RU2651795C1 - Shielded keyboard - Google Patents

Abstract

FIELD: radio engineering and communications.

SUBSTANCE: invention relates to the field of radio engineering, in particular to the protection against information leakage through technical channels, the factor of which is secondary electromagnetic radiation. Technical result is achieved by the fact that the screened keyboard contains a housing consisting of base 1 and cover 2, planar contact membrane 3 with printed keyboard conductors embedded in housing base 1, keys 4 arranged in holes 5 of housing cover 2, elastic gasket 6 with domes, U-shaped thin conductive metal grid 7, between one and the other internal surfaces 50 of which contact diaphragm 3 is located, matrix-optical converter unit 8 is located in shielding housing 10 and comprises keyboard matrix interrogation unit 13 of matrix 14, optical signal scan code packing unit 19, optical transmitter 25, optical receiver 28, first 31 and second 32 fiber optic links, power controller 9 is located in shielding housing 10 and comprises voltage converter unit 34 and voltage monitoring and interlocking unit 35, power supply decoupling unit 11 located in secondary shielding housing 12 galvanically connected to shielding housing 10. Through the first feed-through capacitor 45, power supply decoupling circuit is connected to a power source, and through the second feed-through capacitor 48, power supply decoupling unit 11 is connected to power controller 9. Shielding housing 10 is galvanically connected to one and the other internal surfaces 50 of grid 7, and earth terminal 55 is mounted on shielding housing 10. Impedance counter reflector 57 is mounted on the housing base 1.

EFFECT: technical result is an increase in the level of shielding of magnetic and electromagnetic fields, as well as an increase in the stability of the contact membrane of the keyboard during mechanical actions of the operator's hand on the key.

21 cl, 4 dwg

Description

The invention relates to the field of radio engineering, in particular to the field of information protection from leakage through technical channels, the formation factor of which is secondary electromagnetic radiation, and can find application in computer facilities, in complexes of automated workstations of the operator, in automation and control systems, in tasks electromagnetic compatibility.

A known method of energy-information (shielded) protection of a computer keyboard (RF patent No. 2204889, class H05K 9/00, 2003), comprising a housing, a cover, a push-button system with metal rods and the keyboard itself, mounted on the housing, i.e. an additional keyboard is installed on the main keyboard and connected to the main keyboard with the rods passed through the holes in the cover. The role of the shielding plate in it is performed by a cover made of thin sheet steel with perforated holes of small diameter for the passage of rods through them.

The disadvantage of this keyboard is the low level of electromagnetic shielding, a large size in height due to the presence of a button control system located on top of each other and a main keyboard with contact pairs of buttons mounted on the body and connected to the button control system of metal rods.

A well-known shielded keyboard (CE), consisting of a set of shielded buttons installed in the metal case of the board (England patent No. 2151056, class B41J 5/08, 1986). For the convenience of installing the buttons and fixing them against rotation during operation, a shielded plate is installed, installed in a case with rectangular holes for the buttons. The lid also has windows for keys.

The disadvantage of this FE is the low level of shielding from electromagnetic radiation due to the wide windows in the keyboard cover and the shielding plate, as well as due to the electromagnetic radiation of the connecting wires of the buttons on the circuit board.

Known CE containing a metal case, a mounting plate, a shielding plate with holes, rods with rubber shock absorbers and a guide plate, cover, fasteners (RF patent No. 2368110 C1, CL H05K 9/00, H01H 13/70, 2009) . The guide plate is made in the form of a thin-sheet metal plate, and the guide bushes are provided with two radial protrusions, while the guide bushes contain a support cup in the upper part, and contact pads of conductive elastic material are formed in the lower part of the rubber shock absorbers, and on the mounting plate in places where these the pads are printed with contact pads, the circuit board is attached to the shielding plate through a dielectric gasket, and the cylindrical surfaces of the upper hour These rods are connected to the outer surfaces of the vertical walls by means of a flexible bell-shaped membrane of flexible silicone material.

