KR810001727B1 - Magnetic record apparatus - Google Patents

Abstract

The apparatus includes a magnetoresistive element which comprises an insulating subtrate upon. Which first and second ferromagnetic strips are provided. The strips are connected in series to define a junction therebetween from which an output signal is produced from the junction in the element as a function of the relative positions of leading and trailing edges of the member according to the magnetoresistive element.

Description

Apparatus for identifying magnetic media

1 is a view for explaining the present invention.

2 is a diagram showing the principle configuration of a detection head used in the present invention.

3 and 4 show examples of the actual detection head.

5 to 7 are schematic diagrams of examples of the present invention device.

8 is a waveform diagram for explanation thereof.

In the magnetic tape, the magnetic surface is made of gamma hematite Υ-Fe ₂ O ₃ (hereinafter referred to as a normal tape), chromium dioxide CrO ₂ (hereinafter referred to as chromium tape), There is a two-layer structure (hereinafter referred to as a two-layer tape) of VII-Fe ₂ O ₃ and chromium dioxide CrO ₂ .

In the tape recorder, the magnetic tape switches the bias circuit and the equalizer circuit depending on any of the above.

By the way, as a method of automatically identifying which of the above-mentioned magnetic tapes is any of the above, a signal recorded by making the magnetic tape into forward feed and recording a constant signal thereon, and then rewinding and then recording the tape again by forward feed The tape is identified by reproducing and detecting the level of the reproduced signal, thereby switching circuits, and then rewinding the tape again to bring the recording state.

However, this method is identified by running the tape, and it is necessary to repeat the operation of the forward feed and the rewind twice until the recording state is achieved, and there is a drawback that it is complicated and complicated in construction.

In view of the above, the present invention is intended to automatically identify which tape is the tape in a stopped state.

Next, an example of an apparatus for identifying a magnetic medium according to the present invention will be described with reference to the drawings.

The relationship between the magnetic field H and the magnetic flux density B of the magnetic tape exhibits hysteresis characteristics, as shown in FIG. 1A, and its normal magnetic force (HA) is relatively small as shown by a solid line in a normal tape. It is about 324Oe, and as shown by the broken line in chrome tape, the coercive force HB is relatively large, about 469Oe.

In the present invention, the excitation coil 3 and the detection coil 4A are recommended for the magnetic core 2A having a void 1A as shown in FIG. Vi) to form a magnetic head for detection, and the void 1A is welded to the magnetic surface 5a of the magnetic tape 5 so that the excitation coil 3 flows a change current I on a triangular wave, for example. The tape 5 is identified by detecting the difference between the aspects of the output voltage e obtained by the detection coil 4A. That is, when the magnetic field H generated in accordance with the current I flowing in the coil 3 is changed from negative to positive through zero and then reversed thereto, the magnetic flux density B is determined by the tape 5. ) Is changed like a solid line or broken line in FIG. 1A according to which tape, but the voltage e obtained by the coil 4A is proportional to the rate of change of the magnetic flux density B. FIG. Therefore, when the tape 5 is a normal tape, the voltage e is a negative current value in which the magnetic field H becomes HA when the current I changes from negative to positive through zero, as shown in FIG. A negative peak value is shown at IA, and when the current I changes from positive to zero through negative, the magnetic field H shows a negative peak value at a negative current value -IA where the value of -HA is reached. In the case of chromium tape, the voltage e is the positive peak value at the positive current value IB where the magnetic field H becomes -HB when the current I changes from negative to positive through zero, as shown in FIG. When the current I changes from positive to zero through negative, the magnetic field H changes to form a mountain so as to represent a negative peak value at the negative current value -IB where the value becomes -HB.

Therefore, when the current I becomes zero, detecting the long and short periods of time until the output voltage e indicates a positive or negative peak value, it is possible to automatically identify which tape the tape 5 is.

