JP3398867B2 - Master information carrier and method of manufacturing magnetic recording medium using the same - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a master information carrier for transferring and recording a digital information signal on a magnetic recording medium by applying an external magnetic field in the superposed state to the magnetic recording medium. The present invention also relates to a method of manufacturing a magnetic recording medium having a digital information signal transferred and recorded using a master information carrier.

[0002]

2. Description of the Related Art First, as a reference, the historical background of technology will be described.

[Higher recording density and magnetoresistive element type head]
At present, the magnetic recording / reproducing apparatus tends to have a higher recording density in order to realize a small size and large capacity. In the field of hard disk drives, which are typical magnetic recording / reproducing devices, the areal recording density has already reached 15 Gbit / in ²
Devices exceeding (23.3 Mbit / mm ² ) have been commercialized, and in a few years, the areal recording density will be 40 Gbit / i.
It is recognized that the technical progress is rapid enough to predict the practical application of the n ² (62.0 Mbit / mm ² ) device.

As a technical background for enabling such a high recording density, the linear recording density is improved by the improvement of the performance of the magnetic recording medium and the head / disk interface and the advent of a new signal processing system such as partial response. Is mentioned. However, in recent years, the increasing tendency of the track density greatly exceeds the increasing tendency of the linear recording density, which is a main factor for the improvement of the areal recording density. This is due to the practical application of the magnetoresistive element type head, which is far superior in reproduction output performance to the conventional induction type magnetic head. At present, with the practical use of the magnetoresistive element type head, it is possible to reproduce a track width signal of several μm or less with a high S / N ratio. On the other hand, it is expected that the track pitch will reach the submicron region in the near future with further improvement in head performance.

[Tracking Servo Preformat Recording] In order for the magnetic head to accurately scan such a narrow track and reproduce a signal with a high S / N ratio,
The tracking servo technology of the magnetic head plays an important role. Regarding such tracking servo technology,
For example, “Yamaguchi: High-precision servo technology for magnetic disk devices, Journal of Japan Society for Applied Magnetics, Vol. 20, No. 3, p. 771, (19
96) ”for details. According to this document, in a current hard disk drive, a region where a servo signal for tracking, an address information signal, a reproduction clock signal, etc. are recorded at constant angular intervals during one round of the disk, that is, 360 degrees in angle ( A pre-format recording area) is provided. As a result, the magnetic head can reproduce these signals at a constant interval to confirm its own position and accurately scan the track while correcting the displacement in the radial direction of the magnetic disk as necessary. .

[Dedicated Servo Track Recording Device] The preformat information signals such as the tracking servo signal, the address information signal, and the reproduction clock signal described above serve as reference signals for the magnetic head to accurately scan the track. Therefore, at the time of recording, accurate track positioning accuracy is required. For example, "Uematsu and others: Mecha
According to the contents disclosed in the present state and prospects of servo and HDI technology, the 93rd Workshop of Applied Magnetics Society of Japan, 93-5, pp.35 (1996) ”, the present hard disk drive uses a magnetic disk and a magnetic disk. After the head is installed in the drive, a dedicated servo track recording device is used to record the tracking servo signal, address information signal, reproduction clock signal, etc. by the unique magnetic head installed in the drive. There is. In this case, the required track positioning accuracy is realized by performing preformat recording while precisely controlling the position of the unique magnetic head incorporated in the drive by the external actuator equipped in the servo track recording device. .

[Problems of Preformatted Recording by Magnetic Head] However, the conventional technology for performing preformatted recording by a unique magnetic head incorporated in a drive using a dedicated servo track recording device is as follows. There was a problem.

First, since recording by the magnetic head is basically line recording by relative movement of the magnetic head and the magnetic recording medium, a dedicated servo track recording device is used to precisely position the magnetic head. In the above method of recording while controlling, pre-format recording requires a lot of time. Further, since the dedicated servo track recording device is quite expensive, the cost required for preformat recording becomes high.

This problem becomes more serious as the track density of the magnetic recording / reproducing apparatus increases. In addition to the increase in the number of tracks in the radial direction of the disk, the time required for preformat recording also becomes long due to the following reasons. That is, the higher the track density, the higher the accuracy required for positioning the magnetic head. Therefore, the angular interval for providing a pre-format recording area (servo wedge) for recording an information signal such as a tracking servo signal in one round of the disk is set. Must be small. Therefore, the higher the recording density of the device, the greater the number of servo wedges, and the pre-format recording requires more time.

