FR2554626A1 - Method of obtaining a matrix for copying a magnetic recording, matrix obtained by the said method, method of copying a magnetic recording by means of this matrix, and magnetic recording medium carrying the recording obtained by the said copying method - Google Patents

Abstract

The invention relates to the technique of magnetic recording of data and their reproduction. The method of obtaining a matrix for copying recordings involves applying to the magnetic recording medium 1, 2 a layer of ferromagnetic liquid 4 which, by drying in the magnetic field of the recording, forms a surface with relief corresponding to the recording. A coating of material 5, e.g. a polymer, metal or alloy, is placed on the surface with relief. The coating of material 5 is then detached and provides a matrix for copying the magnetic recording. Application to magnetic recordings methods using various carriers of magnetic data, to holographic recording and the reproduction of such recording, to the processing of optical data, to computer techniques, etc.

Description

 The present invention relates to the field of magnetic recording and the reproduction of information and in particular relates to a method of preparing a matrix for drawing a magnetic recording, the matrix obtained by this method, a method for drawing a magnetic recording by means of said matrix, and a magnetic recording carrier comprising said recording. The invention can be used in particular in the magnetic recording technique using various carriers of magnetic information1 in the technique of holographic recording and of the reproduction of this recording, for the optical processing of information, in the calculation technique , etc.

 A series of methods are known for the preparation of a matrix for drawing a magnetic recording, but the closest to the present invention is a method for preparing a matrix, carried out in the following way: the information on the magnetic layer of a recording medium with high coercive force (approximately 1400 oersteds), for example on a magnetic tape, from another magnetic recording medium (original) in mirror image compared to the recording of the original (see for example, Funkshau 1969, Heft 11S346 "Schnelles kopieren von Video Bandera).

However, this method of preparing a matrix for drawing a magnetic recording has considerable drawbacks, in particular:
- it requires special equipment for mirror recording and mirror reproduction;
- one must have a recording medium with high coercive force (1400 oersteds), later constituting the matrix, special recording and reproduction heads, etc.
- the recording of high frequencies is limited because the matrix must have a high coercive force (limitation in recording density).

 Today there are three main processes for drawing widely known magnetic, thermomagnetic, thermal and magnetic records.

 The process of thermomagnetic drawing of a recording (see for example Japanese patent NO 53-11846 cl. 102E82 "Thermomagnetic device for magnetic tapes") ensures the transfer of information from the original holder of magnetic recording-matrix on a record carrier as follows. The magnetic layer of the recording medium is heated, then it is placed on the magnetic layer side on the magnetic layer of the copy ribbon. It is cooled in the tight state, and when the cooling is complete it has on the tape-copy a recording of the effect of amplified copying. However, this method is characterized by a low efficiency of information transfer. Its realization is complicated, because it requires a high precision of maintenance of the thermomagnetic drawing regime for mobile information carriers and it requires on the other hand the presence of heating and cooling devices. During the drawing, the matrix and the recording carrier undergo thermal deformation, which notably reduces the service life of the matrix and causes a distortion of the transfer of information to the information carrier.

 This process is inapplicable to mass pulling, firstly because of the insufficient longevity of the matrix.

 Another thermal drawing process for a recording (see, for example, Great Britain patent NO 1,489,197 cl.

G5R "Process for thermal copying of information from a magnetic tape") provides for the transfer of information to a record carrier whose magnetic layer consists of chromium dioxide (Cr02) and has a point of Fairly low curia (125 C). The magnetic layer (cor02) of the recording medium is heated to a temperature above the Curie point. Then the heated magnetic layer of the recording medium is brought into contact with the magnetic layer of the matrix, on which the information is recorded in the form of magnetization zones. This contact produces a strong cooling of the recording carrier and the information is re-recorded from the matrix on the magnetic layer of the recording carrier. After the thermal re-recording, the information carrier is subjected to additional heating until at a temperature below the Curie point (700C), but not less than 400C, to reduce deformations.

 However, this method, despite its high efficiency, is limited for mass pulling due to the insufficient precision of the information transfer, due to the thermal deformation of the recording carrier to polymer substrate. On the other hand, for thermal printing, it is possible to use a recording carrier with a magnetic layer exclusively of Cr02.

