JPH05189718A - Magnetic head - Google Patents

Abstract

PURPOSE:To obtain the magnetic head capable of suppressing cross talk without providing a dedicated circuit for suppressing cross talk due to an erase gap at the time of read. CONSTITUTION:A magnetic flux change due to recording information of a recording medium is received by a read/write gap 2, and hence an output voltage V0 is generated between both taps 10a and 10b of a read/write coil 10 and is detected by a read/write circuit 13, so that the recording information of the recording medium is read out. On the other hand, magnetic flux by the recording information of the recording medium is generated by the erase gap 3, whereas a current is conducted in a short-circuit coil part of a erase coil 11 by this magnetic flux, and magnetic flux is generated to cancel a magnetic flux change due to the erase gap 3. As a result, magnetic flux in the erase core 7 is decreased, and a cross talk output voltage generated on the read/write coil 10 is very small, so that the readout can be carried out with good accuracy.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetic head used in a magnetic recording / reproducing apparatus for recording and reproducing information, for example, a magnetic head used for FDD.

[0002]

2. Description of the Related Art FIGS. 6 to 8 show a conventional preceding erase type magnetic head.
Is a magnetic head core body having a read / write gap 2 and an erase gap 3 which is provided at a position preceding the read / write gap 2 and is wider than the width of the read / write gap 2. An L-shaped read / write core 5 that forms the read / write gap 2 with the center core 4, and the center core 4
A read / write back bar 6 for forming a read / write magnetic path with the read / write core 5, and an L-shaped erase core 7 that forms the erase gap 3 between the center core 4 and the erase core 7. An erase back bar 8 for forming an erase magnetic path with the core 7 and the center core 4, and an erase magnetic path provided between the erase back bar 8 and the read / write back bar 6. And a back bar separator 9 for separating the magnetic path for reading and writing.

Reference numeral 10 is a read / write coil wound around the read / write core 5, 11 is an erase coil wound around the erase core 7, and 12 is an erase coil connected between both taps 11a and 11b of the erase coil. It is a coil short-circuit element, and the above-mentioned erase gap 3 at the time of read operation.
This is for short-circuiting between the taps 11a and 11b of the erase coil 11 only during a read operation in order to suppress crosstalk caused by the above. Reference numeral 13 is a read / write circuit connected between both taps 10a and 10b of the read / write coil 10, and based on the information recorded on the magnetic recording medium read by the read / write gap 2 during a read operation. Processing the output voltage appearing between both taps 10a and 10b of
The information is provided to the read / write coil 10 for recording on the magnetic recording medium during a write operation.

Reference numeral 14 denotes an erase circuit connected between both taps 11a and 11b of the erase coil 11 for supplying a predetermined current to the erase coil 11 at the time of writing. Reference numeral 15 is an erase coil short-circuiting means for outputting a control signal for bringing the above-mentioned erase coil short-circuit element 12 into a conductive state at the time of reading.

Next, the operation of the magnetic head having the above structure will be described. First, the case of writing information on a recording medium will be described. A predetermined voltage is applied to the erase coil 11 from the erase circuit 14, and a predetermined current flows through the erase coil 11. When a predetermined current flows through the erase coil 11, the erase core 7
-Center core 4-A magnetic flux having a predetermined magnetic force is generated in the magnetic path formed by the erase back bar 8, and a magnetic flux is generated in the erase gap 3 to erase the previous information recorded on the recording medium. At this time, the erase coil short-circuit means 15
Since the control signal is not output from the device, the erase coil short-circuit element 12 does not operate and the erase coil 11 is not affected at all.

On the other hand, from the read / write circuit 13, a voltage based on the information to be written on the recording medium is applied to the read / write coil 10, and a current based on the applied voltage flows through the read / write coil 10. When a current based on the information to be written flows in the read / write coil 10, a magnetic flux having a magnetic force based on the information to be written is generated in the magnetic path formed by the read / write core 5-center core 4-read / write back bar 6, A magnetic flux is generated in the read / write gap 2 and information is recorded on the recording medium erased by the erase gap 3.

