high sensitivity. .

  In the present invention, when the card is operated in the same way so that the magnetic stripe contacts the first magnetic head, the magnetic data is stored each time the card is operated as in the card reader described in Patent Document 1. The result of reading whether or not it can be read does not change. Similarly, when the card is operated in the same manner so that the magnetic stripe contacts the second magnetic head, the reading result as to whether or not the magnetic data can be read does not change every time the card is operated. . Therefore, in the present invention, it is possible to appropriately determine whether the card can read magnetic data or the card that cannot read magnetic data.

  In the present invention, for example, magnetic data is recorded on a magnetic stripe formed on one surface of a card, one end surface in the short direction of the card is in contact with the contact surface, and the card is in a card passage groove with the front and back facing in the correct direction. When the card passes, the magnetic stripe formed on one surface of the card contacts the first magnetic head, one end surface of the short side of the card contacts the contact surface, and the card is in the opposite direction. When passing through the passage groove, the magnetic stripe formed on one surface of the card contacts the second magnetic head. In a normal operation, the card is operated so that one end surface in the short direction of the card contacts the contact surface and the card passes through the card passage groove with the front and back facing in the correct direction. Therefore, in this case, a card that can read magnetic data with high reading sensitivity but cannot read magnetic data with low reading sensitivity (for example, the magnetic force of magnetic data recorded on the magnetic stripe is weak). It is possible to read the magnetic data of the card) in one card operation.

  In the present invention, for example, in the short direction of the card, the distance between the center of the magnetic data reading portion of the first magnetic head and the contact surface, and the center and contact surface of the magnetic data reading portion of the second magnetic head. The distance between and is substantially equal.

  In the present invention, the card reader generates a demodulated data based on the output signal of the first signal processing unit, and a second demodulated data based on the output signal of the second signal processing unit. A demodulated data generation unit and a data processing unit to which the first demodulated data generated by the first demodulated data generating unit and the second demodulated data generated by the second demodulated data generating unit are input. And when the first demodulated data generation unit generates the first demodulated data, the data processing unit determines whether the first demodulated data is correct and the first demodulated data is correct. Otherwise, the sequence of the first demodulated data is reversed, and when the second demodulated data is generated by the second demodulated data generation unit, it is determined whether the sequence of the second demodulated data is correct, and the second demodulated data is determined. Data When beauty is not correct, it is preferable to reverse the sequence of the second demodulated data. If comprised in this way, it will become possible to output suitable 1st demodulation data and 2nd demodulation data with respect to the high-order apparatus by which a card reader is mounted. Therefore, it is possible to reduce the burden of data processing in the host device.

  As described above, in the card reader of the present invention, magnetic data of a card that can read magnetic data only with a low reading sensitivity and magnetic data of a card that can read magnetic data only with a high sensitivity reading sensitivity are stored. In addition to being able to read, it is possible to appropriately determine whether the card is a card that can read magnetic data or a card that cannot read magnetic data.

It is a perspective view of the card reader concerning an embodiment of the invention. It is the schematic for demonstrating the structure of a card reader from the EE direction of FIG. It is a block diagram for demonstrating the circuit structure of the card reader shown in FIG. It is a figure for demonstrating the relationship between the signal input into the waveform shaping circuit shown in FIG. 3, and the signal output from a waveform shaping circuit. It is a flowchart for demonstrating the process sequence of the demodulation data in CPU shown in FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Configuration of card reader)
FIG. 1 is a perspective view of a card reader 1 according to an embodiment of the present invention. FIG. 2 is a schematic view for explaining the configuration of the card reader 1 from the EE direction of FIG. FIG. 3 is a block diagram for explaining a circuit configuration of the card reader 1 shown in FIG. FIG. 4 is a diagram for explaining the relationship between the signals SG1 and SG2 input to the waveform shaping circuits 12 and 17 shown in FIG. 3 and the signals SG3 and SG4 output from the waveform shaping circuits 12 and 17.

