DE3931374A1 - Magnetic disc system and head unit - with coil windings embedded in insulator to provide high track density and good signal to noise ratio - Google Patents

Abstract

A thin film magnetic head that provides a high signal to noise ratio is used for disc recording with track densities of 1800 tracks per inch or better. The head unit has a base plate (100) with a film (200) that supports a lower magnetic pole piece (300), separated by a gap (G) from an upper pole piece (400). The gap region is provided by an insulator into which is embedded the windings (500) of a coil. The upper and lower magnetic pole pieces have widths of that are related to the track density by the difference in values being less than or equal to 5000/Tr, where Tr is the track density. ADVANTAGE - Improves track density and signal to noise ratio.

Description

The invention relates to a magnetic disk device and a Information recording and reproduction method, more precisely a magnetic disk device as external storage of a primary device, a computer, for example, a thin film magnetic head in this magnetic disk device and a method of information record and play back on this device.

An increase in storage capacity is usually also possible an increase in track density on the magnetic disk.

For this reason, the track width at the ends of the Magnetic poles of the thin film magnetic head reduced.

In a thin film magnetic head, an upper and a lower form Magnetic core a magnetic circuit. He owns one with an insulating film made of non-magnetic material filled gap at the ends of the magnetic cores, that of the magnetic disk are facing.

For writing on the recording medium, a magnetic disk for example, or for reading the magnetic circuit is activated.

The magnetic state of the recording medium that the Recording density is determined by the size of the magnetic field determined in the gap.

One of the main factors affecting the recording density determine a magnetic disk device is the design of the upper and lower magnetic poles of the thin film magnetic head at the ends facing the magnetic plate.

The design of these magnetic pole pieces is therefore of have been studied from various points of view.

The difference in width between the top and the lower magnetic pole piece has not been noticed very often.  

In USP 42 19 855 and in Shingaku Giho, Vol. 85, No. 137, MR85-22 (1985), but is referred to. The label Width of the magnetic pole pieces or tips denotes the lateral extension of the pole ends on the recording medium facing surface when recording or playback. they becomes relative perpendicular to the direction of movement of the magnetic head measured to the recording medium.

USP 42 19 855 describes that an undesirable magnetic field shape, which is referred to as "wraparound" and due to manufacturing non-uniformity, can be avoided if the width of the upper magnetic core is made narrower than that of the lower one.

In Shingaku Giho, Vol. 85, No. 137, MR85-22 (1985) a computer simulation used to show the relationship between the difference in the width of the upper and lower magnetic pole piece and the strength of the magnetic field in the peripheral zones to examine on both sides of the magnetic pole pieces. In this description becomes the expression magnetic boundary zone field ("Magnetic Fringe Field") or fringe flow ("Fringe Flux ") used to separate the part of the magnetic field or To denote flux through the magnetic head in the strip is generated that is slightly across the width of the magnetic pole pieces go out.

The latter literature describes that the magnetic Edge zone field the read / write properties unfavorable influenced and that therefore the difference between the width the upper and lower magnetic pole pieces should be zero. The Border zone field is also disclosed in "Magneto-Optic Determination of Magnetic Recording Head Fields "by Mark E. Re et al. in IEEE Transaction on Magnetics, Vol. Mag. 22, No. 5, September 1986.

The state of the art in USP 42 19 855 Technology does not indicate how large the difference mentioned in the Width should be between the upper and lower magnetic pole piece, to get a magnetic field distribution that is for an increase the recording density is favorable.

Furthermore explains the in the mentioned literature Shingaku Giho, Vol. 85, No. 137, MR85-22 (1985)  State of the art in no way that the magnetic fringe field actually improves the read / write properties, when the track width becomes smaller.

Furthermore, none of the two mentioned on the prior art Writings of knowledge known for an optimal relationship between the track density on the magnetic disk and the difference the widths of the upper and lower magnetic pole pieces, the to an increase in the recording density of the magnetic disk device is optimized.

Accordingly, it is an object of the invention to Relationship between the track density on the magnetic disk and an optimal value for the difference in widths from the top and clarify the lower magnetic pole piece. With this in mind clarified condition is to provide a magnetic disk device in which the signal-to-background ratio is increased and the secondary track properties can be improved. The secondary track property ("Off-Track Characteristic") denotes the maximum permissible deviation of the magnetic head position from the Position exactly opposite the recording track at which the recorded information can still be read correctly can.

Another object of the invention is the condition for the contour of the parts of the magnetic core of a thin-film magnetic head, especially in a magnetic disk device with a Track density of 1800 TPI (1800 tracks per inch, accordingly 709 tracks per cm) or more is used on the recording medium to clarify facing free area. A magnetic disk device with a thin film magnetic head that meets these conditions fulfilled, should be provided.

Another object of the invention is advantageous Construction methods of a thin film magnetic head and a magnetic plate to clarify that in a magnetic disk device with a Track density of 1800 or more TPI can be used and the Thin film magnetic head and the magnetic disk according to this advantageous To provide construction.