The disadvantage of this FE is the significant complexity of the design and the large nomenclature of the element base, poor maintainability, the high complexity of the assembly and high cost.

The closest technical solution - the prototype is CE (US patent No. 4671688, class IPC B41J 29/00; G06C 7/02; NKI 400/714, 1987), containing a steel casing consisting of a base and a lid embedded in the base the contact membrane membrane of the keyboard with the circuit printed on it, a thin flexible grid of corrosion-resistant conductive material, which is galvanically connected to the steel keyboard housing around the keyboard and located between the keyboard’s contact membrane and an elastic rubber gasket with domes for the keys above which ozhena keyboard housing cover with holes for the keys, the keys arranged in the keyboard housing lid, forming the keyboard, and causing through the thin, flexible wire when the closure is pressed in the contact pattern of the membrane, a microprocessor, a steel body keyboard electrically connected to the shielding braid of shielded cable keyboard interface.

The disadvantages of this technical solution are the low level of shielding in the electric and magnetic components of the electromagnetic field - the design of the shielding keyboard housing due to volume resonances in the region of the cavity resonator formed between a flexible grid of conductive material and the steel base of the keyboard housing, which is shielded by a single-layer flexible grid of conductive material; the presence of a shielded cable connecting the keyboard with the technical means of processing information; insufficient stability of the keyboard’s contact membrane with respect to the plastic keys of the keys due to mechanical influences of the operator’s hand on the key, insufficient screening of the connection of the wires of the contact membrane with the microprocessor, large size along the height of the keyboard case, high metal consumption of the case

The technical task of this invention is the creation of FE with a high level of shielding in the electric, magnetic and electromagnetic components of the electromagnetic field and an increased level of shielding of the magnetic component of the electromagnetic field, replacing the shielded keyboard cable with a fiber optic communication line (FOCL), with increased stability of the keyboard contact membrane relative to the plastic stocks of the keyboard keys during mechanical impacts of the operator’s hand on the key, creating a keyboard housing iatury with a substantially smaller height and metal content.

The technical result is achieved in that the FE comprising a housing consisting of a base and a cover, a planar contact membrane with printed keyboard conductors embedded in the base of the housing, keys located in the openings of the housing cover, having protrusions, an elastic gasket with domes for keyboard keys, is thin a conductive metal mesh made of a corrosion-resistant material, while a matrix-optical converter (BMOS) unit and a power controller (CP) are introduced, which are located in the entered screen a housing (EC) made of steel with a corrosion-resistant conductive coating, and a power supply isolation unit (BRCP) is introduced, which is located in the introduced additional EC made of steel with a corrosion-resistant conductive coating, and the EC and additional EC are galvanically interconnected, while the BMOS contains a keyboard matrix polling unit (BOMK), the input conductive conductors of which are connected to the conductive conductors by the contact membrane of the keyboard, and the output of the BOMK is connected to the input of the unit packing of scancodes into an optical signal (BUS), the output of which is connected to the first input of the optical signal reception and transmission control unit, the first output of the optical signal reception and transmission control unit is connected to the input of the optical transmitter, and the second input of the optical signal reception and transmission control unit is connected with the output of the optical receiver, while the output of the optical transmitter and the input of the optical receiver are connected to one end of the first and second FOCLs, respectively, which are through transverse waveguides of a round cross-section, made in EC, come out of EC, and KP contains a voltage converter block (BPN) and a voltage monitoring and blocking block (BKBN), while the input of the BKBN is connected to the input of the BPS, and the output of the BKBN is connected to the third input of the control unit transmission of optical signals, and the power supply of the matrix polling unit, the power input of BUSOS and the power input of the control unit for receiving and transmitting optical signals are parallelly connected to the output of the BPN, while the input of the isolation unit through the power supply through the first passage capacitor is set connected in one end wall of the additional EC, is connected to the power source, and the output of the isolation unit through the second feed-through capacitor installed in the other end wall of the additional EC, common with the EC, is connected to the input of the BPN, while the keyboard case is made of dielectric material , a thin conductive metal mesh is made in a U-shape, between the one and the other inner surfaces of which is the contact membrane of the keyboard, and the outer side edges of one and the other surface a thin conductive metal mesh of a U-shape around the perimeter is galvanically connected to each other by a contact tape element, and mounting holes are made in a thin conductive metal mesh of a U-shape and in the contact membrane of the keyboard, moreover, a thin conductive metal mesh of a U-shape with a contact membrane the keyboard inside is placed on the entered at least two alignment-impedance struts of cylindrical shape mounted on the base of the keyboard body and located identical to the mounting holes, while in the elastic gasket with domes for the keyboard keys, holes are made identical to the mounting holes, and the elastic gasket with domes oriented towards the keyboard body cover is placed on the outer surface of the thin conductive metal mesh of a U-shape on the adjustment impedance racks, and on each alignment-impedance strut, a position lock is installed on top of the elastic gasket with domes, and the diameter of the alignment-impedance struts is equal to d a meter of mounting holes, and an inserted ground terminal is installed on the BMOP EC, and the EC itself is galvanically connected to one and the other inner surfaces of a thin conductive metal mesh of a U-shape, while an impedance counterreflector made in the form of steel is installed on the outside of the base of the keyboard case plates with a corrosion-resistant conductive coating.

