JPH10255211A - Magnetic card recording and reproducing device and magnetic card - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a magnetic card recording and reproducing device which is capable of recording magnetic information onto magnetic cards having different coercive forces with the single device, and a new magnetic card which can cope with increase in quantity of information and enhances concealment. SOLUTION: A magnetic card recording and reproducing device has a coercive force discriminating section 20 for discriminating the coercive force of a magnetic card, and an excitation current selecting section 30 for selecting the excitation current of a recording magnetic head 1 for recording on a magnetic card from a plurality of preset values. A magnetic card is produced by bonding, in a layered manner, a plurality of magnetic tapes coated with magnetic materials having different coercive forces, or by bonding a magnetic tape coated with a mixture of a plurality of types of magnetic materials having different coercive forces.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetic card recording / reproducing apparatus and a magnetic card for recording and reproducing magnetic information on and from a magnetic card. The present invention relates to a technique for increasing the amount of possible magnetic information.

[0002]

2. Description of the Related Art In recent years, magnetic cards such as credit cards and telephone cards have become so popular that they can be said to be indispensable in daily life. On the other hand, the number of electronic devices that cannot avoid the leakage of magnetic flux and healthy accessories that actively generate a magnetic field are increasing, which causes troubles such as loss of data stored on the magnetic card and obscuring the storage state. Occurs frequently.

[0003] In order to avoid these troubles, magnetic cards are beginning to appear in which the magnetic coercive force is increased so that the magnetic cards are not affected by the magnetic field around them. Incidentally, the magnetic coercive force of a card or a credit card specified by JIS Class 1 is 300 Oersted, and the magnetic coercive force of a telephone card is 650 Oersted. Magnetic cards distributed mainly in Europe and the United States have magnetic coercivity of one.
There are 750 Oersteds and 2750 Oersteds, and even those with an enhanced protective function have a magnetic coercive force of 4000 Oersteds.
Also in Japan, magnetic cards having a magnetic coercivity comparable to those in Europe and the United States are used for, for example, highway cards.

[0004]

Since most of the above-mentioned magnetic cards have substantially the same external dimensions, it would be extremely advantageous if the recording / reproducing apparatus could be shared. However, there is a reason that it is difficult to cope with a magnetic card having a diversified magnetic holding force. Hereinafter, this will be described with reference to the drawings.

FIG. 8 is an explanatory diagram for explaining a state of recording magnetic information on a magnetic card. In the figure, a core 1 constituting a ring-type magnetic head is made of a material having high magnetic permeability, has a gap (about 10 μm) 12 at a front end portion (expanded for easy understanding in the drawings), and a base end portion. The coil 2 is wound around the portion. The coil 2 is connected to a current generator 4 for supplying an exciting current at the time of recording magnetic information, via an input unit 3 for performing impedance matching together with current amplification. On the other hand, a magnetic tape 6 coated with a magnetic material is adhered to the magnetic card 5, and is conveyed, for example, in the direction of arrow A.

When a current flows through the coil 2, a magnetic flux 13 corresponding to the magnetomotive force is generated. In this case, depending on the direction of the current, a magnetic flux in a direction indicated by a solid arrow or a magnetic flux in a direction indicated by a broken arrow is generated. These magnetic fluxes form a magnetic field 8 spread near the gap of the core 1. At this time, the spread of the magnetic field 8 can be suppressed by narrowing the gap. Then, by supplying a positive or negative pulse current intermittently to the coil 2 in conjunction with the transport of the magnetic card 5, magnetized regions 9, 10, 11 are formed on the magnetic tape 6 according to the polarity of the magnetic field. .

When forming the magnetized area, that is, when recording magnetic information, the peak value of the pulse current supplied to the coil 2 is determined according to the magnetic coercive force of the magnetic tape 6. Therefore, assuming that the magnetic coercive force of the magnetic card 5 is small, the time interval of the pulse current, that is, the interval between the magnetized regions 9, 10, 11 is determined. However, when a pulse current with a large peak value is applied at the same time interval,
A magnetic field 8 'spread in the direction of transport of the magnetic card is formed. The magnetic field 8 'affects the magnetized area 9 or 10 where the recording of the magnetic information has already been completed, and when the polarity of the current is reversed, the magnetized state is deteriorated or erased. On the other hand, even if a magnetic card 5 having a large magnetic coercive force is inserted into a magnetic card recording / reproducing apparatus for a magnetic card having a small magnetic coercive force, recording of magnetic information is impossible due to insufficient magnetomotive force. As described above, in order to obtain a recording / reproducing apparatus capable of coping with magnetic cards having diversified magnetic coercive force, a recording / reproducing system including a plurality of recording magnetic heads must be designed to cope with magnetic cards having different magnetic coercive forces. And it was difficult to achieve.

A first object of the present invention is to provide a magnetic card recording / reproducing apparatus capable of recording magnetic information with a single recording magnetic head even for magnetic cards having different magnetic coercive forces. is there.

A second object of the present invention is to provide a new magnetic card suitable for this magnetic card recording / reproducing apparatus.