 The method for drawing a magnetic recording closest to the method of the present invention is the method according to Japanese patent NO 52-27526, cl. 102E82, 1977, which is carried out as follows. On a matrix constituting the carrier of the original magnetic recording, for example a magnetic tape with coercive force of 2.5 times that of the recording carrier, information is recorded beforehand in the form of zones of magnetization arranged in mirror image of the information of the recording carrier. Then the magnetic layer of the matrix is brought into contact with the magnetic layer of the recording carrier and, in this position, the two carriers are wound together on the same reel forming a roll. During the winding, the air between the recording carriers is expelled by clamping rollers, which thus ensure close contact between the carriers. Then the coil is subjected to the action of a magnetic field of determined value, so that the information is recorded from the matrix on the magnetic recording carrier.

However, despite the speed and reliability of this process, it has drawbacks, namely:
- the use of a special recording and reproducing apparatus, because the magnetic layers of the matrix and the recording carrier are brought into contact and the mirror image of the image must be recorded on the matrix 'original information;
- a recording medium (a matrix) with high coercive force (1400 oersteds), as well as special recording and reproduction heads must be available;
- the recording of high frequencies is limited, because the matrix must have a high coercive force and, consequently, the carrier of magnetic recording is limited in density of recording of information.

 The object of the present invention is to create a method for preparing a matrix for printing magnetic records which, by means of the transformation of the magnetic information recorded into relief on the surface of the carrier, would make it possible to produce a matrix. ensuring a high density of information, good accuracy and at the same time an increased duration of use for the printing of information, and which would also make it possible to carry out the printing on various record carriers.

Another object of the present invention is the creation of a method for drawing a magnetic recording, which, thanks to the use of the matrix obtained according to the method which is the subject of the present invention, would make it possible to obtain a high signal level from the copy, while retaining a high print capacity and ensuring the reading of information from the copies in various ways,
This problem is solved by the fact that in a method of preparing a matrix for drawing a magnetic recording by transfer to a matrix of information carried by a magnetic recording carrier, matrix, according to the invention is applied to the recording carrier a ferromagnetic liquid which, by drying in the magnetic field of this recording, transforms the recording into relief, then a first layer of material is applied to this relief, then this layer of material is separated and thus obtained a matrix for drawing the magnetic recording.

 This process makes it possible to obtain a metallic matrix resistant to printing with a minimum recording wavelength and a maximum depth of the relief.

 It is advantageous to apply the ferromagnetic liquid as follows: an external magnetic field is created, the induction value of which is chosen between zero and the saturation induction of the magnetic recording carrier, then the carrier is applied to this carrier. ferromagnetic liquid, which dries in the two interacting magnetic fields, i.e. the external magnetic field and the magnetic field of the recording.

 This makes it possible to obtain a frequency of the valleys of the relief equal to the frequency of recording on the magnetic layer of the recording carrier, to increase the depth of the relief, to improve the "sharpness" of the relief.

 The composition of the ferromagnetic liquid can be as follows: magnetite-10%, sodium oleate 82 water 82%.

 These proportions of the components make it possible to transfer in a precise manner the distribution of the magnetization of the magnetic layer of the record carrier and, which is very important, to increase the depth of the relief.

It is advantageous that the transformation into relief of the recorded magnetic information - be carried out according to the relation:
ho (k1U0 + k2f) (1)
where ho (x, y, z) is the profile of the relief formed by the layer
dried ferromagnetic liquid;
OC is a coefficient taking into account the properties of
ferromagnetic liquid;
is a coefficient taking into account the interaction of
external magnetic field and the magnetic field of
the record.

k1, k2 are generalized coefficients of loss of ink
registration in the magnetic recording system
some information;
U0 is the amplitude of the signal recorded on the carrier
magnetic recording;
f is the frequency of the recorded signal.

It is advantageous to apply on the first layer
of material a layer of material serving as a substrate.

 The substrate can be made of polymer material.

The substrate can also be made of metal or
alloy. This makes it possible to obtain a matrix at low cost.
returns.

We can make the pre process more economical
trim the matrices by applying a second coat of
material between the relief formed by the ferromagnetic liquid
dried tick and the first layer of material, and in real
the separation of the layers between the ferro materials
magnetic, thus obtaining two matrices.
matrices constitutes a magnetic recording carrier,
whose magnetization is transformed into relief by the liquid
ferromagnetic, and layers of material according to the
relationship:
* + kf)
ho
in which:
*
ho is the relief profile of the direct matrix;
is a coefficient taking into account the properties of the
ferromagnetic liquid;
is a coefficient taking into account the interaction
between the external magnetic field and the magnetic field
registration;
is a coefficient taking into account the distortion of the
relief due to the first layer of material applied; k1, k2 are generalized coefficients of recording losses
highly in the magnetic recording system of
information;
UO is the amplitude of the signal recorded on the carrier
magnetic recording;
f is the frequency of the recorded signal, while
the other matrix constitutes a layer of material with
or without substrate, whose relief profile is connected to
*
ho (x, y, z) by the relation:
hm (x, y, z) = Y ho (x, y, z) (2)
hm (x, y, z) is the profile of the relief of the matrix
reverse;
is a negative coefficient taking into account losses
in profile of the relief ho (x, y, z) during the cycle
technological manufacturing of dies.

