RU2022365C1 - Method and device for recording and reading out coded information - Google Patents

Abstract

FIELD: computer technology. SUBSTANCE: invention may be used in systems for identification of images and allows to draw random-form code onto surfaces of articles. Under local effect on information carrier, the electro-physical properties of material or internal surface of information carrier are changed. Drawn code is read out by means of optical indication of distribution of magnetization by means of sensitive film magneto-optical element, which is mounted onto external surface of information carrier. Device for recording coded information is made in form of a die from elements for forming local magnetic field. Device for reading coded information out is made in form of light source, polarizer, magneto-sensitive element and analyzer. All the units are communicated optically and connected in series. The element is made in form of magneto-optical film which has cellular structure. Sizes of the cells are specified by condition of maximal admissible quantization of image to be read out. EFFECT: improved efficiency of operation. 36 cl, 9 dwg

Description

 The invention relates to computer technology and is industrially applicable in pattern recognition devices, for example, in turnstiles on magnetic cards.

 There is a known thermomagnetic method for recording and reading encoded information, during the implementation of which a code is applied to the information carrier by local exposure to the medium with subsequent reading of the code [1].

 The disadvantages of this method are the low contrast and brightness of the image during visualization of the recording due to the small angle of rotation of the plane of polarization in the thermomagnetic storage medium.

 The closest technical solution to the claimed method is a known method of recording and reading encoded information, in which the code is applied to the information carrier by local exposure to the medium, followed by reading the code [2].

 A device for recording onto a carrier made of hard magnetic material by means of its local magnetization reversal, containing a means of forming a local magnetic field [3].

 The closest technical solution to the claimed device for visualizing encoded information is a device containing optically coupled and sequentially installed along the optical axis of the light source, a polarizer, a magnetically sensitive element and an analyzer [4].

 The disadvantages of the prototypes are the inability to create a hidden code of arbitrary configuration in arbitrary products and reducing the likelihood of its unauthorized reproduction and reading.

 The aim of the invention is to provide the ability to create a hidden code of arbitrary configuration in arbitrary products and reduce the likelihood of its unauthorized reproduction and reading.

 The goal is achieved by the fact that according to the method of writing and reading encoded information, during which the specified code is applied to the storage medium by local exposure to the medium followed by reading of the code, when exposed locally to the medium, the electrophysical properties in the thickness or on the inner surface of the medium are changed, and reading code is carried out by optical registration of the distribution of magnetization in a sensitive film magneto-optical element mounted on the outer surface but Itel information. In particular, the sensitive film element can be made magnetically uniaxial, and it can be affected by an alternating magnetic field. For covert coding of media made of soft magnetic materials, the code is applied by locally changing the magnetic permeability due to local changes in the thickness of the information medium or local structural changes in the information medium. In order to covertly encode media made of hard magnetic materials with the possibility of erasing and rewriting the code, it is applied by locally changing the magnetic parameters of the information carrier, for example, magnetic anisotropy or coercive force. For the purpose of covert coding of carriers of non-magnetic metals and non-metals with the provision of erasing and rewriting the code, a layer of hard magnetic material is applied to the inner surface of the product, and the code is applied by locally changing the magnetic parameters of this layer. For the purpose of covert coding of carriers of non-magnetic electrically conductive materials, the code is applied by locally changing the electrical resistance of the product due to local changes in its thickness or structure of its material. In this case, the carrier is additionally exposed to an alternating electromagnetic field, which causes the appearance of eddy currents in the carrier. A layer of hard magnetic material deposited on the inner surface of the product may be made of barium hexaferrite, magnetic rubber, magnetic tape, magnetic varnish, magnetic paint or fragments of a magnetic disk. Optical registration of the distribution of magnetization in a sensitive film magneto-optical element is carried out by visual observation directly or from a monitor screen. An alternative is optical recording with a photo detector, which, in particular, can be matrix. In this case, optical registration is carried out using the magneto-optical Faraday effect. After optical registration, it is desirable to carry out computer processing of the signal from the photodetector, a television signal or a signal from a VCR.

 The goal is also achieved by the fact that in the device for recording encoded information on a carrier made of hard magnetic material by means of its local magnetization reversal, containing means for generating a local magnetic field, this tool is made in the form of a type stamp. In this case, the typesetting stamp can be made of permanent magnets, the coercive force of the material is higher than that of the information carrier material, from bipolar permanent magnets in the form of a replaceable set, where the permanent magnets have, in particular, a prismatic or toroidal shape. In order to provide the ability to quickly change the code, the recording device can be made from a set of electrically controlled needle magnetic cores.