[0010]

In a magnetic card recording / reproducing apparatus according to claim 1, magnetic coercive force discriminating means for judging a magnetic coercive force of said magnetic card before recording magnetic information on said magnetic card. And exciting current selecting means for selecting an exciting current of a recording magnetic head used for recording the magnetic information from a plurality of preset values in accordance with a result of the discrimination by the magnetic coercive force discriminating means. Therefore, even if the magnetic cards have different magnetic coercive forces, there is an effect that magnetic information can be recorded by one card.

In the magnetic card recording / reproducing apparatus according to the present invention, the magnetic holding force discriminating means records the pulse current whose peak value changes substantially linearly with the passage of the magnetic card at a predetermined cycle. Pulse current supply means for supplying a magnetic head, AC voltage detection means for detecting an induced voltage of a magnetic head for reproducing a magnetic card, and whether an output of the AC voltage detection means exceeds a reference value earlier than a predetermined time. A comparison means for judging the magnitude of the magnetic coercive force is provided depending on whether or not the discrimination is made, and the discrimination is made by performing the insertion and removal operations two times before and after, so that a reliable discrimination can be made.

In the magnetic card recording / reproducing apparatus according to the third aspect, the exciting current selecting means switches and connects in accordance with the result of the discrimination by the holding force discriminating means, and the size of the switch varies depending on the connection state of the switch. Recording current supply means for supplying different currents, it is possible to perform reliable recording according to the magnetic coercive force.

According to a fourth aspect of the present invention, there is provided a magnetic card recording / reproducing apparatus, further comprising: a thickness sensor for detecting a thickness of the magnetic card; and a recording magnetic contacting the magnetic card according to the detected thickness of the magnetic card. Since the head and the reproducing magnetic head are provided with the contact pressure adjusting means for applying a predetermined pressure, even if the magnetic cards have different thicknesses, there is an effect that recording can be performed by one unit.

According to a fifth aspect of the present invention, there is provided a magnetic card wherein a plurality of magnetic tapes each coated with a magnetic material having a different magnetic coercive force are adhered in layers. By applying the device, it is possible to cope with an increase in the amount of information, and it has an effect of increasing confidentiality.

According to a sixth aspect of the present invention, there is provided the magnetic card according to the first to fourth aspects, wherein a magnetic tape coated with a mixture of a plurality of types of magnetic materials having different magnetic coercive forces is applied. By applying the reproducing apparatus, it is possible to cope with an increase in the amount of information and to increase the confidentiality.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail based on preferred embodiments shown in the drawings.

FIG. 1 is a block diagram showing the configuration of one embodiment of the present invention. In the figure, the same elements as those in FIG. 8 are denoted by the same reference numerals, and description thereof will be omitted. Note that the present embodiment is directed to recording magnetic information on an unused magnetic card, and the reproduction of the magnetic information is not directly related, and therefore detailed description thereof will be omitted. One magnetic head is used for both recording and reproduction, and an input / output unit 15 is connected to the coil 2. Input / output unit 1
Reference numeral 5 has a function of supplying an exciting current to the coil 2 during recording and outputting a voltage generated in the coil 2 during reproduction.

Here, with respect to the input / output unit 15, mainly
The magnetic holding force determination unit 20 and the excitation current selection unit 30 are connected. The magnetic coercive force discriminating section 20 discriminates the magnetic coercive force of the magnetic card, and outputs a pulse current whose peak value changes substantially linearly with the elapse of time during which the magnetic card is conveyed at a predetermined cycle. Pulse current supply means 21 for supplying the AC voltage, an AC voltage detection means 22 for detecting an induced voltage of the magnetic head, and whether or not the output of the AC voltage detection means 22 exceeds a reference value earlier than a predetermined time. And a comparing means 23 for determining the magnitude of the magnetic coercive force. On the other hand, the excitation current selection unit 30 selects the excitation current of the magnetic head from a plurality of preset values according to the determination result of the magnetic coercive force determination unit 20, and includes a switch selection unit 31, a signal pulse generation unit 32, The switch includes switches 33 and 36, a current control means 34 for low magnetic coercivity, and a current control means 35 for high magnetic coercivity.

The operation of the present embodiment configured as described above will be described below.

As is well known, there are ferromagnetic materials that saturate with a small magnetic force and those that do not saturate with a large magnetic force, and are represented by large and small BH curves, respectively. FIG.
Shows the BH curves of these two typical ferromagnetic materials, and the curve 41 shows that the curve 41 saturates with a small magnetic force.
The curve 42 is a BH curve in which the curve 42 is saturated with a large magnetic force. In this case, when the magnetic field is saturated with a small magnetic force, the magnetic flux density is saturated to Bs1 even when a magnetic field of Hs1 or more is applied, and the residual magnetic flux density Br1 is maintained when the magnetic field is removed. Also,
Even when a magnetic field of -Hs1 or more is applied to the magnetic field having the opposite direction, the magnetic flux density saturates to -Bs1, and when the magnetic field is removed, the residual magnetic flux density -Br1 is maintained. Therefore, when the magnetic fields Hs1 and -Hs1 are alternately applied, the hysteresis characteristic according to the illustrated curve 41 is shown. The same is true for those who saturate with a large magnetic force. Even if a magnetic field of Hs2 (> Hs1) or more is applied, the magnetic flux density saturates to Bs2, and when the magnetic field is removed, the residual magnetic flux density Br2 (> Br1) is maintained. I do. Further, even when a magnetic field of -Hs2 or more is applied to the magnetic field having the opposite direction, the magnetic flux density saturates to -Bs2, and when the magnetic field is removed, the residual magnetic flux density -Br2 is maintained. Therefore, the magnetic field Hs2 and-
When a magnetic field of Hs2 is applied alternately, a hysteresis characteristic according to the illustrated curve 42 is shown.