 It is possible to ensure the drawing of the magnetic recording on the magnetic recording carrier by obtaining matrices the first layer of material applied to the relief of the dried ferromagnetic liquid is made of ferromagnetic material.

 The process of manufacturing the matrices for drawing magnetic recordings on the magnetic recording carrier can be carried out more economically by applying a second layer of magnetic ferroma material between the relief, formed by the dried ferromagnetic liquid, and the first layer of ferromagnetic material.

 It is possible to have between the relief formed by the dried ferromagnetic liquid and the layer of ferromagnetic material a layer of current conducting material.

 This improves the technology of the die manufacturing cycle.

Another variant of the process for manufacturing dies with raised profiles corresponding to ho (x, y, z) and hm (x, y, z), executed during the same technological cycle and having ferromagnetic layers of material with hysteresis, consists of the following. A magnetic field is created in which the matrices obtained for the magnetic recording are magnetized1 the distribution of the residual inductions on the surfaces of these matrices being described by the relations
B1 (x, y, z) = B0 & h * # (x, y, z);
B2 (x, y, z) = B h (x, y, z) where Bo is the induction of the magnetic field created;
B1 (x, y, z) is the distribution of the residual induction on the surface of the matrix with profile
* relief ho (x, y, z); ;
B2 (x, y, z) is the distribution of the residual induction at the surface of the matrix with relief profile hm (x, y, z);
61/62 are coefficients which characterize the physico-mechanical and magnetic properties of the layers of ferromagnetic materials of the matrices.

 The problem set out above is also solved by the fact that in a method of drawing a magnetic recording by transferring information from a matrix, obtained according to the claimed method, on a magnetic recording carrier pressed against said matrix , according to the invention a magnetic field is created, then the matrix is passed through this field with the information carrier which ensures the modulation of the magnetic field in accordance with the relief of the surface of the matrix, this modulated field being recorded on the information carrier himself.

Said problem is also solved by the fact that in the process of drawing a magnetic recording by transfer of information from a matrix onto a recording carrier pressed against it, according to the invention the working layer of the carrier. the recording is heated before the printing, then is cooled during the printing, so that one obtains on the recording carrier itself an imprint of the relief, in accordance with the relief of the surface of the matrix
This makes it possible to produce low cost copies for optical reading.

The invention will be better understood and other objects, details and advantages thereof will appear better in the light of the explanatory description which will follow of various embodiments given solely by way of nonlimiting examples with reference to the non-drawing drawings. annexed limitative in which:
- Figure 1 is a schematic overview of a magnetic recording carrier, on which the information is recorded in the form of a distribution of remanent magnetization zones, and the dried relief of the layer of ferromagnetic liquid in the field of the record holder, according to the invention;
- Figure 2 schematically shows the process of forming a relief on the carrier of the original magnetic recording in a magnetic field, according to the invention;
- Figure 3 schematically shows a sectional view of the recording carrier on which are applied the layers of ferromagnetic liquid and material, according to the invention;
- Figure 4 schematically shows an overview of the magnetic recording carrier on which are applied the layers of dried ferromagnetic liquid and material, according to the invention;
- Figure 5 schematically shows an overview of the recording carrier, the layer of dried ferromagnetic liquid, the layer of material and the substrate, obtained during the preparation of the matrix;
- Figure 6 shows schematically a sectional view of the original of the recording carrier in relief of the dried ferromagnetic liquid of the material layer and the substrate, according to the invention;
- Figure 7 schematically shows an overview of the recording carrier with the relief obtained from the layer of dried magnetic liquid and carrying the layers of ferromagnetic materials, 1 according to the invention;
- Figure 8 schematically shows an overview of the recording medium, the layer of dried ferromagnetic liquid on which is applied a layer of ferromagnetic material, and, separated from the latter, another layer of ferromagnetic material in a system linear coordinates x, y, z, according to the invention;
- Figure 9 schematically shows a cross-sectional view of the magnetic recording carrier, the layer of dried ferromagnetic liquid, the current conducting layer, and the ferromagnetic matrix, according to the invention;
- Figure 10 schematically illustrates the method of drawing information from a matrix on a magnetic recording carrier in a magnetic field, according to the invention;
- Figure 11 schematically illustrates the method of drawing information on a carrier from a thermoplastic matrix.