Further, although the magnetic disk medium tends to have a smaller diameter, there is still a great demand for a large diameter disk having a diameter of 95 mm or 84 mm. The larger the recording area of the disc, the larger the amount of signals to be preformatted for recording. The cost performance of such a large-diameter disk also greatly affects the time required for preformat recording.

Secondly, since the recording magnetic field spreads due to the spacing between the magnetic head and the magnetic recording medium and the shape of the tip pole of the magnetic head, the magnetization transition at the end of the preformat-recorded track ends. It lacks steepness.

Since recording by the magnetic head is basically dynamic line recording by relative movement of the magnetic head and the magnetic recording medium, from the viewpoint of interface performance between the magnetic head and the magnetic recording medium, There is no choice but to provide a certain amount of spacing between the magnetic head and the magnetic recording medium.
In addition, since the current magnetic head usually has a structure having two elements for separately recording and reproducing, the width of the trailing edge side pole of the recording gap corresponds to the recording track width.
The width of the pole on the leading edge side is several times larger than the recording track width.

Both of the above two problems are factors that cause the recording magnetic field to spread at the end of the recording track. As a result, there arises a problem that the magnetization transition at the end of the preformatted recording track is lacking in steepness, or an erase area is formed on both sides of the track end. In the current tracking servo technology, the position of the magnetic head is detected based on the amount of change in reproduction output when the magnetic head scans off the track. For this reason, not only is the magnetic head excellent in the S / N ratio when the magnetic head accurately scans over the track as when reproducing the data signal recorded between the servo areas, but also the magnetic head is off the track. It is required that the reproduction output change amount when scanning, that is, the off-track characteristic is steep. Therefore, if the magnetization transition at the end of the preformat-recorded track is not steep as described above, accurate tracking in submicron track recording becomes difficult.

A conventional master information carrier, which is a direct comparison object with the present invention, will be described below.

[Master Information Carrier] In order to solve the two problems in the preformat recording by the magnetic head as described above, a master information carrier having a ferromagnetic thin film pattern corresponding to the preformat information signal formed on the surface of the substrate is used. Japanese Patent Laid-Open No. 10-40544 proposes a technique for collectively recording a preformatted information signal on a magnetic recording medium. According to this preformat recording technique, good preformat recording can be efficiently performed without sacrificing other important performances such as the S / N ratio of the recording medium and the interface performance.

[Multiple Types of Digital Information Signals] By the way, if a magnetic transfer recording technique using a master information carrier proposed in Japanese Patent Laid-Open No. 10-40544 is used, not only preformatted information signals but also video and audio signals can be obtained. Various digital information signals such as AV (audio / visual) signals such as, and application program information executed by a personal computer or the like can be recorded in advance on a magnetic recording medium.

In recording such various digital information signals on a magnetic recording medium, for example, a master information carrier for recording video information or a master information carrier for recording an application program is manufactured. In some cases, it may be more convenient to magnetically transfer and record the digital information signal on the magnetic recording medium using separate master information carriers. In such a case, the digital information signal is magnetically transferred and recorded in another area on the magnetic recording medium on which the digital information signal is recorded.

Here, the digital information signal previously recorded on the magnetic recording medium is referred to as a first digital information signal, and the first digital information signal is recorded on the magnetic recording medium in advance. Then, the digital information signal to be recorded later will be referred to as a second digital information signal.

The magnetic transfer recording technique proposed in Japanese Patent Laid-Open No. 10-40544 discloses an "external magnetic field" in which a master information carrier on which a ferromagnetic thin film pattern corresponding to a digital information signal is formed and a magnetic recording medium are brought into close contact with each other. Is a technique for recording a digital information signal on a magnetic recording medium by applying "". In this publication, there is no concept of coexistent recording of plural kinds of digital information signals on the same magnetic recording medium.

[0020]

When simply applying the technique of the above-mentioned Japanese Patent Laid-Open No. 10-40544 to a new technique involving the concept of the first digital information signal and the second digital information signal, Due to the "application of an external magnetic field", the following inconveniences occur.