Generally, the point at which the curve 41 intersects the H axis is referred to as magnetic coercive force Hc1, and the point at which the curve 42 intersects the H axis is referred to as magnetic coercive force Hc2 (> Hc1). Thus, the magnetic coercive force H
The magnetic card having the magnetic tape coated with the magnetic material of c1 is a magnetic card having a low magnetic coercive force, and the magnetic card having the magnetic tape coated with the magnetic material of Hc2 is a magnetic card having a high magnetic coercive force. is there.

A pulse-like magnetic field is applied to each of the two types of magnetic cards to magnetize regions 9, 10 and 10 shown in FIG.
3, the current shown in the region S is applied to the coil 2 for the magnetic card having a low magnetic coercive force, and the region L is applied to the magnetic card having a high magnetic coercive force, as shown in FIG. Is applied to the coil 2 for recording. On the other hand, when the magnetic card is reproduced, if the horizontal axis is time, an AC voltage shown by a curve Y is generated for a magnetic card having a low magnetic coercive force according to the conveyance of the magnetic card, The magnetic card generates an AC voltage shown by a curve Z.

By paying attention to this fact, the present invention discriminates the actual magnetic coercivity of a magnetic card whose magnetic coercivity is unknown, and executes magnetic recording according to the discrimination result.

Therefore, as shown in FIG. 4, the pulse current supply means 21 constituting the magnetic coercive force discriminating section 20 changes the peak value of the first inserted magnetic card in a substantially linear manner over time, as shown in FIG. By supplying an increasing pulse current at a predetermined cycle, magnetic information is recorded on the magnetic card. At this time, the residual magnetic flux density of the magnetic card having a low magnetic coercive force is low, and the residual magnetic flux density of the magnetic card having a high magnetic coercive force is high.

Next, the magnetic card on which the magnetic information has been recorded is inserted again, and the AC voltage generated at the input / output unit 15 is detected by the AC voltage detecting means 22 this time. At this time, since the magnetic card is moving, the AC voltage shown in FIG. 5 is detected over time. That is, in the case of a magnetic card having a low magnetic coercive force, an AC voltage indicated by a curve Y is detected, and in a magnetic card having a high magnetic coercive force, an AC voltage indicated by a curve Z is detected. At this time, the comparing means 23 compares the detected amplitude of the AC voltage with the reference value VREF, and determines the magnetic coercive force of the magnetic card based on the length of time from when the AC voltage is detected to when the AC voltage exceeds the reference value VREF. I do. That is, the magnetic card having a low magnetic coercive force exceeds the reference value VREF only for the period S, whereas the magnetic card having a high magnetic coercive force exceeds the reference value VREF for the period L. Therefore,
The determination of the magnetic coercive force of the magnetic card is not limited to the time from the occurrence of the alternating current, but can also be determined by measuring the time exceeding the reference value VREF.

As described above, the result of the determination of the magnetic coercive force is applied to the exciting current selector 30. The switch selection means 31 constituting the excitation current selection unit 30 determines whether or not the switch 3 has a low magnetic coercivity according to the determination result.
3 and 36 are switched to the low magnetic coercive force current control means 34 side, whereby the current output from the signal pulse generating means 32 is narrowed down and applied to the input / output unit 15.
Conversely, the switch selecting means 31 constituting the exciting current selecting section 30 switches the switches 33 and 36 to the high magnetic holding force current control means 35 side in accordance with the result of the determination that the card has a high magnetic holding force. Thus, a large current output from the signal pulse generating means 32 is applied to the input / output unit 15.

Thus, according to this embodiment, magnetic recording can be performed with an optimum current value on a magnetic card whose magnetic coercive force is unknown.

The switch 3 constituting the above embodiment is
Although 3 and 36 are shown as mechanical contacts, semiconductor switches and logic switches can be used instead.

Further, a microcomputer can be provided with a part or most of the functions of the above embodiment.

FIG. 5 is a flowchart showing a specific processing procedure. That is, in step 101, a known magnetic card is demagnetized. In the next step 102, a pulse current whose peak value gradually increases over time is supplied. Subsequently, in step 103, the amplitude of the output voltage of the coil of the magnetic head is detected in order to determine the magnetic holding force of the magnetic card inserted for the second time. Then, in step 104, it is determined whether or not the amplitude of the voltage has exceeded the reference value. If the amplitude of the voltage exceeds the reference value early in time, it is determined that the magnetic card has a low magnetic coercive force, and in step 105, recording is performed with a current value corresponding to a magnetic tape having a small magnetic coercive force. If the amplitude of the voltage does not exceed the reference value at an early stage, in step 106, recording is performed with a current value corresponding to a magnetic tape having a large magnetic coercive force.

Thus, the same operations as those of the magnetic coercive force discriminating section 20 and the exciting current selecting section 30 shown in FIG. 1 can be performed.