Another object of the invention is to use of the magnetic disk device with the track density of 1800 or more TPI to provide a recording system.  

Another object of the invention is a method for information recording and playback on a magnetic disk device of the type specified above.

According to the present invention, the magnetic disk device comprises a magnetic disk for information recording, a thin film magnetic head for writing and reading the Information on or from the magnetic disk, a disk drive and means for positioning the thin film magnetic head.

The drawing represents preferred embodiments of the Invention represents

Fig. 1 is a schematic representation of a magnetic disk apparatus according to an embodiment of the invention,

Fig. 2A and 2B, the design of the contour of the surface facing the magnetic disk side seen from an embodiment of the magnetic pole pieces, as used in the thin film magnetic head,

Fig. 3 shows the design of the contour of the magnetic pole pieces according to another embodiment of the invention,

FIGS. 4A, 4B and 4C, the magnetic field intensity on the given by the extension of the gap axis,

Fig. 5 shows the relationship of the signal intensity and the background intensity to the width difference of upper and lower magnetic pole piece,

Fig. 6 shows the dependence of the signal-to-background ratio of the difference in width of the upper and lower magnet pole piece,

Fig. 7 shows the relationship between the reciprocal of the track density and the limit value for the width difference of upper and lower magnetic pole of the thin film magnetic head,

Fig. 8 shows a further embodiment of the design of the contour of the magnetic pole pieces according to the invention,

Fig. 9 is a front view showing a common configuration of the contour of the magnetic pole of a thin film magnetic head,

Fig. 10 is a partial illustration of the position of the track on the magnetic disk and the thin film magnetic head to each other,

Fig. 11 is a perspective view of the construction of a thin film magnetic head.

In the following, the invention will now be described with reference to the figures illustrated embodiments described and closer explained.

Fig. 9 shows an example in an enlarged form on the side facing the recording medium free surface contours of magnetic pole of a thin film magnetic head, as used in a magnetic disk device, and a magnetic gap between the magnetic pole pieces.

An upper magnetic pole piece 21 has an edge with the length C _WU (μm) along a magnetic gap 22 . A lower magnetic pole piece 23 has an edge along the magnetic gap 22 with the length C _WD (μm). The terms "top" and "bottom" are used as seen when the magnetic head is held with its base plate down.

Under the condition that the track density (Tr) of the magnetic disk is 1800 TPI or more, the difference (Δ C _W) between C and C _{WU WD} is sufficient in the present invention the following relationship:

0 < Δ C _W ≦ 5000 / Tr (µm).

In addition, the larger of the two values C _WU and C _{WD must be} smaller than the track spacing of the magnetic disk and larger than the track width.

Assuming that C _{WU is} the smaller value, the track pitch and track width of the magnetic disk are shown in Fig. 10.

The track width is provided with the reference symbol 50 and stands for the width over which information is recorded on the magnetic disk and which is determined by the smaller of the two lengths C _WU and C _WD . In Fig. 10, 56 denotes a center line of a strip between two adjacent tracks, which is called a security strip. The two parts labeled 55 in FIG. 10 are each halves of the security strip. The track spacing of the magnetic disk is denoted by 51 and stands for a width which is composed of the track width 50 and the width of the security strip, which is provided as a protective zone in order to prevent information from overlapping on adjacent tracks.

The upper magnetic pole piece is designated in Fig. 10 with 52 , the lower with 53 and the magnetic gap with 54 .

Under the above condition for the dimensions the signal-to-background ratio turns out to be high, and the secondary track properties are improved.

The present invention is therefore based on the idea that the contours of the magnetic pole pieces with high accuracy Agreement with the track density must be determined to increase the signal-to-background ratio and the secondary tracking properties also in the event that the track density increases will improve.

The optimal range of Δ C _W that satisfies the above relationship may be valid even if the magnetic disk has a track density that is not more than 1800 TPI.

If the track density is low, the signal-to-Substrate is the magnetic disk apparatus strongly determined ratio of factors other than Δ C _W, and there was in the past is no need to prescribe values for Δ C _W firmly.

For a track density of 1800 TPI or more, however, it has been found that the value of Δ C _W influences the signal-to-background ratio of the magnetic disk memory very strongly.

The track spacing of a magnetic disk in a magnetic disk device with high recording density and a track density of 1800 TPI or more is approximately 14 µm.

In accordance with this, the contours of the magnetic pole pieces of the thin film magnetic head facing the magnetic disk free space to be small for information recording to be adapted. Otherwise it would be between neighboring ones Traces of crosstalk occur, the signal-to-background Reduce ratio and accurate reproduction of information prevent.  

In particular, because of the security strip, the track width, which corresponds to the smaller value of C _WU and C _WD and is an important factor for information recording, must be smaller than the track spacing of the magnetic disk.

