SU1150644A1 - Process for reproducing information from magnetic medium - Google Patents

Abstract

A METHOD FOR REPRODUCTION OF INFORMATION FROM A MAGNETIC MEDIA, in which the time-varying magnetic flux is converted into a voltage, generates a current by applying a voltage to the load resistance, and the information is judged by the magnitude of the changeable voltage proportional to the current, characterized in that In order to expand the frequency and dynamic ranges, during the formation of the current, the magnitude of the resistance of the load is changed to obtain a short-circuit current.

Description

The invention relates to a device, namely a magnetic recording-reproduction technique. The known method is implemented in a device containing a magnetic head connected to the input of an LI converter. However, this method is characterized by insufficiently high frequency and dynamic ranges. The closest to the proposed technical essence and the achieved result is a method implemented in a device containing a magnetic head connected to a voltage converter with a low ohm input, forming together with the inductance of the magnetic head an aperiodic circuit C23. However, the limestone method is characterized by low frequency and dynamic ranges. The purpose of the invention is to expand the frequency and dynamic ranges. The goal is achieved in that according to the method in which the time-varying magnetic flux is converted into a voltage, a current is generated by applying a voltage to the load resistance, and the information is judged by the magnitude of the variable voltage proportional to the current, when forming the current makes a change in the resistance to load until a short circuit current is obtained. The drawing shows a device that implements the proposed method. The device contains a magnetic head 1, which includes a winding 2, a converter 3 short circuit current - voltage, which, for example, includes a current amplifier 4, the device works in the following way. When the turns of the winding 2 of the magnetic head 1 intersect with a time-varying magnetic flux, the EMF arising in the winding is determined by the ratio 0, -o, 1 UI ujg - the number of turns of the sensor winding; magnetic flux; 14 . F - VAT; (d is the magnetic resistance of the flow closure medium. The short-circuited winding current with significantly lower values of capacitance and active resistance compared to inductance is determined by the dependence o f-UtNt, (g of which, taking into account the LO-O / RM ratio, (3) where Lp is the inductance of the winding, and (1) we obtain Vti given that a magnetic flux is generated in the winding of the sensor when current flows, directed oppositely to the EMF-generating flow, / R the resulting flux acting on the winding will be determined by the expression Ф Ф2 .- ((( 1m) where A is some about conversion converter, taking into account the potential losses during conversion (A 0); n is the number of balancing iterations carried out in time or in space. Thus, as follows from the above relations, the current in the short-circuited sensor winding does not depend on the magnetic resistance of the magnetic medium flow and its value will be the maximum with the number of winding threads minimally realized. Switching converter 3, characterized by the input resistance R O to the winding of the magnetic head 1, ensures that short circuit and the necessary reformation, in which the output voltage of the converter is dependent on (t to output sh, where K is a conversion coefficient having an impedance (active resistance) dimension) Independence of the signal at the output of converter 3 from the magnetic resistance of the magnetic flux circuit of the magnetic flux circuit in a new way to organize the protection of the contact head-carrier pair as a result of an increase or introduction of a protective layer on the working surface of the gap and (or) carrier, performed by various dstvami, including an air gap at speeds carrier reproduction corresponding to the contact methods. Due to the compensation of the magnetic flux in the magnetic core of the magnetic head 1 in the integrated signal proportional to the current in the winding 2 of the magnetic head 1, losses due to the magnetic core material, i.e. expanding the frequency band of the signal. The expansion of the dynamic range is due to the receipt of a signal proportional to the magnetization (VAT) of the carrier, a significantly larger signal proportional to the rate of change of the magnetic flux realized in known cases, and also as a result of an increase in the signal-to-noise ratio, including combined head) and crosstalk (in a multi-channel head) noise, the level of which is determined in accordance with booting, C8) 5nCi), / lp about the magnetic resistance of the magnetic circuit interference flux including resistance of the air gap of the largest magnitude; R, l MDS interference; 3n (i) is the current in the winding of the head, due to the effect of interference. From expression (6) it follows that the compensation of the magnetic flux that generates the emf in one winding of the head is incomplete. Therefore, it is possible and appropriate for a more complete compensation of the flow to include several windings according to the proposed manual, the signals at the output of the converters of the short circuit current whose voltage can be summed up. At the same time, the total signal for the windings will be approximately 2 times larger than that obtained from the bottom of the winding, and approximately twice as much as that obtained from the successively connected windings, with an approximate increase in the signal-to-noise ratio by 1.4 times and a significant decrease in the common-phase mud, those. in accordance with the expression .i .. where and the total voltage of the outputs of the transducers of individual windings; p is the number of windings, limited by the degree of flow KOMneHcauHt; Ug is the output voltage of a converter connected to series-connected windings. Thus, the proposed method allows to significantly expand the dynamic range depending on the type and degree of perfection of the heads by 10–20 dB, including an increase in the signal-to-noise ratio by approximately 30–40 dB in multichannel combined heads, to significantly increase the frequency range approximately 1.5-3 times, limited by slit losses in the head. When this signal is received at the output of the converter, the short-circuit current, the voltage inversely proportional to the number of turns of the head winding, determines the manufacturability and the only possible implementation of low-turn, including single-turn, inductive magnetic heads, manufactured using integral technology and used for relative. low speeds of movement of the carrier, for example, the corresponding speeds of the contact reproduction method, 1150644

In addition, a considerable amount of

The emergence of parasitic AM, in addition to the magnetic transfusion modulation technique, that occurs when

When reproduced due to non-adherence, more sensitive and

VIE head to carrier, as well as wideband transforms and amplification of the signal due to time-varying magnetic velocity of the carrier, for example, current to voltage, than is possible

when radially moving the head when using traditional inductive magnetic disk, ration sensors.

Claims (1)

METHOD OF PLAYING INFORMATION FROM A MAGNETIC CARRIER, in which a time-varying magnetic flux is converted to voltage, a current is generated by applying voltage to the load resistance, and information is judged by the magnitude of the variable voltage proportional to the current, characterized in that, in order to expand the frequency and dynamic ranges, when forming a current, a change in the value of the load resistance is carried out until a short circuit current is obtained.