RU2790279C1 - Radio frequency identification (rfid) tag with arbitrary reading angle - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: invention relates to the field of radio engineering, and more specifically to radio frequency identification systems. Radio frequency identification (RFID) tag with an arbitrary reading angle, including a single-port chip and a two-port antenna connected to it, the antenna being two orthogonally crossed strip radiators located on a dielectric substrate. The tag path between the antenna and the chip port includes matching circuits, a phase shifter and an addition device, while the matching circuits are connected to the antenna, the phase shifter is connected to the matching circuits, the addition device is connected to the phase shifter and the chip in such a way that a turnstile antenna is formed.

EFFECT: forming at least one turnstile antenna capable of receiving and emitting electromagnetic waves of polarization close to circular.

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Description

The invention relates to the field of radio engineering, and more specifically to systems of radio frequency identification (hereinafter referred to as RFID) and can be used as RFID tags in the ultra-high frequency range (hereinafter referred to as UHF).

Structurally, an RFID tag is a chip, to the port (ports) of which an antenna (antennas) is connected. The entire system is located on a dielectric substrate.

A well-known problem in the development of UHF RFID tags is the fact that the antennas of many tags have non-uniform radiation patterns (RPs), and often have minima (zeros). Therefore, situations are not ruled out when the object is located in such a way that the label placed on it will be directed by the minimum of the RP in relation to the antenna of the reader-interrogator (hereinafter referred to as the USO), and information from it will not be read.

The closest in technical essence to the claimed solution (prototype) is a solution for a two-port chip and a label type tag based on it, described in US patent US9142881B1, developed by Impinj, Inc. (USA), as well as a solution of Mikron JSC (RF) similar in its technical essence, commercially produced with the commercial name M3D.S. The solution is a printed turnstile based on four F-shaped radiators, also known as PIFA (planar inverted F-antenna), combined into diagonal pairs for operation in a symmetrical path and having two symmetrical RF ports connected to the corresponding ports of a Monza 4 chip manufactured by Impinj. The solution provides for each port a quasi-isotropic RP with two zeros, a kind of classical RP of linear polarization, characteristic of an electrically short vibrator. The DN of the two emitters of the tag are turned at an angle of 90° and are mutually orthogonal, and the antenna ports are mutually decoupled in the operating frequency range. The chip provides independent detection for each of the ports and subsequent addition of signals. Thus, the so-called. The "final RP" of the label, measured by the circular polarization of the USO, is formed by the scalar addition of the two described RPs and therefore does not contain explicit zeros. One of the disadvantages of the solution should include a significantly reduced energy at the edges of the operating frequency range, which, however, is not mentioned in the text of the patent, and the RP shown by the authors corresponds to the RP of the mark in the middle of the frequency range, and which, under conditions of closely spaced metal objects, can lead to the formation zeros in the direction of the USO antennas and a decrease in the energy of the channels, respectively. The second drawback is the fundamental need for the chip to have two ports.

A solution for a two-port chip and a label-type tag based on it is known, described in US patent US9087281B2, developed by Impinj, Inc. (USA), as well as a solution of Mikron JSC, similar in its technical essence, commercially available with the commercial name M3D with a Monza 4 chip manufactured by Impinj, which differs from the one described above in that slightly different tuning frequencies of the orthogonal antenna elements are used, which makes it possible to improve the range properties of the label, however, due to this, the energy in the considered polarization basis of the USO decreases over the entire operating frequency range, especially at its edges. To implement such a solution, as in the previous case, a chip with two ports is needed.

A label type label solution is known as described in US patent application US20150076238A1 developed by SMARTRACIPB.V. (Netherlands) and serially produced with the commercial name FROG-3D with a Monza 4 chip manufactured by Impinj. The solution uses a similar turnstile based on F-shaped radiators as an antenna, which, however, use a circular polarization basis for each port and technically differ in some way from the above solutions in terms of power supply. The use of a Monza 4 type chip in the solution makes it possible to receive and transmit USO signals on the left circular polarization (hereinafter - LCP) and right circular polarization (hereinafter - RCP) in free space conditions. To implement such a solution, like all those described above, you need a chip with two ports.

A solution for a chip with lock loops of complex input resistance and a tag based on it is known, described in US patent USRE47755E, proposed by Impinj, Inc. (USA). The solution involves the cascade inclusion of a symmetrical quadripole with an electrically variable value of the complex resistance of the adaptive tuning circuit into the tag path between the chip port and its input circuits, which allows, by estimating the matching level, to automatically adjust the complex resistance of the chip port, brought to the input of such a circuit, within certain limits as described in solving the algorithm. This allows you to adaptively change the energy label depending on the conditions of its use. The disadvantage of the solution is the impossibility of taking into account the phenomenon of multipath propagation, in particular, when the decrease in the energy of the channel is not due to the mismatch of the paths of the antenna and the chip.