  The card reader 1 of this embodiment is a manual card reader that manually moves the card 2 and reads magnetic data recorded on the card 2. Specifically, the card reader 1 moves the card 2 manually along the card passage groove 3 formed in a groove shape shallower than the short width of the card 2 formed in a rectangular shape, and magnetically changes the card 2. This is a so-called swipe type card reader for reading data. The card reader 1 is mounted and used in a predetermined host device. The card reader 1 also includes a first magnetic head 4 (hereinafter referred to as “magnetic head 4”) and a second magnetic head 5 (hereinafter referred to as “magnetic head 5”) for reading magnetic data recorded on the card 2. 2) magnetic heads.

  The card 2 is a rectangular vinyl chloride card having a thickness of about 0.7 to 0.8 mm. The card 2 of this embodiment is a card with a magnetic stripe conforming to an international standard (for example, ISO / IEC7811) or a JIS standard (for example, JISX6302). On the back surface 2a of the card 2, as shown in FIG. 1, a magnetic stripe 2b on which magnetic data is recorded is formed. The magnetic stripe 2 b is formed along the longitudinal direction of the card 2. A magnetic stripe (not shown) is also formed on the front surface of the card 2. This magnetic stripe is also formed along the longitudinal direction of the card 2. The card 2 may be a contact IC card with a magnetic stripe in which contact terminals are formed on the front surface, or a non-contact IC card with a magnetic stripe in which an antenna for data communication is built. It may be.

  In the magnetic stripe 2b, magnetic data of three tracks, that is, the first track, the second track, and the third track can be recorded. The magnetic data of the first track, the second track, and the third track are arranged in this order from the one end face 2c side in the short side direction of the card 2. The magnetic data of one track can be recorded on the magnetic stripe formed on the front surface of the card 2. When viewed from the thickness direction of the card 2, a part of the track recorded on the magnetic stripe on the front surface of the card 2 substantially overlaps the entire area of the second track recorded on the magnetic stripe 2b. In this embodiment, only the magnetic data of the second track of the magnetic stripe 2b is recorded on the card 2. The recording density (more specifically, the average recording density) of the magnetic data of the first track of the magnetic stripe 2b, the magnetic data of the third track, and the magnetic data of the track of the magnetic stripe on the front surface of the card 2 is as follows. The recording density of magnetic data of the second track of the magnetic stripe 2b (more specifically, the average recording density) is 75 bpi.

  The card passage groove 3 is provided with two guides for guiding both the abutment surface 7 with which the short end direction 2c of the card 2 abuts and both sides of the card 2 in the thickness direction of the card 2 passing through the card passage groove 3. It is composed of surfaces 8 and 9. The magnetic heads 4 and 5 are arranged so that the magnetic gap faces the card passage groove 3. The magnetic head 4 is disposed so as to project from the guide surface 8 into the card passage groove 3, and the magnetic head 5 is disposed so as to project from the guide surface 9 into the card passage groove 3. Further, the magnetic head 4 and the magnetic head 5 are arranged such that their magnetic gaps are shifted from each other in the passing direction of the card 2.

  Further, in the short direction of the card 2 (more specifically, the short direction of the card 2 when the card 2 passes through the card passage groove 3), the magnetic head 4 is compared with the center CL1 of the magnetic data reading portion. The distance L1 between the contact surface 7 and the distance L2 between the center CL2 of the magnetic data reading portion of the magnetic head 5 and the contact surface 7 are substantially equal. In the direction, the magnetic stripe formed on the front surface of the card 2 and the magnetic stripe 2b are disposed at a position where the card 2 passes. Specifically, when the card 2 passes through the card passage groove 3 with one end surface 2c of the card 2 abutting against the abutment surface 7 and with the front and back facing in the correct orientation, the second track of the magnetic stripe 2b is applied to the magnetic head 4. At the same time, the magnetic stripe on the front surface of the card 2 abuts on the magnetic head 5, the one end surface 2 c of the card 2 abuts on the abutment surface 7, and the card 2 passes through the card passage groove 3 with the front and back facing in opposite directions. The magnetic heads 4 and 5 are arranged at positions where the magnetic stripe on the front surface of the card 2 contacts the magnetic head 4 and the second track of the magnetic stripe 2b contacts the magnetic head 5 when passing. Yes.

