JPH09305907A - Induction type magnetic head and drive circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To secure a sufficient reproducing output in reproducing and make it possible to meet a magnetic recording of high density and high frequency. SOLUTION: An induction type magnetic head performs magnetic recording and reproducing by a change of magnetic flux caused by electromagnetic induction. The magnetic head is provided with a series of coil 3 having at least three coil terminals 33, 34 and 35. Two of the three coil terminals 33-35 form a pair of terminals, which constitutes a pair of reproducing terminals 33 and 34. The other two coil terminals form another pair of coil terminals constituting a pair of recording terminals 34 and 35. A recording coil inductance produced between the pair of recording terminals 34 and 35 is set lower than a reproducing coil inductance produced between the pair of reproducing terminals 33 and 34. By applying both positive and negative recording currents only to the pair of recording terminals, a sufficient reproducing output is obtained and magnetic recording of high density and high frequency is achieved.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an induction type magnetic head used in a magnetic disk device and a drive circuit for the induction type magnetic head.

[0002]

2. Description of the Related Art A magnetic disk device such as a hard disk drive device (HDD) is used because of the necessity of high speed data processing and large amount of data processing. Such a magnetic disk device is provided with a magnetic head for recording and reproducing information. A magnetic head performs magnetic recording on a magnetic medium or reads out magnetic recording for reproduction by changing magnetic flux due to electromagnetic induction. In FIG. 7, the magnetic disk device is equipped with a magnetic head 1 including a magnetic core 5. The magnetic head 1 is mounted on a slider 4 and is floated and supported on a disk surface, which is a magnetic medium, at minute intervals. There is. As a result, the magnetic head 1 is arranged to face the magnetic recording surface with a minute gap.

Conventionally, as a magnetic head used in a magnetic disk device, there is an induction type magnetic head which magnetically records and reproduces information by a magnetic flux change caused by electromagnetic induction.
Ferrite head and metal-in-gap type (MI
G) Magnetic heads, thin-film magnetic heads, etc. are known. FIG. 8 is a schematic diagram of a configuration example of a ferrite head or a metal-in-gap (MIG) magnetic head. FIG.
In the magnetic head, in the magnetic head, two cores 26 made of an oxide magnetic material such as ferrite are formed with a magnetic gap 8 abutting the cores 26 with a non-magnetic film interposed therebetween, and the magnetic gaps 8 are fixed by glass 9 or the like. The circuit 6 is configured. In the metal-in-gap type (MIG) magnetic head, a soft magnetic thin film 7 having a high saturation magnetic flux density higher than that of ferrite such as FeAlSi alloy is arranged near the magnetic gap 8. Further, in the thin-film magnetic head, a lower magnetic body and an insulating film are formed on a substrate, a coil conductor is spirally formed on the lower magnetic body, and an upper magnetic body is laminated via an insulating film to form a closed magnetic circuit. Is forming.

FIG. 9 is a schematic block diagram of a conventional induction type magnetic head and drive circuit. In FIG. 9, the magnetic head 1
Is provided with one coil 53, while the drive circuit 2 is connected to the same coil 53 by a reproducing circuit 51 and a recording circuit 52.
It has. The reproducing circuit 51 reads the inductive current induced in the coil 53 to reproduce it, and the recording circuit 52 supplies the coil 53 with a recording current in the forward and reverse directions.
FIG. 10 is a diagram for explaining a recording state by a conventional induction type magnetic head and a drive circuit. In FIG. 10, the recording circuit 52 supplies a recording current I to the coil 53 when receiving a control signal formed based on the recording data. The control signal in FIG. 10 shows the case of an NRZI control signal which performs code conversion for each input of recording data.

The magnetic medium is magnetized by the magnetic field in the magnetic gap portion generated by the recording current. When the magnitude of the recording current I is small and the magnetic medium is in an unsaturated state, it is in an insufficient magnetized state (A in the figure), and the recording current I is a medium magnetizing current sufficient to magnetically saturate the magnetic medium (in the figure). When it exceeds I +, I-) shown by the broken line (C in the figure), the magnetic medium is in a sufficiently magnetized state (B in the figure), whereby information is recorded.

