RU183432U1 - NUCLEAR MAGNETIC RESONANCE SCANNER - Google Patents

Abstract

The utility model relates to the field of radio spectroscopy, namely to devices for generating a pulse and indicating metal transponders, consisting of a ferromagnetic, antiferromagnetic or ferrimagnetic alloy having the properties of nuclear magnetic resonance, which can be widely used in automatic non-contact authentication (authentication) of various objects on which metal transponders are applied, including wireless microcontrollers or microprocessors used in technology Near Field Communication (NFC), Cryptographic Labels Technology, and Blockchain technology. The technical result is enhanced functionality and increased ease of use of the device. The technical result is achieved due to the fact that nuclear the magnetic resonance scanner contains an electromagnet consisting of a transmitting coil designed to irradiate a metal transponder with an electromagnetic wave of a first frequency, a receiving a coil designed to receive a second frequency from a metal transponder, a transceiver module, a control module, an antenna, a Bluetooth wireless module, a battery, a battery charge module and charge-discharge control module.

Description

The utility model relates to the field of radio spectroscopy, namely to devices for generating a pulse and indicating metal transponders, consisting of a ferromagnetic, antiferromagnetic or ferrimagnetic alloy having the properties of nuclear magnetic resonance, which can be widely used in automatic non-contact authentication (authentication) of various objects on which metal transponders are applied, including wireless microcontrollers or microprocessors used in technology Near Field Communication (NFC) short-range wireless communications, Cryptographic Labels Technology, and Blockchain technology.

The term "metal-transponder" in a utility model is understood (RF patent No. 50023 dated June 30, 2005) to be a ferromagnetic, antiferromagnetic, ferrimagnetic metal or alloy having nuclear magnetic resonance properties due to electric / magnetic dipole or tunnel junctions between the Stark-Zeeman levels, which has at least two resonance frequencies.

The basis of Cryptographic Labels Technology: readers and cryptographic tags, which will be supplied with various objects, with their help consumers will be able to trace the entire path of the object, from its production to the time of sale or storage. At Cryptographic Labels Technology, a nuclear magnetic resonance scanner can be used as part of a reader.

A well-known modern wireless identification reader is described in the patent for utility model No. 72592 dated January 10, 2008.

The modern wireless identification reader contains a GSM / GPRS modem, a GSM antenna, a subscriber’s ID card reader, a radio frequency identification contactless microcontroller (RFID) reader for transmitting energy and reading identification data recorded in the contactless microcontroller’s memory, and a second antenna capable of transmitting energy and identification data with a radio channel frequency of 125 kHz / 134.2 kHz or 13.56 MHz, a microcontroller designed for connecting external devices and controlling the operation of a modern identification wireless reader, a tag reader with nuclear magnetic resonance (NMR) properties, designed to generate a pulse and indicate tags consisting of a ferromagnetic and / or antiferromagnetic and / or ferrimagnetic metal / alloy having NMR properties due to electric / magnetic dipole or tunnel junctions between the Stark-Zeeman levels, a third antenna designed to transmit a pulse and with a frequency of 1 MHz to 1 GHz and receiving a response from tags with NMR properties, the Start button, indication LEDs, power supply unit, external power supply port, designed to connect an external power source.

Disadvantage: A modern wireless ID reader does not work in a Bluetooth wireless network.

The known identity terminal described in US patent No. 9696397 from 04/04/2017. This terminal contains a reader for nuclear magnetic resonance (NMR) tags, a QR code reader, a display with a control unit.

Disadvantage: it does not have the ability to work in a Bluetooth wireless network, the inability to work in a global identity network due to the lack of a cellular module, and low functionality.

Also known is an identity data transmission terminal described in US Pat. No. 5,986,550 of November 16, 1999. This terminal contains a transceiver module (transmitting and receiving module), an electromagnet. This terminal is designed to identify data from metal transponders deposited on the surface of objects: drugs, securities, cash banknotes, credit cards.

The terminal described in US patent No. 5986550 from 11.16.1999, we choose for the prototype.

In the prototype, it is possible to transmit only one code combination (i.e., one metal-transponder frequency), either it is (it is “1”) or it is not (it is “0”).

The prototype (US patent No. 5986550 dated 11.16.1999) has significant drawbacks: low functionality due to the inability to work in Bluetooth wireless networks, lack of a display with a touchscreen (sensor) and, as a result, low ease of use.

Thus, the technical result is to expand the functionality and improve the usability of the device.