FIG. 7 is a front view of the magnetic card recording / reproducing apparatus 60 according to the above embodiment. Here, an insertion slot 61 for a magnetic card is provided at the upper part of the case 65, and a switch 62 for a high magnetic coercivity magnetic card, a switch 63 for a low magnetic coercivity magnetic card, and a switch 64 for full automatic operation are vertically arranged below the case. It is arranged. If the magnetic coercive force is known in advance, the magnetic recording is performed by operating the high magnetic coercive force magnetic card switch 62 or the low magnetic coercive force magnetic card switch 63. If the magnetic coercivity is unknown, or
When it is difficult to determine, the fully automatic switch 64 is operated.

Thus, according to the present embodiment, it is possible to provide a magnetic card recording / reproducing apparatus which can record data on magnetic cards having different magnetic coercive force by one unit.

In the above-described embodiment, whether the magnetic coercive force of the magnetic card is high or low is detected. However, according to the same principle as described above, the discrimination when there are three or more magnetic coercive forces and the optimum Recording by electric current is also possible.

Incidentally, some magnetic cards have not only different magnetic coercive force but also different thicknesses. If these magnetic cards can be recorded by a single magnetic card recording / reproducing device, a more convenient device can be provided. To realize this, first, a thickness sensor for detecting the thickness of the magnetic card, and contact pressure adjusting means for applying a predetermined pressure to the magnetic head that contacts the magnetic card according to the detected thickness of the magnetic card You just need to add In addition,
For the thickness sensor and the contact pressure adjusting means, the technology applied by the present applicant as Japanese Patent Application No. 9-29675 can be used.

On the other hand, a magnetic card recording / reproducing apparatus capable of coping with magnetic cards having different magnetic coercive forces can perform recording with a strong magnetic field, and can record with a weak magnetic field. Paying attention to this point, magnetic tapes with different magnetic coercive force are superimposed in multiple layers, first recorded with a strong magnetic field,
If recording is sequentially performed with a weak magnetic field, it is possible to store information several times higher and to provide a magnetic card with enhanced confidentiality. In this case, separate magnetic signals may be extracted by modulating one or both of the magnetic tapes at different frequencies.

Also, instead of laminating magnetic tapes having different magnetic coercive forces in multiple layers, a magnetic tape formed by mixing and applying magnetic materials having different magnetic coercive forces may be attached, as described above. It is possible to provide a magnetic card that can store twice as much information and has high confidentiality.

[0038]

As is apparent from the above description, according to the magnetic card recording / reproducing apparatus of the first aspect, there is an effect that one magnetic card having different magnetic coercive force can be recorded.

According to the magnetic card recording / reproducing apparatus of the second aspect, there is also an effect that the magnetic coercive force of the magnetic card can be reliably determined.

According to the magnetic card recording / reproducing apparatus of the third aspect, there is also obtained an effect that reliable recording according to the magnetic coercive force can be performed.

According to the magnetic card recording / reproducing apparatus of the fourth aspect, a new effect is obtained in that recording can be performed by one magnetic card even when the thickness of the magnetic card is different.

According to the magnetic card of the fifth or sixth aspect, an increase in the amount of information can be dealt with, and there is an effect of increasing confidentiality.

[Brief description of the drawings]

FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention.

FIG. 2 is a BH curve for explaining the operation of the embodiment shown in FIG. 1;

FIG. 3 is a diagram showing a relationship between an AC voltage, current, and time involved in recording / reproducing for explaining the operation of the embodiment shown in FIG. 1;

FIG. 4 is a diagram showing a relationship between a current peak value and time at the time of recording in order to explain the operation of the embodiment shown in FIG. 1;

FIG. 5 is a diagram showing a relationship between an AC voltage and time at the time of reproduction for explaining the operation of the embodiment shown in FIG. 1;

FIG. 6 is an exemplary flowchart showing a processing procedure when the microcomputer has main functions of the embodiment shown in FIG. 1;

FIG. 7 is a front view of the embodiment shown in FIG. 1;

FIG. 8 is a schematic configuration diagram of a conventional magnetic card recording / reproducing apparatus.

[Explanation of symbols]

 Reference Signs List 1 core 2 coil 15 input / output unit 20 magnetic holding force discriminating unit 21 pulse current supply unit 22 AC voltage detecting unit 23 comparing unit 30 exciting current selecting unit 31 switch selecting unit 32 signal pulse generating unit 33, 36 switch 34 low magnetic holding force Current control means for high magnetic coercivity 35

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[Procedure amendment]

[Submission date] April 16, 1997

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

Patent application title: Magnetic card recording / reproducing apparatus and magnetic card

[Claims]

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetic card recording / reproducing apparatus and a magnetic card for recording and reproducing magnetic information on and from a magnetic card. The present invention relates to a technique for increasing the amount of possible magnetic information.

[0002]

2. Description of the Related Art In recent years, magnetic cards such as credit cards and telephone cards have become so popular that they can be said to be indispensable in daily life. On the other hand, the number of electronic devices that cannot avoid the leakage of magnetic flux and healthy accessories that actively generate a magnetic field are increasing, which causes troubles such as loss of data stored on the magnetic card and obscuring the storage state. Occurs frequently.