In addition, since the voltage e _c obtained by the hysteresis characteristic of the core 2A cannot actually be ignored with respect to the voltage e caused by the hysteresis characteristic of the tape 5 described above, the voltage obtained by the detection coil 4A is practically practical. The dummy core may be separately provided to cancel the voltage e _c due to the hysteresis characteristics of the core 2A.

That is, for example, as shown in FIG. 3, the dummy core 2B constituting the same path as the core 2A is integrally formed with the core 2A, and the excitation coil is formed on both common paths. (3) is recommended, and each of the detection coils 4A and 4B is recommended, and the void 1A of the core 2A is welded to the magnetic surface 5a of the tape 5, and the core 2A The air gap 1A is supplied with a change current I through the excitation coil 3, and the voltage obtained by both detection coils 4A and 4B is allowed to air gap in the differential amplifier 6, without causing this to be treated. In this way, the voltage obtained by the detection coil 4A is applied to the above-mentioned voltage e by the hysteresis characteristic of the tape 5, e _c by the hysteresis characteristic of the core 2A is applied, and the detection coil 4B Since the voltage obtained at is only the voltage e _c due to the hysteresis characteristic of the core 2B, only the above-described voltage e due to the hysteresis characteristic of the tape 5 is obtained at the output terminal 6 a of the amplifier 6.

In addition, as shown in FIG. 4, the cores 2A and 2B are separately formed and arranged side by side in the width direction of the tape 5, and the space 2A of the core 2A is formed on the tape 5 by the core 2A. The core 2A may be treated so that the void 1A does not come into contact with the tape 5. In this case, the space is not taken in the thickness direction of the tape 5 as in the case of integrally forming as shown in FIG.

The above-described detecting magnetic head may combine recording and reproduction with the magnetic head and the erasing magnetic head, or may be provided separately from these heads. When separately installed, the gap is 1A if it is a cassette type tape recorder. Can be made to serve, for example, in a so-called green belt of a tape in a small window of a cassette.

In actual operation, by first operating the recording button, the gap 1A of the detection head is first welded to the tape 5, and in this case, the tape 5 is given tension and sufficient welding pressure is applied. Subsequently, a change current I is flowed through the excitation coil 3 to identify the tape 5 and automatically switch the bias circuit or the equalizer circuit by the identification output by processing the output voltage e. When the head is separate from the lock head and the erasing head, the head may be separated from the tape 5 and then switched to the recording state.

The identification circuit can be configured, for example, as shown in FIGS. 5 to 7. That is, in the example of Fig. 5, reference numeral 7 denotes an earth table multivibrator, in which the DT factor obtains a square wave signal So (Fig. 8A) of 1/2, which is supplied to the flip-flop circuit 8, A square wave signal SF (Fig. 8B) divided in half is obtained, and this is supplied to the integrating circuit 9, and the current I (the eighth) which changes to a triangular wave with a positive boundary at zero boundaries is obtained. C) is obtained and supplied to the excitation coil 3. Then, the output voltage e of the differential amplifier 6 is supplied to the differential circuit 10 for differentiation, and the output thereof is supplied to the zero detection circuit 11 to supply the pulse signal at the positive and negative peak values of the above-described output voltage e. Get

Then, the square wave signal So from the earth table multivibrator 7 is supplied to the set side of the flip-flop circuit 12 to set the circuit 12 at the time when the signal So falls, that is, when the current I becomes zero, and the zero point. The pulse signal from the detection circuit 11 is supplied to the reset side of the flip-flop circuit 12 to reset the circuit 12 at the time of the positive and negative peak values of the output voltage e. Therefore, in the case where the tape 5 is a normal tape, the output voltage e shows peak values at the time when the current I becomes IA and -IA as shown in FIG. Similarly, a pulse signal SA having a relatively small pulse width is obtained, and in the case where the tape 5 is chromium tape, the output voltage e exhibits a peak value when the current I becomes I _B and -I _B as in the case of the same degree E. As a result, a pulse signal S _B having a relatively large pulse width is obtained from the circuit 12 as in the same diagram G.

