KR20080040914A - Rfid system - Google Patents

Abstract

An RFID(Radio Frequency IDentification) system is provided to recognize a tag by installing microwave reflecting material at the specified position, even when the electric power is weakened or the straight waves are blocked by interference of reflecting waves. An RFID system comprises a reader(300), a reader antenna(302), a tag(304) and a microwave reflecting material(306). The reader antenna and a tag antenna use a UHF(Ultra High Frequency) band of 900MHz. The reader modulates an RF(Radio Frequency) signal having the specified carrier frequency for transmitting interrogation signals to the tag, and emits the signals through the reader antenna. The reader antenna emits microwaves to recognize the tag in a uniform range. The RFID tag is able to be attached on articles for recognition. The tag receives the microwaves emitted from the reader antenna. The microwave reflecting material reflects the microwaves emitted from the reader antenna to transmit intentional reflecting waves to the tag, and amplifies the receiving power of the tag to be recognized by the reader antenna if the articles exist at the specified section where the reader can not recognize the tag or the reader can not recognize the tag due to a barrier.

Description

RFID system {RFID system}

1 is a diagram schematically showing an RFID system of a conventional UHF band.

Figure 2 is a graph showing the experimental results of the intensity of the received power of the tag according to the distance between the existing reader antenna and the tag.

3 is a view schematically showing an embodiment of an RFID system provided with the electromagnetic wave reflecting material of the present invention.

Figure 4 is a graph showing the experimental results for one embodiment of the present invention.

Figure 5 is a graph showing the experimental results for another embodiment of the present invention.

Figure 6 schematically shows another embodiment of the RFID system provided with the electromagnetic wave reflector of the present invention.

The present invention relates to an RFID system which can extend a recognition period of a tag by using an electromagnetic wave reflector.

RFID (Radio Frequency IDentification) is a technology that provides a foundation for recognizing, tracking, and controlling objects by recognizing tags attached to remote objects using radio frequency. Unlike conventional barcodes, the laser reader had to be in direct contact with the barcode or scanned in the visible band.However, the RFID method attaches and processes a small chip and an antenna, which are mediated by radio waves to objects. It is a non-contact automatic identification technology that can be recognized at all times regardless of the packaging status, material of the target surface or environmental changes. In addition, much more information can be exchanged compared to bar codes, recognition distance is also very long (1.5 ~ 27m), and it is possible to penetrate obstacles except metal.

Due to these many advantages, RFID has recently been spotlighted as the next generation technology that succeeds the barcode in the industry, and its application field is applicable to various fields such as logistics, distribution, transportation, security, and access control as well as information communication.

The RFID system basically consists of a tag, a reader, a reader antenna, and a data processing system capable of processing data read from the tag.

The tag consists of memory that stores data, IC circuit, microprocessor and antenna, and is classified into passive type and active type. This is classified by the presence of an internal energy source. The passive tag data transmission method uses a backscatter modulation method. In this case, the backscattered modulation is generated by the tag after receiving the radio wave transmitted from the reader, and generates the power to be activated by the tag, and modulates the magnitude or phase of the scattered radio wave when the scattered wave is transmitted to the reader. It is a way to send me information.

When the tagged object is placed in the reader's recognition area, the reader modulates an interrogation signal having a specific carrier frequency to the tag, and the tag responds to the question. That is, the reader modulates a continuous electromagnetic wave having a specific frequency to transmit a question signal to the tag, and the tag receives the electromagnetic wave transmitted from the reader, and then transmits the information stored in the internal memory of the tag chip to the reader. Back-Scattering Modulation is sent back to the reader.

The frequency of UHF band RFID is 860 ~ 960MHz, but the frequency selection method such as frequency and frequency hopping of each country is delegated to comply with the laws and regulations of each country. The Republic of Korea decided the band of 908.5 ~ 914MHz as the allowed RFID frequency.

Looking at the RFID-related radio wave method in Korea, the radio wave power of the RFID reader should be less than 1W, the effective isotropic radiated power (EIRP) should be less than 4W, the antenna gain should not exceed 6dBi. In addition, the frequency hopping range is 908.5 to 914 MHz, and the frequency band width per channel is 200 kHz. Therefore, when the reader calculates the distance that the reader can generally recognize the tag (minimum power of a typical RFID passive tag is 100 uW), it is about 8 m. do.