Normally, the recording current I flowing through the coil for exciting the magnetic head is controlled based on a constant cycle of the inversion interval T, and the recording current exceeds the medium magnetizing current value from the input of the control signal, so that the medium magnetizes. Until the normal polarity reversal time T
There is a delay time of r. The polarity reversal time Tr depends on the circuit characteristics of the recording circuit 52 and the inductance of the magnetic head. When the ratio to the reversal interval T becomes large, for example, an unsaturated magnetized portion (A in FIG. 10) in the medium is adjacent. It is magnetized in the opposite direction by the magnetic field in the opposite direction of the saturated magnetization portion (B in FIG. 10) (D in FIG. 10), and a good magnetization state is obtained by a phenomenon such as a shift of the magnetization transition point (C in FIG. 10). Becomes difficult. In particular, this phenomenon of deviation of the magnetization transition point becomes remarkable at high frequencies. Therefore, it is usually desired that the polarity reversal time Tr is 1/2 or less of the reversal interval T, and especially when high-frequency recording is performed, the reversal interval T becomes short, so that a short polarity reversal time Tr is required. Become.

In the magnetic disk device, high density and high frequency recording is desired. For example, as the recording density, the track density is 6000 TPI, and the linear recording density is 134 KFCI.
High density is required and recording frequency is 50MHz
The above high frequency recording is desired. At 50 MHz, the reversal interval T of the recording current is 10 ns, so the polarity reversal time Tr of 5 ns or less is required. However, for example, using a currently available recording circuit, a polarity reversal time Tr of 5 n is set in a magnetic head of a coil having 42 turns.
In order to obtain s, the inductance needs to be about 0.6 μH. However, the inductance of a metal-in-gap (MIG) magnetic head with 42 turns is about 1.8 μH, and the polarity reversal time Tr is 5 n.
It is difficult to set s or less. Therefore, it is necessary to reduce the inductance in order to reduce the polarity reversal time Tr. The magnitude of the inductance of the magnetic head depends on the number of coil turns and the magnetic material cross-sectional area of the coil winding portion. However, since the magnetic circuit is formed by machining ferrite in the MIG head, There is a limit to the reduction of the magnetic material cross-sectional area, and it is necessary to reduce the number of coil turns to reduce the inductance.

However, since the conventional magnetic head shown in FIG. 9 performs recording and reproduction using the same coil, there is a problem that the reproduction output is reduced when the number of turns of the coil is reduced.

Therefore, in order to reduce the recording during recording without lowering the reproduction output in the MIG head, as shown in FIG. 11, the read coil 54 having a large number of coil turns.
A method is known in which the write coil 55 having a small number of coil turns is separately wound around the magnetic circuit 6 to drive the coils 54 and 55 independently. However, the method of using the read coil and the write coil having different numbers of coil turns as described above has a problem that the process of winding the coil increases, and in particular, the process of separately winding two types of coils on a minute core. Will take a long time.

Therefore, as a method for reducing the recording at the time of recording without lowering the reproduction output without requiring the step of separately winding the two types of coils in the MIG head, for example, Japanese Patent Laid-Open No. 132532/1980. There has been proposed a three-terminal magnetic head as shown in FIG.

FIG. 12 is a schematic circuit diagram of the three-terminal magnetic head and drive circuit. In the magnetic head 1 of FIG. 12, a three-terminal coil 63 is configured by a first coil 64 and a second coil 65 having a connecting portion as a common terminal, and a reproducing circuit 61 on the drive circuit 2 side via a switching means 66 and It is connected to the recording circuit 62. FIG. 13 is a diagram for explaining operating states of a conventional three-terminal magnetic head and a drive circuit. FIG. 13A shows an operation state at the time of reproduction, and at the time of reproduction, the read current I _R is passed through all the coils 63 in which the first coil 64 and the second coil 65 are connected in series,
This ensures a predetermined reproduction output with a large inductance. On the other hand, FIGS. 13 (b) and 13 (c)
Shows the operation state during recording. During recording, the first coil 64 and the second coil 65 are alternately switched by the head selection signal, the recording current IW1 is passed through the first coil 64, and the second coil 65 is recorded. By passing the current IW2 and passing the recording current through the half of the coils, the inductance is reduced to about 1/4 of that during reproduction.