In this technical solution, the introduced BMOS, containing: BOMK, BUSOS, a transmit-receive control unit, an optical transmitter, an optical receiver and two FOCLs, converts informative current pulses of the keyboard (spurious electromagnetic radiation) into an optical signal.

At the same time, the BMOS and the control gear are located in a single EC, on which an earth terminal is installed.

In BMOS, pulsed signals from the keyboard matrix are converted into optical signals, and information is exchanged through the optical transmitter and optical receiver via FOCL with the information processing equipment, which includes the FE. The EC, galvanically connected to one and the other surfaces of a thin conductive metal mesh of a U-shape, provides shielding of spatial signals resulting from the conversion of pulsed signals to optical, while the FOCL exit the EC through transcendental waveguides, which completely eliminates side electromagnetic radiation and interference from informative exchange signals into free space.

The CP, which contains the BPN and BKBN, provides control of the stability of the BMOS and eliminates the possibility of false conversion of the digital signal of the keyboard matrix into an optical signal.

The isolation block on the power circuit, which is located in the additional EC and is galvanically connected to the EC, is connected to the input of the BPN through one passage capacitor, and connected to the power source through the other passage capacitor.

Thus, in this technical solution, the information component of the electromagnetic field is almost completely eliminated.

The implementation of a thin conductive metal mesh of a U-shape, the location between its inner surfaces of the keyboard contact membrane and galvanic connection of the external side edges of the metal U-shape by a contact ribbon element between them, form a fully shielded contact membrane in height (thickness) almost equal to its own height contact membrane on which an elastic gasket with domes for keyboard keys is installed. Placing on the alignment-impedance struts of a cylindrical shape mounted on the base of the keyboard case, a shielded contact membrane with an elastic gasket with domes for the keyboard keys on the mounting holes allows you to use the standard keyboard case made of dielectric material and to provide increased stability of the keyboard contact membrane in relation to plastic stocks of the keyboard keys during repeated mechanical impacts of the operator’s hand on the keys. The installation of a position fixer on the adjustment-impedance racks from above on an elastic gasket with domes allows galvanic contact of the U-shaped metal mesh in the place of the mounting holes and creates additional structural rigidity and high operational reliability.

Installing an impedance counterreflector on the outside of the base of the keyboard body increases the efficiency of shielding a thin conductive metal mesh in the form of a U-shape from the side opposite to the location of the elastic strip with domes for the keyboard keys.

The implementation of all structural metal elements of the keyboard with a corrosion-resistant conductive coating eliminates the possibility of the formation of galvanic pairs. For example: (G. Ott. Methods for suppressing noise and interference in electronic systems .. Transl. From English. - M.: Mir, 1979. - 310 p.).