The manufacturing process, however, lays down the reduction of Size of the magnetic pole pieces restrictions, and too small Magnetic pole pieces endanger the reading of the information.

In view of the importance of the dimensions of the contour of the magnetic core under these circumstances and the positioning accuracy of the magnetic disk device, the inventors have come to the idea that the value C _{WU should} differ from C _WD and that the edge zone magnetic field which arises due to this difference is advantageously used shall be.

The values C _WU and C _WD must be precisely defined in order to generate a precisely controlled edge zone magnetic field. The edge zone magnetic field that arises due to their difference is used to write information over a large area and thereby improve the secondary track properties.

The effect of the present invention is based on magnetic edge zone fields on the regions adjacent to the two lateral ends of the two magnetic pole pieces. Therefore, the difference ( Δ C _W ′) between each of the lateral edges of one side of the upper ( C _WU ) and lower ( C _WD ) magnetic pole piece along the magnetic gap satisfies the following relation:

0 < Δ C _W ′ ≦ 2500 / Tr (µm).

As in the case of the relationship previously described for the Dimensions, it turns out that this relationship is the signal to underground ratio increased and the secondary track properties improved.

Considering the manufacturing process, the lower limit of Δ C _W in practice can preferably be 0.2 µm and the lower limit of Δ C _W 'can preferably be 0.1 µm.

It was also demonstrated that the upper magnetic pole piece preferably essentially symmetrical with respect to the central,  axis of symmetry running in writing and reading direction of the lower magnetic pole piece is to be arranged to be uniform generate magnetic fields in the areas run into the lateral ends of the two magnetic pole pieces.

On the other hand, both the track density and the linear recording density can be increased to the total recording density to improve a magnetic disk device.

Because the signal-to-background ratio decreases with increasing linear recording density, precise control of the values of Δ C _W or Δ C _W 'as prescribed in the present invention is of great importance.

It is found that the linear recording density is preferred Should be 12 or more kilo bits per centimeter.

Furthermore, it turns out that the surface recording density preferably 8.4 or more mega bits per square centimeter should be.

As described above, the increased signal-to-background Ratio and the improved secondary track property for ensure a high recording density of the magnetic disk device, by making the length difference between the sides along the magnetic Gaps between the upper and lower magnetic pole piece exactly controlled and kept in an optimal range.

On the other hand, the magnetic boundary zone field changes depending on the width of the sides of the magnetic pole pieces and depending on the angles on the transverse sides. This Context has been investigated by the inventors.

It has been shown that the angle ( R _S ) between the end edge of the magnetic pole pieces and the side facing the magnetic gap is preferably in the range

45 ° ≦ R _S ≦ 150 °

should be observed in order to form an effective magnetic boundary zone field. This applies to that of the upper or lower magnetic pole piece, the side ( C _WU or C _WD ) of which is shorter along the magnetic gap.

For R _S <45 °, the magnetic core and its edge become magnetically saturated, and as a result, an effective magnetic field cannot be generated during writing, and the signal-to-background ratio during reading is reduced.

For R _S <150 °, the track width is increased considerably, and an effective magnetic field cannot be generated either.

It has also been shown that the angle ( R _L ) between the end edge of the magnetic pole piece and its side along the magnetic gap is preferably in the range

91 ° ≦ R _L ≦ 150 °

should be observed in order to obtain an effective magnetic boundary zone field. This applies to that of the upper or lower magnetic pole piece that has the longer edge ( C _WU or C _WD ) along the magnetic gap.

It has also been shown that the effect can be increased if the most favorable ranges of the angles R _S and R _L are observed at the same time.

In this way, an effective magnetic fringe field generated to the secondary track property and that Improve crosstalk behavior when reading.

Although an example in which C _{WU is} shorter than C _{WD was} chosen in the arrangement of the magnetic cores shown in FIG. 9, the effect of the invention is in no way impaired if C _{WU is} longer than C _WD .

However, in the practical manufacturing process of a magnetic head having a length C _WU longer than C _WD , non-magnetic insulating members having the same thickness as the lower magnetic pole piece have to be placed adjacent to both of its lateral ends in order to obtain parallel, flat surfaces and the state of encompassing the outside Avoid magnetic field.

In order to form the non-magnetic insulating elements, a complicated manufacturing step is required. Therefore, C _{WU is} preferably shorter than C _WD .

In a thin film magnetic head, a conductive coil and the insulation film form a step with a height of 10 to 20 µm, and the upper magnetic pole piece is usually structured and machined on its lower part adjacent to the step so that the side length ( C _WU ) along the magnetic Gap results.

The value of C _WU can be controlled by this profile formation method so that it interacts well with the side length value C _WD along the magnetic gap of the lower magnetic pole piece to achieve the effect of the invention. However, in the practical manufacturing process, it is difficult to manufacture the magnetic core with high accuracy at its lower part adjacent to the step portion.