 The claimed method of preparing a matrix for drawing a magnetic recording is carried out as follows.

 Information is recorded on the magnetic layer 1 of a magnetic recording carrier, which usually consists of the magnetic working layer 1 (FIG. 1) and a substrate 2, in the form of zones of longitudinal magnetization characterized by the frequencies f, the distribution of which in the volume of the magnetic working layer 1 is represented by the magnetic lines of force 3.

 Then a layer of ferromagnetic liquid 4 is applied, which makes the distribution of the magnetization of the recording carrier visible by creating a relief on its surface. The frequency of the relief thus formed is twice as high as the frequency of the information recorded, the height of the "bumps" in the relief corresponding to the depth of magnetization of the magnetic recording carrier.

 After the layer of ferromagnetic liquid 4 has dried, a first layer of material 5 is applied (FIGS. 3, 4) which, by coming into contact with the relief obtained, constitutes its mirror image. Said layer of material may consist of a polymer material, or of a metal, or even of an alloy.

The product known under the trade name "Lavsan", for example, can be used as polymer material.

The metals, such as for example copper, nickel, or the alloys such as for example the alloy known under the trade name "Permalloy" brass, can be applied for example by vaporization under vacuum.

Then the material layer 5 is separated from the other layers, i.e. from the ferromagnetic liquid layer 4 and from the magnetic working layer 1 of the recording carrier, which are removed, for example, by a chemical-mechanical method, thus obtaining a matrix for drawing the magnetic recording.

In order to preserve the information introduced at the frequency of the recorded signal, the ferromagnetic liquid 4 (FIG. 2) is applied in an external magnetic field created for example by the permanent magnet 6. This field can be a continuous, alternating or pulsating field, its induction being chosen (as a function of the type of magnetic recording, of the type of magnetic recording carrier, of the magnetic parameters of the working layer 1 of the magnetic recording carrier, of the parameters of the ferromagnetic liquid 4) in a range from from zero to a value close to the saturation induction of the magnetic recording carrier. To form a "sharper" relief from the ferromagnetic liquid 4 on the magnetic layer 1 of the magnetic recording carrier carrying the information, it is advantageous to carry out the process of application and drying of the ferromagnetic liquid 4 in a pulsating magnetic field, including the amplitude of the pulsations and the frequency are chosen according to the characteristics of the magnetic recording and the magnetic properties of the ferromagnetic liquid. When the magnetic field in which the application and the drying of the ferromagnetic liquid 4 are carried out on the magnetic layer 1 of the record carrier carrying the information has an induction close to zero, a doubling of the frequency of the projections of the relief is observed, while in the case of a magnetic field having an induction close to the saturation induction of the magnetic recording carrier, a decrease in the height of the relief is observed, and on the other hand, the "sharpness of the relief becomes less good when induction of magnetic fields occurs
approximates zero and the saturation induction of the
working magnetic layer 1 of the record holder
is lying.

Interaction of the magnetic field of the electromagnet
6 (Figure 2) and magnetization zones of the layer
working magnetic 1 of the provo record holder
that a change in the distribution of the magnetic field
inside and above the surface of its layer of
1.The shape and direction of the magnetic field
are chosen to transform the information
mations recorded in relief of ferromagnetic liquid
tick dried in this clamp in a coordinate system
consistent with the relationship:
(k1U0 + k2f) (1)
od ho (x, y, z) is the relief profile of the ferromag liquid
tick on the surface of the record holder
in a rectangular coordinate system;
g is a coefficient taking into account the properties of the
ferromagnetic liquid;
is a coefficient taking into account the interaction of
external magnetic field with the magnetic field of
the record; k1, k2 are generalized coefficients of losses from
recording in the magnetic recording system
that information;
UO is the amplitude of the signal recorded on the carrier
magnetic recording;
f is the frequency of the signal recorded on the carrier
magnetic recording;
The profile of the relief ho (x, y, z) in the rectangular coordinate system, formed by the ferromagnetic liquid 4 dried on the surface of the magnetic recording carrier under the action of an external magnetic field chosen between zero and the value of the saturation induction of the magnetic recording carrier, and of the magnetic field of the recording carrier, is determined by the physico-mechanical and magnetic properties of the magnetic recording carrier, by the characteristics of the recorded signal, by the characteristics of the recording means (heads), by the conditions of the recording process, by the characteristics of the ferromagnetic liquid, by the value and the character of the external magnetic field in which the ferromagnetic liquid dries.

