DE3535671A1 - MAGNETIC HEAD - Google Patents

Abstract

Magnetic head (49) for reading digital magnetic information on a magnetic recording support (9), in which three or more magnetic sensors (12, 13, 14) are provided per recording track. An increase in the recording density of signals on the magnetic recording support (9) is achieved by equalization of the playback signals in the local region. The desired reduction in the half amplitude width (33) of playback signals is achieved by the interconnection of the output signals which differ in value and polarity from at least three sensors (12 to 14), which simultaneously scan the environment of a magnetic flux change in the information carrier. The distance between the sensors (12 to 14) in the recording direction (11) corresponds approximately to half of the half amplitude width (33) of the local resolution of the central sensor (12). The differing value of the output signals (32, 34, 35) occurs because of the differing geometrical dimensions of the sensors (12 to 14). The different polarity of the signal (32) of the central sensor (12) compared with the signals (34, 35) of the adjacent sensors (13, 14) can be obtained, in the case of magnetoresistive sensors by the choice of the operating points (68, 69, 70) in the regions of increases in the characteristic curve having differing signs. The equalization in this magnetic head arrangement operates irrespective of the speed at which the magnetic recording carrier (9) moves.

Description

State of the art

The invention is based on a magnetic head according to the Gat the main claim. When storing data on magnetic recording media will be one if possible high recording density sought. The recording density is due to the electrical and mechanical properties the recording medium and the recording or playback device limited. Is the system featured? then a higher recording density can be obtained by equalizing the read signals in the time domain. In "Electronics", Issue 19, 1981, pages 97 to 101 and "Electronics", Issue 20, 1981, pages 93 to 101 is a pulse-forming network for equalizing the read signals specified in the time domain. It is a trans Versalfilter, which consists of two term elements, three coefficients catenary elements and a summing amplifier is constructed. The read signal is transmitted via a first coefficient element, an inversion and a weakening of the entrance signals causes a first input of a summing ver  strengthened. At the same time, the read signal arrives via a first time delay element and a second Coefficient element, which in the simplest case is the time delayed read signal not inverted and not weakened lets, to a second input of the summing amplifier. The read signal, which is delayed once, also passes through a second time delay and a third coefficient client, which is the twice delayed reading signal inverted and attenuated, to the third input of the summing amplifier. The coefficient terms after undelayed and after the twice delayed reading signal are set so that the desired optimally equalized pulse shape of a recorded sig nales at the output of the summing amplifier results.

A disadvantage of this method of equalizing reading vinegar is in the time domain, especially in multi-span the high electronic effort. Especially after However, it is partial that the equalization in the time domain on the speed of magnetic recording carrier depends.

Advantages of the invention

The magnetic head according to the invention has the opposite part that without additional electronic circuit equalization of the reading signals takes place. Especially it is advantageous that the equalization is independent of the transport speed of the magnetic record carrier. This is done by dividing the magnet sensors in several, offset relative to each other achieved partial elements that are different at the same time Scan locations of a magnetic flux change. This sensor Sub-elements are in terms of sensitivity,  the phase position and its relative contribution to the total signal interpreted differently and interconnected so that the desired optimal pulse narrowing for gives the overall signal.

By the measures listed in the subclaims are advantageous developments of the main claim specified magnetic head possible. The different Sensitivity of the sensor sub-elements is determined by below different geometrical dimensions and / or through Varia tion of the material composition obtained. Especially The arrangement in which the difference is advantageous sensitivity of the partial sensor elements only through whose different width is determined.

The sensors are magnetoresistive elements. you will be manufactured in thin film technology and are therefore inexpensive to manufacture.

Further details and advantageous developments of the magnetic head according to the invention result from the fol description.

drawing

Fig. 1 and Fig. 3 show embodiments of the Anord voltage of sensors of the magnetic head according to the invention,

Fig. 2 shows a diagram of output signals of the sensors Sen of the magnetic head as a function of position on the magnetic recording medium,

Fig. 4 shows a sectional view of the magnetic head and

Fig. 5 shows the Sen sorkennlinie magnetoresistive sensors.

Description of the embodiment

Fig. 1 shows a magnetic recording medium 9, which is moved in a recording direction 11 at a first sensor 12, second sensor 13 and a third sensor 14. The second sensor 13 is located at a first distance 15 in the recording direction 11 in front of the first sensor 12 . The third sensor 14 is located at a second distance 16 in the recording direction 11 after the first sensor 12 . The first sensor 12 has a height 17 and a width 18 , the second sensor 13 a height 19 and a width 20 and the third sensor 14 a height 21 and a width 22 . The first sensor 12 has a connection 23 and a connection 24 , the second sensor 13 a connection 25 and a connection 26 , the third sensor 14 a connection 27 and a connection 28 .

