CS197815B1 - Method of thermomagnetic record of the signal - Google Patents

Description

BACKGROUND OF THE INVENTION The present invention relates to a thermomagnetic signal recording with simultaneous action of an alternating pre-magnetising field

Thermomagnetic recording is a recording on a magnetic carrier under the simultaneous action of magnetic and thermal fields. It does not matter which of the two fields carries information about the recorded signal. The principle of thermomagnetic recording is to magnetize the heated carrier and stabilize its magnetic state during cooling.

The shape of the magnetic field and the magnetic properties of the recording medium determine the resulting arrangement of the magnetic state of the carrier. The highest effect is achieved by heating the carrier to a Curie temperature at which the recording medium becomes paramagnetic. Low Curie temperature magnets are suitable as carriers for this recording method. The most prominent representative of this type of carrier today is chromium dioxide CrOg with a Curie temperature of 125 ° C.

A thermomagnetic record is also a record where the carrier of information about the recorded signal is a magnetic recording field and where the thermal field serves to heat the carrier to a Curie temperature or to a temperature higher than the Curie temperature.

A disadvantage of this method is the danger of mechanical deformation of the carrier, in particular its support, due to excessive warming. When using a carrier with CrOg

197 815

197 81S as a recording medium, the carrier should be heated to a temperature greater than or equal to 125 ° C. The polyester pad used as standard is deformed even at temperatures close to 100 ° C. Reduce or prevent carrier deformation by lowering carrier temperature *

However, thermomagnetic recording of signals, carried out on low-Curie temperature carriers, such as CrOg (125θ 125 ° C), is degraded by significant distortion at temperatures below the Curie temperature. The cause of the distortion is the non-linear dependence of the retentive polarization of the recording medium on the recording magnetic field. The above-mentioned drawbacks are overcome by the method of thermomagnetic signal recording according to the invention. In essence, the signal recording carrier heated to a temperature in the range of 20 ° C to the Curie temperature of the carrier used, together with the recording field, is subjected to an alternating pre-magnetizing field.

By pre-magnetising the recording medium with an alternating magnetic field, an efficient increase in the linearity of the thermomagnetic recording process is achieved, thereby effectively reducing the distortion of the recorded signal. At the same time, the sensitivity of the record carrier is increased.

The magnitude of the required alternating magnetic field varies with the magnetic properties of the recording medium as a function of its temperature. At room temperature it takes the values defined as the carrier operating point, at Curie temperature it drops to zero.

Two examples of this method of thermomagnetic signal recording are shown schematically in Figures 1 and 2.

Fig. 1 is an arrangement diagram where the heater 2 supplied from the heating source 6 is structurally separated from the source of the recording and alternating bias fields 2t supplied by the recording amplifier 6 and the source of the high-frequency current 2.

The signal recording carrier 1 is heated to an appropriate temperature in the heating device 2 before entering the area of application of the recording and pre-magnetizing field induced by the source 2 where the signal recording itself takes place.

The example shown in FIG. 2 assumes the concentration of the recording and, in particular, the heating and biasing device in one assembly. The source of the biasing field, together with the heating device, which are jointly arranged in the block 2 *, is located in the recording field created by the recording device 8. The recording device 8 supplies power to the recording device 8. The high-frequency current source 11 supplies the bias circuit and the heater 10 supplies the block 2 heater.

As the signal recording support 1 passes through the device thus arranged, the recording and pre-magnetising fields act simultaneously on the support 1 heated in the heating device of the block 2.

In this method of thermomagnetic signal recording, the temperature of the heated carrier 1 does not undesirably decrease as a result of its cooling as it passes from the heater to the recording area. On the other hand, this arrangement is structurally more complex than in the case described in Fig. 1.

Claims (1)

A method of thermomagnetic signal recording, characterized in that an alternating pre-magnetizing field is applied to the signal recording carrier heated to a temperature in the range of 20 ° C to the Curie temperature of the carrier used.