That is, the second digital information signal (eg, audio-visual signal) is recorded on the magnetic recording medium on which the first digital information signal (eg, preformatted information signal) is recorded in advance, and the arrangement pattern of the ferromagnetic thin films. The master information carrier having the form of is superposed. Then, by applying an external magnetic field to the master information carrier, the array pattern is transferred and recorded from the master information carrier to the magnetic recording medium as a magnetization pattern. In the method of manufacturing such a magnetic recording medium, if the technique of Japanese Patent Laid-Open No. 10-40544 is simply applied as it is, the second digital information signal is transferred to the magnetic recording medium due to the application of the external magnetic field. Although recorded, the first digital information signal previously recorded on the magnetic recording medium is, on the contrary, DC-erased by the external magnetic field.

This phenomenon is shown in FIG. When a second digital information signal 75b different from the first digital information signal 75a is recorded by magnetic transfer on the magnetic recording medium 71 on which the first digital information signal 75a is recorded in advance, the second digital information Master information carrier 7 on which ferromagnetic thin film pattern 73 corresponding to signal 75b is formed
Prepare 2. The master information carrier 72 and the magnetic recording medium 71 are brought into close contact with each other and a DC external magnetic field 74 is applied.
By applying the DC external magnetic field 74, the second digital information signal 75b is magnetically transferred and recorded on the magnetic recording medium 71.
However, conversely, the previously recorded first digital information signal 75a is erased from the magnetic recording medium 71.

This point will be described in detail below.

First, the basic mechanism of magnetic transfer will be briefly described.

The role of the ferromagnetic thin film in the master information carrier is to form an array pattern corresponding to the digital information signal, and in the magnetic transfer under the external magnetic field applied state, the magnetic flux due to the external magnetic field does not reach the magnetic recording medium. Is to secure. The magnetic part made of a ferromagnetic thin film must have a plurality of magnetic parts separated from each other at appropriate intervals in order to form an array pattern corresponding to a digital information signal.

When an external magnetic field is applied, the magnetic flux of the external magnetic field is significantly trapped in the magnetic portion and leaked to the outside in a region where the magnetic portions in the separated state are present, that is, the amount acting on the magnetic recording medium is significantly increased. Limited. On the other hand, in the region between the magnetic parts and where the magnetic part does not exist, all of the magnetic flux acts on the magnetic recording medium and magnetizes the region. That is, the magnetization pattern is transferred and recorded on the magnetic recording medium in a negative form of the pattern of the magnetic portion. The above is a brief description of the mechanism of magnetic transfer.

What becomes clear from the above description is that the magnetic flux acts on the magnetic recording medium to magnetize it in the region between the magnetic portions. If the region of the magnetic flux action magnetization is continuous without division, no pattern is formed. In order to form a pattern, a region in which magnetic flux action is prohibited must be secured between regions of magnetic flux action. The magnetic part actually fulfills that function. The magnetic portion plays a role of trapping the magnetic flux and preventing the magnetic flux from leaking to the outside, that is, the magnetic recording medium side.

In the transfer recording of the second digital information signal, the magnetic portion which plays a role of such magnetic flux trapping-ensuring of the magnetization prohibition area, with respect to the first digital information signal already recorded on the magnetic recording medium. The problem is that is not present.

Both the first digital information signal and the second digital information signal of different forms are recorded on the same magnetic recording medium.
Since the final form in which the digital information signals of the kind or more exist simultaneously in the magnetic recording medium is assumed, the recording area of the first digital information signal and the recording area of the second digital information signal are Must be a completely different area.

If the technique disclosed in Japanese Unexamined Patent Publication No. 10-40544 is simply applied as it is, when recording the first digital information signal and the second digital information signal on the magnetic recording medium, the master information is recorded. In the carrier, the ferromagnetic thin film does not exist other than the region of the array pattern of the ferromagnetic thin films formed in the shape corresponding to the second digital information signal. That is, in the formation area of the first digital information signal recorded in advance on the magnetic recording medium, there is no magnetic portion formed by the ferromagnetic thin film on the non-magnetic substrate.

The fact that there is no magnetic portion for the magnetic flux trapping-ensuring of the magnetization inhibition region for the first digital information signal means that the first digital information signal is directed in one direction by the application of an external magnetic field. That is, it is erased with the forced magnetization.

Therefore, in magnetically recording the second digital information signal, which is another digital information signal, on the magnetic recording medium on which the first digital information signal is recorded in advance, using the master information carrier, It is an important task not to erase the prerecorded first digital information signal.

The present invention has been made to solve the above problems, and is for magnetic transfer recording onto a magnetic recording medium by superimposing the first digital information signal on the magnetic recording medium previously recorded. Of the master information carrier having the second digital information signal, the second digital information signal can be recorded on the magnetic recording medium by magnetic transfer without erasing the prerecorded first digital information signal. The purpose is to

[0034]

In order to achieve the above object, a master information carrier of the present invention and a magnetic recording medium manufacturing method using the master information carrier are configured as follows.