  A sinusoidal output signal output from the magnetic head 4 is input to the amplifier circuit 11. In the amplifier circuit 11, the output signal of the magnetic head 4 is amplified and becomes sine wave-like amplified signals SG1 and SG2. Amplified signals SG <b> 1 and SG <b> 2 that are output signals of the amplifier circuit 11 are input to the waveform shaping circuit 12. In the waveform shaping circuit 12, the sinusoidal amplified signals SG1 and SG2 are shaped into rectangular wave shaped signals SG3 and SG4. The shaping signals SG3 and SG4, which are output signals of the waveform shaping circuit 12, are input to the demodulation circuit 13. The demodulation circuit 13 generates demodulated data (first demodulated data) based on the shaping signals SG3 and SG4.

  Similarly, the sine wave output signal output from the magnetic head 5 is input to the amplifier circuit 16, and the amplifier circuit 16 amplifies the output signal of the magnetic head 5 into sine wave amplification signals SG1 and SG2. Amplified signals SG1 and SG2 that are output signals of the amplifier circuit 16 are input to the waveform shaping circuit 17, and the waveform shaping circuit 17 shapes the sinusoidal amplified signals SG1 and SG2 into rectangular wave shaped signals SG3 and SG4. . The shaping signals SG3 and SG4, which are output signals of the waveform shaping circuit 17, are input to the demodulation circuit 18. The demodulating circuit 18 generates demodulated data (second demodulated data) based on the shaped signals SG3 and SG4.

  The demodulated data generated by the demodulating circuit 13 and the demodulated data generated by the demodulating circuit 18 are input to a CPU (Central Processing Unit) 20 as a data processing unit. The CPU 20 is connected to a host control unit 21 that is a control unit of a host device on which the card reader 1 is mounted.

  In this embodiment, the read sensitivity of the magnetic data read by the magnetic head 4 is higher than the read sensitivity of the magnetic data read by the magnetic head 5 (that is, the read sensitivity of the magnetic data read by the magnetic head 4 is high sensitivity). Thus, in the waveform shaping circuit 12, the threshold value th1 (with respect to the amplified signals SG1 and SG2 (that is, the output signal of the magnetic head 4 after amplification)) is reduced (so that the reading sensitivity of the magnetic data read by the magnetic head 5 becomes low). 4A) is set, and the waveform shaping circuit 17 sets the threshold th2 (see FIG. 4B) for the amplified signals SG1 and SG2 (that is, the output signal of the magnetic head 5 after amplification). Yes. That is, in this embodiment, the threshold th1 set by the waveform shaping circuit 12 is smaller than the threshold th2 set by the waveform shaping circuit 17.

  Therefore, as shown in FIG. 4, when the magnetic data of the second track of the magnetic stripe 2b is read by the magnetic head 4, the amplified signals SG1 and SG2 input to the waveform shaping circuit 12 and the second of the magnetic stripe 2b Even if the amplified signals SG1 and SG2 input to the waveform shaping circuit 17 when the magnetic data of the track is read by the magnetic head 5 are the same, the amplified signal generated by the waveform shaping circuit 12 has a small amplitude. The signal level of the shaping signal SG3 with respect to SG1 varies according to the signal level of the amplified signal SG1 (see FIG. 4A), but the signal level of the shaping signal SG3 with respect to the amplified signal SG1 generated by the waveform shaping circuit 17 May not fluctuate. On the other hand, for example, even if the amplified signal SG2 having a large amplitude includes noise, in the shaped signal SG4 for the amplified signal SG2 generated by the waveform shaping circuit 17, there is a possibility that the signal level varies according to the noise. However, in the shaping signal SG4 for the amplified signal SG2 generated by the waveform shaping circuit 12, there is a high possibility that the signal level varies according to noise. Actually, when the magnetic data of the second track of the magnetic stripe 2b is read by the magnetic head 5, the amplified signals SG1 and SG2 input to the waveform shaping circuit 17 are the magnetic signals of the second track of the magnetic stripe 2b. When the data is read by the magnetic head 4, the amplified signals SG1 and SG2 input to the waveform shaping circuit 12 are inverted on the left and right in FIG.