For this, a nuclear magnetic resonance scanner containing an electromagnet consisting of a transmitting coil designed to irradiate a metal transponder with an electromagnetic wave of a first frequency, a receiving coil intended to receive a second frequency from a metal transponder, a transceiver module further comprises a control module for for controlling the operation of the modules, antenna, Bluetooth wireless module, designed to receive data from / to smartphones, battery, battery charge module the transmitter and the charge-discharge control, the first output of the transceiver module is connected to the first input of the transmitting coil of the electromagnet, the second output of which is connected to the ground of the general circuit, the first output of the receiving coil of the electromagnet is connected to the second input of the transceiver module, the second output of the receiving coil of the electromagnet is connected to ground the general scheme, while the third input-output of the transceiver module is connected to the first input-output of the control module, the second input-output of which is connected to the first input-output of the mode I have a Bluetooth wireless connection, the second input-output of which is connected to the first input-output of the antenna, while the first output of the battery is connected to the fourth input of the transceiver module, the third input of the control module and the third input of the Bluetooth wireless module, the second input of the mentioned battery is connected to the first output of the battery charge module and charge-discharge control.

The claimed utility model is illustrated by the following drawings: figure 1, which shows a structural diagram of the claimed nuclear magnetic resonance scanner; figure 2, which shows the operation of the claimed nuclear magnetic resonance scanner.

Consider the structure and operation of a nuclear magnetic resonance (NMR) scanner 1 or Nuclear Magnetic Resonances (NMR) Scanner.

As can be seen from the drawing of FIG. 1, a nuclear magnetic resonance scanner 1, contains an electromagnet 2, consisting of a transmitting coil 3, designed to irradiate a metal transponder with an electromagnetic wave of a first frequency, a receiving coil 4, a transceiver module 5, a control module 6, an antenna 8, a Bluetooth 7 wireless module , rechargeable battery 9, battery charge and charge-discharge control module 10.

The first output of the transceiver module 5 is connected to the first input of the transmitting coil 3 of the electromagnet 2, the second output of which is connected to the ground of the general circuit, the first output of the receiving coil 4 of the electromagnet 2 is connected to the second input of the transceiver module 5, the second output of the receiving coil of the electromagnet is connected to ground of the general circuit, the third input-output of the transceiver module 5 is connected to the first input-output of the control module 6, the second input-output of which is connected to the first input-output of the Bluetooth 7 wireless module, the second one output of which is connected to the first input-output of the antenna 8, while the first output of the battery 9 is connected to the fourth input of the transceiver module 5, the third input of the control module 6 and the third input of the Bluetooth 7 wireless module, the second input of the said battery 9 is connected to the first output of the battery charge module and charge-discharge control 10.

The transceiver module 5 contains a transmitting part consisting of: a control generator, an electronic switch and a power amplifier (not shown in the drawing) and a receiving part consisting of: a high-frequency amplifier, a frequency mixer, an intermediate frequency amplifier, a phase detector, and a high-frequency power amplifier (not shown )

The operation of the NMR scanner 1 is shown in figure 2.

The user, clicking the icon on the displays with touchscreen (not shown in the drawing), via special software (STR) turns on the smartphone 14, which has a built-in Bluetooth wireless module (not shown). The user turns on the scanner 1, after a short period of time, the scanner 1 and the smartphone 14 establish between themselves a wireless Bluetooth communication network. The main feature of Bluetooth technology is that various Bluetooth devices connect to each other automatically, they only need to be within reach. The user does not have a headache about cables, drivers, or anything else, all that is required of him is to make sure that the Bluetooth devices, smartphone 14 and reader 1 are close enough to each other, they should take care of everything else Bluetooth devices and software themselves.

The distance over which a Bluetooth connection between the smartphone 14 and the reader 1 can be established is small and ranges from 10 to 30 meters.

The user, by clicking the icon on the displays of the smartphone 14 with touchscreen, through special software (STR) activates NMR scanner 1 by transmitting command 16 via Bluetooth channel.

The scanner 1, using the transmitting unit and the card 3, includes a control generator, an electronic switch and a power amplifier (not shown) of the transceiver module 5. Electromagnetic energy 12 is supplied to the object containing the metal transponder 11 from the transmitting card 3 with a frequency of 1 MHz to 1 GHz.

A metal transponder 11 deposited on an object (not shown in the drawing) has at least two resonance frequencies and consists, for example, of a ferrimagnetic alloy MgFe ₂ O ₄ with nuclear magnetic resonance properties due to electric / magnetic dipole or tunnel junctions between Stark - Zeeman levels.

The electromagnetic field formed by the coils 3 and 4 of the electromagnet 2 of the NMR scanner 1, the resonant frequency causes quantum transitions between the magnetic sublevels of the ferrimagnetic alloy MgFe ₂ O ₄ .