The first digital information signal is recorded in advance on the magnetic recording medium. This does not matter as to how the first digital information signal was recorded on the magnetic recording medium. In the master information carrier,
An array pattern made of a ferromagnetic thin film corresponding to the second digital information signal is formed on the surface of the substrate. The master information carrier faces the magnetic recording medium and is superposed in a close contact state. At this time, the pattern area of the second digital information signal on the master information carrier is prevented from overlapping the recording area of the first digital information signal on the magnetic recording medium. This is because, in the magnetic recording medium, a state in which the first digital information signal and the second digital information signal are simultaneously and coexistently recorded is finally revealed. In the superposed state, an external magnetic field is applied to the master information carrier to transfer and record the second digital information signal on the master information carrier onto the magnetic recording medium.

As described above, with respect to the master information carrier used when manufacturing the magnetic recording medium, the present invention provides the recording area of the first digital information signal on the magnetic recording medium in the above-mentioned superposed state. A ferromagnetic shield film for magnetic shielding is formed on the base body of the master information carrier. The formation region of the ferromagnetic shield film is a region different from the pattern region of the second digital information signal.

In summary, the master information carrier of the present invention transfers the second digital information signal to the magnetic recording medium by superimposing it on the magnetic recording medium on which the first digital information signal is recorded and applying an external magnetic field. What is recorded is a master information carrier having an array pattern made of a ferromagnetic thin film corresponding to the second digital information signal formed on the surface of a substrate, wherein
In the area different from the pattern area of the digital information signal of
A ferromagnetic shield film for magnetically shielding the recording area of the first digital information signal on the magnetic recording medium is formed.

The operation of the above configuration for the master information carrier is as follows. Presence of a ferromagnetic shield film on the master information carrier when an external magnetic field is applied when transferring and recording the second digital information signal on the master information carrier to the magnetic recording medium on which the first digital information signal is recorded in advance. This makes it possible to protect the previously recorded first digital information signal from the erasing action by the external magnetic field. That is, finally, the state of simultaneous coexisting recording of the first digital information signal and the second digital information signal on the magnetic recording medium is obtained.

Further, in summary, the magnetic recording medium manufacturing method of the present invention is such that the magnetic portion formed of the ferromagnetic thin film has the second digital information on the magnetic recording medium on which the first digital information signal is recorded. the master information carrier having the arrangement pattern which is formed in a shape corresponding to the signal, the with magnetic portion side superposed so as to face the magnetic recording medium by applying an external magnetic field to the master information carrier, wherein A magnetic recording medium manufacturing method for transferring and recording the array pattern formed on a master information carrier as a magnetization pattern on the magnetic recording medium, wherein the first magnetic field on the magnetic recording medium is applied when the external magnetic field is applied.
Is characterized in that the external magnetic field is applied after magnetically shielding the recording area of the digital information signal from the external magnetic field.

In the invention of the method for manufacturing a magnetic recording medium, it is essential to magnetically shield the recording area of the first digital information signal when the external magnetic field is applied. The subject of magnetic shielding does not particularly matter. Like the master information carrier described above, a ferromagnetic shield film may be formed on the base body of the master information carrier, or a ferromagnetic shield film member separate from the master information carrier is prepared and its ferromagnetic Shield film member,
It may be inserted between the master information carrier and the magnetic recording medium by the stage of applying the external magnetic field at the latest.

The operation of the above-described structure of the magnetic recording medium manufacturing method is as follows. When the master information carrier is faced to the magnetic recording medium in which the first digital information signal is recorded in advance and superposed in a close contact state, and the second digital information signal on the master information carrier is transferred and recorded on the magnetic recording medium, When the external magnetic field is applied, the recording area of the first digital information signal on the magnetic recording medium is magnetically shielded from the external magnetic field, so that the first digital information signal recorded in advance on the magnetic recording medium is
It is possible to protect from the erasing action by the external magnetic field. That is, finally, the magnetic recording medium on which the first digital information signal and the second digital information signal are simultaneously and coexistently recorded can be manufactured well as expected.