With this technical solution, the FE is performed in a standard dielectric casing.

CE can be made with a conductive coating (metallization) of the inner surface of the base and the cover of the dielectric housing, providing galvanic contact between the base and the housing cover assembly, while the conductive coating of the housing is galvanically connected to the BMOS EC.

CE can be performed by applying a dielectric and / or additional EC diffuse coating of permalloy alloy on the inner surface of the base and cover of the dielectric and / or on the outer surface of the EC.

The use of a coating of permalloy alloy allows you to create additional shielding for the magnetic component of the electromagnetic field. Permalloy alloy coating is in the form of plates and can be installed on flat surfaces without bending.

CE can be performed with installation on the inner surface of the base and cover of the dielectric housing, and / or on the outer surface of the EC and additional EC of the tape of a soft magnetic amorphous metal alloy with an initial magnetic permeability of at least 10-10 ³ . Amorphous metal alloy tapes on the keyboard surfaces can, for example, be overlapped with an overlap of at least the thickness of the tape itself and be fixed relative to each other using an elastic coating having an elasticity of at least 250 and an adhesion value between surfaces of at least 1 MPa.

Tapes of a soft magnetic amorphous metal alloy have a thickness of the order of 15-100 μm and a width of the order of 5-100 mm and can be practically freely bent without losing their high magnetic properties. ([Electronic resource]. - Access mode: pnzzi.kpi.ua/4/04-p66.pdf).

The use of an amorphous metal alloy coating makes it possible to create additional shielding by the magnetic component of the electromagnetic field.

CE can be performed by installing at least one layer of ferrite foil on the inner surface of the base and cover of the dielectric housing, and / or on the outer surface of the EC and additional EC. For example: (J. Smith, H. Wayne. Ferrites. Physical properties and practical applications. Transl. From English. - M.: Foreign Literature, 1962. - 504 s); ([Electronic resource]. - Access mode: katalog.we-online.com/de/pbs/we - FSFS Flexible Ferritfolie.)

The use of ferrite foil coatings allows for additional shielding with respect to the magnetic component of the electromagnetic field. A multilayer coating with a ferrite foil, with a layerwise different value of relative magnetic permeability, allows you to expand the frequency range.

CE can be performed by coating the inner surface of the base and the cover of the dielectric housing and / or on the outer surface of the EC and the additional EC with a microwave radio-absorbing material. For example: (David Morgan. A handbook for EMC testing and measurement / Published by: Peter Peregrinus Ltd., on behalf on the institution of Electrical Engineers, London, United Kingdom, 1994).

The use of coatings with microwave radio-absorbing material allows you to create additional shielding for the electrical and electromagnetic component of the electromagnetic field.

The use of a copper coating as a substrate for coating with permalloy or a tape of a soft magnetic amorphous metal alloy allows one to remove the static potential. For example: (Shielding of technical equipment and shielding screens / L.N. Kechiev, B. B. Akbashev, P. V. Stepanov. - 2010 - 470 s; ill. - (EMC Library), Published under the editorship of the Journal “ EMC technology ").

FE can be performed with adjusting-impedance racks of dielectric material.

FE can be performed with adjusting-impedance steel racks coated with corrosion-resistant conductive material.

FE can be performed by installing a closed coil on the adjustment-impedance racks made in the form of a ribbon conductor made of permalloy alloy coated with a thin layer of dielectric material, while the external diameter of the closed coil is identical to the diameter of the mounting hole.

The implementation of the alignment-impedance racks made of steel allows you to compensate for the surface and volume components of the electromagnetic field that occur above the surface of the elastic strip with domes under the keyboard keys. The installation of a closed coil of permalloy alloy on the adjustment-impedance racks made of steel allows you to additionally compensate for the surface and volume magnetic components of electromagnetic fields.

FE can be performed by installing on the surface of the impedance counterreflector from the side of the dielectric base: - an amorphous metal alloy tape with an initial magnetic permeability of at least 10-10 ³ ; - at least one layer of ferrite foil, with a multilayer coating with ferrite foil, with layerwise different values of relative magnetic permeability, which allows you to expand the frequency range; - microwave radio-absorbing material.