  In this embodiment, the amplification circuit 11 and the waveform shaping circuit 12 constitute a first signal processing unit 14 to which an output signal of the magnetic head 4 (first magnetic head 4) is input. The amplifier circuit 16 and the waveform shaping circuit 17 constitute a second signal processing unit 19 to which an output signal of the magnetic head 5 (second magnetic head 5) is input. The demodulating circuit 13 of this embodiment is a first demodulated data generating unit that generates demodulated data based on the output signal of the first signal processing unit 14, and the demodulating circuit 18 is an output signal of the second signal processing unit 19. 2 is a second demodulated data generating unit that generates demodulated data based on the above.

(Method of processing demodulated data in CPU)
FIG. 5 is a flowchart for explaining the processing procedure of the demodulated data in CPU 20 shown in FIG.

  When the demodulated data is generated by the demodulation circuit 13, the CPU 20 determines whether or not the order of the demodulated data is correct. If the order of the demodulated data is correct, the CPU 20 sends the demodulated data to the upper control unit 21. If the demodulated data sequence is not correct, the demodulated data sequence is inverted, and the demodulated data after inversion is output to the upper control unit 21. Similarly, when the demodulated data is generated by the demodulating circuit 18, the CPU 20 determines whether or not the demodulated data sequence is correct. If the demodulated data sequence is correct, the CPU 20 determines the demodulated data to be the upper control unit 21. If the demodulated data sequence is not correct, the demodulated data sequence is inverted, and the demodulated data after inversion is output to the upper control unit 21.

  Here, in this embodiment, as described above, only the magnetic data of the second track of the magnetic stripe 2b is recorded on the card 2, the one end surface 2c of the card 2 contacts the contact surface 7, and the front and back are correct. When the card 2 passes through the card passage groove 3 in the direction, the second track of the magnetic stripe 2b comes into contact with the magnetic head 4, the one end surface 2c of the card 2 comes into contact with the contact surface 7, and the card is faced in the opposite direction. When 2 passes through the card passage groove 3, the second track of the magnetic stripe 2 b comes into contact with the magnetic head 5.

  Therefore, when the card 2 is operated so that the one end surface 2c of the card 2 abuts against the abutment surface 7 and the card 2 passes through the card passage groove 3 with the front and back facing in the correct orientation, Demodulated data is generated, and the demodulating circuit 18 does not generate demodulated data. On the other hand, when the card 2 is operated so that the one end surface 2c of the card 2 abuts against the abutment surface 7 and the card 2 passes through the card passage groove 3 with the front and back facing in opposite directions, the demodulation circuit 13 Instead of being generated, the demodulating circuit 18 generates demodulated data whose order is opposite.

  Therefore, in this embodiment, as shown in FIG. 5, when the operation of the card 2 is started and the magnetic data is read by the magnetic head 4 or the magnetic head 5 (step S1), the CPU 20 receives the demodulation circuit 13 or the demodulation circuit. It is determined whether the order of the demodulated data generated in 18 is correct (step S2). The card 2 is operated so that the one end surface 2c of the card 2 abuts against the abutment surface 7 and the card 2 passes through the card passage groove 3 with the front and back facing in the correct direction, and demodulated data is generated by the demodulation circuit 13. In this case, since the arrangement of the demodulated data determined by the CPU 20 is correct (that is, “Yes” in step S2), the CPU 20 outputs the demodulated data to the upper control unit 21 (step S3). .

  On the other hand, the card 2 is operated so that the one end surface 2c of the card 2 abuts against the abutment surface 7 and the card 2 passes through the card passage groove 3 with the front and back sides facing away from each other. In this case, since the arrangement of the demodulated data determined by the CPU 20 is reversed (that is, “No” in step S2), the CPU 20 inverts the arrangement of the demodulated data (step S4). ), The process proceeds to step S3, and the demodulated data after inversion is output to the upper control unit 21.

  In normal operation, it is assumed that the card 2 is operated such that the one end surface 2c of the card 2 contacts the contact surface 7 and the card 2 passes through the card passage groove 3 with the front and back facing in the correct orientation. If the magnetic data of the second track of the magnetic stripe 2b does not include a noise component that causes an error when the magnetic data is read by the magnetic head 4, "Yes" is obtained in step S2, and the demodulation circuit 13 The demodulated data generated in (1) is output to the upper control unit 21.