[0003] In order to avoid these troubles, magnetic cards have been beginning to appear in which the magnetic coercive force is increased so as not to be affected by the magnetic field around them. Incidentally, the magnetic coercive force of a card or a credit card prescribed in JIS Class 1 is 300 Oersted, and the magnetic coercive force of a telephone card is 650 Oersted. Magnetic cards distributed mainly in Europe and the United States have a magnetic coercive force of 1 unit.
There are 750 Oersteds and 2750 Oersteds, and magnetic coercive forces of 4000 Oersteds have begun to be provided with enhanced protection functions.
Also in Japan, a magnetic card having a magnetic coercive force comparable to that of Europe and the United States is used for, for example, an expressway card.

[0004]

Since most of the above-mentioned magnetic cards have substantially the same external dimensions, it would be extremely advantageous if the recording / reproducing apparatus could be shared. However, there is a reason that it is difficult to cope with a magnetic card having a diversified magnetic coercive force. Hereinafter, this will be described with reference to the drawings.

FIG. 8 is an explanatory diagram for explaining a state of recording magnetic information on a magnetic card. In the figure, a core 1 constituting a ring-type magnetic head is made of a material having high magnetic permeability, has a gap (about 10 μm) 12 at a front end portion (expanded for easy understanding in the drawings), and a base end portion. The coil 2 is wound around the portion. The coil 2 is connected to a current generator 4 for supplying an exciting current at the time of recording magnetic information, via an input unit 3 for performing impedance matching together with current amplification. On the other hand, a magnetic tape 6 coated with a magnetic material is adhered to the magnetic card 5, and is conveyed, for example, in the direction of arrow A.

When a current flows through the coil 2, a magnetic flux 13 corresponding to the magnetomotive force is generated. In this case, depending on the direction of the current, a magnetic flux in a direction indicated by a solid arrow or a magnetic flux in a direction indicated by a broken arrow is generated. These magnetic fluxes form a magnetic field 8 spread near the gap of the core 1. At this time, the spread of the magnetic field 8 can be suppressed by narrowing the gap. Then, by supplying a positive or negative pulse current intermittently to the coil 2 in conjunction with the transport of the magnetic card 5, magnetized regions 9, 10, 11 are formed on the magnetic tape 6 according to the polarity of the magnetic field. .

When forming the magnetized area, that is, when recording magnetic information, the peak value of the pulse current supplied to the coil 2 is determined according to the magnetic coercive force of the magnetic tape 6. Therefore, assuming that the magnetic coercive force of the magnetic card 5 is small, the time interval of the pulse current, that is, the interval between the magnetized regions 9, 10, 11 is determined. However, when a pulse current with a large peak value is applied at the same time interval,
A magnetic field 8 'spread in the direction of transport of the magnetic card is formed. The magnetic field 8 'affects the magnetized area 9 or 10 where the recording of the magnetic information has already been completed, and when the polarity of the current is reversed, the magnetized state is deteriorated or erased. On the other hand, even if a magnetic card 5 having a large magnetic coercive force is inserted into a magnetic card recording / reproducing apparatus for a magnetic card having a small magnetic coercive force, recording of magnetic information is impossible due to insufficient magnetomotive force. As described above, in order to obtain a recording / reproducing apparatus capable of coping with a magnetic card having a diversified magnetic coercive force, a recording / reproducing system including a plurality of recording magnetic heads must be designed to cope with magnetic cards having different magnetic coercive forces. And it was difficult to achieve.

A first object of the present invention is to provide a magnetic card recording / reproducing apparatus capable of recording magnetic information with a single recording magnetic head even on magnetic cards having different magnetic coercive forces. is there.

A second object of the present invention is to provide a new magnetic card suitable for this magnetic card recording / reproducing apparatus.

[0010]

A magnetic card recording / reproducing apparatus according to claim 1, wherein magnetic coercive force determining means for determining magnetic coercive force of said magnetic card before recording magnetic information on said magnetic card. And exciting current selecting means for selecting an exciting current of a recording magnetic head used for recording the magnetic information from a plurality of preset values in accordance with a result of the discrimination by the magnetic coercive force discriminating means. Therefore, even if the magnetic cards have different magnetic coercive forces, there is an effect that magnetic information can be recorded by one unit.

In the magnetic card recording / reproducing apparatus according to the present invention, the magnetic coercive force discriminating means records the pulse current whose peak value changes substantially linearly with the elapse of the magnetic card transport time at a predetermined cycle. Pulse current supply means for supplying a magnetic head, AC voltage detection means for detecting an induced voltage of a magnetic head for reproducing a magnetic card, and whether an output of the AC voltage detection means exceeds a reference value earlier than a predetermined time. A comparison means for discriminating the magnitude of the magnetic coercive force is provided depending on whether or not the discrimination is performed, and the discrimination is made by performing the insertion and removal operations twice before and after, so that a reliable discrimination can be made.

In the magnetic card recording / reproducing apparatus according to the third aspect, the exciting current selecting means switches and connects in accordance with the result of the discrimination by the magnetic coercive force discriminating means, and the size of the switch varies depending on the connection state of the switch. Since recording current supply means for supplying different currents is provided, reliable recording according to the magnetic coercive force can be performed.

According to a fourth aspect of the present invention, there is provided a magnetic card recording / reproducing apparatus, further comprising: a thickness sensor for detecting a thickness of the magnetic card; and a recording magnetic contacting the magnetic card according to the detected thickness of the magnetic card. Since the head and the reproducing magnetic head are provided with the contact pressure adjusting means for applying a predetermined pressure, even if the magnetic cards have different thicknesses, there is an effect that recording can be performed by one unit.