In a preferred embodiment of the above-mentioned manufacturing method invention, the magnetic field is shielded when the external magnetic field is applied so that the recording area of the first digital information signal on the magnetic recording medium is magnetically shielded. The magnetic shield is formed by forming a ferromagnetic shield film on the master information carrier in advance and positioning the ferromagnetic shield film in the recording area of the first digital information signal at the time of the superposition.

In this case, the recording area of the first digital information signal on the magnetic recording medium can be covered with the ferromagnetic shield film on the master information carrier by superimposing the master information carrier on the magnetic recording medium. The number of steps can be reduced as compared with the case where a separate ferromagnetic shield film member is inserted.

In the final state of the magnetic recording medium, the relative positional relationship between the recording areas of the first digital information signal and the second digital information signal is extremely strict. During the superposition, the pattern area of the second digital information signal of the master information carrier is precisely positioned with respect to the recording area of the first digital information signal on the magnetic recording medium. Then, the magnetic shield also needs to be strictly aligned with the recording area of the first digital information signal.

However, by forming both the second digital information signal and the ferromagnetic shield film on the master information carrier in advance, the pattern area of the second digital information signal with respect to the recording area of the first digital information signal is formed. With the strict setting of the relative positional relationship of the above, it is possible to perform the strict alignment of the ferromagnetic shield film with respect to the recording area of the first digital information signal only by the setting without any other special measures. it can. Also in this sense, the number of steps can be reduced, and the productivity can be improved advantageously.

This advantage is not only in the magnetic recording medium manufacturing method, but also in the effect of the master information carrier.

Although partially repeated, in the invention of the above manufacturing method, the magnetic recording medium in which the first digital information signal is recorded in advance may be in any of the following two forms. One form is a magnetic recording medium in which the first digital information signal is recorded by the relative movement of the magnetic head with respect to the magnetic recording medium. Another form is a magnetic recording medium in which the first digital information signal is recorded by magnetic transfer accompanied by application of an external magnetic field in the same superposition state as described above, using another master information carrier. The latter is more preferable for increasing the recording density or for manufacturing a large-diameter magnetic recording medium.

In the above description, the expressions "first digital information signal" and "second digital information signal" are used.
This does not necessarily mean that there are two types of digital information signals simultaneously and co-existingly recorded on the same magnetic recording medium. For the magnetic recording medium on which the first and second digital information signals are recorded in advance,
It is also possible to include the case where the third digital information signal is recorded by magnetic transfer using another master information carrier. In this case, the previously recorded first and second digital information signals are replaced with the first digital information signal, and the third digital information signal to be transferred and recorded later is replaced with the second digital information signal. Shall be interpreted. The same applies to the fourth, fifth, etc. digital information signals.

Typical examples of the plurality of types of digital information signals are a preformat information signal for tracking servo, an audio / visual data signal, an application program information signal and the like.
It is arbitrary which of these digital information signals is the first digital information signal and which is the second digital information signal (and which is the third digital information signal).

[0050]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a master information carrier and a magnetic recording medium manufacturing method according to the present invention will be specifically described below with reference to the drawings.

In the embodiment of the present invention, the preformat information signals such as the tracking servo signal, the address information signal and the reproduction clock signal are the first digital information signals. Further, a data signal such as a video / audio signal is used as a second digital information signal. The master information carrier having the ferromagnetic thin film array pattern corresponding to the first digital information signal is used as the first master information carrier 12a, and the master thin film master pattern having the ferromagnetic thin film array pattern corresponding to the second digital information signal is used. Second information carrier
Of the master information carrier 12b.

Hereinafter, a method of transfer recording on the magnetic recording medium (magnetic disk) 11 using the first master information carrier 12a and the second master information carrier 12b will be described.

FIG. 2 shows an example of the structure of the magnetic recording medium 11. In conclusion, the first digital information signal 15a is recorded on the magnetic recording medium 11 at a predetermined angular interval and in a predetermined area, and the second digital information signal 15a is recorded between the recording areas of the second digital information signal 15a. The information signal 15b is about to be recorded.

FIG. 3 shows the first digital information signal 15a.
A configuration example of the first master information carrier 12a for transferring and recording the data on the magnetic recording medium 11 is shown. On the surface of the first master information carrier 12a, the first digital information signal 1
The first ferromagnetic thin film array pattern forming regions 13a corresponding to 5a are provided at predetermined angular intervals. FIG. 6 is an enlarged view of a region B which is a part of the first ferromagnetic thin film array pattern forming region 13a.