 The goal is also achieved by the fact that in a device for reading encoded information containing optically coupled and sequentially installed along the optical axis a light source, a polarizer, a magnetically sensitive element and an analyzer, the magnetically sensitive element is made in the form of a magneto-optical film. At the same time, a cellular structure can be made in the magneto-optical film, which ensures the storage of the visualized picture. The magnetosensitive element may contain a mirror layer and a protective coating deposited on the side adjacent to the carrier, as well as an antireflection coating on the opposite side. In order to covertly encode media made of soft magnetic materials, the visualization device may further comprise a magnetizing system including permanent magnets and a contactor. For the purpose of covert coding of carriers of non-magnetic electrically conductive materials, it may further comprise an electromagnetic unit for generating eddy currents in the carrier. In particular, the imaging device may further comprise a unit for generating an alternating magnetic field magnetically coupled to a magnetically uniaxial film. It may also contain an additional beam splitting element mounted on the optical axis between the magneto-optical film and the polarizer.

 In FIG. 1 shows a device for reading encoded information on a magnetic medium; in FIG. 2 - a device for recording encoded information on a carrier of hard magnetic material containing a needle core; in FIG. 3 - sensitive film magneto-optical element; in FIG. 4 - a device for reading encoded information recorded on a soft magnetic medium; in FIG. 5 - a device for reading encoded information recorded on a non-magnetic electrically conductive material; in FIG. 6 - a means of forming a local magnetic field in the form of a set stamp; in FIG. 7 - a permanent magnet of a prismatic shape; in FIG. 8 - a permanent magnet of a toroidal shape; in FIG. 9 - a means of forming a local magnetic field in the form of a set of electrically controlled needle magnetic cores.

 A device for reading encoded information recorded on a magnetic medium (Fig. 1) contains a light source 1, a polarizer 2, a magnetically sensitive element from a substrate 3, a magneto-optical film 4 and a reflective coating 5, as well as an analyzer 6 and an eyepiece 7. A sensitive film element, comprising a substrate 3, a film 4, and a reflective coating 5, is in magnetic contact with the information carrier 8.

 A device for recording encoded information on a medium of hard magnetic material (Fig. 2) contains a needle core 10 and coils 11 installed in the housing 9, which are electrically connected to the current source 12.

 The sensitive film element (Fig. 3) contains a substrate 3, a magneto-optical film 4, reflecting 5, a protective and antireflective coating.

 A device for reading encoded information recorded on a soft magnetic medium (FIG. 4), compared with the device shown in FIG. 1 further comprises a beam splitter 13, a lens 14, an output glass 15, permanent magnets 16 and a contactor 17 (polarizer 2 and analyzer 6 are not shown). In the information carrier 8, an intra-volume structural change 18 is shown, causing a distortion of the magnetic field lines 19.

 A device for reading encoded information recorded on a non-magnetic electrically conductive material (FIG. 5), compared with the device shown in FIG. 1 further comprises an electromagnetic unit 20 for generating eddy currents in the carrier 8.

 The means of forming a local magnetic field in the form of a set of needle magnetic cores 21, (Fig. 9) comprises a holder 22 and coils 23.

 To record encoded information on a magnetic medium, a magnetic contact is created between the information medium and the recording device. As a result, magnetic magnetization reversal of the information carrier occurs, which remains indefinitely long after removal of the recording device. If this device is made in the form of a stamp, then the same code can be recorded on different media. The code can be changed by typing a new pattern of permanent magnets of a prismatic or toroidal shape. Operational code change can be achieved by using electrically controlled needle magnetic cores. The code can be written on soft or non-magnetic electrically conductive media using scratches or hardening. When using an electrically controlled stamp or a needle core to increase the contrast and brightness of the image of the visualized information, pulses are supplied to the coils from an alternating current source with adjustable duration, amplitude and duty cycle. If necessary, covert coding of carriers of non-magnetic metals and non-metals with the provision of erasing and rewriting the code on the inner surface of the product is applied a layer of hard magnetic material, and the code is applied by local changes in magnetic permeability, magnetic anisotropy or coercive force of the material.