Next, the case of reading the information recorded on the recording medium will be described. A voltage is not output from the erase circuit 14, and a control signal is output from the erase coil short-circuit means 15 to make the erase coil short-circuit element 12 conductive, thereby short-circuiting both taps 11a and 11b of the erase coil 11. ing. Then, the read / write gap 2 receives the change of the magnetic flux based on the information recorded on the recording medium, and the read core 5 -center core 4
-A magnetic flux having a magnetic force based on the information recorded on the recording medium is generated in the magnetic path formed by the read / write back bar 6, and a current flows through the read / write coil 10 by this magnetic flux. The output voltage V appearing between the taps 10a and 10b due to the current flowing through the read / write coil 10.
₀ is detected by the read / write circuit 13, and the information recorded on the recording medium is read out.

By the way, it will be explained that the erase coil short-circuit means 15 and the erase short-circuit element 12 in the above-mentioned structure can suppress the crosstalk caused by the erase gap 3 at the time of reading. First, a case where the erase coil short-circuit element 15 does not make the erase coil short-circuit element 12 conductive when the information recorded on the recording medium is read (during reading) will be described. The erase gap 3 receives a magnetic flux based on the information recorded on the recording medium, and the magnetic flux is shunted from the erase core 7 to the center core 4 and the read / write core 5 through the erase back bar 8, as shown in FIG. Crosstalk output voltage V is applied to the read / write coil 10.
₀₂ will appear. As a result, the sum voltage of the output voltage V ₀₁ and the crosstalk output voltage V ₀₂ due to the magnetic flux based on the information recorded on the recording medium by the read / write gap 2 is output to the read / write coil 10. Therefore, accurate reading cannot be performed.

On the other hand, as described above, when the taps 11a and 11b of the erase coil 11 are short-circuited by the erase coil short-circuit means 15 and the erase short-circuit element 12 at the time of reading, the erase gap 3 is recorded on the recording medium. The magnetic flux based on the information is received, and this magnetic flux is generated in the magnetic path formed by the erase core 7-center core 4-erase back bar 8, so that a current flows through the shorted erase coil 11. When this current flows through the erase coil 11, the erase coil 11 generates a magnetic flux in the magnetic path formed by the erase core 7-center core 4-erase back bar 8 that cancels the change in the magnetic flux received by the erase gap 3. become. As a result, the magnetic flux in the erase core 7 is reduced, and as shown in FIG. 10, the crosstalk output voltage V ₀₂ appearing in the read / write coil 10 becomes very small, and accurate reading can be performed. is there.

It should be noted that, in such a leading erase type magnetic head, as a means for suppressing crosstalk at the time of reading due to an erase gap, it is disclosed in Japanese Patent Laid-Open No. 2-35610.
It is also shown in the official gazette. What is shown in this publication is
In order to suppress crosstalk, a canceling coil is provided separately from the erase coil, and at the time of reading, the erase coil and the canceling coil are controlled so as to short-circuit a line connected in series.

[0011]

However, in the devices shown in FIGS. 6 to 8 and the device disclosed in the above publication, a magnetic head is used in order to suppress crosstalk during reading due to the erase gap. Separately, it is necessary to provide an erase coil short-circuit element and erase coil short-circuit means exclusively for this magnetic head, which complicates the circuit for read / write of the magnetic head including the read / write circuit and the erase circuit. There is a problem in that it is not possible to use a circuit for read / write of a magnetic head used other than the magnetic head.

The present invention has been made in view of the above-mentioned points, and even when a circuit for reading / writing a magnetic head is not provided with a dedicated circuit for suppressing crosstalk, a read operation by an erase gap is performed. The purpose is to obtain a magnetic head capable of suppressing crosstalk.

[0013]

A magnetic head according to a first aspect of the present invention includes a magnetic head core body having a read / write gap and an erase gap, and a read / write coil wound around the magnetic head core body. An erase coil wound around a magnetic head core body and having an electrically short-circuited portion is provided.

A magnetic head according to a second aspect of the present invention is a magnetic head core body having a read / write gap and an erase gap, a read / write coil wound around the magnetic head core body, and a magnetic head core body. Further, an erase circuit is connected to the center tap and one of the taps, and an erase coil in which the center tap and the other tap are electrically short-circuited is provided.