As shown in FIG. 6, the ferromagnetic thin film patterns corresponding to the tracking servo signal, the address information signal, and the reproduced clock signal are arranged in order. In FIG. 6, the hatched portion is made of a ferromagnetic material such as Co. First master information carrier 1
Regarding the method of forming a ferromagnetic thin film pattern on the surface of 2a, JP-A-10-40544 and JP-A-10-2
The technical contents described in Japanese Patent Publication No. 69566 can be referred to. Here, detailed description is omitted.

FIG. 4 shows that the first ferromagnetic thin film array pattern forming region 13a on the first master information carrier 12a is the first
The situation in which magnetic transfer recording is performed on the magnetic recording medium 11 as the digital information signal 15a is shown.

FIG. 5 shows the second digital information signal 15b.
An example of the configuration of the second master information carrier 12b for transferring and recording the data is shown. On the surface of the second master information carrier 12b, a second digital information signal 15b corresponding to the second digital information signal 15b is formed.
The ferromagnetic thin film array pattern forming regions 13b are provided at predetermined angular intervals. Further, a ferromagnetic shield film 13c is formed between the second ferromagnetic thin film array pattern forming regions 13b.

The ferromagnetic shield film 13c is the first digital data recorded in advance on the magnetic recording medium 11 when the magnetic recording medium 11 and the second master information carrier 12b are faced to each other and superposed on each other. Information signal 15a
Is formed in a region corresponding to the recording region of. The above publication can also be referred to for the method of forming the second ferromagnetic thin film array pattern forming region 13b and the ferromagnetic shield film 13c on the surface of the second master information carrier 12b. It is the same method as when forming the ferromagnetic thin film pattern of the first digital information signal 15a on the surface of the first master information carrier 12a.

FIG. 1 is a schematic sectional view schematically showing each step of a magnetic recording medium manufacturing method according to an embodiment of the present invention. In this case, the first digital information signal 15a is transferred and recorded on the magnetic recording medium 11, and then the second digital information signal 15b is transferred and recorded on the magnetic recording medium 11. That is, a case where the method for recording the first digital information signal 15a on the magnetic recording medium 11 is the magnetic transfer recording method will be described.

FIG. 1 shows a cross section of the magnetic recording medium 11 taken along the alternate long and short dash line AA shown in FIG. 2. In this portion, the first digital information signal 15a is magnetically transferred by using the first master information carrier 12a. The method of recording on the recording medium 11 and then recording the second digital information signal 15b on the magnetic recording medium 11 using the second master information carrier 12b is briefly shown.

First, as shown in FIG. 1A, a DC external magnetic field 14a parallel to the surface of the magnetic recording medium 11 is applied to the surface of the magnetic recording medium 11 to erase the DC of the magnetic recording medium 11.
As a means for applying the DC external magnetic field 14a, a permanent magnet or an electromagnet can be used. Arrow 15 in FIG. 1 (a)
Indicates the direction of magnetization in the magnetic recording medium 11.

Next, as shown in FIG. 1B, the first digital information signal 15a is magnetically transferred and recorded on the magnetic recording medium 11 using the first master information carrier 12a. The magnetic recording medium 11 and the first master information carrier 12a are brought into close contact with each other in a facing state. That is, the surface of the first master information carrier 12a on which the first ferromagnetic thin film array pattern forming region 13a is located is superposed and closely attached to the magnetic recording medium 11.

In the superposed contact state, the DC external magnetic field 14b is applied to the first master information carrier 12a. The method of applying the DC external magnetic field 14b is the same as the magnetic recording medium 1
It is possible to use the magnetic field applying means used when erasing DC in No. 1. The direction of the DC external magnetic field 14b is opposite to that of the DC external magnetic field 14a applied when the DC is erased.
In this way, first the first digital information signal 15a
Is recorded on the magnetic recording medium 11.

Next, the second digital information signal 15b is transferred and recorded on the magnetic recording medium 11 on which the first digital information signal 15a is recorded. As shown in FIG. 1C, the second digital information signal 15b corresponding to the second
The second master information carrier 12b on which the ferromagnetic thin film array pattern forming region 13b and the ferromagnetic shield film 13c are formed is brought into close contact with the magnetic recording medium 11. At this time, the second ferromagnetic thin film array pattern forming region 13b is
The second digital information signal 1 in the magnetic recording medium 11
5b is accurately aligned with a predetermined position to be recorded. The position is a portion between the recording areas of the first digital information signal 15a.