 Reading the code recorded on the hard magnetic material is carried out using a visualization device placed near the outer surface of the product. The scattering fields of the information carrier cause a change in the distribution of magnetization in the magneto-optical film 3, for example, by changing its domain structure or the angle of exit of the magnetization from the plane of the film. The distribution of magnetization in the magneto-optical film is visualized using the Faraday effect, and the observation is carried out “for reflection” (Figs. 1, 4, and 5). If the encoded information is recorded on a soft magnetic medium (Fig. 4), then it must be magnetized to saturation in the plane of the film. When information is recorded on a non-magnetic electrically conductive carrier, eddy currents are excited in it. To increase the contrast and brightness of the image on the magnetically sensitive film element, on the one hand, a reflective coating 5 and a protective layer are applied, and on the other hand, an antireflection coating. To create an equilibrium domain structure in a magneto-optical film 4, an alternating magnetic field is applied to it.

 When using a magnetic medium, the code is rewritten by erasing the originally recorded code using a permanent magnet, which magnetizes the medium to saturation, and writing another code using a type stamp or needle core.

Hidden coding of a carrier made of soft magnetic material in the form of a steel plate is carried out by scratching the back surface of the plate or by hardening with subsequent polishing. Covert coding of carriers made of magnetically hard materials can be carried out by locally changing the magnetic parameters of the information carrier during annealing, namely magnetic anisotropy and coercive force. These parameters are restored upon subsequent heating of the carrier in the presence of a magnetic field. Covert coding of carriers made of non-magnetic metals and non-metals can be carried out by applying a layer of magnetic rubber on the inner surface of the carrier and its local magnetization reversal. Covert coding of carriers of non-magnetic electrically conductive materials in the form of an aluminum plate can be accomplished by scratching the back surface of the plate and by hardening with subsequent polishing. Then, during visualization, the carrier is exposed to an alternating electromagnetic field, which causes the appearance of eddy currents in the carrier. Instead of magnetic rubber, a fragment of a magnetic tape or magnetic disk, a layer of magnetic varnish or magnetic paint can also be applied to the back surface of the carrier. As a sensitive film element, magnetically uniaxial epitaxial films of a ferrite garnet of the composition (Y, Lu, Pr, Bi) ₃ (Fe, Ga) ₅ O ₁₂ deposited on a nonmagnetic garnet substrate of the composition (Gd, Ca) ₃ (Mg, Zr, Ga) ₅ O ₁₂ with the (111) orientation. Optical registration of the distribution of magnetization in a sensitive film element can be carried out using the magneto-optical Faraday effect in the "reflection" geometry. Registration can be carried out visually directly or from the monitor screen, as well as using a VCR. Another approach is to use a photodetector, in particular, a CCD. During visual registration, a ferrite garnet film can be exposed to an alternating magnetic field in excess of its coercive force. The code is visualized as areas in which the domain walls are fixed.

 Writing encoded information onto a medium made of hard magnetic material can be done using a typesetting stamp made of permanent samarium-cobalt magnets, in particular, in the form of a removable set of bipolar magnets of prismatic or toroidal shape. An alternative is to make a set of steel needle-type magnetic circuits, passed through 100-coil coils. In addition, you can use a "magnetic pencil" with a needle core made of a permanent samarium-cobalt magnet. In an alternative embodiment, a steel needle core is used, passed through a 100-turn coil, which is connected to a source of alternating pulse current with an adjustable duration, amplitude and duty cycle.

The visualization of coded information can be carried out using a "magneto-optical magnifier" with backlight. The light is sent to the magneto-optical sensing element either normal to the plane of the element (a beam splitter is used) or at an angle to the normal. The magnifier uses film polarizer and analyzer. To memorize the visualized information in a magneto-optical film, a structure of magnetically insulated cells with a size of 100x100 μm ^{2 is} performed. To improve image quality, on the magnetically sensitive element, on the one hand, a mirror layer and a protective coating of silicon oxide are applied, and on the other hand, an antireflection coating. When recording encoded information on a soft magnetic carrier, the magneto-optical magnifier is equipped with a magnetizing system consisting of permanent samarium-cobalt magnets and is closed in steel, and when recording on a non-magnetic electrically conductive carrier, it is equipped with an electromagnetic unit for generating eddy currents in the carrier. In addition, this magnifier, if necessary, is equipped with an inductor connected to an AC source. A gadolinium-gallium garnet plate is used as a beam splitting element.