The task to be solved by the claimed invention is to develop a tag with an antenna polarization close to circular and as uniform as possible to ensure the possibility of reliable data exchange between the tag and the USO at an arbitrary angular arrangement of them relative to each other. In this case, the tag can include both two- and one-port chips.

The technical result consists in the formation of at least one turnstile antenna capable of receiving and emitting electromagnetic waves of polarization close to circular, the RP of which, as is known, does not have obvious zeros. The specified technical result is achieved by including matching circuits, a phase shifter and an adder in the tag path between the antenna and the input circuits of existing chip solutions, in particular, a Monza 4 type chip. Such a scheme has a gain in energy compared to the prototype.

For a better understanding of the essence of the claimed invention, further explanations are given with the involvement of graphic materials.

In FIG. Figure 1 shows a block diagram of the tag, including antenna 1 with two ports, which we will call item 1 and item 2, matching circuits 2, phase shifter 3, non-decoupled equal-amplitude in-phase adder (hereinafter - adder) 4 and chip 5. Antenna 1 is a turnstile and receives the interrogation signal from the USO and emits the response signal of the tag, forming a quasi-isotropic DN. Matching circuits 2, connected to the ports of antenna 1 on one side and to phase shifter 3 and adder 4 on the other, provide an energetically optimal pairing of antenna path 1 with paths of phase shifter 3, adder 4 and chip 5. Phase shifter 3 connected between matching circuits 3 and adder 4 in any of the two channels (a channel means the signal path from item 1 or item 2 of antenna 1) ensures the phase rotation of the RF signal in its circuit by minus 90°, and the adder 4 adds the channels, forming the most consistent antenna power supply. Chip 5 provides for the receipt of the polling and the formation of the response signals of the tag in accordance with the information recorded in its non-volatile memory.

In FIG. 2a and 2b show an example of the label topology from the side of the upper layer, and Fig. 3, a and 3, b - from the side of the lower layer of conductors. The antenna 1 of the tag consists of two orthogonally crossed and structurally combined, but electrically mutually decoupled strip radiators (shoulders are designated as 6 and 7), the terminals of the ports of which (power points) p. 1 and p. 2 are designated as 8 and 9, respectively. The matching circuit 2 and the phase shifter 3 are partly made on discrete elements (L and C), partly on long lines and circuitry represent a G-link in a symmetrical (differential) inclusion. The adder 4 is made according to a non-decoupled scheme and actually represents a combination of three branches in a symmetrical (differential) design, two of which correspond to the paths of the combined channels, and one is the resultant one and is connected to the corresponding terminal of the chip port 5. The upper and lower layers of the tag are connected through the corresponding interlayer transitions 10.

The technical solution of the tag described above assumes the use of a single-port chip, however, it is technically possible to use a two-port chip using only one port, while the second port of the chip is not used.

A variant of the technical solution is the implementation of two turnstile antennas operating on different ports of a two-port chip. This solution makes it possible to provide energy in a general sense better than the previous one, however, it requires the use of a fundamentally two-port chip and has a somewhat larger geometric area of the label.

In FIG. 4 shows a block diagram of the tag, including two similar antennas 1 (denoted as 1.1 and 1.2), two matching circuits 2 (denoted as 2.1 and 2.2), two phase shifters 3 (denoted as 3.1 and 3.2), two adders 4 (denoted as 4.1 and 4.2) and a two-port chip 5. The scheme involves the construction of two separate functionally identical to the above-described solution paths for the formation of pattern, connected to separate ports of item 1 and item 2 of chip 5.

In FIG. 5a and 5b show an example of the label topology from the side of the upper layer, and in Fig. 6, a and 6, b - from the side of the lower layer of conductors. The tag antenna 1 consists of two turnstile radiators 1.1 and 1.2, rotated relative to each other at an angle of 135° and structurally combined, but electrically operating individually, each of which is made similar to the above-described technical solution shown in Fig. 2 and FIG. 3. The arms of the strip emitters from the turnstile 1.1 are designated as 6.1 and 7.1. The arms of the emitters from the turnstile 1.2 are designated as 6.2 and 7.2. Conditional terminals of emitter ports (power points) p.1 and p.2 are designated as 8.1, 9.1 and 8.2, 9.2 respectively. Matching circuits 2.1, 2.2, phase shifters 3.1, 3.2 and adders 4.1 and 4.2 are made in the same way as the technical solution described above. Elements 2.1, 3.1, 4.1 are placed on the top layer of the label, elements 3.2, 4.2 and 5 are on the bottom, and element 2.2 is on the top and bottom layers. The layers are connected through the corresponding interlayer transitions 10.