At this time, the ferromagnetic shield film 13
The c is in close contact with the magnetic recording medium 11 so as to cover the recording area of the first digital information signal 15a recorded on the magnetic recording medium 11.

Finally, as shown in FIG. 1D, a DC external magnetic field 14c is applied to the second master information carrier 12b. As the method of applying the DC external magnetic field 14c, the magnetic field applying means used when the magnetic recording medium 11 is DC erased can be used.

At this time, the direction of the DC external magnetic field 14c is
The polarity is opposite to that of the DC external magnetic field 14b in the case of FIG. 1B applied when the first digital information signal 15a is transferred and recorded.

Here, the directionality of the external magnetic field at the time of magnetic transfer recording of the digital information signal will be supplementarily described.

By applying the DC external magnetic field 14a shown in FIG. 1A, the magnetization direction 15 in the magnetic recording medium 11 is the same as the DC external magnetic field 14a. As shown in FIG. 1B, the direction of the DC external magnetic field 14b applied in the magnetic transfer recording of the first digital information signal 15a is as shown in FIG.
Must have a polarity opposite to the magnetization direction 15.
At this time, by applying the DC external magnetic field 14b, the direction 16 of magnetization in the area where no signal is recorded between the first digital information signals 15a in the magnetic recording medium 11 is as shown in FIG.
In the case of (a), the magnetization direction 15 is reversed. With the same reasoning as above, as shown in FIG.
The direction of the DC external magnetic field 14c applied in the magnetic transfer recording of the second digital information signal 15b must have a polarity opposite to the magnetization direction 16 of FIG.

As shown in FIG. 1D, the second digital information signal 15b is recorded on the magnetic recording medium 11 by applying the DC external magnetic field 14c to the second master information carrier 12b. Here, the first that was already recorded
The digital information signal 15a is not erased by the DC external magnetic field 14c. This is the ferromagnetic shield film 13 formed on the second master information carrier 12b.
This is because the DC external magnetic field 14c is prevented from leaking onto the magnetic recording medium 11 by c.

After the first digital information signal 15a is transferred and recorded on the magnetic recording medium 11 as described above, the second digital information signal 15a is not erased by the DC external magnetic field 14c. The signal 15b can be transferred and recorded on the magnetic recording medium 11.

As described above, in the present embodiment, the first digital information signal 15a is first transferred and recorded on the magnetic recording medium 11, and then the second digital information signal 15b is transferred and recorded. Second digital information signal 1
The second master information carrier 12b used when transferring and recording 5b has a second ferromagnetic thin film array pattern forming region 13b corresponding to the second digital information signal 15b, and also has a second ferromagnetic thin film. Array pattern forming area 13
A ferromagnetic shield film 13c is formed between b. The ferromagnetic shield film 13c has the first digital information signal 15a already recorded on the magnetic recording medium 11 when the magnetic recording medium 11 and the second master information carrier 12b are faced to each other and superposed in a close contact state. Is formed in a region corresponding to the position of. It is possible to further record the second digital information signal 15b on the magnetic recording medium 11 by making the second master information carrier 12b and the magnetic recording medium 11 face each other and superposing them in close contact with each other and applying the external magnetic field 14c. it can. Due to the effect of the ferromagnetic shield film 13c formed on the second master information carrier 12b, the first digital information signal 15a is transferred to the external magnetic field 1
It is not erased by 4c.

In this embodiment, the first digital information signal 15a is previously recorded on the magnetic recording medium 11.
For recording the first master information carrier 12
Although the transfer recording method using a is adopted, the present invention is not limited to this method. Magnetic recording medium 11
The first digital information signal 15a may be recorded on the magnetic recording medium 11 by relative movement of the magnetic head with respect to.

Further, after the second digital information signal 15b is transcribed and recorded, another signal is transcribed and recorded.
The same method can be used in the case where a plurality of types of signals are transferred and recorded a plurality of times by using different master information carriers.

[0075]

As described above, the magnetic recording medium on which the first digital information signal is previously recorded is further provided with the master information carrier having the shape pattern of the ferromagnetic thin film corresponding to the second digital information signal. It becomes possible to newly transfer and record the second digital information signal without erasing the first digital information signal.

According to the present invention concerning the master information carrier, when the second digital information signal on the master information carrier is transcribed and recorded on the magnetic recording medium on which the first digital information signal is recorded beforehand, the external magnetic field is applied. When applied, the presence of the ferromagnetic shield film on the master information carrier can protect the first digital information signal from the erasing action by the external magnetic field, and finally, the first digital information on the magnetic recording medium. Signal and second
It is possible to obtain the state of simultaneous coexisting recording with the digital information signal of.