Claims (38)

 1. A method of recording and reading encoded information, including applying a predetermined code to a storage medium by local exposure to the storage medium and subsequent reading of the applied code, characterized in that upon local exposure to the storage medium, the electrophysical properties in the material or on the inner surface of the storage medium are changed, and reading the applied code is carried out by optical registration of the distribution of magnetization using a sensitive film magneto-optical th element mounted on the outer surface of the storage medium.  2. The method according to claim 1, characterized in that the sensitive film magneto-optical element is magnetically uniaxial.  3. The method according to p. 2, characterized in that the sensitive film magneto-optical element is exposed to an alternating magnetic field.  4. The method according to claim 1, characterized in that when using a medium of soft magnetic material, a predetermined code is applied by a local change in magnetic permeability.  5. The method according to claim 4, characterized in that the magnetic permeability is changed by locally changing the thickness of the information carrier.  6. The method according to claim 4, characterized in that the magnetic permeability is changed by local structural changes in the storage medium.  7. The method according to claim 1, characterized in that when using an information carrier made of hard magnetic material, a predetermined code is applied by locally changing the magnetic parameters of the information carrier.  8. The method according to claim 7, characterized in that locally change the magnetic anisotropy of the information carrier.  9. The method according to claim 7, characterized in that locally change the coercive force of the information carrier.  10. The method according to claim 1, characterized in that when using a storage medium of non-magnetic metals or non-magnetic non-metals, a layer of hard magnetic material is applied to the internal surface of the storage medium, and a predetermined code is applied by locally changing the magnetic parameters of this layer.  11. The method according to claim 10, characterized in that barium hexaferrite is used as a magnetically solid material.  12. The method according to claim 10, characterized in that the magnetic rubber is used as a hard magnetic material.  13. The method according to claim 10, characterized in that the layer of hard magnetic material is made in the form of magnetic tape.  14. The method according to claim 10, characterized in that the layer of hard magnetic material is made in the form of fragments of a magnetic disk.  15. The method according to claim 10, characterized in that the layer of hard magnetic material is applied with a magnetic varnish.  16. The method according to claim 10, characterized in that the layer of hard magnetic material is applied with magnetic paint.  17. The method according to claim 1, characterized in that when using a storage medium of non-magnetic electrically conductive material, a predetermined code is applied by locally changing the electrical resistance of the storage medium.  18. The method according to 17, characterized in that the electrical resistance of the information medium is changed by local changes in the thickness of the information medium.  19. The method according to 17, characterized in that the electrical resistance of the information medium is changed by local changes in the structure of the material of the information medium.  20. The method according to 17, characterized in that when reading the printed code on the medium additionally exposed to an alternating electromagnetic field, causing the appearance of eddy currents in the information carrier.  21. The method according to claim 1, characterized in that the optical registration of the distribution of magnetization in a sensitive film magneto-optical element is carried out using the magneto-optical Faraday effect.  22. The method according to item 21, wherein the optical registration is carried out visually.  23. The method according to p. 22, characterized in that the optical registration is carried out visually from the screen of a television or video reading device.  24. The method according to item 21, wherein the optical registration is carried out using a photodetector.  25. The method according to paragraph 24, wherein the optical registration is carried out using a matrix photodetector.  26. The method according to item 21, wherein the optical, registration is carried out using a VCR.  27. A device for recording encoded information on a medium of hard magnetic material, comprising means for forming a local magnetic field, characterized in that the tool is made in the form of a type stamp from elements for forming a local magnetic field.  28. The device according to item 27, wherein the type-setting stamp is made of permanent magnets, the coercive force of the material of which is higher than that of the material of the information carrier.  29. The device according to p. 28, characterized in that the typesetting stamp is made of bipolar permanent magnets in the form of a replaceable set.  30. The device according to clause 29, wherein the permanent magnets have a prismatic section.  31. The device according to clause 29, wherein the permanent magnets have a toroidal cross section.  32. The device according to item 27, wherein the type-setting stamp is made of electrically controlled needle magnetic cores.  33. A device for reading encoded information containing optically coupled and sequentially installed along the optical axis a light source, a polarizer, a magnetically sensitive element and an analyzer, characterized in that the magnetically sensitive element is made in the form of a magneto-optical film with a cellular structure, the cell sizes of which are determined taking into account the maximum allowable quantization of the read image.  34. The device according to claim 33, wherein the magneto-optical film is coated with a mirror layer and a protective coating on the side adjacent to the information carrier, and an antireflection coating on the opposite side.  35. The device according to p. 33, characterized in that when reading from information carriers from soft magnetic material, a magnetizing system of permanent magnets connected by a contactor is introduced into the device.  36. The device according to p. 33, characterized in that when reading from information carriers from a non-magnetic electrically conductive material, an electromagnetic unit for generating eddy currents in the information carrier is inserted into the device.  37. The device according to p. 33, characterized in that it introduced the block forming an alternating magnetic field magnetically connected with a magneto-optical film.  38. The device according to p. 33, characterized in that it introduced a beam splitting element mounted on the optical axis between the magneto-optical film and the polarizer.

Images