Between the dielectric base of the case and the impedance counter-reflector, surface and volume magnetic and electric components of the electromagnetic field can be excited, therefore, the use of an amorphous metal alloy tape, ferrite foil, microwave radio-absorbing material individually or in combination allows you to completely eliminate these electromagnetic fields in a wide frequency range and thereby increase shielding efficiency.

FE can be made with a position lock in the form of a washer made of dielectric material, for example, from capralon.

FE can be performed with a space key consisting of at least three parts, while the contact key for the space bar is the central key, the longitudinal size of which is equal to or more font keys on the keyboard, and the remaining space keys are rigidly fixed. This execution of the space bar allows you to improve the vibro-acoustic parameters of the keyboard.

The invention is illustrated by the following figures.

In FIG. Figure 1 shows a general view of a FE with a construction fragment of the arrangement of the BMOS and KP ECs with two FOCLs and an earth terminal, an additional BRTSP EC, a U-shaped metal mesh mounted on a shielding case, and an alignment-impedance rack; in FIG. 2 is a sectional view of the FE body of FIG. 1 with a keyboard contact membrane installed in a thin conductive metal mesh of a U-shape with a contact ribbon element, an elastic gasket with domes for keyboard keys, keys, an impedance counter-reflector; in FIG. 3 is a structural diagram of a BMOS and KP with two fiber optic links and a BRCP, which are schematically located in an EC with an earth terminal and an additional EC; in FIG. 4 is a cross-sectional view of a CE design fragment with an alignment-impedance struts mounted on the base of the housing and the location of the contact membrane in a thin conductive metal mesh of a U-shape with an elastic gasket with domes for keys and an impedance counter-reflector.

CE of FIG. 1, FIG. 2 and FIG. 3 comprises a housing consisting of a base 1 and a cover 2, a planar contact membrane 3 with printed keyboard conductors embedded in the base 1 of the housing, keys 4 located in the holes 5 of the housing cover 2 having protrusions, an elastic gasket 6 with domes for keyboard keys 4 a thin conductive metal mesh 7 made of a corrosion-resistant material, while BMOP 8 and KP 9, which are located in the EC 10, made of steel with a corrosion-resistant conductive coating and BRTSP 11, which is located in the additional EC 12, made of steel with a corrosion-resistant conductive coating, and EC 10 and additional EC 12 are galvanically connected to each other, while BMOP 8 contains BOMK 13 keyboard matrix 14, input conductive conductors 15 of the polling unit 13 are connected to conductive conductors 16 by a membrane membrane 3 of the keyboard, and the output 17 BOMK 13 matrix keyboard 14 is connected to the input 18 BUSOS 19, the output 20 of which is connected to the first input 21 of the control unit for the reception and transmission of optical signals 22, and the first output 23 of the control unit for the reception and transmission of optical signal 22 is connected to the input 24 of the optical transmitter 25, and the second input 26 of the control unit for receiving and transmitting optical signals 22 is connected to the output 27 of the optical receiver 28, while the output 29 of the optical transmitter 25 and the input 30 of the optical receiver 28 are connected to one end of the first 31 and the second 32 FOCLs, respectively, which, through transcendental waveguides 33 made in EC 10, exit EC 10, wherein CP 9 contains BPN 34 and BKBN 35, while input 36 of BKBN 35 is connected to input 37 of BPN 34, and output 38 of BKBN 35 connected to the third input of the 39 control unit receiving and transmitting optical signals 22, and to the output 40 of the BPN 34, the power input 41 of the BOMK 13 of the matrix 14, the power input 42 of the BUSOS 19 and the power input 43 of the control unit for receiving and transmitting optical signals 22 are connected in parallel with the input 44 of the BRTSP 11 through the first loop-through a capacitor 45 installed in one end wall 46 of the additional EC 12 is connected to a power source, and the output 47 of the BRTSP 11 through a second feedthrough capacitor 48 installed in another end wall 49 of the additional EC 12, common with EC 10, is connected to the input 37 of the BPN 34 while the keyboard case in made of a dielectric material, a thin conductive metal mesh 7 is made in a U-shape, between one and the other inner surfaces 50 of which there is a keyboard contact membrane 3, and the outer side edges 51 of one and the other surface of a thin conductive metal mesh 7 in a perimeter galvanically interconnected by a contact tape element 52, and in a thin conductive metal mesh 7 U-shaped and in the contact membrane 3 of the keyboard made installation holes, and a thin conductive metal mesh 7 U-shaped, with the contact membrane 3 of the keyboard inside, is placed on at least two alignment-impedance racks 53 of cylindrical shape mounted on the base of the keyboard body 1 and located identically to the mounting holes 5, with this, in the elastic gasket 6 with domes for the keys of the keyboard 4, holes are made identical to the mounting holes 5, and the elastic gasket 6 with domes oriented towards the cover of the body of the keyboard 2 is placed on the outer surface of the thin conductive metal mesh 7 is U-shaped on the alignment-impedance struts 53, and on each alignment-impedance strut on top 53 of the elastic strip 6 with domes, a position lock 54 is installed, and the diameter of the alignment-impedance struts 53 is equal to the diameter of the mounting holes 5, moreover, an earthing terminal 55 is installed on EC 10 BMOPS 8, and the case itself is galvanically connected to one and the other inner surfaces 50 of a thin conductive metal mesh 7 of a U-shape, while on the outside 56 anija keyboard housing 1 mounted kontrreflektor impedance 57, formed as a steel plate with a corrosion-resistant conductive coating.