Further, according to the present invention regarding the method of manufacturing the magnetic recording medium, since the recording area of the first digital information signal on the magnetic recording medium is magnetically shielded from the external magnetic field,
A magnetic recording medium capable of protecting the first digital information signal from the erasing action by an external magnetic field, and finally recording the first digital information signal and the second digital information signal in a coexisting manner. It can be manufactured satisfactorily as expected.

[Brief description of drawings]

FIG. 1 is a sectional view schematically showing each step of a magnetic recording medium manufacturing method according to an embodiment of the present invention.

FIG. 2 is a plan view schematically showing the structure of a magnetic recording medium manufactured by a magnetic recording medium manufacturing method according to an embodiment of the present invention.

FIG. 3 is a plan view schematically showing the structure of a first master information carrier for transferring and recording a first digital information signal (preformat information signal) according to the embodiment of the present invention.

FIG. 4 is a plan view schematically showing the structure of the magnetic recording medium on which the first digital information signal is recorded in the magnetic recording medium manufacturing method according to the embodiment of the present invention.

FIG. 5 is a second for transferring and recording a second digital information signal (data signal) according to the embodiment of the present invention.
Plan view schematically showing the structure of the master information carrier of FIG.

6 is an enlarged view showing an example of a ferromagnetic thin film pattern corresponding to a first digital information signal formed on the surface of the master information carrier of FIG.

FIG. 7 is a cross-sectional view schematically showing a method for transferring and recording another digital information signal to a magnetic recording medium on which a digital information signal is recorded in advance, using a conventional master information carrier.

[Explanation of symbols]

11 magnetic recording medium (magnetic disk) 12a first master information carrier 12b second master information carrier 13a first ferromagnetic thin film array pattern forming region 13b second ferromagnetic thin film array pattern forming region 13c ferromagnetic shield film 14a DC external magnetic field 14b DC external magnetic field 14c DC external magnetic field 15a First digital information signal (preformatted information signal) 15b Second digital information signal (data signal)

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Claims (5)

(57) [Claims] 1. A second digital information signal is transferred and recorded on the magnetic recording medium by applying an external magnetic field to the magnetic recording medium on which the first digital information signal is recorded, and the second digital information signal is transferred and recorded on the magnetic recording medium. A master information carrier having an array pattern formed of a ferromagnetic thin film corresponding to a second digital information signal, wherein the master information carrier comprises:
A ferromagnetic shield film for magnetically shielding the recording area of the first digital information signal on the magnetic recording medium is formed in an area different from the pattern area of the second digital information signal. Master information carrier to be used. 2. A master having a magnetic recording medium on which a first digital information signal is recorded, having an array pattern in which a magnetic portion made of a ferromagnetic thin film is formed in a shape corresponding to the second digital information signal. an information carrier, wherein together with the magnetic portion side superposed so as to face the magnetic recording medium by applying an external magnetic field to the master information carrier, the arrangement pattern formed on the master information carrier as a magnetic pattern A method of manufacturing a magnetic recording medium for transfer recording to the magnetic recording medium, wherein, when the external magnetic field is applied, a recording area of the first digital information signal on the magnetic recording medium is magnetically shielded from the external magnetic field. The method of manufacturing a magnetic recording medium, wherein the external magnetic field is applied according to the method. 3. The master information carrier is formed in advance so as to magnetically shield the recording area of the first digital information signal on the magnetic recording medium in order to perform magnetic shielding when applying the external magnetic field. 3. The method of manufacturing a magnetic recording medium according to claim 2, wherein the magnetic shield is performed by positioning a ferromagnetic shield film in the recording area of the first digital information signal at the time of the superposition. 4. A magnetic recording medium on which the first digital information signal is recorded is used as the magnetic recording medium on which the first digital information signal is recorded, by relative movement of a magnetic head with respect to the magnetic recording medium. The method of manufacturing a magnetic recording medium according to claim 2, wherein 5. A magnetic recording medium on which the first digital information signal is recorded, another master information carrier is used, and the first magnetic recording medium is magnetically transferred by applying an external magnetic field in the same superposition state as described above. 4. The method of manufacturing a magnetic recording medium according to claim 2, wherein the magnetic recording medium on which the digital information signal of 1 is recorded is used.