According to a fifth aspect of the present invention, there is provided a magnetic card wherein a plurality of magnetic tapes each coated with a magnetic material having a different magnetic coercive force are adhered in a layered manner. By applying the device, it is possible to cope with an increase in the amount of information, and it has an effect of increasing confidentiality.

According to a sixth aspect of the present invention, there is provided the magnetic card according to the first to fourth aspects, wherein a magnetic tape coated with a mixture of a plurality of magnetic materials having different magnetic coercive forces is applied. By applying the reproducing apparatus, it is possible to cope with an increase in the amount of information and to increase the confidentiality.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail based on preferred embodiments shown in the drawings.

FIG. 1 is a block diagram showing the configuration of one embodiment of the present invention. In the figure, the same elements as those in FIG. 8 are denoted by the same reference numerals, and description thereof will be omitted. Note that the present embodiment is directed to recording magnetic information on an unused magnetic card, and the reproduction of the magnetic information is not directly related, and therefore detailed description thereof will be omitted. One magnetic head is used for both recording and reproduction, and an input / output unit 15 is connected to the coil 2. Input / output unit 1
Reference numeral 5 has a function of supplying an exciting current to the coil 2 during recording and outputting a voltage generated in the coil 2 during reproduction.

Here, with respect to the input / output unit 15, mainly
The magnetic coercive force determination unit 20 and the excitation current selection unit 30 are connected. The magnetic coercive force determination unit 20 determines the magnetic coercive force of the magnetic card, and outputs a pulse current whose peak value changes substantially linearly with the elapse of time during which the magnetic card is conveyed at predetermined intervals. Pulse current supply means 21 for supplying the AC voltage, an AC voltage detection means 22 for detecting an induced voltage of the magnetic head, and whether or not the output of the AC voltage detection means 22 exceeds a reference value earlier than a predetermined time. And a comparing means 23 for determining the magnitude of the magnetic coercive force. On the other hand, the excitation current selection unit 30 selects the excitation current of the magnetic head from a plurality of preset values according to the determination result of the magnetic coercive force determination unit 20, and includes a switch selection unit 31, a signal pulse generation unit 32, It comprises switches 33 and 36, a low magnetic coercive force current control means 34, and a high magnetic coercive force current control means 35.

The operation of the present embodiment configured as described above will be described below.

As is well known, there are ferromagnetic materials that saturate with a small magnetic force and those that do not saturate with a large magnetic force, and are represented by large and small BH curves, respectively. FIG.
Shows the BH curves of these two typical ferromagnetic materials, and the curve 41 shows that the curve 41 saturates with a small magnetic force.
The curve 42 is a BH curve in which the curve 42 is saturated with a large magnetic force. In this case, when the magnetic field is saturated with a small magnetic force, the magnetic flux density is saturated to Bs1 even when a magnetic field of Hs1 or more is applied, and the residual magnetic flux density Br1 is maintained when the magnetic field is removed. Also,
Even when a magnetic field of -Hs1 or more is applied to the magnetic field having the opposite direction, the magnetic flux density saturates to -Bs1, and when the magnetic field is removed, the residual magnetic flux density -Br1 is maintained. Therefore, when the magnetic fields Hs1 and -Hs1 are alternately applied, the hysteresis characteristic according to the illustrated curve 41 is shown. The same is true for those who saturate with a large magnetic force. Even if a magnetic field of Hs2 (> Hs1) or more is applied, the magnetic flux density saturates to Bs2, and when the magnetic field is removed, the residual magnetic flux density Br2 (> Br1) is maintained. I do. Further, even when a magnetic field of -Hs2 or more is applied to the magnetic field having the opposite direction, the magnetic flux density saturates to -Bs2, and when the magnetic field is removed, the residual magnetic flux density -Br2 is maintained. Therefore, the magnetic field Hs2 and-
When a magnetic field of Hs2 is applied alternately, a hysteresis characteristic according to the illustrated curve 42 is shown.

Generally, the point at which the curve 41 intersects the H axis is referred to as a magnetic coercive force Hc1, and the point at which the curve 42 intersects the H axis is referred to as a magnetic coercive force Hc2 (> Hc1). Thus, the magnetic coercive force H
A magnetic card having a magnetic tape coated with a magnetic material of c1 is a magnetic card having a low magnetic coercive force, and a magnetic card having a magnetic tape coated with a magnetic material having a magnetic coercive force of Hc2 is a magnetic card having a high magnetic coercive force. is there.

A pulse-like magnetic field is applied to each of the two types of magnetic cards to magnetize regions 9, 10 and 10 shown in FIG.
3, the current shown in the area S is applied to the coil 2 with respect to the magnetic card having a low magnetic coercive force, while the area L is applied to the magnetic card having a high magnetic coercive force as shown in FIG. Is applied to the coil 2 for recording. On the other hand, when this magnetic card is reproduced, if the horizontal axis is time, an AC voltage shown by a curve Y is generated in a magnetic card having a low magnetic coercive force according to the transport of the magnetic card, and a high magnetic coercive force is generated. Generates an AC voltage shown by a curve Z.