The profile ho (x, y, z) of the relief in the rectangular coordinate system is described by an exponential function whose exponent represents the sum of the amplitude UO and the frequency f of the signal to be recorded with coefficients k1 and k2 appropriate taking into account the properties of the magnetic recording carrier: the remanent magnetization, the coercive force, the shape of the hysteresis loop, as well as the recording losses in the magnetic recording system of the information, due to the absence of contact of the recording head with the magnetic recording carrier, to the variation of the speed of movement of the magnetic recording, to the characteristic of the recording head, etc. coefficient takes into account the properties of the ferromagnetic liquid: of the magnetization. saturation, dimensions and material of magnetic particles, density, surface tension, etc. The external coefficient and the magnetic count of the recording, which is magnetic on the dried ferromagnetic liquid
The profile of the relief ho (x, y, z) according to the relation (1) corresponds all the more to the signal to be recorded, the lower the recording losses in the recording head-carrier system for magnetic recording, the higher saturation magnetization of the ferromagnetic liquid, the lower density and smaller are the dimensions of the magnetic particles of the ferromagnetic liquid.

 The ferromagnetic liquid applied can, for example, have the following composition: magnetite 10%, distilled water 82%, sodium oleate 8%, with a viscosity of the order of 16 to 18 cSt.

 It should be noted that the ferromagnetic liquid may have another known and characteristic composition for ferromagnetic liquids. As a ferromagnetic liquid it is advantageous to use in particular a colloidal ferromagnetic liquid, since it gives a more contrasted relief to the surface of the carrier and has a greater longevity during storage.

 After the layer 4 of ferromagnetic liquid has dried, the layer of material 5 is applied (FIG. 3, 4) which, entering with the relief obtained, constitutes its mirror image. The layer of material 5 can be applied in any known manner, for example chemically. Then the layer of material 5 is separated from the other layers. This separation leaves on the layer of material with the mirror image of the relief traces of the previous layers: ferromagnetic liquid 4, the magnetic working layer 1 of the recording carrier, which is made to disappear, for example, by chemical or mechanical means. The layer of material 5 forming the mirror relief corresponding to the relief of the dried magnetic liquid 4 and removed from the other layers constitutes the matrix intended for printing the magnetic recording.

 The matrix for drawing a magnetic recording can be obtained as follows. On the relief of the layer 4 (FIGS. 5, 6) of dried ferromagnetic liquid, the layer of material 5 is applied according to any known method, for example by vaporization of metal under vacuum.

Then a layer 7 of polymeric material constituting the substrate is applied, for example by means of contact rollers. This polymer material can be, for example, "Lavsan". The substrate (7) carrying the layer of material 5 separated from the other layers (1, 4) serves as a matrix. The substrate (7) can be made of metal, for example according to an electroplating process of depositing a metal or an alloy either ferromagnetic, such as nickel, "Permalloy", or magnetic, such as copper, brass, on layer 5. The metal matrices have a better endurance when drawn compared to that of the matrices with a polymer material substrate.

 The production of matrices for printing a magnetic recording on a recording carrier (1,2) can be made more economical, from which the reading is carried out according to an optical process, for example by operating as follows. After the layer 4 (FIG. 7) of ferromagnetic liquid has dried, a first and a second layer of a material (5,8) which may be a polymer, are successively applied to the working surface 1 of the magnetic recording carrier. , a metal or an alloy, by any known method. Then the first layer of material is separated from the second, thus obtaining two matrices 10, 11 (FIG. 8) whose respective profiles are mirror images, one with respect to the other.

The profile of the relief of the matrix 10, which is constituted by the magnetic recording carrier (1,2), the layer of ferromagnetic liquid 4 and the layer of material 8, in the event of transfer of the relief to the layer 8, corresponds to the relationship:
ho (x, y, z) e (k1U0 + k2f),
o (x, y, o in which ho (x, y, z) is the profile of the relief of the direct matrix;
is a coefficient taking into account the properties
ferromagnetic liquid;
is a coefficient taking into account the deformation
tion of the relief, due to the layer of material ap
plicated ;;
is a coefficient taking into account the interaction
of the external magnetic field with the magnetic field
registration tick; k1, k2 are generalized coefficients of losses
recording in the recording system
magnetic information;
UO is the amplitude of the signal recorded on the
magnetic recording carrier;
f is the frequency of the recorded signal.