However, the recognition range of the tag inferred as described above is for an ideal environment in which electromagnetic waves are not reflected, and in reality, an environment in which an RFID system is used may include reflected waves due to the ground. Therefore, there is a problem that the power supplied to the tag may be weakened due to the interference between the reflected wave and the straight wave.

1 schematically shows an RFID system of a conventional UHF band.

Referring to FIG. 1, the RFID system of the UHF band includes a reader 100 of the UHF band, a reader antenna 102 of the UHF band, and a tag 104 of the UHF band.

When the linear wave of the electromagnetic wave (LOS: 112) transmitted by the reader antenna 102 and the reflected wave 114 by the ground and the like reach the tag 104 simultaneously, the reflected wave 114 is an electromagnetic wave. Due to the periodic characteristics of the interference with the straight wave 112, this may cause a section in which the reader 100 does not recognize the tag 104.

The reason that the reader 100 does not recognize the tag 104 is generated because the power supplied to the tag by the reader is canceled due to the interference of the reflected wave by the ground so that the tag does not receive sufficient power to operate. Because.

The problem of the above phenomenon, that is, where the section in which the reader does not recognize the tag occurs may be determined according to the height of the reader antenna and the tag and the distance between the reader antenna and the tag.

FIG. 2 shows the distance R _g 110 between the reader antenna and the tag when the height H _a 106 of the reader antenna 102 is 1.4 m and the height H _t 108 where the tag 104 is located is 1 m. This graph shows the results of experiments on the strength of the received power of tags. The test result may vary depending on the height of the reader antenna or the tag.

Referring to FIG. 2, when the minimum power for operating the tag 104 is 100 uW, the receiving power of the tag in the interval 200 between the reader antenna 102 and the tag 104 is 2.5 to 2.8 m. It can be seen that the strength of is weak, and this is the section where the reader does not recognize the tag. In addition, the maximum distance that can be recognized by the reader antenna is about 4.8m, and the reflected wave and the straight wave resonate in the range of 6 to 8.8m corresponding to the long range, but the signal starts to increase. There is a problem that the reader does not recognize because it does not reach the minimum power to operate.

In addition, even when an obstacle exists between the reader antenna and the tag, a straight wave may be blocked, which may cause a problem in that the tag cannot be recognized.

Accordingly, an object of the present invention is to solve the problem that a specific section that did not recognize the tag due to the interference of the straight wave and the reflected wave or a long distance, obstacle, etc. occurs by utilizing the frequency characteristics of the UHF band. The present invention provides an RFID system capable of recognizing a tag by installing an electromagnetic wave reflector at a location specified by the present invention.

The present invention for achieving the above object is a tag of the UHF band that is attached to a predetermined recognition object, and stores identification information and data information of the recognition object, a reader antenna for transmitting and receiving electromagnetic waves, and a question having a specific frequency. A UHF band reader that receives a signal modulated and transmitted to the tag, and the tag modulates backscatter modulation, and an artificial reflected wave through the electromagnetic wave reflector received by the tag satisfy the Snell's law, It is characterized in that it comprises an electromagnetic wave reflector which is provided at a position capable of amplifying the received power of the tag by the phase.

On the other hand, the electromagnetic wave reflector is characterized in that the electromagnetic wave reflectance is made of Ag, Al, Ni, Au or a combination thereof.

Hereinafter, the objects, features and advantages of the present invention will be described in detail with reference to FIGS. 3 to 6.

FIG. 3 schematically shows an RFID system in which an electromagnetic wave reflector 306 is installed at an effective position to prevent a section in which the reader antenna 302 does not recognize the tag 304 as an embodiment of the present invention. will be. An RFID system according to a preferred embodiment of the present invention includes a reader 300, a reader antenna 302, a tag 304, and an electromagnetic wave reflector 306. And the reader antenna and tag antenna constituting the present invention uses the UHF frequency band of 900MHz.

The reader 300 modulates an RF signal having a specific carrier frequency to send an interrogation signal to the tag, and emits the RF signal through the reader antenna 302. It also plays a role of receiving identification information, data information, etc. transmitted by the tag.