However, when the conventional three-terminal magnetic head and drive circuit are used, the current IW1 and current IW2
Since the delay time Td is generated at the time of switching, the polarity reversal time Tr becomes long, which makes it difficult to cope with high frequency recording. FIG. 14 is a diagram showing states of recording current and medium magnetization in a conventional three-terminal magnetic head and drive circuit. In FIG. 14, for example, a delay time Td1 occurs due to the electrical characteristics of the switching means 66 and the recording circuit 62 from the start of decreasing the recording current IW1 to the start of increasing the recording current IW2, and conversely, the recording current IW2. The delay time Td2 is generated from the start point of the decrease of the write current IW1 to the start point of the increase of the write current IW1 (in the figure, the direction of the write current IW2 is opposite). This delay time T
With respect to d1 and Td2, the polarity reversal time Tr is lengthened in the recording current I obtained by combining the recording current IW1 and the recording current IW2.

Further, when the conventional three-terminal magnetic head and drive circuit are used, there is a difference between the inductance L1 of the first coil 64 and the inductance L2 of the second coil 65 due to variations in manufacturing the coil. This difference in inductance causes a difference in the delay time Td,
There is also a problem in that the magnetization state of the medium magnetization varies. Therefore, in general, a conventional three-terminal magnetic head and drive circuit are not used in a high frequency magnetic disk device having a recording frequency of 30 MHz or higher.

[0014]

Therefore, in the conventional magnetic head and drive circuit, the polarity reversal time Tr can be shortened at the time of recording due to a large coil inductance, a delay at the time of coil switching, etc. as described above. Since it is difficult, it is difficult to deal with high density and high frequency magnetic recording.

Therefore, the present invention solves the above-mentioned problems of the conventional magnetic head and drive circuit, ensures a sufficiently large reproduction output at the time of reproduction, and is compatible with high-frequency magnetic recording at high density. An object is to provide an inductive magnetic head and a drive circuit.

[0016]

The induction type magnetic head of the present invention is an induction type magnetic head which performs magnetic recording and reproduction of information by a change in magnetic flux due to electromagnetic induction.
A coil having at least three coil terminals is provided, and one coil terminal pair formed by two coil terminals of the coil terminals is a reproduction terminal pair, and two of the coil terminals are provided.
The other coil terminal pair formed by one coil terminal is used as the recording terminal pair, and the inductance of the recording coil formed by the coil section between the recording terminal pairs is smaller than the inductance of the reproducing coil formed by the coil section between the reproducing terminal pairs. And by passing the recording current in both the forward and reverse directions only between the pair of recording terminals,
(EN) An inductive magnetic head which can secure a sufficiently large reproduction output at the time of reproduction and can cope with high-frequency magnetic recording with high density.

Among the terminals of the coil used in the magnetic head of the present invention, the output terminal pair for obtaining the reproduction output is formed by two coil terminals of at least three coil terminals provided in this coil, and recording is performed. The recording terminal pair for passing current is formed by two coil terminals out of at least three coil terminals of the same coil. The combination of the coil terminals at this time is a combination in which the inductance of the recording coil formed by the coil portion between the recording terminal pair is smaller than the inductance of the reproducing coil formed by the coil portion between the reproducing terminal pair. This makes it possible to configure a reproducing coil having a large inductance and a recording coil having a small inductance by using one continuous coil, and shorten the polarity reversal time Tr to cope with the short reversal interval T in high frequency recording. it can. In addition, since the recording coil passes the recording current in both forward and reverse directions, the delay time due to the switching of the recording coil and the variation in medium magnetization due to the difference in the inductance of the recording coil do not occur.