A magnetic head according to a third aspect of the present invention includes a magnetic head core body having a read / write gap and an erase gap, a read / write coil wound around the magnetic head core body, and a magnetic head core body. The erase coil has an erase circuit connected to the center tap and one of the taps, and an inductance element connected between the center tap of the erase coil and the other tap.

[0016]

According to the first aspect of the present invention, a magnetic flux that cancels a change in the magnetic flux received by the erase gap at the time of reading information from the recording medium is generated by the portion where the erase coil is electrically short-circuited.

In the second aspect of the present invention, the change in the magnetic flux received by the erase gap at the time of reading information from the recording medium by the coil portion between the center tap in which the erase coil is short-circuited and the other tap. Generate a magnetic flux that cancels out.

In the third aspect of the present invention, the coil portion between the center tap and the other tap in the erase coil and the inductance element are magnetic fluxes received by the erase gap when reading information from the recording medium. The magnetic flux that cancels the change of is generated.

[0019]

【Example】

Example 1. Embodiment 1 of the present invention will be described below with reference to FIGS.
In the drawings, reference numeral 1 is a magnetic head core body having a read / write gap 2 and an erase gap 3 provided at a position preceding the read / write gap 2 and wider than the width of the read / write gap 2. The I-shaped center core 4 and the L-shaped read / write core 5 forming the read / write gap 2 between the center core 4 and the center core 4 and the read / write core 5 form a read / write magnetic path. An L-shaped erase core 7 that forms the erase gap 3 between the read / write back bar 6 and the center core 4, and an erase magnetic path is formed by the erase core 7 and the center core 4. Between the erase back bar 8 for forming and the erase back bar 8 and the read / write back bar 6. It provided, in which is constituted by a back bar separator 9 to separate the magnetic path of the magnetic path for the erase and read-write.

Reference numeral 10 is a read / write coil wound around the read / write core 5, and 11 is an erase coil wound around the erase core 7 and having an electrically short-circuited portion, and a pair of taps 11a and 11b. Center tap 1
1c and the erase gap 3 at the time of read operation.
The center tap 11c and the other tap 11b are connected by a wire and short-circuited in order to suppress the crosstalk caused by. Reference numeral 13 is a read / write circuit connected between both taps 10a and 10b of the read / write coil 10, and based on the information recorded on the magnetic recording medium read by the read / write gap 2 during a read operation. For reading the information recorded on the recording medium by processing the output voltage appearing between the two taps 10a and 10b, and for giving the information for recording on the magnetic recording medium to the read / write coil 10 during the write operation. is there. Reference numeral 14 denotes an erase circuit connected between one tap 11a of the erase coil 11 and a center tap 11c, which is for passing a predetermined current through the erase coil 11 during writing.

Next, the operation of the magnetic head having the above structure will be described. First, the case of writing information on a recording medium will be described. A predetermined voltage is applied to the erase coil 11 from the erase circuit 14, and a predetermined current flows through the erase coil 11. When a predetermined current flows through the erase coil 11, the erase core 7
-Center core 4-A magnetic flux having a predetermined magnetic force is generated in the magnetic path formed by the erase back bar 8, and a magnetic flux is generated in the erase gap 3 to erase the previous information recorded on the recording medium. At this time, the short-circuited coil portion between the center tap 11c and the other tap 11b of the erase coil 11 has no influence on the write operation.

On the other hand, from the read / write circuit 13, a voltage based on the information to be written on the recording medium is applied to the read / write coil 10, and a current based on the applied voltage flows through the read / write coil 10. When a current based on the information to be written flows in the read / write coil 10, a magnetic flux having a magnetic force based on the information to be written is generated in the magnetic path formed by the read / write core 5-center core 4-read / write back bar 6, A magnetic flux is generated in the read / write gap 2 and information is recorded on the recording medium erased by the erase gap 3.

Next, the case of reading the information recorded on the recording medium will be described. No voltage is output from the erase circuit 14. Then, the read / write gap 2 receives the change of the magnetic flux based on the information recorded on the recording medium, and the information recorded on the recording medium in the magnetic path formed by the read / write core 5-center core 4-read / write back bar 6. A magnetic flux having a magnetic force based on is generated, and the magnetic flux causes a current to flow in the read / write coil 10. The output voltage V ₀ appearing between the taps 10a and 10b due to the current flowing in the read / write coil 10 is detected by the read / write circuit 13, and the information recorded on the recording medium is read.