Under these circumstances, as an exemplary embodiment of the invention, a magnetic pole piece with a contour as shown in FIG. 3 was invented, in which the magnetic core produces a dimensionally accurate track width and a high track density can thus be achieved.

In this embodiment 31 has an upper magnetic pole piece a middle portion (in Fig. 3 with a) having a side length C _WU which is to Δ C _W shorter than the side length C _WD of a lower magnet pole piece 33 along a magnetic gap 32, and lateral Portions (denoted by b in Fig. 3) extending in a direction away from the lower magnetic pole piece.

How the thin film magnetic head having the shape shown in Fig. 3 is manufactured will now be described.

First the lower magnetic pole piece is manufactured and then a non-magnetic insulating layer that both sides and covered both side edges, so deposited that above a recess remains on the lower magnetic pole piece.

Then the recess is closed with a magnetic gap Film covered and the upper magnetic film deposited on this.

In the case of a thin-film magnetic head with the contour shown in FIG. 3, the track width of the magnetic pole piece is determined by the value C _WU . In this arrangement, the height of the step can be minimized and the length C _{WU can} be controlled with high accuracy.

As in the case of the thin film magnetic head with the arrangement shown in Fig. 9, it has also been shown here that for a magnetic disk device having a track density of 1800 TPI or more, the value Δ C _{W of} the condition

0 < Δ C _W ≦ 5000 / Tr (µm)

should be enough.

It was also shown that the difference Δ C _W 'between the central portion a of the upper magnetic pole piece 31 and each of the two lateral ends of the lower magnetic pole piece 33 is preferably the condition

0 < Δ C _W ′ ≦ 2500 / Tr (µm)

should be enough.

In practice, considering the manufacturing process, the lower limit of Δ C _{W should} preferably be 0.2 µm and that of Δ C _W 'should preferably be 0.1 µm.

Furthermore, considering the desire that the upper magnetic pole piece 31 and the lower magnetic pole piece 33 should be arranged symmetrically to the axis in the read / write direction, and that the linear recording density 12 or more kilo-bits per centimeter and the area recording density 8.4 or should be more mega bits per square centimeter, shown that the angle at the end edge of the upper magnetic pole piece (labeled R _S in Fig. 3) and the angle at the end edge of the lower magnetic pole tip (labeled R _L in Fig. 3) are preferred the following condition should be met:

45 ° ≦ R _S ≦ 150 °

91 ° ≦ R _L ≦ 150 °

To achieve a high recording density, the magnetic part, i.e. the recording medium on the  Magnetic plate has a high coercive force and a small thickness have.

In view of the effect of the invention, the magnetic Layer has a coercive force of 48,000 A / m or more and have a thickness of 0.35 µm or less.

With the aim of a sufficiently high, effective magnetic field to generate with the magnetic head, the magnetic pole pieces can each preferably from a single layer film with a saturation magnetic flux density from a Tesla or more or from one multilayer film of the same saturation magnetic flux density, with one or more non-magnetic films interposed be made, and the number of turns of the conductor coil can be 18 or more.

To the efficiency of writing and reading on the magnetic disk to increase and so a high recording density reach, the flying height of the magnetic head must be minimized. According to the invention, it can preferably be 0.25 μm or be less.

In the thin film magnetic head of the invention described above is the difference between the widths of the upper and lower magnetic pole piece optimized to the best combination of fringe magnetic field when writing and underground reduced zone to achieve when reading. This ensures that the Signal-to-background ratio of the magnetic disk device increased and the side lane behavior can be improved.

Accordingly, the effect of the present invention be improved if the thin-film magnetic head works inductively and read and write head are identical.

However, even if the thin film magnetic head, for example is realized as a mixed type, which is inductive when writing and acts as a magneto-resistance head when reading (MR- Type), the teachings of this invention can at least be based on the writing part of the thin film magnetic head are used, and the effect desired by the invention can be obtained.

Because the present invention is based on the relationship between the structure of the magnetic pole pieces of the thin film magnetic head and the recording density of the magnetic disk device that with this  Head works, based, the invention places the manufacturing process of the thin film magnetic head no restriction on.

However, as for the structure, the location of the ends of the magnetic pole pieces precisely, so this should preferably by dry or wet etching one by sputtering shaped magnetic device happen, as in M. Hanazono et al., "Design and Fabrication of Thin-Film Heads Based on a Dry Process ", J. Appl. Phys., Vol. 61, No. 8, pp. 4157-4162 (1987), or by selective metallization under Using a photoresist mask. As in R.E. Jones Jr., "IBM 3370 Film Head Design and Fabrication", IBM Disk Storage Technology, February 1980, pp. 6-9.

In addition, in a thin film magnetic head for use in a magnetic disk device of this type, the value Δ C _{W of} the relationship should be

0 < Δ C _W ≦ 5000 / Tr

are sufficient, where Tr denotes the track density of the magnetic disk.