Mounting holes 10 are made in the contact membrane 3 and the elastic gasket 6, which are placed on the alignment-impedance struts 11 of the cylindrical shape of FIG. 4, mounted on the base of the keyboard body 1 and on each alignment-impedance rack 11, a position lock 12 is installed on top of the elastic strip 6.

Space bar, for example, FIG. 1 is made of three parts, while the contact key for the space bar 58 is the center key, the right and left space keys 59 are rigidly fixed.

Electromagnetic radiation of electric and magnetic fields accompanying informative current pulses of the keyboard (spurious electromagnetic radiation) received by a technical device, in particular a computer, must have effective shielding on all possible structural elements, radiation sections and information transmission lines from the keyboard to the information processing means .

The problem is solved by shielding the contact membrane 3 of a conductive metal mesh 7 U-shaped and shielding BMOS 8 EC 9, galvanically connected to each other. Thus, this technical solution CE provides almost complete electromagnetic shielding of its own spurious electromagnetic radiation.

The shielded keyboard works as follows.

By pressing the key 4 of the keyboard of FIG. 1 of FIG. 2, the dome of the elastic strip 6 lowers and locally presses with a protrusion on the surface of the conductive metal mesh 7 of a U-shape, closes the portion of the contact membrane 3 corresponding to the symbol of the key 4. The informative current pulse generated in the contact membrane 3 through the conductive conductors 16 of the keyboard matrix 14, connected to the input conductive conductors 15 enter the BMOS 8, namely, the BOMK 13 matrix 14, the output of which 17 are fed to the input 18 BUSOS 19, where the generation of scancodes.

From output 20, BUSOS 19, the generated scancodes are fed to the first input 21 of the optical signal reception-transmission control unit 22, the output 23 of which is connected to the input 24 of the optical transmitter 25, and the second input 26 is connected to the output 27 of the optical receiver 28. Output 29 of the optical transmitter 25 and the input 30 of the optical receiver 28 are connected to the first 31 and second 32 FOCLs, which through transcendent waveguides 33 exit EC 10. FOCLs 31 and 32 connect the keyboard to the information processing means.

EC 10 provides shielding of informative surface and volume electromagnetic fields arising from the conversion of informative current pulses generated in the contact membrane 3 into optical signals. Beyond the waveguides 33 provide the passage of the fiber optic link 33 through EC 10.