The reader antenna 302 emits electromagnetic waves to recognize the tag 304 within a predetermined range. The emitted electromagnetic wave is transmitted to the tag 304 within the recognition range.

The RFID tag 304 may be attached to an object to be recognized in various forms, and its position may be moved. When the tag 304 is located within a recognition range of electromagnetic waves emitted from the reader antenna 302, the tag 304 receives electromagnetic waves emitted from the reader antenna 302.

The electromagnetic wave reflector 306 may detect the tag 304 due to an obstacle or the like when an object to be attached with the tag 304 exists in a specific section in which the reader 300 cannot recognize the tag 304. If it is not recognized, the reader antenna 302 recognizes the tag 304 by reflecting electromagnetic waves emitted from the reader antenna 302 so that the tag 304 receives an artificial reflected wave and amplifies the received power of the tag. To do it.

Referring to FIG. 3, the height from the ground of the reader antenna 302 is H _a 308, the height of the tag 304 is H _t 310, the position of the reader antenna 302 in the ground and the tag 304. If the distance between positions is R _g 326, the linear distance R _d 314 between the reader antenna 302 and the tag 304 by the straight wave 312 may be represented by the following equation.

Similarly, the linear distance R _r 318 of the reflected wave 316 reflected from the ground to the tag can be expressed by the following equation.

Here, D _a 322 refers to the distance from the reader antenna 302 to the ground, D _t 324 refers to the distance from the ground to the tag 304 among the linear distances of the reflected wave path, and G _a 328 refers to the reader. The distance in the ground from the antenna to the point where the reflected wave is reflected, G _t 330, is the distance in the ground from the point where the reflected wave is reflected to the tag.

The G _a and G _t may vary according to the height of the reader antenna, the height of the tag, and the distance between the reader antenna and the tag, and according to Snell's Law, electromagnetic waves incident on the ground are reflected at the same angle. G _a and G _t can be represented by the following equation.

Meanwhile, the total received voltage induced by the electromagnetic wave received by the tag 304 is generated by the received voltage by the straight wave 312 from the reader antenna 302 to the tag and the reflected wave 316 reflected on the ground. It can be expressed as the sum of received voltages. In addition, assuming that there are n reflected waves, including reflected waves caused by the ground, the total received voltage induced in the tag may be represented by the following equation.

Here, V _d is the voltage induced by the straight wave, V _r is the voltage induced by the reflected wave reflected on the ground, R _d is the straight line distance of the straight wave path, R _rn is the straight line distance of the reflected wave path Say. c is the luminous flux (3 × 10 ⁸ m / s), k ₀ is the propagation constant of free space, and Γ _n is the reflection coefficient.

If Equation 4 is converted into a general equation for power input to a tag, it may be represented by Equation 5.

Here, P _r is the total power reaching the tag, P _t is the power value transmitted from the reader antenna, R _d is the distance of the straight wave between the reader antenna and the tag, and R _rn is the linear distance of the reflected wave. λ is the wavelength of the electromagnetic wave transmitted from the reader antenna, G _r1 is the gain of the reader antenna at the straight angle between the reader antenna and the tag, G _t1 is the gain of the tag antenna at the straight angle between the reader antenna and the tag, and G _r2 Is the reader antenna gain at the reflected angle between the reader antenna and the tag, and G _t2 is the tag antenna gain at the reflected angle between the reader antenna and the tag. K ₀ is a free space propagation constant (2π / λ) and Γ _n is a reflection coefficient.

Equation 5 above represents power delivered to the tag according to the distance between the reader antenna 302 and the tag 304, but the optimum electromagnetic wave reflector 306 for a section in which the tag cannot be recognized using this equation. ) The installation location can be obtained.

For example, when the reader antenna 302 is installed at a height of 1 m and the tag 304 is located at a height of 1 m, the electromagnetic wave received by the tag is only the reflected wave 316 by the ground besides the straight wave 312. If it is present, the power received in the tag can be represented by the following equation using Equation 5 above.

Here, Γ ₁ is the reflection coefficient of the reflected wave by the ground, and R _r1 means the linear distance of the reflected wave path by the ground.