A recording system using the magnetic disk device can be connected to a primary device, such as a computer, be connected to a system with large storage capacity to provide.

As previously stated, the invention clarifies the conditions the design of the contour of the magnetic pole pieces Thin film magnetic head on the storage medium facing must be made available for use in a free area Magnetic disk device with high storage density and a magnetic disk with a track density of 1800 or more TPI.

Specifically, the difference between the length C _{WU of} the upper magnetic pole piece and C _{WD of} the lower magnetic pole piece along the magnetic gap is optimized in accordance with the track density of the magnetic disk of the magnetic disk device in order to increase the signal-to-background ratio and to improve the secondary tracking properties, even if the recording density is high.

Using the thin film magnetic head having a lower and an upper magnetic pole piece, the contours of which on the side facing the recording medium are shaped as shown in Fig. 4A, the inventors examined the intensity of the magnetic field generated by the magnetic pole pieces. The results of measuring the longitudinal magnetic field of the recording medium at a point on the extension line of the magnetic gap in the Z direction ( Fig. 4A) in the height at which the head hovers over the recording medium ( Fig. 4B) that the intensity decreases as the distance increases in the Z direction. The results also show that the distance in the Z direction, at which a certain value Ha of the magnetic field intensity is assumed, increases as the difference Δ C _W between C _WU and C _WD increases, as in the example of the lengths W ₀, W ₁ and W ₂ shown. However, the value converges toward W ₂₀₀ as shown in Fig. 4C. The value of Δ C _W is indicated in Fig. 4C by the index 0, 1, 2 and 200. The graphic representation shows that the scattering magnetic field is limited in its intensity, even if the difference Δ C _W increases.

The values W ₀, W ₁ and W ₂₀₀ for the distance in the Z direction correspond to lengths for the scattering of the magnetic field generated by the magnetic pole pieces.

In this way, the relationship between the value of Δ C _W and the width of the peripheral magnetic field can be determined to enable the relationship between the signal intensity and Δ C _{W to also be} determined when a thin film magnetic head with a certain track width is used. The results are shown by curve S in FIG. 5.

On the other hand, as the value of Δ C _{W increases,} the intensity of the background signal, in particular of the background generated by crosstalk from adjacent tracks and of the secondary track background when reading, increases, as shown in curve N of FIG. 5.

Correspondingly, the relationship between the signal-to-background ratio as a typical feature of the performance of a magnetic disk device and the value Δ C _{W is shown} in FIG. 6. It has been shown that the signal-to-background ratio in a range 0 <Δ C _W <Δ C _Wlim is greater than Δ _W = C 0th

Fig. 6 also shows that the signal-to-background ratio decreases and the value Δ C _{Wlim decreases} to Δ C _Wlim 'when the track density of the magnetic disk is further increased.

Fig. 7 shows the relationship between the track density (Tr) of the magnetic disk and Δ C _Wlim . It proves that the value of Δ C _Wlim is substantially proportional to the reciprocal of the track density (1 / Tr ), with a proportionality constant of approximately 5000.

It was also shown that the value Δ C _Wlim , measured as a function of the difference Δ C _W ′ between the side C _WU and the side C _WD , at each of the lateral ends of the magnetic pole pieces was also substantially proportional to the reciprocal of the track density (1 / Tr ) and the proportionality constant is approximately 2500.

Correspondingly, in a high-density magnetic disk device using a magnetic disk with a track density of 1800 TPI or more, the signal-to-background ratio may be larger than at Δ C _W = 0 or Δ C _W ′ = 0 if the values are in the range

0 < Δ C _W ≦ 5000 / Tr

0 < Δ C _W ′ ≦ 2500 / Tr

to get voted.

According to the invention, a thin film magnetic head with high signal-to-background ratio for use in a magnetic disk device with a high track density of 1800 or more TPI can be realized, and a high recording density can be realized by the magnetic disk device.

There are also conditions for the shape of the magnetic pole pieces a thin film magnetic head for use in one Magnetic disk device of high recording density clarified.

In addition, the thin film magnetic head and the magnetic plate,  which are higher for use in the magnetic disk device Suitable recording density, clarified.

In the following practical embodiments of the Invention described.

Fig. 1 is a schematic representation which illustrates a corresponding embodiment of the invention a magnetic disk apparatus.

As shown in Fig. 1, the structure of the magnetic disk device has the components identified by reference numerals 1 to 8 and a voice coil controller.

1 denotes a base plate and 2 denotes a spindle.

A plurality of circular magnetic disks 4 are carried by the single spindle as shown in FIG. 1.

In the example shown, the spindle carries five magnetic disks. However, the number of magnetic disks is in no way limited to five.

Alternatively, a plurality of spindles can be provided, each of which in turn carries a plurality of magnetic disks in the manner shown in FIG. 1.

3 with a motor is named, which drives the spindle 2 to rotate the magnetic plates.