Further, the induction type magnetic head of the present invention is an induction type magnetic head for magnetically recording and reproducing information by magnetic flux change due to electromagnetic induction. The magnetic head has continuous end terminals and intermediate intermediate terminals. The coil portion between the end terminals at both ends of the coil is used as a reproducing coil, and the coil portion between one end terminal and the intermediate terminal is used as a recording coil. By supplying a recording current, a sufficiently large reproduction output is ensured at the time of reproduction, and a three-terminal inductive magnetic head having a high density and compatible with high-frequency magnetic recording is constructed.

According to this induction type magnetic head, since the end terminals and the intermediate terminals at both ends of the coil are used as terminals of the reproducing coil and the recording coil in one continuous coil, the inductance of the recording coil formed is reproduced. Always smaller than the inductance of the coil,
Further, the recording current flows in both the forward and reverse directions through the recording coil. As a result, the polarity reversal time Tr can be shortened to cope with the short reversal interval T in high frequency recording. In addition, since the recording coil passes the recording current in both forward and reverse directions, the delay time due to the switching of the recording coil and the variation in medium magnetization due to the difference in the inductance of the recording coil do not occur.

Further, by setting the reading coil inductance to 0.95 μH or less and the recording coil inductance to 0.3 μH or less, it is possible to cope with high frequency recording at a recording frequency of 50 MHz or more.

Further, one continuous coil can be formed by winding the coil around the core. At this time, the coil is formed by winding the parallel wire, and the end portion of the parallel wire is used as a terminal to form the parallel wire. The reproducing coil and the recording coil can be formed in one step of winding.

Further, one continuous coil can be formed by a thin film coil, and by forming a part of the coil as a terminal when forming the thin film coil, the reproducing coil and the recording coil can be formed in one step.

Further, the drive circuit of the induction type magnetic head of the present invention is provided with one continuous coil having at least three coil terminals, and the induction type magnetic head for performing magnetic recording / reproduction of information by magnetic flux change by electromagnetic induction. In the drive circuit, a reproducing circuit that is connected to one coil terminal pair formed by two coil terminals of the coil terminals and reproduces a signal from a reproducing coil formed by a coil portion between the one coil terminal pair; Connected to another coil terminal pair formed by two coil terminals of the coil terminals, and supplying a recording current in the forward and reverse directions only to the recording coil formed by the coil portion between the other coil terminal pair. And a recording circuit that operates.
As a result, at the time of reproduction, the reproduction circuit inputs the signal from the reproduction coil to read the information recorded on the magnetized medium,
At the time of recording, the recording circuit applies a recording current in the forward and reverse directions to only one recording coil without switching the recording coil to write information on the magnetized medium. As a result, it is possible to secure a sufficiently large reproduction output during reproduction and drive the induction type magnetic head compatible with high-frequency magnetic recording with high density.

[0024]

Embodiments of the present invention will be described below in detail with reference to the drawings. The configurations of the induction type magnetic head and the drive circuit of the present invention will be described with reference to FIG. In FIG. 1, the magnetic head 1 comprises one coil 3, while the drive circuit 2 is a reproducing circuit 2 connected to the coil 3.
1 and a recording circuit 22. One coil 3 has three terminals, which are end terminals 33 and 35 at both ends and an intermediate terminal 34. All the coils formed between the terminals of the end terminals 33 and 35 form a reproducing coil and are connected to the reproducing circuit 21.
This coil 3 is divided into two coil portions by an intermediate terminal 34, a first coil 31 is formed between the terminals of the end terminal 33 and the intermediate terminal 34, and a second coil is formed between the terminals of the end terminal 35 and the intermediate terminal 34. The coil 32 is formed. Either one of the first coil 31 and the second coil 32 constitutes a recording coil and is connected to the recording circuit 22. FIG.
Although the second coil 32 is connected to the recording circuit 22 as a recording coil in the configuration example shown in, it is also possible to connect the first coil 31 to the recording circuit 21 as a recording coil.