Referring to FIG. 2, it can be seen from the experimental result that a section having a minimum power of 100 uW, which is the minimum power that the tag 304 can operate, occurs between 200 and 2.5 m to 2.8 m.

The section in which the received power of the tag is 100 uW or less, that is, the section in which the tag cannot be recognized is generated due to interference by the reflected wave 316 reflected on the ground, and is related to the right item of Equation 6.

Accordingly, when the received power of the tag 304 is measured, the reflection point of the reflected wave 316 by the ground can be determined through Snell's law and the above Equations 1 to 3 and 6 above.

The effective installation position of the electromagnetic wave reflector can be found in the same manner as that of the reflection point of the reflected wave 316 by the ground.

According to the present invention, another reflected wave is artificially added by using the electromagnetic wave reflector 306 to suppress the power supplied to the tag from being canceled due to the interference of the straight wave 312 and the reflected wave 316 by the ground. can do.

Referring to FIG. 3, it can be seen that the reflection wave 320 is artificially added by installing the electromagnetic wave reflector 306 in a specific section between the reader antenna 302 and the tag 304. The power received by the tag 302 in consideration of the influence of) may be represented by Equation 5 as the following equation.

Here, G _r3 and G _t3 are gains of the reader antenna and the tag antenna at the angle reflected by the electromagnetic wave reflector, respectively, and R _r2 denotes the linear distance of the path of the reflected wave 320 added through the electromagnetic wave reflector 306.

The electromagnetic wave reflector 306 according to the present invention should be installed in accordance with Snell's law at a position such that the received power of the tag is 100 uW or more in a section in which the reader antenna 302 does not recognize the tag 304.

On the other hand, the power received by the tag by the reflected wave 320 added by the electromagnetic wave reflector 306 may be amplified or attenuated due to the nature of the electromagnetic wave, which is the reader antenna 302 from the electromagnetic wave reflector 306 ) And H _r 332, which is the distance orthogonal to the straight path between the tag 304. This is because when the distance H _r 332 is changed, the received power of the tag 304 is amplified due to the phase difference between the straight wave 312 and the reflected wave 316 by the ground because the path of the additional reflected wave 320 is changed. It can be or attenuate.

Therefore, the installation of the electromagnetic wave reflector 306 using Snell's law and the above Equations 1 to 3 and 7 by measuring the received power of the tag 304 in the environment in which the electromagnetic wave reflector 306 is installed. Locate the location of the electromagnetic wave reflector so that the received power of the tag is amplified to be greater than 100 uW by adjusting Hr 332, which is a distance orthogonal to the straight path between the reader antenna 302 and the tag 304. You can get it.

FIG. 4 shows that the RFID reflector 306 has a distance of 1 m to 2 m from the reader antenna when the reader antenna 302 and the tag 304 are located at a height of 1 m, respectively. It is a graph showing the experimental result of measuring the intensity of the received power of the tag according to the distance between the reader antenna and the tag installed at a point where the distance Hr 332 perpendicular to the straight path and the electromagnetic wave reflector becomes 1 m.

Compared with the graph of FIG. 2, it can be confirmed that the minimum receiving power for operating the tag is measured at 100 uW or more in the 2.5 to 2.8 m section 400 where the reader antenna could not recognize the tag.

On the other hand, when the reader antenna and the tag are located at the same height, the position of the electromagnetic wave reflector may be characterized in that the distance orthogonal to the straight path between the reader antenna and the tag is the same as the height of the reader antenna and the tag. .

For the example install the reader antenna and the tag electromagnetic wave reflecting material, where the distance H _r (332) is 1m perpendicular to the straight path between the reader antenna and the tag if present, each located at 1m height of the tags in a particular section Receive power can be increased.

The position of the electromagnetic wave reflector 306 according to the present invention may be changed depending on the height of the reader antenna 302 and the tag 304, and the like.

5 is a result of measuring the received power of a tag according to another embodiment of the present invention RFID system, the reader antenna 302 and the tag 304 are each located at a height of 1m, the electromagnetic wave reflector 306 When the distance Hr 332 where the straight path between the tag and the reader antenna and the electromagnetic wave reflector are orthogonal to each other at a distance of 3.75 m to 5 m from the reader antenna is installed at a position of 0.4 m, This graph shows the experimental results of measuring the received power.