5 denotes magnetic heads for data information and 5 a a magnetic head for positioning.

6 is a carriage, 7 is a voice coil and 8 is a magnet.

The voice coil 7 and the magnet 8 form the voice coil drive.

The positioning of the head is carried out by means of the carriage 6 of the coil 7 and the magnet 8 .

The voice coil 7 is connected to the magnetic heads 5 and 5 a via a voice coil control.

In Fig. 1, the primary device comprises, for example, a computer system.

The thin-film magnetic head 5 in FIG. 1 has magnetic pole pieces with a contour on the free surface facing the magnetic plate 4 , as is shown enlarged in FIGS. 2A and 2B.

The thin film magnetic head is constructed as shown in FIG. 11.

In Fig. 11, reference numeral 100 denotes the base plate and 200 a base film for forming a flat surface.

Stacked on the backing film 200 are a lower magnetic pole piece 300 made of magnetic material, an insulating film 600 to define a magnetic gap G , and an upper magnetic pole piece 400 also made of magnetic material, in that order.

Coil conductors 500 are embedded in the insulating film 600 and are electrically excited to induce a magnetic field.

Reference numeral 700 denotes a protective film which is deposited on the upper magnetic pole piece 400 .

The hatched portion in FIG. 11 is specially designed as shown in FIG. 2A or in FIG. 2B.

In accordance with the teachings of the invention, a thin film magnetic head used in the magnetic disk device with a track density of 2500 TPI uses magnetic cores with a contour configuration on the free surface facing the recording medium as shown in Fig. 2A or 2B.

Particularly in the case of a thin-film magnetic head, the magnetic pole pieces of which were produced by means of magnetron sputtering of a magnetic material and by means of shaping by means of an ion beam etching process, the magnetic pole pieces have a contour configuration on the free surface facing the magnetic plate, as shown in FIG. 2A.

In the magnetic pole in Fig. 2A, an upper magnetic pole piece 11 has the width _WU C of 6.9 microns and a lower magnetic pole piece 13 has a width of 8.7 microns (C _WD), in each case along a Magnetpolspaltes 12th

The upper and lower magnetic pole pieces 11 and 13 are arranged so that their contours, viewed from the side facing the magnetic plate, are symmetrical with respect to a common axis lying in the read / write direction.

The properties of the thin film magnetic head described above when writing and reading with the magnetic disk device were examined, and the results showed that the signal-to-background ratio compared to a magnetic head with C _WU = 6.9 µm and C _WD = 9.1 µm, was 4.3% larger.

On the other hand, in a thin film magnetic head having a magnetic core in which a lower magnetic pole piece 16 was made by magnetron sputtering a magnetic material and patterning by an ion beam etching process, and an upper magnetic pole piece 14 by patterning by a selective metallization process using a photoresist mask, the magnetic pole pieces have one Contour as shown in Fig. 2B.

In the magnetic pole tip shown in FIG. 2B, the upper magnetic pole piece 14 has a width ( C _WU ) of 7.0 μm and the lower magnetic pole piece 16 has a width ( C _WD ) of 8.6 μm, each along a magnetic gap 15 .

The difference between a lateral end of the upper magnetic pole piece 14 and the corresponding end of the lower magnetic pole piece 16 is 0.9 μm, whereas the difference between the other lateral end of the upper magnetic pole piece and the corresponding end of the lower magnetic pole piece is 0.7 μm.

The properties of the thin film magnetic head described above when writing and reading with the magnetic disk device were examined, and the results showed that the signal-to-background ratio was 8.6% compared to a magnetic head with C _WU = 7.0 µm and C _WD = 9.5 µm, was increased.

According to the teachings of the invention, a thin film magnetic head for use in a magnetic disk device with a track density of 3000 TPI has a magnetic pole arrangement with a contour configuration on the surface facing the recording medium as shown in Fig. 8.

In particular, in a thin film magnetic head using a magnetic pole assembly made by magnetron sputtering a magnetic material and patterning by an ion beam etching process, the magnetic core assembly has a contour as shown in FIG. 8.

To form this magnetic pole structure, a lower magnetic pole piece 83 is first produced, then a non-magnetic insulating material 84 is deposited on both sides and on the lateral end regions of the surface of the lower magnetic pole piece in such a way that a cutout 85 remains on top of the lower magnetic pole piece 83 , and then deposited a magnetic gap film 82 to cover the non-magnetic insulating material and the recess.

This manufacturing process is suitable for controlling the value of C _WU very precisely.

The upper magnetic pole piece 81 has a width ( C _WU ) of 6.0 μm and the lower magnetic pole piece 83 has a width ( C _WD ) 7.2 μm, in each case along the magnetic gap.

The properties of the above thin film magnetic head when writing and reading with the magnetic disk device were examined, and the results showed that the signal-to-background ratio was 8.6% compared to a magnetic head with C _WU = 6.0 µm and C _WD = 8 , 0 µm was increased.