A power controller 9, comprising a voltage converter unit 34 and a voltage monitoring and blocking unit 35. BPN 34 provides stability of the supply voltage of the BMOS 8, and BKBN 35 provides control of the supply voltage and, in the event of deviations from the set value, turns off the power. Thus, the possibility of false conversion of the pulse signal into an optical signal is eliminated.

The isolation block on the power circuit 11 provides isolation between the power source and the power controller 9 and, in particular, filters out all kinds of interference.

Claims (21)

1. A shielded keyboard comprising a housing consisting of a base and a cover, a planar contact membrane with printed keyboard conductors embedded in the base of the housing, keys located in openings of the housing cover, having protrusions, an elastic gasket with domes for keyboard keys, a thin conductive metal mesh made of corrosion-resistant material, characterized in that the matrix-optical converter unit and the power controller are inserted, which are located in the introduced shielding case made of steel with a corrosion-resistant conductive coating and a power supply isolation unit is introduced, which is located in the inserted additional shielding case made of steel with a corrosion-resistant conductive coating, the shielding case and the additional shielding case being galvanically interconnected, while the matrix-optical converter unit comprises a keyboard matrix polling unit, the input conductive conductors of which are connected to the conductive conductors of the contact key membrane of the keyboard, and the output of the polling unit of the matrix of the keyboard is connected to the input of the unit for packing the scancodes into an optical signal, the output of which is connected to the first input of the control unit for receiving and transmitting optical signals, and the first output of the control unit for receiving and transmitting optical signals is connected to the input of the optical transmitter, and the second input of the optical signal reception and control unit is connected to the output of the optical receiver, while the output of the optical transmitter and the input of the optical receiver are connected to one end the first and second fiber-optic communication lines, respectively, which through transcendental waveguides made in the shielding case exit the case, the power controller comprising a voltage converter unit and a voltage monitoring and blocking unit, while the input of the voltage monitoring and blocking unit is connected to the input of the converter unit voltage, and the output of the control unit and voltage blocking is connected to the third input of the control unit for the reception and transmission of optical signals, and to the output of the converter unit the voltage is connected in parallel to the power input of the matrix polling unit, the power input of the scanning code packaging unit to the optical signal and the power input of the optical signal receiving and transmitting control unit, while the input of the isolation block through the power supply circuit through the first passage capacitor installed in one end wall of the additional shielding housing, connected to a power source, and the output of the isolation block on the power circuit through a second feedthrough capacitor installed in the other end wall of the additional shielding housing, o in general with a shielding case, connected to the input of the voltage converter unit, while the keyboard case is made of dielectric material, the thin conductive metal mesh is made in a U-shape, between which the keyboard’s contact membrane is located, and the outer side edges of one and the other the surface of a thin conductive metal mesh of a U-shape around the perimeter is galvanically connected to each other by a contact tape element, moreover, in a thin conductive Mounting holes are made in the U-shaped metal mesh and in the keyboard contact membrane, and a thin U-shaped conductive metal mesh with the keyboard contact membrane inside is placed on the inserted at least two cylindrical adjustment-impedance racks mounted on the base of the case keyboards and located identically to the mounting holes, while in an elastic pad with domes for the keyboard keys, holes are made identical to the mounting holes, and an elastic gasket with domes oriented toward the keyboard case cover is placed on the outer surface of a thin conductive metal mesh of a U-shape on an alignment-impedance racks, and a position lock is installed on top of each alignment-impedance strut on top of an elastic gasket with domes, and the diameter of the alignment is impedance racks is equal to the diameter of the mounting holes, and the entered ground terminal is installed on the shielding case of the matrix-optical converter unit, and the case itself is galvanic The esk is connected to one and the other inner surfaces of a thin conductive metal mesh of a U-shape, while an impedance counter-reflector introduced in the form of a steel plate with a corrosion-resistant conductive coating is installed on the outside of the base of the keyboard case. 2. The shielded keyboard according to claim 1, characterized in that the inner surface of the base and the cover of the dielectric housing of the keyboard is made with a conductive coating that provides galvanic contact between the base and the cover of the assembly, while the inner conductive coating of the housing is galvanically connected to the surface of the shielding housing. 