Further, the position of the intermediate terminal 34 in the coil 3 can be set arbitrarily, and the inductance of the recording coil can be set within a polarity reversal time Tr capable of realizing a frequency for magnetic recording. Make settings so that

Next, the operation of the induction type magnetic head and the drive circuit of the present invention will be described with reference to FIG. FIG.
(A) shows an operation state at the time of reproduction. At the time of reproduction, all the coils of the coil 3 are used as reproduction coils, and information of the magnetization medium is reproduced by measuring the read current I _R by the reproduction circuit 21. By setting the total inductance Lh at the time of reading of the coil 3 to, for example, about 0.95 μH, it is possible to correspond to a magnetic disk device having a maximum recording frequency of 50 MHz or more, and a predetermined reproduction output can be secured.

On the other hand, FIG. 2 (b) shows an operating state during recording when the second coil is a recording coil. At the time of recording, only one of the second coils is used, and the recording circuit 22 causes the recording current IW1 and the recording current IW2 which is the reverse of the recording current IW1 to flow through the second coil 32. As a result, the inductance L1 during recording can be made lower than the inductance Lh during reproduction. For example, the intermediate terminal 3
When 4 is set in the substantially middle portion of the coil 3, the inductance L of the coil 3 is in proportion to the square of the number of turns N, so that the inductance L1 at the time of recording is approximately 1/4 of the inductance Lh at the time of reproducing.

Further, the recording current I flowing through the second coil 32
Since the recording current directions of W1 and the recording current IW2 in the forward and reverse directions are determined by the direction of the output current of the recording circuit 22, no switching means for switching the recording current is required, and there is only one recording coil. Therefore, switching means for switching and supplying the recording current to the two recording coils is not required. Further, the first coil 31 of the coils 3 is not connected to the recording circuit 22 and is not used during recording.

FIG. 3 is a diagram for explaining a recording state by the induction type magnetic head and the drive circuit of the present invention. FIG.
In, the recording circuit 22 supplies the recording current I _R to the second coil 32 of the coil 3 when receiving the control signal formed based on the recording data. Note that the control signal in FIG. 3 shows the case of an NRZI control signal that performs code conversion for each input of recording data, and the recording current I _R is represented by IW1 in the positive direction and IW2 in the negative direction. The positive and negative directions are set for the sake of convenience, and can be expressed in the opposite directions.

The magnetic medium is magnetized by the magnetic field generated by the recording current. The recording current I _R according to the change of the control signal
When the flow of _R is reversed, the recording current I _R changes with a time constant corresponding to the magnitude of the inductance L2 of the recording coil. When the recording current I _R exceeds a medium magnetizing current (I +, I− shown by broken lines in the figure) sufficient to magnetically saturate the magnetic medium, the magnetic medium is in a sufficiently magnetized state, whereby information is recorded. Be seen. At this time, the recording current I _R flowing through the coil to excite the magnetic head is controlled based on a constant cycle of the inversion interval T, and the medium magnetization is such that the recording current exceeds the medium magnetization current value from the input of the control signal. Is performed after a delay time of the polarity reversal time Tr until is performed.

The polarity reversal time Tr depends on the circuit characteristics and the inductance of the recording circuit 22, and the inductance L2 of the recording coil 32 is set to, for example, 0.3 μH or less so that it is 1 with respect to the reversal interval T normally desired in magnetic recording. The polarity reversal time Tr of / 2 or less can be obtained, and the maximum recording frequency can be applied to the magnetic disk device of 50 MHz or more.

Further, when the reversal interval T is shortened by the high frequency recording and the ratio of the polarity reversal time Tr to the reversal interval T is increased, the reverse magnetization due to the magnetic field in the opposite direction from the adjacent saturation magnetization part in the medium is reversed. A phenomenon such as a shift of the magnetization transition point occurs due to a phenomenon such as directional magnetization, but the polarity reversal time T due to a decrease in the inductance of the recording coil.
By shortening r, the phenomenon such as the shift of the magnetization transition point can be reduced.