The output voltage V ₀ appearing between the taps 10a and 10b due to the current flowing in the read / write coil 10 is as follows. In other words, the erase gap 3 receives a magnetic flux based on the information recorded on the recording medium, and this magnetic flux is generated in the magnetic path formed by the erase core 7-center core 4-erase back bar 8 so that the center tap 11c and the other of the center tap 11c are separated. A current will flow through the coil portion short-circuited with the tap 11b. When this current flows through the short-circuited coil portion of the erase coil 11, the erase coil 1
The shorted coil portion 1 causes a magnetic flux that cancels the change in the magnetic flux received by the erase gap 3 in the magnetic path formed by the erase core 7-center core 4-erase back bar 8.

As a result, the magnetic flux in the erase core 7 is reduced, and as shown in FIG. 10, the crosstalk output voltage V ₀₂ appearing in the read / write coil 10 is the output voltage V appearing in the read / write coil 10 due to the read / write gap 2. ₀₁
Will be very small against. Therefore, the output voltage V ₀ appearing between the taps 10 a and 10 b of the read / write coil 10 is the output voltage V ₀₁ and the crosstalk output voltage V _02.
However, since the crosstalk output voltage V ₀₂ is very small with respect to the output voltage V ₀₁ , there is almost no effect of crosstalk, that is, as shown at the left end (short) in the drawing shown in FIG. Crosstalk value relative value {= 20
Since xlog (V ₀₂ / V ₀₁ )} is much smaller than the right end (open) in the drawing, accurate reading can be performed.

In addition, the magnetic head having the above-described structure does not require the erase coil short-circuit element and the erase coil short-circuiting means as shown in the conventional example, and the magnetic head including the read / write circuit and the erase circuit. This also simplifies the circuit for read / write, and also has the effect that a circuit for read / write of a magnetic head used in addition to the preceding erase type magnetic head can be used.

Example 2. 3 and 4 show a second embodiment of the present invention, in which the first embodiment has the center tap 11c of the erase coil 11 and the other tap 11b.
It is characterized in that an inductance element 16 is connected between the center tap 11c of the erase coil 11 and the other tap 11b, in contrast to the short circuit between The second embodiment configured as described above operates in the same manner as the first embodiment described above, and exhibits the same effect, and also has the center tap 11c and the other tap 11b in the erase coil 11. Since the magnetic flux canceled out by the inductance of the coil portion and the inductance of the inductance element between the two becomes large, the effect of improving crosstalk by the erase gap 3 at the time of reading can be further enhanced.

Next, in the second embodiment, the inductance element 16 connected between the center tap 11c of the erase coil 11 and the other tap 11b.
The effect of improving the inductance and the crosstalk will be described. The relative value of the crosstalk value can be expressed by the following equation (1). 20 × log (V ₀₂ / V ₀₁ ) ... (1) Further, the center tap 11c in the erase coil 11
As a result of investigating the relationship between the ratio of the inductance L _int of the coil portion and the inductance L _ext of the inductance element 16 (= L _ext / L _int ) between the other tap 11b and the other cross-talk value, FIG. The result is as follows. In addition, in FIG. 5, the right end is the conventional example shown in FIGS. 6 to 8, and the left end is the above-mentioned FIG.
2 and that of the first embodiment shown in FIG.

As can be seen from FIG. 5, by providing the inductance element 16, the relative crosstalk value is smaller than that of the conventional example shown in FIGS. 6 to 8, and the inductance L _{ext of the} inductance element 16 is reduced.
Is less than or equal to 5 times the inductance L _int of the coil portion between the center tap 11c and the other tap 11b of the erase coil 11, the crosstalk value relative value is smaller than that shown in the first embodiment, and the inductance element is small. The inductance L _ext of 16 corresponds to the center tap 11c and the other tap 11b of the erase coil 11.
The effect of improving crosstalk is most obtained by making the inductance L _int of the coil portion between and the same. That is, the inductance L _ext of the inductance element 16 is equal to the erase coil 11
5 times or less than the inductance L _int of the coil portion between the center tap 11c and the other tap 11b has an effect on good crosstalk, and the same value is the best.