  On the other hand, if the magnetic data of the second track of the magnetic stripe 2b includes a noise component that causes an error when the magnetic data is read by the magnetic head 4, the reading result by the magnetic head 4 becomes an error. Therefore, the card reader 1 or the host device performs a predetermined display or the like and prompts the user to operate the card 2 again. In accordance with the display of the card reader 1 or the host device, the user again places the card 2 so that the one end surface 2c of the card 2 contacts the contact surface 7 and the card 2 passes through the card passage groove 3 with the front and back facing in opposite directions. 2 is operated. In this case, if the magnetic data of the second track of the magnetic stripe 2b does not include a large noise component that causes an error when the magnetic data is read by the magnetic head 5, "No" is obtained in step S2, The demodulated data generated by the demodulating circuit 18 is output to the upper control unit 21 after its arrangement is inverted.

(Main effects of this form)
As described above, the card reader 1 according to the present embodiment projects from the guide surface 8 to the inside of the card passage groove 3 and from the guide surface 9 to the inside of the card passage groove 3. The magnetic head 5 is arranged. In the present embodiment, the threshold value th1 for the amplified signals SG1 and SG2 is set in the waveform shaping circuit 12 so that the read sensitivity of the magnetic data read by the magnetic head 4 is higher than the read sensitivity of the magnetic data read by the magnetic head 5. Is set, and the waveform shaping circuit 17 sets a threshold th2 for the amplified signals SG1 and SG2.

  Therefore, in this embodiment, for example, magnetic data can be read with high sensitivity, as with the card 2 in which the magnetic force of the magnetic data recorded on the magnetic stripe 2b is weak, but with low sensitivity. Even if the card 2 cannot read magnetic data, the magnetic data of the card 2 can be read by operating the card 2 so that the magnetic stripe 2b contacts the magnetic head 4. Further, for example, magnetic data can be read with a low reading sensitivity, but the magnetic data can be read with a high sensitivity reading sensitivity like the card 2 in which the noise data is included in the magnetic data recorded in the magnetic stripe 2b. Even if the card 2 cannot be read, the magnetic data of the card 2 can be read by operating the card 2 with the front and back sides of the card 2 reversed so that the magnetic stripe 2 b contacts the magnetic head 5. That is, in this embodiment, it is possible to read the magnetic data of the card 2 that can read the magnetic data only with the low reading sensitivity and the magnetic data of the card 2 that can read the magnetic data only with the high reading sensitivity. become.

  Further, in this embodiment, when the card 2 is operated in the same manner so that the magnetic stripe 2 b contacts the magnetic head 4, the read result of whether or not the magnetic data can be read every time the card 2 is operated. It will not change. Similarly, when the card 2 is operated in the same manner so that the magnetic stripe 2b is in contact with the magnetic head 5, the reading result as to whether or not the magnetic data can be read changes every time the card 2 is operated. Absent. Therefore, in this embodiment, it is possible to appropriately determine whether the card 2 is capable of reading magnetic data or whether the card 2 is not capable of reading magnetic data.

  In this embodiment, the magnetic stripe 2b comes into contact with the magnetic head 4 when the one end surface 2c of the card 2 comes into contact with the contact surface 7 and the card 2 passes through the card passage groove 3 with the correct front and back. As described above, in normal operation, it is assumed that the card 2 is operated such that the one end surface 2c of the card 2 contacts the contact surface 7 and the card 2 passes through the card passage groove 3 with the front and back facing in the correct direction. Therefore, in this embodiment, the magnetic data of the card 2 that can read the magnetic data with a high reading sensitivity but cannot read the magnetic data with the low reading sensitivity can be read with one operation. become.

  In this embodiment, when the demodulated data is generated by the demodulating circuit 13, the CPU 20 determines whether or not this demodulated data sequence is correct. If the demodulated data sequence is not correct, the CPU 20 determines the demodulated data sequence. The demodulated data after inversion is output to the upper control unit 21. Further, when the demodulated data is generated by the demodulation circuit 18, the CPU 20 determines whether or not the order of the demodulated data is correct. If the order of the demodulated data is not correct, the CPU 20 inverts the order of the demodulated data. The demodulated data after inversion is output to the upper control unit 21. For this reason, in this embodiment, it is possible to output appropriate demodulated data to the upper control unit 21, and as a result, it is possible to reduce the burden of data processing in the upper control unit 21.