Next, the structure of the magnetic head of the present invention will be described with reference to FIG. 4 as an example of the structure of a magnetic head having a core. In FIG. 4A, the magnetic head forms a coil by winding the parallel wire 10 around a magnetic circuit 16 formed by a core of a magnetic material such as ferrite. A metal magnetic film (Fe-Ta-N) 17 having a high magnetic permeability is provided in the magnetic gap 18 portion of the magnetic circuit 16. The parallel line 10 is composed of two conductors as shown in FIG. One line (indicated by a solid line in the figure) is terminal a
And the terminal b1 and the other line (indicated by the broken line in the figure)
Has terminals b2 and c. When this parallel wire 10 is wound around a core, and terminals a and c are end terminals 13 and 14 as shown in FIG. 4 (c), a reproducing coil in which wires of two lengths are wound is formed. Can be formed. If the terminals b1 and b2 of the respective wires are connected to form the intermediate terminal 14, one terminal is provided between the end terminal 13 and the intermediate terminal 14 and the other terminal 15 and the intermediate terminal 14 are provided. It is possible to form the recording coils 11 and 12 in which the length wire is wound. Comparing the recording coils 11 and 12 with the reproducing coil, the ratio of the number of turns wound around the core is about 1.
The ratio is 2 and the inductance ratio is about 1: 4.

Numerical examples in the configuration example shown in FIG. 4 will be described. Using a MIG head, the magnetic material has a cross-sectional area of 25
A parallel wire 10 in which a wire having a wire diameter of 20 μm is used as a bifarer in a winding part of 00 μm ² (50 μm × 50 μm).
Is wound for 13 turns, the wound parallel wire 10 is divided, and one ends of different wires at both ends are connected to form an intermediate terminal b.
Create by connecting so that the remaining ends of both ends are in series.
As a result, the number of turns of the coil during reproduction is 26 turns, and the number of turns of the coil during recording is 13 turns.

At this time, the measured value of the inductance of the coil formed between the terminals ac is 0.83 μH, the measured value of the inductance of the coil formed between the terminals bc is 0.26 μH, and the measured value of the terminal ab. The measured value of the inductance of the coil formed between was 0.24 μH. When a single wire (monofilar) was used for the head and a winding of 26 turns was applied to form a two-terminal head, the inductance of the coil was 0.80 μH.

Generally, the number of turns of the coil is set from the inductance Lh of the coil during reproduction so that the resonance frequency f0 of the reproducing system including the head and the reproducing circuit becomes a predetermined frequency, and is represented by the following equation. f0 = 1 / {2π (Lh.C) ^1/2 } C is the sum (Cin + Ch) of the input capacitance Cin of the reproducing circuit and the stray capacitance Ch between the coil wires.

In the above equation, assuming that the input capacitance Cin is 7 pF and the stray capacitance Ch between coil lines is 4 pF, the inductance Lh of the coil during reproduction is 0 in the application example to which the induction type magnetic head of the present invention is applied. Since it is 0.83 μH, the resonance frequency f0 is 52.7 MHz, and when applied to a two-terminal head using a conventional single wire (monofilar), the coil inductance Lh during reproduction is 0.80 μH. Resonance frequency f0 is 5
It becomes 3.7 MHz.

Also, Hc is 2000 Oe at 3.5 inches.
The disk was rotated at 5200 rpm, and the flying height of the head was 30 at a measurement radial position r of 37.3 mm corresponding to a relative speed of the head and the disk of 20.32 m / s.
nm and a recording frequency of 50 MHz (corresponding to a linear recording density of 125 kFCI), an induction magnetic head of the present invention was applied and a conventional two-terminal head using a single wire (monofilar). The recording current reversal time is 7.7 ns when compared with the case of application.
To 5 ns, and the non-linear magnetization transition shift (NLTS) used as an evaluation value for determining the quality of the magnetization state of the magnetization medium is improved from 50% to 25%.