Claims (22)

1. Magnetic disk device with
a magnetic disk ( 4 ) for information recording,
a thin film magnetic head ( 5 ) for writing and reading information on and from the magnetic disk ( 4 ) with an upper magnetic pole piece ( 400; 52; 21 ) and a lower magnetic pole piece ( 300; 53; 23 ) which form a magnetic gap ( G ; 54; 22 ) form
Means ( 3 ) for rotating the magnetic plate ( 4 ) and
Devices ( 6, 7, 8 ) for positioning the thin-film magnetic head, characterized in that
that the magnetic disk ( 4 ) has a track density Tr of 1800 TPI (tracks per inch, corresponding to 709 tracks per centimeter) or more and
that the upper and the lower magnetic pole piece, seen from the side facing the magnetic plate, have different contours, the difference Δ C _W in µm between the width C _{WU of} the upper ( 400; 52; 21 ) and the width C _{WD of} the lower ( 300; 53; 23 ) magnetic pole piece, measured along the magnetic gap ( G ; 54; 22 ), fulfills the following relation: 0 < Δ C _W ≦ 5000 / Tr , but preferably 0.2 ≦ Δ C _W ≦ 5000 / Tr . 2. Magnetic disk device according to claim 1, characterized in that the difference Δ C _W 'in µm between the respective corresponding lateral ends of the upper ( 400; 52; 21 ) and the lower ( 300; 53; 23 ) magnetic pole piece, measured along the magnetic Gap ( G ; 54; 22 ), the following relation is fulfilled: 0 < Δ C _W ′ ≦ 2500 / Tr , but preferably 0.1 ≦ Δ C _W ′ ≦ 2500 / Tr . 3. Magnetic disk device according to claim 1 or 2, characterized in that the upper magnetic pole piece ( 31 ) on its front surface facing the magnetic plate has a central region which is substantially parallel to the front surface of the lower magnetic pole piece ( 33 ), and lateral end regions, so run that they are further away from the front surface of the lower magnetic pole piece than the central region. 4. Magnetic disk device according to one of claims 1 to 3, characterized characterized in that the front surfaces of the upper and lower Magnet pole piece with respect to the in the read / write direction running central axis of symmetry essentially symmetrical are.   5. Magnetic disk device according to one of claims 1 to 4, characterized in that the width C _{WU of} the upper ( 400; 52; 21 ) measured along the magnetic gap ( G ; 54; 22 ) is smaller than the width C _{WD of} the lower ( 300 ; 53; 23 ) Magnetic pole piece. 6. Magnetic disk device according to one of claims 1 to 5, characterized in that the magnetic disk ( 4 ) has a linear recording density of 12 or more kilobits per centimeter. 7. Magnetic disk device according to one of claims 1 to 6, characterized in that the magnetic disk ( 4 ) has a surface recording density of 8.4 or more megabits per square centimeter. 8. Magnetic disk device according to one of claims 1 to 7, characterized in that the magnetic plate ( 4 ) has on its surface a magnetic element with a coercive force of 48,000 A / m or more and a thickness of 0.35 µm or less. 9. Magnetic disk device according to one of claims 1 to 8, characterized in that for that of the two magnetic pole pieces whose width C _WU or C _{WD is} smaller, the angle R _S between the edge along the magnetic gap and the lateral end edge fulfills the relation: 45 ° ≦ R _S ≦ 150 °. 10. Magnetic disk device according to one of claims 1 to 9, characterized in that for that of the two magnetic pole pieces whose width C _WU or C _{WD is} longer, the angle R _L between the edge along the magnetic gap and the lateral end edge fulfills the following relation: 91 ° ≦ R _L ≦ 150 °. 11. Magnetic disk device according to one of claims 1 to 10, characterized characterized in that both magnetic pole pieces from a magnetic Material with a saturation magnetic flux density of Consist of 1 Tesla or more and a single layer film structure to have. 12. Magnetic disk device according to one of claims 1 to 10, characterized characterized in that both magnetic pole pieces from a magnetic Material with a saturation magnetic flux density of 1 Tesla or more and a multi-layer film structure with one or more intermediate layers of non-magnetic films to have. 13. Magnetic disk device according to one of claims 1 to 12, characterized in that the thin film magnetic head ( 5 ) contains a conductor coil with 18 or more turns. 14. Magnetic disk device according to one of claims 1 to 13, characterized in that the thin-film magnetic head ( 5 ) is used by floating at a height of 0.25 µm or less above the magnetic plate ( 4 ). 15. Magnetic disk device according to one of claims 1 to 14, characterized characterized in that one of the two magnetic pole pieces is produced by using a magnetic material a sputtering process and a drying or structured wet etching process. 16. Magnetic disk device according to one of claims 1 to 14, characterized characterized in that one of the two magnetic pole pieces using a selective plating process is structured using a photoresist mask. 17. Magnetic disk device according to one of claims 1 to 16, characterized in that a non-magnetic, insulating layer ( 84 ) on both side surfaces and the lateral areas of the front surface of the lower magnetic pole piece ( 83 ) is applied so that on the top of the front surface a recess ( 85 ) is formed and the magnetic gap is minimized at this point. 18. Magnetic disk device with