In the first embodiment, the center tap 11c of the erase coil 11 and the other tap 11b are short-circuited.
The part of the coil to be short-circuited is not limited to this part, and other parts may be used. The point is to provide a part of the erase coil 11 which is short-circuited. Also,
In the second embodiment, the erase coil 11 is used.
Although the inductance element 16 is connected between the center tap 11c and the other tap 11b in the above, other portions may also be used, in short, if the inductance element 16 is connected in parallel with a part of the erase coil 11. It's a good one.

[0031]

According to the first aspect of the present invention, since the erase coil having the electrically short-circuited portion is wound around the magnetic head core body, the electrically short-circuited portion of the erase coil is This has the effect of generating a magnetic flux that cancels the change in the magnetic flux received by the erase gap when reading information from the recording medium, and suppressing crosstalk due to the erase gap when reading information.

In a second aspect of the present invention, an erase circuit is connected to the center tap and one tap, and the center tap and the other tap are electrically short-circuited, and an erase coil is wound around the magnetic head core body. Therefore, the coil portion between the short-circuited center tap and the other tap in the erase coil generates a magnetic flux that cancels the change in the magnetic flux received by the erase gap at the time of reading information from the recording medium. This has the effect of suppressing crosstalk due to the erase gap during reading.

According to the third aspect of the present invention, since the inductance element is connected between the center tap of the erase coil and the other tap, the coil between the center tap of the erase coil and the other tap is formed. The portion and the inductance element generate a magnetic flux that cancels a change in the magnetic flux received by the erase gap when reading information from the recording medium, and have an effect of suppressing crosstalk due to the erase gap when reading information. ..

[Brief description of drawings]

FIG. 1 is a side sectional view showing a configuration of a magnetic head according to a first embodiment of the invention.

FIG. 2 is a diagram showing a connection relationship between a magnetic head and a circuit and a circuit configuration according to the first embodiment of the present invention.

FIG. 3 is a side sectional view showing a configuration of a magnetic head according to a second embodiment of the present invention.

FIG. 4 is a diagram showing a connection relationship between a magnetic head and a circuit and a circuit configuration according to a second embodiment of the present invention.

FIG. 5 is an inductance element 1 and an inductance L _int of the coil portion between the center tap 11c and the other tap 11b of the erase coil 11 for explaining the crosstalk suppressing effect in the embodiment of the invention.
Ratio of 6 to inductance L _ext (= L _ext / L _int )
The figure which shows the relationship of the crosstalk value relative value with respect to.

FIG. 6 is a partial plan view seen from the sliding surface side showing the arrangement of the read / write gap 2 and the erase gap 3 of the conventional magnetic head.

FIG. 7 is a side sectional view showing a configuration of a magnetic head in a conventional example.

FIG. 8 is a diagram showing a connection relationship between a magnetic head and a circuit and a circuit configuration in a conventional example.

FIG. 9 is a diagram showing an output voltage of the read / write coil 10 when crosstalk due to the erase gap 3 is large.

FIG. 10 is a diagram showing an output voltage of the read / write coil 10 when crosstalk due to the erase gap 3 is small.

[Explanation of symbols]

 1 magnetic head core body 2 read / write gap 3 erase gap 10 read / write coil 11 erase coil 11a erase coil tap 11b erase coil tap 11c erase coil center tap 13 read / write circuit 14 erase circuit 16 inductance element

[Procedure amendment]

[Submission date] September 30, 1992

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0007

[Correction method] Change

[Correction content]

Next, the case of reading the information recorded on the recording medium will be described. A voltage is not output from the erase circuit 14, and a control signal is output from the erase coil short-circuit means 15 to make the erase coil short-circuit element 12 conductive, thereby short-circuiting both taps 11a and 11b of the erase coil 11. ing. Then, the read / write gap 2 receives the change of the magnetic flux based on the information recorded on the recording medium, and the read core 5 -center core 4
-A magnetic flux having a magnetic force based on the information recorded on the recording medium is generated in the magnetic path formed by the read / write back bar 6, and the read / write coil 1 is caused by a change in this magnetic flux.
An output voltage V ₀ is induced between both 0 taps 10a and 10b.
To be done. The output voltage V ₀ is detected by the read / write circuit 13, and the information recorded on the recording medium is read out.