Nonlinear magnetization transition shift (NLTS)
Is the ratio of the magnetization transition shift amount δ to the reversal interval T (δ
/ T), and the smaller the ratio, the better the magnetization state of the magnetization medium. The above-mentioned nonlinear magnetization transition shift (N
There are several known methods for obtaining the numerical value of (LTS), but here, it is the value obtained by the fifth harmonic extraction method.

The magnetic head in the above embodiment is
A 50% size composite type MIG head in which a magnetic core is molded with glass on a non-magnetic slider is used. Here, the 50% size has a length of 1.6 mm and a width of 1.
The geometrical dimensions are 2 mm and the thickness is 0.4 mm. According to this embodiment, by using the parallel wire, the reproducing coil and the recording coil can be simultaneously formed in one winding step.

Next, an example in which the induction type magnetic head of the present invention is applied to a thin film coil will be described with reference to FIG. FIG.
In, the thin-film coil 40 is formed by a normal thin-film technique, centering on the coupling portion connecting the two upper magnetic layers 41 and the lower magnetic layer 42.

The thin film coil 40 has an end terminal 4 at the end.
3, 45 and an intermediate terminal 44, a reproducing coil is formed between the end terminals 43 and 45 in the same manner as shown in the configuration example of FIG. 4, and a recording coil is formed between the end terminal 43 or 45 and the intermediate terminal 44. Make up. The end terminals 43 and 45 and the intermediate terminal 44 can be formed at the same time when the pattern of the thin film coil is formed. A magnetic gap 48 is formed between the ends of the upper magnetic layer 41 and the lower magnetic layer 42.

The example shown in FIG. 6 is a configuration example in which the number of terminals is increased. In the magnetic head, similarly to FIG. 4, the conductor wire 46 is wound around a magnetic circuit formed by a core of a magnetic material such as ferrite to form a coil. Conductor 46 is shown in FIG.
It is composed of three lines as shown in FIG. One line (indicated by a solid line in the figure) includes terminals a and b, the other line (indicated by a broken line in the figure) includes terminals c and d, and another line (in the figure). Is indicated by a dot-dash line)
Has a terminal e and a terminal f. The conductor 46 is wound around the core, and the terminals b and c are connected as shown in FIG.
When the terminal d and the terminal e are connected and the terminal a and the terminal f are the end terminals, it is possible to form a reproducing coil in which three wires are wound as shown in FIG. 6C. it can.

Further, as shown in FIG. 6 (c), if the terminals a and b are end terminals, a recording coil can be constructed by one line shown by a solid line, and the terminals c and db can be connected. When the end terminals are used, a recording coil can be constructed by one line shown by a broken line, and when the terminals e and f are end terminals, a recording coil can be constructed by one line shown by a chain line. You can Further, when the terminals a and d are end terminals, a recording coil having two lines shown by a solid line and a broken line can be constructed, and when the terminals c and f are end terminals, they are shown by a broken line and a dashed line. It is possible to construct a recording coil with two wires that are connected. According to this embodiment, the size of the inductance can be changed by the combination of the end terminal and the intermediate terminal.

[0045]

As described above, according to the present invention,
It is possible to provide an induction type magnetic head and a drive circuit which can secure a sufficiently large reproduction output at the time of reproduction and can cope with high frequency and high frequency magnetic recording.

[Brief description of drawings]

FIG. 1 is a diagram for explaining a configuration of an induction type magnetic head and a drive circuit of the present invention.

FIG. 2 is a diagram for explaining the operation of the induction type magnetic head and the drive circuit of the present invention.

FIG. 3 is a diagram for explaining a recording state by the induction type magnetic head and the drive circuit of the present invention.

FIG. 4 is a diagram for explaining a configuration example of a magnetic head having a core, which is a configuration of the magnetic head of the present invention.

FIG. 5 is a diagram for explaining an example in which the induction type magnetic head of the present invention is applied to a thin film coil.

FIG. 6 is a diagram for explaining another configuration example of the magnetic head having a core in the configuration of the magnetic head of the present invention.

FIG. 7 is a schematic view of a magnetic head.

FIG. 8 is a schematic configuration diagram of a magnetic head.