(Other embodiments)
The above-described embodiment is an example of a preferred embodiment of the present invention, but is not limited to this, and various modifications can be made without departing from the scope of the present invention.

  In the embodiment described above, no magnetic data is recorded on the magnetic stripe on the front surface of the card 2, but magnetic data may be recorded on the magnetic stripe on the front surface of the card 2. In this case, the magnetic data is read by the magnetic head 4 and the magnetic head 5 in the above-described step S1, and in step S2, the CPU 20 determines whether or not the arrangement of the demodulated data generated by the demodulation circuit 13 is correct. At the same time, it is determined whether or not the order of the demodulated data generated by the demodulation circuit 18 is correct. If the arrangement of the demodulated data generated by the demodulator circuit 13 and the demodulated data generated by the demodulator circuit 18 are correct, the CPU 20 outputs the demodulated data to the upper control unit 21 in step S3. If the arrangement of the demodulated data generated by the demodulation circuit 13 and the arrangement of the demodulated data generated by the demodulation circuit 18 are not correct, the arrangement of the demodulated data is inverted in step S4, and then the inverted data in step S3. The demodulated data is output to the upper control unit 21.

  When the magnetic data is recorded on the magnetic stripe on the front surface of the card 2 and the magnetic data of the second track of the magnetic stripe 2b is recorded, the one end surface 2c of the card 2 is in contact with the contact surface 7. And when the card 2 is operated so that the card 2 passes through the card passage groove 3 with the front and back facing in the correct direction, the magnetic data recorded on the magnetic stripe on the front surface of the card 2 can be read. When the magnetic data of the second track of the magnetic stripe 2b cannot be read, or when the magnetic data of the second track of the magnetic stripe 2b can be read but the magnetic data recorded on the magnetic stripe on the front surface of the card 2 cannot be read. Then, the card reader 1 or the host device performs a predetermined display or the like, and operates the card 2 again with the front and back reversed. Be as prompt.

  In the embodiment described above, the second track of the magnetic stripe 2b is applied to the magnetic head 4 when the card 2 passes through the card passage groove 3 with the one end surface 2c of the card 2 in contact with the contact surface 7 and with the front and back facing in the correct orientation. The second track of the magnetic stripe 2b comes into contact with the magnetic head 5 when the end face 2c of the card 2 comes into contact with the contact face 7 and the card 2 passes through the card passage groove 3 with the front and back facing in opposite directions. Magnetic heads 4 and 5 are arranged at the positions. In addition to this, for example, when the card 2 passes through the card passage groove 3 with the one end surface 2c of the card 2 abutting against the abutment surface 7 and the front and back thereof being in the correct orientation, the second track of the magnetic stripe 2b is The second track of the magnetic stripe 2b contacts the magnetic head 4 when the one end surface 2c of the card 2 abuts the contact surface 7 and the card 2 passes through the card passage groove 3 with the front and back facing in opposite directions. The magnetic heads 4 and 5 may be disposed at the contact positions.

  In the embodiment described above, the card reader 1 includes the CPU 20, but the card reader 1 may not include the CPU 20. In this case, the demodulated data generated by the demodulating circuit 13 and the demodulated data generated by the demodulating circuit 18 are input to the upper control unit 21. Further, when the demodulated data is generated by the demodulating circuit 13, the upper control unit 21 determines whether or not this demodulated data sequence is correct, and if the demodulated data sequence is correct, the demodulated data is used as it is. If the demodulated data sequence is not correct, the demodulated data sequence is inverted, and the demodulated data after the inversion is used to execute the predetermined processing. Further, when the demodulated data is generated by the demodulating circuit 18, the upper control unit 21 determines whether or not the demodulated data is correctly arranged. If the demodulated data is correct, the upper controller 21 uses the demodulated data as it is. If the demodulated data sequence is not correct, the demodulated data sequence is inverted, and the demodulated data after the inversion is used to execute the predetermined processing.