The relief profile of the second matrix obtained
11, constituted by the layer of material 6, is inverse -and
corresponds to the relation:
h (x, y, z) = Y h (x, y, z) (2)
is a negative coefficient taking into account losses
*
of the profile of the relief ho (x, y, z) during the cycle
technological.

 hm (x, y, z) is the relief profile of the inverse matrix.

The coefficient ~ takes into account the transformation
mirror of the relief profile ho (x, y, z) into a relief profile h (x, y, z), of the physico-mechanical properties of the
m
applied layer, homogeneity, etc.

Relation 2 highlights the fact that the process
the more effective the value of
coefficient 2 gets closer to unity.

The matrix for drawing the magnetic recording
on a magnetic recording carrier can be obtained
as follows.

The information is recorded in the form of zones
has longitudinal magnetization on the magnetic working layer 1 (FIGS. 5, 6) of a magnetic recording carrier. Then a layer of ferromagnetic liquid 4 is applied, which; by drying in an external magnetic field and the magnetic field of the recording, forms a relief.

The layer of ferromagnetic material 5 is applied according to any known method, for example chemically.

The layer of ferromagnetic material 5 is separated from the other layers, and the traces of the previous layers are removed: ferromagnetic liquid 4 and the working magnetic layer 1 of the recording medium, by a chemical mechanical method for example. The cleaned layer 5 of ferromagnetic material constitutes a matrix for printing the magnetic recording on a magnetic recording carrier.

 The production of matrices for printing on a magnetic recording carrier can be made more economical in the following manner. After the layer of ferromagnetic liquid 4 (Figure 7) has dried, two layers are successively applied to the surface of the recording medium: a layer 8 of ferromagnetic material and a layer 5 of ferromagnetic material. Then the layers 5 and 8 of ferromagnetic materials are separated, thereby obtaining two matrices 10 and 11 (Figures 8) whose profiles are mirror images with respect to each other.

 Today, one of the most advantageous processes, from the technological point of view of preparing the matrix for printing on a magnetic recording carrier is the following.

 On the relief obtained on the working surface 1 (FIG. 9) of the magnetic recording carrier by means of the ferromagnetic liquid 4, a layer 9 of conductive material is applied, for example a layer of copper, by vacuum vaporization. Next, a galvanic plastic treatment of the metallized relief is carried out in a nickel amino sulfate electrolyte, thereby depositing a ferro magnetic layer 5 of nickel on the conductive layer 9.

Then the ferromagnetic nickel layer 5 is separated from the other layers: from the magnetic layer 1 of the recording medium, from the dried ferromagnetic liquid layer 4 and from the conductive layer 9. After the separation, it remains on the mirror image. of the relief of the layer 5 of ferromagnetic material from the remains of said layers, which are made to disappear by chemical-mechanical means, thereby obtaining a nickel matrix for drawing the magnetic recording on magnetic recording carriers
The proposed method of preparing a matrix offers wide possibilities for the mass production of recordings in the audio and video technique. This method is highly advantageous from the technological point of view, since the relief is created directly on the magnetic carrier of the record and the matrix represent a mirror image.

 The matrices obtained according to the claimed method have a low cost price, improve the range of information recording frequencies, which, in turn, increases the density of the information that can be transferred.

On the other hand, if the known matrix for the drawing supports up to 1000 contacts, the metal matrices produced according to the claimed process have a practically unlimited lifetime.

 The matrices intended for the printing of magnetic recordings can also be obtained according to another alternative embodiment of the present invention.

 For carrying out this process, the ferromagnetic layers, which include volume reliefs, are made of material having a high coercive force, that is to say a material with hysteresis.

Such matrices are subjected to the action of an external magnetization field (6) whose lines of force are perpendicular to the relief surfaces. Consequently, the ferromagnetic layers of the matrices magnetize and one of the poles is placed on the surfaces comprising a relief. On the other hand, one of the matrices has a distribution of the residual induction above the surface of the relief corresponding to the relation:
B1 (x, y, z) = B06 IhO (x, y, z) (3) and to the other:
B2 (x, y, z) = Bo where Bo is the induction of the magnetic field created,
ff 1 t y2 are coefficients characterizing the physico-mechanical and magnetic properties of the layers of ferromagnetic materials of the matrices.

 These relations also highlight the fact that the distribution of the residual induction above the relief surfaces depends on the value of the magnetic induction created by the magnetic field, on the relief profiles on the surface of the ferromagnetic layers of the matrices. and physico-mechanical and magnetic properties of the layers of ferromagnetic materials in the matrices, in particular the induction of saturation, the coercive force, the magnetic permeability, the process for producing the ferromagnetic layer, which includes the dimensions and orientation of its particles, the homogeneity of its composition, the density of the material, as well as the deformations which occur during manufacture.