FIG. 9 is a schematic configuration diagram of a conventional induction type magnetic head and a drive circuit.

FIG. 10 is a diagram for explaining a recording state by a conventional induction type magnetic head and a drive circuit.

FIG. 11 is a diagram for explaining another configuration of the conventional induction type magnetic head.

FIG. 12 is a schematic circuit diagram of a conventional three-terminal magnetic head and drive circuit.

FIG. 13 is a diagram for explaining operating states of a conventional three-terminal magnetic head and a drive circuit.

FIG. 14 is a diagram showing states of recording current and medium magnetization in a conventional three-terminal magnetic head and drive circuit.

[Explanation of symbols]

 1 Magnetic Head 2 Drive Circuit 3,53 Coil 8, 18, 48 Magnetic Gap 10 Parallel Wire 11,31 First Coil 12,32 Second Coil 13,15,43,45 End Terminal 14,44 Intermediate Terminal 21,51 Playback circuit 22, 52 Recording circuit

Front Page Continuation (72) Inventor Norio Koji 6-735 Kita-Shinagawa, Shinagawa-ku, Tokyo Sony Corporation (72) Keiji Narizawa 6-35 Kita-Shinagawa, Shinagawa-ku, Tokyo Sony Incorporated (72) Inventor Takashi Yanagibashi 6-735 Kita-Shinagawa, Shinagawa-ku, Tokyo Sony Corporation (72) Inventor Seiji Saito 6-35 Kita-Shinagawa, Shinagawa-ku, Tokyo Sony Corporation Within

Claims (7)

[Claims] 1. An induction type magnetic head for magnetically recording and reproducing information by magnetic flux change due to electromagnetic induction, wherein the magnetic head comprises a coil having at least three coil terminals, and two of the coil terminals are coil terminals. Is a reproduction terminal pair, and another coil terminal pair formed by two coil terminals of the coil terminals is a recording terminal pair, and a coil portion between the recording terminal pairs is formed. The inductance of the recording coil is set to be smaller than the inductance of the reproducing coil formed by the coil portion between the reproducing terminal pair, and the inductance when reading the reproducing coil is 0.9.
5μH or less, the recording coil inductance is 0.3
An induction type magnetic head characterized in that the recording current is applied in both forward and reverse directions only between a pair of recording terminals, at a value of μH or less. 2. An induction type magnetic head for magnetically recording and reproducing information by changing magnetic flux by electromagnetic induction, wherein the magnetic head includes coils having end terminals at both ends and intermediate intermediate terminals, and the end portions at the both ends. The coil portion between the terminals is a reproducing coil, the coil portion between one end terminal and the intermediate terminal is a recording coil, the reading coil has an inductance of 0.95 μH or less, and the recording coil has an inductance of 0. An induction type magnetic head characterized in that the recording current is set to 3 μH or less, and a recording current in both forward and reverse directions is flowed only through the recording coil. 3. The induction type magnetic head according to claim 1, wherein the coil is formed by winding it around a magnetic circuit. 4. The induction type magnetic head according to claim 3, wherein the magnetic circuit is composed of a core or a thin film composed of a metal magnetic film. 5. The induction type magnetic head according to claim 3, wherein the coil is formed by winding a parallel wire, and an end portion of the parallel wire serves as a terminal. 6. The induction type magnetic head according to claim 1, wherein the coil is formed of a thin film coil. 7. A drive circuit of an induction type magnetic head, comprising a coil having at least three coil terminals, wherein two coil terminals of the coil terminals are formed in a drive circuit of an inductive magnetic head for magnetically recording and reproducing information by magnetic flux change due to electromagnetic induction. A reproducing circuit that is connected to one coil terminal pair and reproduces a signal from a reproducing coil formed by a coil portion between the one coil terminal pair, and another coil circuit formed by two coil terminals of the coil terminals. An inductive type comprising: a recording circuit connected to one coil terminal pair and supplying a recording current in forward and reverse directions only to a recording coil formed by a coil portion between the other coil terminal pair. Magnetic head drive circuit.