RU1793464C - Magnetoresistive head - Google Patents

Abstract

Usage: for magnetic recording and reproduction of information in information storage devices. SUMMARY OF THE INVENTION: the presence of hyperbolic notches in the screens on the side of the magnetoresistive element allows a more uniform distribution of the displacement field along the height of the magnetoresistive element, which extends the amplitude range of the reproduced signal, reduces frequency distortion and, therefore, improves the quality of reproduction. 2 ill.

Description

The invention relates to instrumentation, in particular to a technique for magnetic recording and reproduction of information, and can be used in electronic computing equipment in magnetic memory devices.

A known magnetoresistive head containing a non-magnetic substrate, a magnetoresistive element, biasing the conductors of the magnetic screens on both sides of the magnetoresistive element.

The disadvantage of this head is the poor signal reproduction quality associated with the insufficiently uniform distribution of the bias field over the height of the magnetoresistive element.

The closest in technical essence to the invention is a magnetoresistive head containing a magnetoresistive element and two parallel magnetic screens located on both sides at different distances from it.

The disadvantage of this head is the low quality of signal reproduction associated with uneven distribution of the displacement field along the height of the magnetoresistive element, -

The aim of the invention is to improve the quality of reproduction. Using the invention, it is possible to increase the amplitude of the reproduced signal by 6% without increasing its distortion or to reduce distortion of the reproduced signal at the same maximum amplitude.

The goal is achieved due to the fact that in the magnetoresistive head containing the magnetoresistive element and two parallel magnetic screens located on both sides at different distances from it, in the screens from the side of the magnetoresistive element and symmetrically to its center line are made notch hyper sj

u with

N about

bolic form, the width of which is equal to the width of the magnetoresistive element.

The essence of the invention is that the presence of hyperbolic notches in the screens on the side of the magnetoresistive element allows a more uniform distribution of the displacement field along the height of the magnetoresistive element, which extends the amplitude range of the reproduced signal, reduces frequency distortion and, therefore, improves the quality of reproduction.

A significant difference of the invention is the presence of hyperbolic recesses in the screens from the side of the magnetoresistive element, symmetrical to its center line and equal in width to the magnetoresistive element.

In FIG. 1 shows a cross section of the proposed magnetoresistive head; in FIG. 2 - graphs of the distribution of the magnetization M along the height H of the magnetoresistive element under the influence of the bias field in the prototype (a) and in the invention

(b) ..

The magnetoresistive head (Fig. 1) comprises a magnetoresistive element 1 and two magnetic screens 2 and 3, each of which has recesses 4 of a hyperbolic shape.

Magnetoresistive head operates as follows.

Under the influence of an external signal magnetic field in the magnetoresistive element 1, the orientation of the magnetization vector changes relative to the orientation of the detection current density vector by a certain angle b, which causes a change in the electrical resistivity p of the material of which the magnetoresistive element 1 is made, according to the law

 + D / e cos2 (# + / 4), (1)

where p is isotropic component of the electrical resistivity of the material of the magnetoresistive element 1; D / e - the maximum value of the change

the resistance in the magnetoresistive element 1. When a direct current, called the detection current, flows through the magnetoresistive element 1, a change in the electrical voltage on the magnetoresistive element is proportional to the change in its resistance.

Magnetoresistive Flow

To element 1, a detection current induces a constant magnetic field around the magnetoresistive element, which magnetizes magnetic screens 2 and 3 in opposite directions. Moreover

the magnetic shield 2, located closer to the magnetoresistive element, is magnetized more strongly. Magnetic fields induced by screens act on the magnetoresistive element and create

mute working point offset. In FIG. 2a shows the magnetization distributions M over the height H of the magnetoresistive element 1 caused by each of the screens 2 and 3 (see Fig. 2a, curves 5 and 6), and their resulting effect for the prototype (curve 7). As can be seen from the figure, the magnetization of the magnetoresistive element 1 caused by each of the screens 2 and 3, as well as the resulting magnetization have

significantly, a larger value in the middle part of the magnetoresistive element 1 than on its edges. The use of hyperbolic recesses 4 in screens 2 and 3 makes it possible to planerize the magnetization distributions caused by each of screens 2 and 3 (see Fig. 2b, curves 5, 6), which allows to planerize the distribution of the resulting magnetization (see Fig. 26 curve 7) and, consequently, the displacement of the operating point.

Thus, due to the fact that there are recesses 4 in the screens 2 and 3, the distribution of the displacement of the operating point along the height H of the magnetoresistive element 1 is planned and, therefore, the amplitude range of the reproduced signal is expanded, the frequency distortion is reduced, and therefore, the quality of reproduction is improved.

Formula and Magnetoresistive head containing a magnetoresistive element and two screens parallel to it, located on both sides at different distances from it, characterized in that, for the purpose of

To improve the quality of reproduction, in the screens from the side of the magnetoresistive element and symmetrically to its middle line, hyperbolic recesses are made / whose width is equal to the width of the magnetoresistive element.

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