RU1810905C - Method and device for magnetic recording - Google Patents

Abstract

The invention relates to magnetic recording methods based on the relative movement of the transducer and the magnetic recording medium, and can be used in professional and household information storage devices. SUMMARY OF THE INVENTION: in a magnetic recording method, which involves moving the recording medium near the gap of the magnetic head, the magnetic field in the gap of the magnetic head is modulated by the voltage of the recorded signal along the length of the gap to form a line, the line is recorded on the carrier layer simultaneously along the entire length of the gap in this way that the law of variation of the longitudinal component of the residual magnetization in the row corresponds to the distribution of the recorded signal along the length of the gap. In a device for implementing a magnetic recording method comprising a magnetic head, consisting of two C-shaped ferromagnetic half-cores, separated by working and additional gaps, and a winding placed on half-cores, and a voltage source of the recorded signal in the working gap of the magnetic head is placed in a semiconductor a delay line, which is a rectangular plate of piezoelectric semiconductor, the length of the working part of which is equal to the length of the gap, at one end of which is placed electroacoustic transducer, and on the other, a sensor and an absorber of an acoustic wave, electrodes are applied at both ends of the plate, the output of the voltage source of the recorded signal is connected to the electro-acoustic transducer, the terminals of the constant current source are connected to the electrodes, the acoustic wave sensor is connected to the electrodes the input of the pulse generator with an external trigger, the output of which is connected to the outputs of the winding, and the pulse repetition period of which is determined by the propagation time Rhondda acoustic wave in the plate from one end of the gap to another. 2 s.p. f-ls, 1 ill. (L C 00 S o o e

Description

The invention relates to the accumulation of information, in particular to magnetic recording methods based on the relative movement of the transducer and the magnetic recording medium, and may be

used in professional and household information storage devices.

The purpose of the invention is to increase the recording density without decreasing the relative speed of the magnetic head and the carrier or narrowing the gap, increasing the recording speed and expanding the recorded frequency band without increasing the relative speed of the magnetic head and the carrier or narrowing the gap.

The drawing shows one of the possible variants of the device implementing the proposed method of magnetic recording.

A device for implementing the magnetic recording method comprises a magnetic head, a voltage source of a recorded signal 1, a constant current source 2, a pulse generator with an external trigger 3, a magnetic head consists of two ferromagnetic cores 4, separated by a working and additional gaps, a winding 5, placed on the 4 hearts and the piezoelectric semiconductor delay line located in the working gap. The piezoelectric semiconductor delay line consists of a piezo-semiconductor wafer with a rectangular cross section, on one end of which electrodes 7 and 8 are applied, which are an electro-acoustic transducer, the other end of the plate 6 is equipped with an acoustic wave absorber 11 and electrodes 9 and 10, which are an acoustic receiver waves and acting as an acoustic wave sensor. The length of the working fluid of the delay line corresponds to the length of the gap. The pulse repetition period of the generator 3 is determined by the time of movement of the front of the acoustic wave from one end of the gap to the other. The voltage source of the recorded signal 1 is connected to the electrode 9, the constant current source 2 is connected to the electrodes 7 and 9, the electrode 9 is connected to the input of the generator 3 through the circuit for generating a start pulse 12, the output of the generator 3 is connected to the terminals of the winding 5. Electrodes 8 and 10 are grounded.

The device operates as follows.

A magnetic recording medium with a ferromagnetic working layer moves near the working gap of the magnetic head. A constant electric current is passed between the electrodes 7 and 9 in the piezoelectric semiconductor wafer under the influence of a constant current source 2. At time TI, the voltage source of the recorded signal 1 begins to generate the voltage of the recorded signal, which is supplied to the electrode 7. An acoustic wave is excited in the piezoelectric semiconductor wafer b, whose front at the time Ti is at one end of the gap. At time T2, the front of the acoustic wave reaches the second end of the gap and acts on the sensor. At this point in time (T2), the strain distribution of plate b corresponds to the voltage distribution of the recorded signal in the interval from Ti to

T2. The sensor at time T2 starts the start pulse generation circuit 12, which generates the start pulse of the generator 3 and, upon its completion, disconnects the sensor from the input of the generator 3. Formed

the pulse at time T2 starts the generator 3. The generated pulse at time T2 starts the pulse generator 3, which starts to generate pulses with a repetition period

T T2-Ti. At time T2, the pulse from the generator 3 enters the winding 5, a magnetic field is induced in the gap, as a result of which the intrinsic magnetic field of plate b sharply increases due to leakage

electric current in it. But the electric current flowing in the plate 6, at time Tz, turns out to be a distribution of the deformation of the plate modulated along the length of the gap due to

rarefaction and thickening of the current carriers in the plate 6 at a portion of the plate corresponding to the length of the gap. Accordingly, it turns out to be modulated, ° and

intrinsic magnetic field of the plate. When the magnetic field in the gap interacts with

the carrier layer at time T2 on the carrier layer forms a line of remanent magnetization, the distribution of which along the line corresponds to the voltage distribution of the signal over a period of time from Ti to T2. Then ° the pulse ends and the magnetic field in the gap drops sharply. The carrier continues to move near the gap, and the acoustic wave continues to propagate in the plate b along the gap without recording. At time T3, when the portion of the acoustic wave that at the time T2 was at the beginning of the gap reaches the end of the gap, generator 3 generates a new pulse, which is fed to the winding 5. When the magnetic field in the gap interacts with the carrier working layer which over time T

managed to advance to the area for recording the next line, a new line is being recorded. The described steps are repeated until the recording of the entire signal is completed, after which the medium stops and the generator is turned off.

Claims (2)

1. The method of magnetic recording, in which the carrier is carried out in the magnetic recording zone, an acoustic wave is generated, it is propagated at an angle to the direction of movement of the medium, the material properties of the structural element of the recording device are changed under the influence of the acoustic wave, creating recording sections, characterized in that, in order to increase the recording density, expand the recorded frequency band and increase the recording speed, the recording sections are formed by modulating the acoustic wave with a recording signal and then By spreading it in a piezo-semiconductor wafer of rectangular cross section in the direction of the wafer length, recording is carried out simultaneously along the entire length of the piezoelectric semiconductor wafer, for which its modulated magnetic field is amplified by a pulsed magnetic field of the same direction common to all recording sections, the pulse repetition period of which equal to the time that the front of the acoustic wave travels the plate length. 2. A device for magnetic recording, comprising a magnetic head from a magnetic soft magnetic circuit with a gap and a winding located on the magnetic conductor, the source of the recorded signal, 5 an acoustic transducer containing a pair of electrodes, an acoustic wave absorber, characterized in that, in order to increase the recording density, expand the recorded frequency band and increase the recording speed, a rectangular piezoelectric semiconductor wafer, an acoustic wave sensor containing a second pair of electrodes are introduced into the device a constant current source, an external trigger pulse generator, a trigger pulse generation circuit, while the piezoelectric semiconductor wafer is located in the working gap, the working lengths th part of its length is equal to the working air gap on a one ohm end plate arranged electroacoustic transducer and the other-sensors and an acoustic wave absorber, the source output voltage is connected to the recording signal elektroakustichesko-. to the transducer, the direct current source output is connected to the electrodes of the acoustic wave sensor and electro-acoustic transducer, the acoustic wave sensor is connected to the input of the pulse generator with an external start through the pulse generation circuit, the output of which is connected to the terminals of the winding, the pulse repetition period of which is determined by the propagation time of the front of the acoustic wave in the plate from one end of the gap to the other. 0 0