 The magnetization of the matrices is carried out in magnetic fields either continuous or alternating, or in a combination of such fields.

 The method claimed for drawing a magnetic recording by transfer of information from a matrix onto a recording carrier makes it possible to transform the latter, in one case, into the remanent magnetization of a magnetic recording carrier. , and in another, in relief, for example, on a thermoplastic recording carrier. When printing on a magnetic recording carrier, matrices executed in ferromagnetic, hysteresis, magnetically soft materials or matrices whose relief working layer 5 is executed in ferromagnetic material are used. During printing on a thermoplastic carrier , when the relief of the matrix is transformed into a relief on said recording carrier, one can use any matrix among those produced according to the claimed method.

 The copies obtained on a magnetic recording carrier are read on tape recorders by means of magnetic heads, while the copies obtained on a thermoplastic recording carrier and having a relief are read, for example, by an optical process.

 The claimed method of drawing a magnetic recording by transferring information from a matrix onto a magnetic recording carrier is implemented as follows.

 The matrix 10 (11) (FIG. 10) intended for drawing a magnetic recording constituted, for example, by a uniform layer of magnetically soft ferromagnetic material, on one of the surfaces of which there is a relief corresponding to the magnetic recording, is pressed against the work surface 1 of the magnetic recording carrier. By means of the electromagnet 6, an external magnetic field is created, perpendicular to the working surfaces of the matrix 10 (11) and of the recording carrier (1 ′, 2 ′), then it is passed through this field the matrix 10 (11) with the information carrier (1 ', 2').

 The relief of the matrix 10 (11), under the action of the external magnetic field, modulates the magnetic field which magnetizes the working layer 1 of the recording carrier.

 The external magnetic field can be either continuous or alternating, or can have a combination of such fields.

 The claimed method of drawing a magnetic recording by transferring information from a matrix onto a thermoplastic recording carrier is implemented as follows.

 The recording carrier 1 ′ (FIG. 11), for example a thermoplastic recording carrier, is heated on the side of its recording working layer and is pressed against the matrix 10 (11) constituted, for example, by a layer of metal on one of the surfaces of which there is a relief corresponding to the magnetic recording, the matrix 10 (11) and the carrier (1 ′, 2 ′) of recording being brought into contact by their respective working surfaces , i.e. the relief and the recording layer. During printing in the compressed state, the matrix and the recording carrier (1 ', 2') are cooled, the printing of the working layer of the recording carrier (1 ', 2') being produced by the surface having the relief. there remains on the copy a corresponding relief.

 The claimed printing process transforms a type of presentation of information: the relief of the matrix, into other forms of presentation of information, either a magnetization of a magnetic recording carrier: a copy, or a relief of a thermoplastic carrier.

 The claimed method of transferring information offers wide possibilities for mass printing in the technique of video and sound recordings, which is particularly important for rapid multiplication and for obtaining copies at low cost. The proposed drawing process has particular advantages in the calculation technique.

 Thus it becomes possible to transform the magnetization of a magnetic carrier carrying information into an appropriate relief of a matrix and the reverse transformation of the information corresponding to a relief on an information carrier or into a relief on a carrier information, either by magnetization of a magnetic recording carrier.

Claims (16)