The mode of operation of the magnetic head according to the invention is explained with reference to FIG. 2. This shows in ordinate direction 30 the output signals of the magnetic sensors as a result of a change in flow due to a change in magnetization of the record carrier 9 moving past as a function of the location 31 . At the zero point of the abscissa, the change in magnetization of the recording medium 9 lies exactly below the middle sensor 12 . A first signal 32 with the greatest amplitude arises at the first sensor 12 between the connections 23 and 24 . This signal 32 corresponds to the output signal of a conventional magnetic head with only one sensitive element. A half-width 33 of the first signal is shown. A second signal 34 arises at the second sensor 13 between the connections 25 and 26 , a third signal 35 at the third sensor 14 between the connections 27 and 28 . The maximum amount of the second signal 34 is offset by the first distance 15 and the maximum amount of the third signal 35 is offset by the second distance 16 from the maximum of the first signal 32 . The different amplitude of the first signal 32 on the one hand and the second and third signals 34 , 35 on the other hand results from the different widths 18 , 20 , 22 of the sensors 12 to 14 . The width 18 of the first sensor 12 is greater than the width 20 of the second sensor 13 and the width 22 of the third sensor 14 , the widths 20 and 22 preferably being the same for symmetrical signal 32 . All three widths 18 , 20 , 22 added together result in the reading track width 10 on the magnetic recording medium 9 . The height 17 , 19 , 21 of the sensors 12 to 14 is the same in each case.

The addition of the first, second and third signals 32 , 34 , 35 results in a resulting signal 36 . The half-value width 37 of the resulting signal 36 is smaller than the half-value width 33 of the first signal 32 . An optimal shape of the resulting signal 36 , that is to say the smallest possible half-value width 37 and the largest possible amplitude, are obtained by varying the first distance 15 , the second distance 16 and the amplitude of the second and third signals 34 , 35 . An optimal result for a symmetrical read signal form 32 results if the first distance 15 is equal to the second distance 16 and these distances are equal to half the half-width 33 of the first signal 32 of the first sensor 12 and the amplitudes of the second signal 34 and the third signal 35 are the same size and are 30 to 40% of the amplitude of the first signal 32 .

The different polarity of the first signal 32 on the one hand and the second or third signal 35 , 34 on the other hand, as well as the addition of the three signals 32 , 34 , 35 is given by a special wiring of the sensors 12 to 14 . Additional electronic devices are not required. This is easily possible if magnetoresistive sensors are used. In the magnetoresistive sensors, the electrical resistance can be changed by a magnetic field lying in the sensor plane.

62 Fig. 5 shows the characteristics of such sensors. The change in resistance of a sensor strip 63 is plotted on the ordinate 64 as a function of the angle 65 between the inner magnetization 66 of the mag netoresistive sensor 63 and the reading current direction 67 in the sensor. Different polarities of the output signals of the partial sensors 13 and 14 compared to 12 result when the operating points 68 , 69 of sensor 13 and 14 are on a slope with an opposite sign as the slope in the operating point 70 from sensor 12 , for example as shown in FIG. 5 .

The working point setting itself can be known ter way both by rotating the inner sensor magnet tization from the current direction by permanent or electromagnetically generated magnetic fields, as well Rotation of the current flow direction itself by means of the streak inclined short-circuit bridges.

If the magnetic field for setting the operating point, which rotates the inner sensor magnetization 66 from the current direction 67 , is generated by the field of the read current 67 itself, which is possible if the sensor is located off-center between soft magnetic shields (as from IEEE Trans. On Magn. Vol. MAG-11, No 5, September 1975, page 1206-1208 known), or a part of the reading current flows through a short-circuit layer located under the sensor, the sign of the bias field is dependent on the current direction. Then can be achieved by switching the sensors 12 to 14 as in Fig. 1 that the magnetic field to be detected in the first sensor 12, for example, an increase in resistance, but in the other two sensors 13 , 14 causes a resistance reduction. The addition to the resulting signal 36 takes place through the series connection of the sensors.

Fig. 3 shows a second embodiment of an arrangement, the sensors 12 to 14. The width of all sensors is equal to the reading track width 10 of the magnetic recording medium 9 running in the recording direction 11 . The heights 40 , 41 , 42 of the sensors 12 , 13 , 14 are the same. The first distance 15 and the second distance 16 between the three sensors 12 to 14 for a symmetrical read signal 32 of the sensor 12 are also the same. The two distances 15 , 16 are then expediently equal to half the half-width 33 of the first signal 32 of the first sensor 12 .

The different amplitude of the first signal 32 of the first sensor 12 on the one hand and the amplitude of the second signal 34 of the second sensor 13 and the third signal 35 of the third sensor 14 on the other hand is preferred by a different thickness 58 of the first sensor 12 compared to the given the same thicknesses 59 , 60 of the second and third sensors 13 , 14 . The required thickness ratio corresponds approximately to the reciprocal of the desired amplitude ratio. For an optimal resultant signal 36 , the two thicknesses 59 , 60 of the second and third sensors 13 , 14 are 2.5 to 3.5 times the thickness 58 of the first sensor 12 . The under different polarity of the signals 34 and 35 of the sensors 1 and 14 to the signal 32 of the sensor 12 is ensured if the current direction in sensor 12, for example by + 45 ° and in sensors 13 and 14 by -45 ° from the inclined short-circuit bridges 61 Longitudinal direction of the strip is rotated. This corresponds to the working points 68 to 70 shown in FIG. 5. The inner magnetizations of all three sensors must lie at rest in the same direction along the strip, which can be achieved by a small auxiliary magnetic field of a few A / cm, which penetrates all strips 12 to 14 in FIG. 3 in the longitudinal direction.