By paying attention to this, the present invention discriminates the actual magnetic coercivity of a magnetic card whose magnetic coercivity is unknown, and executes magnetic recording according to the discrimination result.

Therefore, as shown in FIG. 4, the pulse current supply means 21 constituting the magnetic coercive force discriminating section 20 changes the peak value of the magnetic card inserted almost linearly with time as shown in FIG. By supplying an increasing pulse current at a predetermined cycle, magnetic information is recorded on the magnetic card. At this time, the residual magnetic flux density of the low magnetic coercivity magnetic card is low, and the residual magnetic flux density of the high magnetic coercivity magnetic card is high.

Next, the magnetic card on which the magnetic information has been recorded is inserted again, and the AC voltage generated at the input / output unit 15 is detected by the AC voltage detecting means 22 this time. At this time, since the magnetic card is moving, the AC voltage shown in FIG. 5 is detected over time. That is, in the magnetic card having a low magnetic coercive force, an AC voltage indicated by a curve Y is detected, and in the magnetic card having a high magnetic coercive force, an AC voltage indicated by a curve Z is detected. At this time, the comparing means 23 compares the detected amplitude of the AC voltage with the reference value VREF, and determines the magnetic coercive force of the magnetic card according to the length of time from when the AC voltage is detected to when the AC voltage exceeds the reference value VREF. I do. That is, the magnetic card having a low magnetic coercive force exceeds the reference value VREF only for the period S, whereas the magnetic card having a high magnetic coercive force exceeds the reference value VREF for the period L. Therefore,
The determination of the magnetic coercive force of the magnetic card is not limited to the time from the occurrence of the alternating current, but can also be determined by measuring the time exceeding the reference value VREF.

In this manner, the result of the determination of the magnetic coercive force is applied to the exciting current selecting section 30. The switch selecting means 31 constituting the exciting current selecting section 30 determines whether or not the switch 3 has a low magnetic coercive force according to the determination result.
3 and 36 are switched to the low magnetic coercivity current control means 34 side, whereby the current output from the signal pulse generating means 32 is narrowed down and applied to the input / output unit 15.
Conversely, the switch selecting means 31 constituting the exciting current selecting section 30 switches the switches 33 and 36 to the high magnetic coercive force current control means 35 side in accordance with the result of the determination that the card has a high magnetic coercive force. Thus, a large current output from the signal pulse generating means 32 is applied to the input / output unit 15.

Thus, according to this embodiment, magnetic recording can be performed with an optimum current value on a magnetic card whose magnetic coercive force is unknown.

The switch 3 constituting the above embodiment is
Although 3 and 36 are shown as mechanical contacts, semiconductor switches and logic switches can be used instead.

Further, a microcomputer can be provided with a part or most of the functions of the above embodiment.

FIG. 5 is a flowchart showing a specific processing procedure. That is, in step 101, a known magnetic card is demagnetized. In the next step 102, a pulse current whose peak value gradually increases over time is supplied. Subsequently, in step 103, the amplitude of the output voltage of the coil of the magnetic head is detected in order to determine the magnetic coercive force of the magnetic card inserted for the second time. Then, in step 104, it is determined whether or not the amplitude of the voltage has exceeded the reference value. If the amplitude of the voltage exceeds the reference value early in time, it is determined that the magnetic card has a low magnetic coercive force, and in step 105, recording is performed with a current value corresponding to a magnetic tape having a small magnetic coercive force. If the voltage amplitude does not exceed the reference value at an early stage, in step 106, recording is performed with a current value corresponding to a magnetic tape having a large magnetic coercive force.

As a result, the same operations as those of the magnetic coercivity discriminating section 20 and the exciting current selecting section 30 shown in FIG. 1 can be performed.

FIG. 7 is a front view of the magnetic card recording / reproducing apparatus 60 according to the above embodiment. Here, an insertion slot 61 for a magnetic card is provided at the upper part of the case 65, and a switch 62 for a high magnetic coercive force magnetic card, a switch 63 for a low magnetic coercive force magnetic card, and a switch 64 for full automatic operation are vertically arranged below the case. It is arranged. If the magnetic coercive force is known in advance, the magnetic recording is executed by operating the high magnetic coercive force magnetic card switch 62 or the low magnetic coercive force magnetic card switch 63. If the coercivity is unknown, or
When it is difficult to determine, the fully automatic switch 64 is operated.

Thus, according to the present embodiment, it is possible to provide a magnetic card recording / reproducing apparatus which can record data on magnetic cards having different magnetic coercive forces by one unit.

In the above-described embodiment, whether the magnetic coercive force of the magnetic card is high or low is detected. However, according to the same principle as described above, it is determined whether the magnetic coercive force is three or more, Recording by electric current is also possible.

Incidentally, some magnetic cards have not only different magnetic coercive forces but also different thicknesses. If these magnetic cards can be recorded by a single magnetic card recording / reproducing device, a more convenient device can be provided. To realize this, first, a thickness sensor for detecting the thickness of the magnetic card, and contact pressure adjusting means for applying a predetermined pressure to the magnetic head that contacts the magnetic card according to the detected thickness of the magnetic card You just need to add In addition,
For the thickness sensor and the contact pressure adjusting means, the technology applied by the present applicant as Japanese Patent Application No. 9-29675 can be used.