3. The screened keyboard according to claim 1, characterized in that the diffuse coating of permalloy alloy is applied to the inner surface of the base and the cover of the dielectric case of the keyboard. 4. The screened keyboard according to claim 3, characterized in that the diffuse coating of the permalloy alloy is galvanically connected to the surface of the shielding housing. 5. The screened keyboard according to any one of paragraphs. 3 and 4, characterized in that the diffusion coating of permalloy alloy is applied to the introduced diffusion coating of copper, which is applied to the inner surface of the base and the cover of the dielectric keyboard housing. 6. The screened keyboard according to claim 1, characterized in that tapes of an amorphous metal alloy with an initial magnetic permeability of at least 10-10 ^{3 are} installed on the inner surface of the base and the cover of the dielectric housing and / or on the shielding and additional shielding cases. 7. The screened keyboard according to claim 6, characterized in that the tapes of the amorphous metal alloy are galvanically connected to the surface of the shielding housing. 8 Keyboard shielded according to any one of paragraphs. 6 and 7, characterized in that the tapes of the amorphous metal alloy are mounted on the introduced diffuse copper coating, which is deposited on the inner surface of the base and the cover of the dielectric keyboard housing. 9. The keyboard is shielded according to any one of p. 1 or 2, characterized in that at least one layer of ferrite foil is installed on the inner surface of the base and cover of the dielectric housing and / or on the outer surface of the shielding and additional shielding housing. 10. The shielded keyboard according to claim 9, characterized in that an inserted copper foil is installed between the inner surface of the base and the cover of the dielectric housing and the ferrite foil, which is galvanically connected to the surface of the shielding housing. 11. The shielded keyboard according to any one of p. 9 or 10, characterized in that the inserted copper foil is installed on the outer surface of the shielding and additional shielding case with galvanic contact. 12. The keyboard is shielded according to any one of p. 1 or 2, characterized in that on the inner surface of the base and the cover of the dielectric housing and / or on the outer surface of the shielding and additional shielding housings installed microwave radio-absorbing material. 13. The screened keyboard according to any one of paragraphs. 1 or 2, characterized in that a film with a resistive coating is installed on the inner surface of the base and cover of the dielectric housing and / or on the outer surface of the shielding and additional shielding cases. 14. The screened keyboard according to claim 1, characterized in that the alignment-impedance racks are made of dielectric material. 15. The screened keyboard according to claim 1, characterized in that the alignment-impedance racks are made of steel and coated with a corrosion-resistant conductive material. 16. The screened keyboard according to any one of paragraphs. 14 or 15, characterized in that an inserted closed coil is installed on the just-impedance racks, made in the form of a ribbon conductor made of permalloy alloy and coated with a thin layer of dielectric material, while the outer diameter of the closed coil is identical to the diameter of the mounting hole. 17. The screened keyboard according to claim 1, characterized in that on the surface of the impedance counterreflector, from the dielectric base of the keyboard case, inserted tapes of an amorphous metal alloy with an initial magnetic permeability of at least 10-10 ^{3 are} installed. 18. The screened keyboard according to claim 1, characterized in that at least one layer of ferrite foil is installed on the surface of the impedance counterreflector, from the dielectric base of the keyboard case. 19. The screened keyboard according to claim 1, characterized in that an inserted microwave radio-absorbing material is installed on the surface of the impedance counterreflector, from the dielectric base of the keyboard case. 20. The screened keyboard according to claim 1, characterized in that the position lock is made in the form of a washer of dielectric material. 21. The keyboard is shielded according to claim 1, characterized in that the space bar is made of at least three parts, while the space bar is a central key, the longitudinal size of which is equal to or more font keyboard keys, and the remaining space keys are hard fixed.

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