Therefore, the pulse signal S _A or S _B is supplied to the AND circuit 13, while the signal SO from the earth table multivibrator 7 is supplied to the monomultivibrator 14, so that the current I becomes zero. When the signal Sc (FIG. 8H) which becomes "0" is acquired between the fall of the pulse signal S _{A and} the fall of the pulse signal S _B from a viewpoint to a viewpoint, and supplies to these AND circuits 13, an AND circuit From (13), a pulse signal S _D (Fig. 8) having a constant pulse width is obtained only when the tape 5 is a chrome tape. Therefore, when the output of this end circuit 13 is supplied to the smoothing circuit 15, the output stage 16 becomes zero when the tape 5 is a normal tape, and when it is chromium tape, it has a positive fixed value. The output voltage is obtained so that it is possible to identify which tape the tape 5 is, and to automatically switch the bias circuit, the equalizer circuit and the like to this output voltage.

In the example of FIG. 6, a clock pulse generator 17 is provided to obtain a floc pulse having a constant repetition frequency, and is supplied to the gate circuit 18, and the tape 5 obtained from the flip flop circuit 12 is a tape. In response to the application, a pulse signal S _A or S _B (FIG. 8 F, G) having a different pulse width is supplied to the circuit 18 to gate the floc pulse in the interval of the pulse width. Clock pulse groups PA or PB (Fig. 8, J and K) having different numbers depending on the application of the tape are counted by the counter 19, and their output is converted into a DC voltage by the circuit 20 to the output terminal 21. This is the case where the same identification output voltage as in the above example is obtained.

In the example of FIG. 7, the square wave signal So (Fig. 8A) from the earth table multivibrator 7 is supplied to the AND gate circuit 22, while the pulse signal from the zero detection circuit 11 is monopolized. The pulse signal which is supplied to the multivibrator 23 and becomes "I" for a predetermined time at the time when the output voltage e represents a peak value, and thus the pulse of which the position of the section of "I" differs depending on which tape the tape 5 is. _A signal M _A or M _B (Fig. 8 L, M) is obtained and supplied to the end circuit 22, and in the end circuit 22, the pulse signal S having a constant pulse width only when the tape 5 is chrome tape. _E (Fig. 8 N) is obtained, and the output of this AND circuit 22 is supplied to the smoothing circuit 23 to obtain the same identification output voltage at the output terminal 25. FIG.

Then, the integral circuit 9 is not provided separately from the excitation coil 3, and a resistor is connected between the flip-flop circuit 8 and the coil 3, and this resistor and the coil 3 are integrated circuits. It can also be configured.

The current I flowing through the excitation coil 3 may be changed into a sine wave, for example.

Also, the current I is changed from the middle value of I _A and I _{B to} the middle value of -I _A and I _B so that in the case of chromium tape, no acid is generated in the output voltage e. Perception may be identified.

This technique can be applied to the identification of higher alloy tapes of HC.

Since the peak value of the acid peak value of the output voltage e is proportional to the thickness of the magnetic film of the tape, the thickness of the magnetic film can be detected by detecting the peak value level. Since it is inversely proportional to the distance between the tape and the gap 1A of the detection head, the looseness of the tape can be detected by detecting the level of the peak value.

This technique can be applied to automatic stop and automatic extraction L / End detection. According to the present invention described above, since the tape can be identified while the tape is stopped without running, the operation is remarkably simple and the configuration can be extremely simplified. In addition, automatic identification is made, and the switching of the bias circuit and the equalizer circuit is performed automatically, so that there is no malfunction, and the user does not need to worry about it.

Claims (1)

A current generating circuit for recommending an excitation coil and a detection coil to a core serving a magnetic medium as shown in the drawings and described above in the text, and allowing a change current to flow through the excitation coil; and the detection A detection circuit is provided to which an output signal obtained from a coil is supplied. By this detection circuit, a difference in the peak value of the output signal with respect to the current based on a difference in the coercive force of each magnetic medium is detected. And a magnetic medium identifying device for identifying the magnetic medium.

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