On the other hand, a magnetic card recording / reproducing apparatus capable of coping with magnetic cards having different magnetic coercive forces can perform recording with a strong magnetic field and can record with a weak magnetic field. Focusing on this point, magnetic tapes with different magnetic coercive forces are superimposed in multiple layers, first recorded with a strong magnetic field,
If recording is sequentially performed with a weak magnetic field, it is possible to store information several times higher and to provide a magnetic card with enhanced confidentiality. In this case, separate magnetic signals may be extracted by modulating one or both of the magnetic tapes at different frequencies.

Also, instead of laminating magnetic tapes having different magnetic coercive forces in multiple layers, a magnetic tape formed by mixing and applying magnetic materials having different magnetic coercive forces may be attached, as described above. It is possible to provide a magnetic card that can store twice as much information and has high confidentiality.

[0038]

As apparent from the above description, according to the magnetic card recording / reproducing apparatus of the first aspect, there is an effect that one magnetic card having different magnetic coercive force can be recorded.

According to the magnetic card recording / reproducing apparatus of the second aspect, there is also an effect that the magnetic coercive force of the magnetic card can be reliably determined.

According to the magnetic card recording / reproducing apparatus of the third aspect, there is also obtained an effect that reliable recording according to the magnetic coercive force can be performed.

According to the magnetic card recording / reproducing apparatus of the fourth aspect, a new effect is obtained in that recording can be performed by one magnetic card even when the thickness of the magnetic card is different.

According to the magnetic card of the fifth or sixth aspect, an increase in the amount of information can be dealt with, and there is an effect of increasing confidentiality.

[Brief description of the drawings]

FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention.

FIG. 2 is a BH curve for explaining the operation of the embodiment shown in FIG. 1;

FIG. 3 is a diagram showing a relationship between an AC voltage, current, and time involved in recording / reproducing for explaining the operation of the embodiment shown in FIG. 1;

FIG. 4 is a diagram showing a relationship between a current peak value and time at the time of recording in order to explain the operation of the embodiment shown in FIG. 1;

FIG. 5 is a diagram showing a relationship between an AC voltage and time at the time of reproduction for explaining the operation of the embodiment shown in FIG. 1;

FIG. 6 is an exemplary flowchart showing a processing procedure when the microcomputer has main functions of the embodiment shown in FIG. 1;

FIG. 7 is a front view of the embodiment shown in FIG. 1;

FIG. 8 is a schematic configuration diagram of a conventional magnetic card recording / reproducing apparatus.

DESCRIPTION OF REFERENCE NUMERALS 1 core 2 coil 15 input / output unit 20 magnetic coercivity discriminating unit 21 pulse current supply unit 22 AC voltage detection unit 23 comparison unit 30 excitation current selection unit 31 switch selection unit 32 signal pulse generation unit 33, 36 switch 34 Current control means for low magnetic coercive force 35 Current control means for high magnetic coercive force

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FIG.

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[Document name to be amended] Drawing

[Correction target item name] Fig. 6

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──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification code FI G11B 5/09 361 G11B 5/80 5/80 G06K 19/00 B

Claims (6)

[Claims] 1. A magnetic card recording / reproducing apparatus for recording and reproducing magnetic information on a magnetic card, comprising: a magnetic holding device for determining a magnetic holding force of the magnetic card before recording magnetic information on the magnetic card; Force discriminating means, and exciting current selecting means for selecting an exciting current of a recording magnetic head used for recording the magnetic information from a plurality of preset values in accordance with a result of the discrimination by the magnetic holding force discriminating means. A magnetic card recording / reproducing device, comprising: 2. The magnetic coercive force discriminating means, comprising: a pulse current supplied to the recording magnetic head at a predetermined cycle with a pulse current having a peak value that changes substantially linearly with the elapse of time during which the magnetic card is conveyed. Supply means; AC voltage detection means for detecting an induced voltage of a reproducing magnetic head used for reproducing the magnetic information; and whether an output of the AC voltage detection means exceeds a reference value earlier than a predetermined time. And a comparing means for discriminating the magnitude of the magnetic coercive force, performing the operation of inserting and removing the magnetic card two times before and after, and the magnetic information by the pulse current supply means by the previous inserting operation. 2. The magnetic recording apparatus according to claim 1, wherein recording is performed, and voltage detection by said AC voltage detecting means and discrimination of magnitude of magnetic coercive force by said comparing means are performed by a later inserting operation. Card recording and reproducing apparatus. 3. An exciting current selecting means, comprising: a switch that is switched and connected in accordance with a result of the discrimination by the holding force discriminating means; and a recording current supplying means that supplies a current having a different magnitude in accordance with a connection state of the switch. The magnetic card recording device according to claim 1, further comprising: 4. A thickness sensor for detecting a thickness of the magnetic card, and a predetermined pressure applied to the recording magnetic head and the reproducing magnetic head in contact with the magnetic card in accordance with the detected thickness of the magnetic card. 4. A magnetic card recording apparatus according to claim 1, further comprising: a contact pressure adjusting means for applying a pressure. 5. A magnetic card in which a plurality of magnetic tapes each coated with a magnetic material having a different magnetic coercive force are stuck in layers. 6. A magnetic card formed by adhering a magnetic tape coated with a mixture of a plurality of types of magnetic materials having different magnetic coercive forces.