Another variant for setting different sensitivity is the choice of a height 41 , 42 of the outer sensors 13 , 14 times the factor of 2.5 to 3.5 compared to the height 40 of the middle sensor 16 , with the same thicknesses 58 , 59 , 60 of the sensors 12 to 14 .

Fig. 4 shows a sectional view of the magnetic head 49 according to the invention in the sensor arrangement corresponding to the exemplary embodiment from FIG. 1. On a soft magnetic substrate 50 , which is, for example, a NiZn ferrite, a first gap 51 follows, which consists for example of silicon monoxide. The three sensors 12 to 14 with their contact points 23 to 27 are applied to this layer. The three sensors 13 to 14 are in three different planes, which were in the recording direction 11 from the first 15 and the second distance 16 . These levels were created by etching two depressions into the ferrite substrate 50 . The three sensors 12 to 14 are from a soft magnetic shield 52 z. B. a NiFe multilayer separated by a second gap 53 , which consists of silicon dioxide. Between the shield 52 and a cover 54 made of ferrite, a leveled protective layer 55 made of aluminum oxide is arranged. At the input terminals 56 , 57 , a constant current is impressed into the series circuit with the three sensors 12 to 14 . The resulting signal 36 is then available as a voltage value between the connecting terminals 56 , 57 .

An expansion option of the magnetic head 49 according to the invention is that further partial sensors are seen before. In each expansion step, a sensor is arranged in the recording direction 11 in front of or behind sensors that are already present. With these extensions, it is possible to obtain an increasingly better equalization of the read signal by adding additional partial signals to the first signal 32 , which are simultaneously read at different locations on the magnetic recording medium 9 .

Claims (10)

1. Magnetic head for reading the signal fields on a magnetic table ( 9 ) with at least one recording track, characterized in that the magnetic head ( 49 ) in addition to a first sensor ( 12 ) at least two further sensors ( 13 , 14 ) for reading one Has track. 2. Magnetic head according to claim 1, characterized in that the distance ( 15 , 16 ) of the sensors ( 12 , 13 , 14 ) in the running direction ( 11 ) of the magnetic recording medium ( 19 ) in the region of half the full width at half maximum ( 33 ) of the local resolving power the sensors ( 12 , 13 , 14 ). 3. Magnetic head according to one of claims 1 or 2, characterized in that a central sensor ( 12 ) provides a be higher reading signal than the two adjacent sensors ( 13 , 14 ). 4. Magnetic head according to one of claims 1 to 3, characterized in that the central sensor ( 12 ) with the same phase control of all sensors ( 12 to 14 ) with a magnetic field provides a read signal ( 32 ) which has opposite polarity than that Sensor signals ( 34 , 35 ) from the neighboring sensors ( 13 , 14 ). 5. Magnetic head according to one of claims 1 to 4, characterized in that the sensors ( 12 , 13 , 14 ) each have the same width ( 18 , 20 , 22 ), the carrier width approximately equal to the track width ( 10 ) on the magnetic recording ( 9 ) is. 6. Magnetic head according to one of claims 1 to 5, characterized in that a higher sensitivity of the mittle ren sensor ( 12 ) to the two adjacent sensors ( 13 , 14 ) by different materials and / or by a factor of 0.15 to 0.4 lower height ( 40 ) of the middle sensor ( 12 ) than the heights ( 41 , 42 ) of the two adjacent sensors ( 13 , 14 ) is given. 7. Magnetic head according to one of claims 1 to 5, characterized in that the higher sensitivity of the medium-sized sensor ( 12 ) compared to the adjacent sensors ( 13 , 14 ) by a factor 0.15 to 0.4 smaller thickness ( 58 ) of the middle sensor ( 12 ) than the thicknesses ( 59 , 60 ) of the two adjacent sensors ( 13 , 14 ) are given. 8. Magnetic head according to claim 1 to 5, characterized in that the higher sensitivity of the middle sensor ( 12 ) with respect to the two adjacent sensors ( 13 , 14 ) by different materials and / or by a width 2 to 5 times larger ( 18 ) of the middle sensor ( 12 ) as that of the two adjacent sensors ( 13 , 14 ) is given. 9. Magnetic head according to one of claims 1 to 8, characterized in that the output signal ( 32 ) of the middle sensor ( 12 ) is combined in phase opposition with the output signals ( 34 , 35 ) of the two adjacent sensors ( 13 , 14 ). 10. Magnetic head according to one of claims 1 to 9, characterized in that the sensors ( 12 , 13 , 14 ) are designed as magnetoresistive elements.