When an object 2 with a metal transponder 11 (MgFe ₂ O ₄ alloy) is placed in a constant magnetic field, the magnetic moment of the nucleus system, like a spinning top brought out of a vertical position, moves along the surface of the cone of rotation around the axis of the field direction (precessional motion).

The effect of external alternating electromagnetic radiation 12 with a frequency f0 = 536 MHz on the MgFe ₂ O ₄ alloy cores located in the constant magnetic field of electromagnet 2 of the NMR scanner 1 leads to the selective (resonant) absorption of the energy of electromagnetic radiation 12 and the appearance of an NMR signal 13 (Zeeman effect , which is based on the splitting of spectral lines under the influence of a magnetic field) with a frequency fIF = f0 (536 MHz) + 10.7 MHz.

If the NMR scanner 1 detected the presence of a metal transponder 11 (MgFe ₂ O ₄ ferrimagnetic alloy) on the object (not shown in the drawing), then it sends a command to the control module 6, which transmits using a microcontroller and an interface unit (not shown in the drawing) received signal to the Bluetooth 7 wireless module.

The Bluetooth 7 wireless module through a Bluetooth connection will transfer the authentication data 15 to the smartphone 14. The display (not shown) of the smartphone 14 shows the process of positive or negative authentication (the process of authenticating the object) with the metal transponder 11 applied.

If the NMR scanner 1 did not detect the presence of a metal transponder 11 on the object, then it does not transmit the command 15 to the smartphone 14, it is considered that the authentication of the object (not shown in the drawing) is not passed.

The smartphone 14 transmits information data received from the object with the metal transponder 11 through the base stations of the cellular communication network to servers with a distributed database (not shown in the drawing). Smartphone 14 can work with blockchain technology.

Blockchain technology is a huge public database that operates without a centralized management. In the case of metal transponder 11, verification of positive authentication, NMR frequency of a metal transponder is carried out by miners - participants of the system who confirm the authenticity of the actions performed and then form blocks from authentication (transaction) records. Since the mining process itself is fraught with complex mathematical problems, miners have powerful computers. Maneuvers have a distributed database of NMR frequencies of metal transporters, consisting of a “chain of blocks”. The distributed nature of the database is based on the blockchain and allows you to control the authenticity of the authentication (transactions) of metal transponders 11 without the supervision of any regulators.

The power of all modules of the scanner 1 is carried out from the battery 9, the battery is charged and the charge-discharge control is carried out using module 10.

NMR scanner 1 allows you to have multifunctionality mode, as it has the ability to work with various smartphones 14. The presence of a built-in Bluetooth 7 wireless module in scanner 1 allows you to use NMR scanner 1 not only for information and telecommunications exchange scanner 1 - smartphone 14, but also in blockchain technology.

The user has the ability to manage by simply pressing the touchscreen (not shown) of the smartphone 14 not only the process of the scanner 1, but also the authentication data 15, enter them into the memory of the smartphone 14 if necessary, which is convenient for using the NMR scanner 1.

Thus, the technical result of the utility model is achieved: expanding the functionality and improving the usability of the NMR scanner 1.

The production of NMR scanner 1 shown in the drawings of FIG. 1 and FIG. 2, is carried out from typical electronic components and typical products of manufacturers.

As can be seen from the drawing of FIG. 2, a prototype NMR scanner 1 was manufactured. Tests have shown that NMR scanner 1 meets the requirements that apply to NMR radio spectroscopy devices.

Claims (1)

A nuclear magnetic resonance scanner containing an electromagnet consisting of a transmitting coil for irradiating a metal transponder with an electromagnetic wave of a first frequency, a receiving coil for receiving a second frequency from a metal transponder, a transceiver module, further comprising a control module, designed to control the operation of the modules, antenna, Bluetooth wireless module, designed to receive data from / to smartphones, battery, module l the battery charge and charge-discharge control, while the first output of the transceiver module is connected to the first input of the transmitting coil of the electromagnet, the second output of which is connected to ground of the general circuit, the first output of the receiving coil of the electromagnet is connected to the second input of the transceiver module, the second output of the receiving coil of the electromagnet is connected with grounding of the general circuit, while the third input-output of the transceiver module is connected to the first input-output of the control module, the second input-output of which is connected to the first input-in the course of the Bluetooth wireless module, the second input-output of which is connected to the first input-output of the antenna, while the first output of the battery is connected to the fourth input of the transceiver module, the third input of the control module and the third input of the Bluetooth wireless module, the second input of the said battery is connected with the first output of the battery charge module and charge-discharge control.

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