CLAIMS ============================  1. Method for obtaining a matrix for drawing a magnetic recording by transferring the information carried by a magnetic recording carrier (1, 2) onto a matrix (10, 11), characterized in that the a layer of ferromagnetic liquid (4) is applied to the magnetic recording carrier (1, 2) which, on drying in the magnetic field of this recording, forms a relief corresponding to this, after which the relief is applied a layer of material (5), for example  of polymeric material, metal or alloy, then this layer of material (5) is detached and a matrix is thus obtained for drawing the magnetic recording.  2. Method according to claim 1, characterized in that an external magnetic field (6) is created whose induction value is chosen in a range going from zero to the value of the saturation induction of the recording carrier magnetic, then a ferromagnetic liquid layer (4) is applied to this carrier (1, 2) which dries in said external magnetic field and said field of the recording interacting with each other.  3. Method according to one of claims 1 and 2, characterized in that the ferromagnetic liquid consists of 10% magnetite, 8% sodium oleate and 82% water.  4. Method according to one of claims 1, 2 and 3, characterized in that the transformation into a relief of the magnetic information recorded is carried out according to the relation: ho (x, y, z) = # dB Oe (k1U0 + k2f ) in which ho (x, y, z) is the profile of the relief formed by the layer (4) of dried ferromagnetic liquid;  oC is a coefficient which takes into account the properties of the ferromagnetic liquid;  is a coefficient taking into account the interaction of the external magnetic field and the magnetic field of the recording;  k1, k2 are generalized coefficients of recording losses in the magnetic information recording system;  UO is the amplitude of the signal recorded on the magnetic recording carrier;  f is the frequency of the recorded signal.  5. Method according to one of claims 1 and 2, characterized in that on a first layer of material (5) is applied another layer of material (7) which serves as a substrate and which consists of a polymer material, of a metal or an alloy.  6. Method according to one of claims 1, 2 and 5, characterized in that between the relief formed by the layer of dried ferromagnetic liquid (4) and the first layer of material (2) a second layer of material is placed (9), and that the layers (5 and 9) are separated between these layers, thereby obtaining two matrices (10 and 11).  7. Method according to claim 6, characterized in that the relief of one (10) of the matrices obtained corresponds to the relation: h * <x, y, z) = 'L0 # e (k1U0 + k2f),  o in which: ho (xry, z) is the profile of the relief of the layer (4) and of the direct matrix;  is is a coefficient taking into account the properties of the ferromagnetic liquid;  is a coefficient taking into account the interaction of the external magnetic field and the magnetic field of the recording;  is a coefficient taking into account the distortions of the relief due to the first layer of material applied;  k1, k2 are generalized coefficients of recording losses in the magnetic information recording system;  UO is the amplitude of the signal recorded on the magnetic recording carrier;  f is the frequency of the recorded signal, the relief of the second matrix obtained (11) corresponding to the relationship  hm (x, y, z) S Y ho (xwyz)  o in which: hm (x, y, z) is the profile of the relief of the inverse matrix;  Y is a negative coefficient taking into account the profile losses of the relief during the technological cycle of obtaining the latter.  8. Method according to one of claims 1, 2 and 5, characterized in that the first layer of material applied to the relief of the dried ferromagnetic liquid consists of a ferromagnetic material.  9. Method according to one of claims 6 and 7, characterized in that the first layer of material applied to the relief of the dried ferromagnetic liquid consists of a ferromagnetic material, the second layer of material, disposed between them, also being made up of a ferromagnetic material.  10. Method according to claim 8, characterized in that between the relief formed by the layer of ferromagnetic liquid (4) dried and the first layer of ferromagnetic material (5) is a layer (8) of a conductive material d 'electricity.  11. Method according to one of claims 8 and 9, characterized in that another magnetic field is created, in which the matrices obtained for the magnetic recording are magnetized.  1.2. Method according to one of claims 8 and 9, characterized in that another magnetic field is created, in which the matrices obtained (10, 11) are magnetized for drawing the magnetic recording, distributing the remanent inductions over the surfaces of these matrices (10, 11) being effected in accordance with the relationships:  *  1 (xyxz) = BoC1 ho (x, y, z) B2 (x, y, z) Bo6 2hm (x, y, z)  o in which:  B1 (x, y, z); B2 (x, y, z) are the distributions of the residual inductions on the surfaces of the matrices (10,11) comprising the profiles of the reliefs ho (x, y, z); hm (x, y, z), respectively;  Bo is the induction of the magnetic field created; are 2 are coefficients characterizing the physico-mechanical properties and the magnetic properties of the layers of ferromagnetic materials of the corresponding matrices (10, 11).  13. Matrix for drawing a magnetic recording, characterized in that it is obtained characterized in accordance with the method according to one of claims 1 to 11.  14. Method for drawing a magnetic recording by transfer of information from a matrix (10, 11) according to one of claims 1 to 10 on a tight magnetic recording carrier (1 ', 2') against it, characterized in that a magnetic field is created, then the matrix (10, 11) is passed through this field together with the magnetic recording carrier (1 ', 2'), which has the effect modulating this magnetic field in accordance with the relief of the surface of the matrix (10, 11), the magnetic field thus modulated attaching to the magnetic recording carrier (1, 2) itself.  15. Method for drawing a magnetic recording by transfer of information from a matrix according to one of claims 1 to 11 on a recording carrier pressed against it, characterized in that the layer of work of the recording carrier before the printing and that it is cooled during the printing, so that one obtains on the recording carrier itself an imprint whose relief corresponds to the relief of the surface of the matrix.  16. Magnetic recording carrier, characterized in that it comprises a recording obtained by the drawing process according to one of claims 14 and 15.