a magnetic disk ( 4 ) for information recording,
a thin film magnetic head ( 5 ) for writing information on the magnetic disk ( 4 ) with an upper magnetic pole piece ( 400; 52; 21 ) and a lower magnetic pole piece ( 300; 53; 23 ) which have a magnetic gap ( G ; 54; 22 ) form,
a magnetic head for reading the information written on the magnetic disk ( 4 ),
Means ( 3 ) for rotating the magnetic plate ( 4 ) and
Devices ( 6; 7; 8 ) for positioning the thin-film magnetic head, characterized in that
that the magnetic disk ( 4 ) has a track density Tr of 1800 TPI (tracks per inch, corresponding to 709 tracks per centimeter) or more and
that the upper ( 400; 52; 22 ) and the lower ( 300; 53; 23 ) magnetic pole piece at the areas forming the magnetic gap ( G ; 54; 22 ), from the side facing the magnetic disk, have different contours, the Difference Δ C _W in µm between the width C _{WU of} the upper ( 400; 52; 21 ) and the width C _{WD of} the lower ( 300; 53; 23 ) magnetic pole piece, measured along the magnetic gap ( G ; 54; 22 ), the following relation fulfilled: 0 < Δ C _W ≦ 5000 / Tr . 19. Recording system with
a head-plate assembly for performing the magnetic write or read function,
a read / write circuit for switching the write and read function and
an interface to connect the head-plate assembly to a primary device via the read / write circuit,
wherein the head-disk assembly is a magnetic disk device according to any one of claims 1 to 18. 20. Thin-film magnetic head ( 5 ) for use in a magnetic disk device with a magnetic disk ( 4 ) having a track density Tr of 1800 TPI (tracks per inch, corresponding to 709 tracks per centimeter) or more, the magnetic head ( 5 ) having a lower magnetic pole piece ( 300; 53; 23 ) and an upper magnetic pole piece ( 400; 52; 21 ), which form a magnetic gap ( G ; 54; 22 ), characterized in that the upper and lower magnetic pole pieces, viewed from the side facing the magnetic plate , have different contours, the difference Δ C _W in µm between the width C _{WU of} the upper ( 400; 52; 21 ) and the width C _{WD of} the lower ( 300; 53; 23 ) magnetic pole piece, measured along the magnetic gap ( G ; 54; 22 ), the following relation is fulfilled: 0 < Δ C _W ≦ 5000 / Tr . 21. Thin-film magnetic head according to claim 20, characterized in
that the upper magnetic pole piece ( 400; 52; 21 ) is formed over the lower magnetic pole piece ( 300; 53; 23 ) and is connected at one end to one end of the lower magnetic pole piece ( 300; 53; 23 ) and to the other end opposite the other end of the lower magnetic pole piece ( 300; 53; 23 ) so that a magnetic circuit is formed with a magnetic gap ( G ; 54; 22 ) formed between these ends,
that an insulating layer ( 600 ) is arranged between the two magnetic pole pieces and
that a conductor coil ( 500 ) is embedded in this intermediate layer and wound so that it cuts the magnetic circuit. 22. A method for recording and reproducing information using a magnetic disk device, comprising the steps:
Rotating a magnetic disk ( 4 ) which has a track density Tr of 1800 TPI (tracks per inch = 709 tracks per cm) or more,
Causing a thin film magnetic head (5) which is designed for writing and reading on and from the magnetic disk (4) on the magnetic disk (4) has access, wherein the thin film magnetic head (5) comprises an upper magnetic pole piece (400; 52; 21) and has a lower magnetic pole piece ( 300; 53; 23 ) which form a magnetic gap ( G ; 54; 22 ) at respective end regions and which have different contours at the regions forming the magnetic gap, as seen from the side facing the magnetic plate ( 4 ) , the difference Δ C _W in µm between the width C _{WU of} the upper ( 400; 52; 21 ) and the width C _{WD of} the lower ( 300; 53; 23 ) magnetic pole piece, measured along the magnetic gap ( G ; 54; 22 ) fulfills the following relation: 0 < Δ C _W ≦ 5000 / Tr , magnetic writing of information by means of the thin film magnetic head ( 5 ) over a track width which is evenly enlarged by the size of the edge zone magnetic field in the difference area determined by C _W t,
Causing the thin film magnetic head ( 5 ) to access the magnetic plate ( 4 ), and
Reading the information recorded on the magnetic disk ( 4 ) about the evenly enlarged track width corresponding to the longer of the two sides with the width C _WU or C _WD .