The first version of the device works as follows. The components of the electromagnetic field of the interrogation signal radiated into space by the USO antenna are received by strip radiators 6 and 7 of antenna 1 and are fed to matching circuits 2, which pair the impedance of antenna 1 with the impedance of phase shifter 3, adder 4 and chip 5. After this, the component corresponding to the conditional phase delay 0° enters the phase shifter 3, where a phase delay of 90° is carried out, and then to the port of an uncoupled equal-amplitude and in-phase adder 4, and the second component, corresponding to a conditional phase delay of 90°, enters the other port of the adder 4 without additional phase delay. Thus, both components entering adder 4 are added, after which the sum signal is fed to chip port 5. In this case, the quadrature components received by antenna 1 are aligned in phase and added in phase and equal amplitude by the adder, while components other than quadrature, add in the general case out of phase, forming a quasi-isotropic RP in the general case with a polarization that differs significantly from circular. In the case of using a two-port chip 5, the second port does not receive a signal. The tag response signal generated by chip 5 is converted in the reverse order, after which the formed quadrature components are emitted into space.

The second version of the device works as follows. Conventionally, the first pair of components of the electromagnetic field of the interrogation signal radiated into space by the USO antenna is received by strip radiators 6.1 and 7.1 from the turnstile 1.1, after which its components are processed similarly to the above option and arrive at port 1 of the chip 5. At the same time, conditionally the second pair of components fields rotated relative to the components of the first pair by 135° (which corresponds to the rotation of a pair of emitters by the same angle), is received by emitters 6.2 and 7.2, after which its components are processed similarly to the above option and arrive at port 2 of chip 5. In this case, the provisions regarding reception quadrature and non-quadrature components emitters 6.1 and 7.1, as well as 6.2 and 7.2 correspond to the above technical solution, incl. regarding the formation of a quasi-isotropic MD in the general case with polarization significantly different from circular. Thus, taking into account the relatively small correlation of signals at ports 1 and 2 of chip 5, due to the provision of a sufficient level of decoupling between turnstiles 1.1 and 1.2, there is an additional gain in the energy of the tag in the range from zero (which is observed when processing purely quadrature components and corresponds to RP with circular polarization of radiation) up to 2…2.5 dB (which is observed for correlated components and corresponds to RP with polarization close to linear) relative to the first option. The tag response signal generated by chip 5 on both ports is converted in the reverse order, after which the generated components are emitted into space.

The presented description is given for the purpose of illustrating the claimed invention, while the topologies in the figures are shown and described conditionally, and it should be clear to the specialist that various modifications and changes are possible, taking into account the preservation of the number and types of structural units and the circuitry of their operation (principle of operation).

Claims (6)

1. Radio frequency identification (RFID) tag with an arbitrary reading angle, including a single-port chip and a two-port antenna connected to it, while the antenna is two orthogonally crossed strip radiators located on a dielectric substrate, characterized in that in the tag path between the antenna and the port The chip includes matching circuits, a phase shifter and an addition device, while the matching circuits are connected to the antenna, the phase shifter is connected to the matching circuits, the addition device is connected to the phase shifter and the chip in such a way that a turnstile antenna is formed. 2. The device according to claim 1, characterized in that the matching circuits, the phase shifter and the addition device are made on an integrated circuit. 3. Radio frequency identification (RFID) tag with an arbitrary reading angle, including a two-port chip and a two-port antenna connected to it, while the antenna is two orthogonally crossed strip radiators located on a dielectric substrate, characterized in that in the tag path between the antenna and the first the chip port includes matching circuits, a phase shifter and an adder, while the matching circuits are connected to the antenna, the phase shifter is connected to the matching circuits, the adder is connected to the phase shifter and the chip in such a way that a turnstile antenna is formed, and the second port of the chip is not used. 4. The device according to claim 3, characterized in that the matching circuits, the phase shifter and the addition device are made on an integrated circuit. 5. Radio frequency identification (RFID) tag with an arbitrary reading angle, including a two-port chip and an antenna connected to it, which is two orthogonally crossed strip radiators located on a dielectric substrate, characterized in that the tag path between the antenna and the first port of the chip includes matching circuits, a phase shifter and an adder, wherein the matching circuits are connected to the antenna, the phase shifter is connected to the matching circuits, the adder is connected to the phase shifter and the chip in such a way that a turnstile antenna is formed, and an additional analogous antenna, matching circuits, a phase shifter and adding device in such a way that another turnstile antenna is formed. 6. The device according to claim 5, characterized in that the matching circuits, the phase shifter and the addition device are made on an integrated circuit.

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