[Procedure Amendment 2]

[Document name to be amended] Statement

[Name of item to be corrected] 0023

[Correction method] Change

[Correction content]

Next, the case of reading the information recorded on the recording medium will be described. No voltage is output from the erase circuit 14. Then, the read / write gap 2 receives the change of the magnetic flux based on the information recorded on the recording medium, and the information recorded on the recording medium in the magnetic path formed by the read / write core 5-center core 4-read / write back bar 6. A magnetic flux having a magnetic force based on is generated, and the magnetic flux causes a current to flow in the read / write coil 10. Due to this change in magnetic flux, the read / write coil 1
The output voltage V ₀ appearing between both taps 10a and 10b of ₀
Is detected by the read / write circuit 13, and the information recorded on the recording medium is read.

[Procedure 3]

[Document name to be amended] Statement

[Correction target item name] 0024

[Correction method] Change

[Correction content]

By the way, due to this change in magnetic flux, the lead
The output voltage V ₀ appearing between both taps 10a and 10b of the write coil 10 is as follows. In other words, the erase gap 3 receives a magnetic flux based on the information recorded on the recording medium, and this magnetic flux is generated in the magnetic path formed by the erase core 7-center core 4-erase back bar 8 so that the center tap 11c and the other of the center tap 11c are separated. A current will flow through the coil portion short-circuited with the tap 11b. When this current flows through the short-circuited coil portion of the erase coil 11, the short-circuited coil portion of the erase coil 11 is received by the erase gap 3 in the magnetic path formed by the erase core 7-center core 4-erase back bar 8. A magnetic flux that cancels the change in the magnetic flux is generated.

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0028

[Correction method] Change

[Correction content]

Next, in the second embodiment, the inductance element 16 connected between the center tap 11c of the erase coil 11 and the other tap 11b.
The effect of improving the inductance and the crosstalk will be described. The relative value of the crosstalk value can be expressed by the following equation (1). 20 × log (V ₀₂ / V ₀₁ ) ... (1) Further, the center tap 11c in the erase coil 11
As a result of investigating the relationship between the relative value of the crosstalk value with respect to the ratio (= L _ext / L _int ) of the inductance L _int of the coil portion and the inductance L _ext of the inductance element 16 between the other tap 11b and FIG. The result is as follows. Incidentally, in FIG. 5, the right end is click
The case where the loss talk is not improved is shown, and the left end shows the example 1 shown in FIGS. 1 and 2.

[Procedure Amendment 5]

[Document name to be amended] Statement

[Name of item to be corrected] 0029

[Correction method] Change

[Correction content]

As can be seen from FIG. 5, by providing the inductance element 16, the realization shown in FIGS.
The relative value of the crosstalk value is smaller than that of the first embodiment, and the inductance L _{ext of the} inductance element 16 is reduced.
Is less than or equal to 5 times the inductance L _int of the coil portion between the center tap 11c and the other tap 11b of the erase coil 11, the crosstalk value relative value is smaller than that shown in the first embodiment, and the inductance element is small. The inductance L _ext of 16 corresponds to the center tap 11c and the other tap 11b of the erase coil 11.
The effect of improving crosstalk is most obtained by making the inductance L _int of the coil portion between and the same. That is, the inductance L _ext of the inductance element 16 is equal to the erase coil 11
5 times or less than the inductance L _int of the coil portion between the center tap 11c and the other tap 11b has an effect on good crosstalk, and the same value is the best.

Claims (3)

[Claims] 1. A magnetic head core body having a read / write gap and an erase gap, a read / write coil wound around the magnetic head core body, and an erase having a portion wound around the magnetic head core body and electrically short-circuited. A magnetic head with a coil. 2. A magnetic head core body having a read / write gap and an erase gap, a read / write coil wound around the magnetic head core body, and an erase circuit wound around the magnetic head core body for a center tap and one tap. And a magnetic head having an erase coil in which the center tap and the other tap are electrically short-circuited. 3. A magnetic head core body having a read / write gap and an erase gap, a read / write coil wound around the magnetic head core body, and an erase circuit wound around the magnetic head core body for a center tap and one tap. And a magnetic head having an inductance element connected between the center tap of the erase coil and the other tap.