  In the embodiment described above, the distance L1 between the center CL1 of the magnetic data reading portion of the magnetic head 4 and the contact surface 7 and the center CL2 of the magnetic data reading portion of the magnetic head 5 in the short direction of the card 2 The distance L2 with the contact surface 7 is substantially equal. In addition to this, for example, when the card 2 passes through the card passage groove 3 with the one end surface 2c of the card 2 abutting against the abutment surface 7 and the front and back are in the correct orientation, the magnetic head 4 The magnetic head 4 is arranged so that the center CL1 of the magnetic data reading portion and the center of the second track of the magnetic stripe 2b substantially coincide with each other, and the center CL2 of the magnetic data reading portion of the magnetic head 5 The magnetic head 5 may be arranged so that the center of the magnetic stripe on the front surface substantially coincides.

  In the embodiment described above, the card reader 1 includes the amplifier circuits 11 and 16. However, when the output of the magnetic heads 4 and 5 is large, the card reader 1 may not include the amplifier circuits 11 and 16. good. In the above-described embodiment, the card 2 is a rectangular vinyl chloride card having a thickness of about 0.7 to 0.8 mm, but the card 2 has a thickness of about 0.18 to 0.36 mm. PET (polyethylene terephthalate) card or a paper card with a predetermined thickness may be used.

1 card reader 2 card 2b magnetic stripe 2c one end face (one end face in the short direction)
3 Card passage groove 4 Magnetic head (first magnetic head)
5 Magnetic head (second magnetic head)
7 Contact surface 8, 9 Guide surface 13 Demodulation circuit (first demodulated data generation unit)
14 First signal processing unit 18 Demodulation circuit (second demodulated data generation unit)
19 Second signal processing unit 20 CPU (data processing unit)
th1, th2 threshold

Claims (4)

In a manual card reader that manually moves a rectangular card and reads magnetic data recorded on the magnetic stripe of the card,
A card passage groove composed of a contact surface with which one end surface in the short direction of the card abuts and two guide surfaces for guiding both sides of the card in the thickness direction of the card; and the two guides A first magnetic head that protrudes from the guide surface of one of the surfaces into the card passage groove and is disposed at a position where the magnetic stripe passes in the short direction of the card; and the two guide surfaces A second magnetic head protruding from the other guide surface of the card into the card passage groove and disposed at a position where the magnetic stripe passes in a short direction of the card, and an output of the first magnetic head A first signal processing unit to which a signal is input; and a second signal processing unit to which an output signal of the second magnetic head is input;
In the first signal processing unit, the output signal of the first magnetic head is set so that the read sensitivity of the magnetic data read by the first magnetic head is higher than the read sensitivity of the magnetic data read by the second magnetic head. Alternatively, a threshold for the output signal of the first magnetic head after amplification is set, and a threshold for the output signal of the second magnetic head or the output signal of the second magnetic head after amplification is set by the second signal processing unit. A card reader. Magnetic data is recorded on the magnetic stripe formed on one side of the card,
The magnetic stripe formed on one surface of the card when one end surface of the short side of the card is in contact with the contact surface and the card passes through the card passage groove with the front and back facing in the correct direction. Abutting against the first magnetic head;
The magnetic stripe formed on one side of the card when one end surface of the short side of the card abuts the abutment surface and the card passes through the card passage groove with the front and back being opposite directions 2. The card reader according to claim 1, wherein the card reader is in contact with the second magnetic head.   In the short direction of the card, the distance between the center of the magnetic data reading portion of the first magnetic head and the contact surface, the center of the magnetic data reading portion of the second magnetic head, and the contact surface The card reader according to claim 1, wherein the distance is substantially equal. A first demodulated data generating unit that generates demodulated data based on an output signal of the first signal processing unit; a second demodulated data generating unit that generates demodulated data based on an output signal of the second signal processing unit; A data processing unit to which the first demodulated data generated by the first demodulated data generating unit and the second demodulated data generated by the second demodulated data generating unit are input;
The data processing unit determines whether or not the first demodulated data sequence is correct when the first demodulated data generation unit generates the first demodulated data, and the first demodulated data sequence is determined. If it is not correct, the sequence of the first demodulated data is inverted, and when the second demodulated data is generated by the second demodulated data generation unit, it is determined whether the sequence of the second demodulated data is correct. 4. The card reader according to claim 1, wherein when the second demodulated data is not correctly arranged, the second demodulated data is reversed.

Images