Referring to FIG. 5, by installing the electromagnetic wave reflector 306, a tag at a far distance, which is a section that the reader antenna 302 could not recognize when the electromagnetic wave reflector is not installed, may be recognized. Compared with the graph of FIG. 2, when the electromagnetic wave reflector is not installed, the minimum reception power for operating the tag in the range of 7.5m to 9.5m 500, which is less than the operating power of the tag, is measured. You can check it.

6 is a view showing another embodiment of the present invention RFID system.

Referring to FIG. 6, even though an obstacle 608 is present between the reader antenna 602 and the tag 604 and the straight wave 610 and the reflected wave 612 by the ground are blocked, the reflected wave using the electromagnetic wave reflector 606 is used. Tag 604 may be recognized by 614.

In each of the above-described embodiments, only one electromagnetic wave reflector is used, but a plurality of electromagnetic wave reflectors may be installed on the opposite side, the ground, and the ceiling to increase efficiency.

Although the present invention has been described in detail with reference to exemplary embodiments above, those skilled in the art to which the present invention pertains can make various modifications to the above-described embodiments without departing from the scope of the present invention. I will understand. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

As described above, according to the RFID system of the UHF band using the electromagnetic wave reflecting material to extend the recognition period of the RFID tag of the present invention, the received power of the tag due to the interference of the reflected wave by the straight wave and the ground transmitted from the reader antenna to the tag In the case where the straight wave is blocked due to the weakening or obstacle, the tag can be recognized by installing the electromagnetic wave reflector at a specific position.

Claims (5)

A tag of a UHF band attached to a predetermined recognition object and storing identification information and data information of the recognition object; A reader in a UHF band that modulates a question signal having a specific frequency for transmission to the tag, and recognizes and processes a signal carried by the tag by backscattering modulation; A reader antenna which transmits a question signal modulated by the reader, receives a signal carried by the tag, and sends the signal to the reader; And an electromagnetic wave reflector installed at a position capable of generating reflected waves to amplify the received power of the tag. The method of claim 1, wherein the position of the electromagnetic wave reflector; While satisfying the following Equations 1 and 2, the distance H _r at which the electromagnetic wave reflector is orthogonal to the straight path between the reader antenna and the tag is equal to or higher than the minimum operating power of the tag because the reflected wave and the straight wave are in phase. RFID system, characterized in that installed in the position to be measured. Equation  One

Where P _r is the total power reaching the tag, P _t is the power transmitted by the reader antenna, R _d is the distance between the reader antenna and the tag, R _r1 is the linear distance of the reflected wave path by the ground, R _r2 Is the linear distance of the reflected wave path added through the electromagnetic wave reflector, λ is the wavelength of the electromagnetic wave transmitted from the reader antenna, G _r1 , G _t1 is the gain of the reader antenna and tag antenna at the straight angle between the reader antenna and the tag, G _r2 and G _t2 are the gains of the reader and tag antennas at the angle reflected by the ground, respectively, G _r3 and G _t3 are the gains of the reader and tag antennas at the angle reflected by the electromagnetic wave reflector, respectively, and K ₀ is The propagation constant (2π / λ) of free space, and Γ ₁ and Γ ₂ are reflection coefficients by the ground and the electromagnetic wave reflector, respectively. Equation  2

Here, R _r2 is the linear distance of the reflected wave path added through the electromagnetic wave reflector, R _a is the distance from the reader antenna to the electromagnetic wave reflector, R _t is the distance from the electromagnetic wave reflector to the tag, R _g is transmitted from the reader antenna Is the distance of the straight path received by the tag, G _a is the distance on the straight path of the reader antenna and the tag from the reader antenna to the point reflected by the electromagnetic wave reflector, and G _t is the reader antenna and tag from the electromagnetic wave reflector to the tag. Is the distance on the straight wave path of and H _r is the distance orthogonal to the straight path between the reader antenna and the tag. The method of claim 1, wherein the position of the electromagnetic wave reflector; And the reflected wave reflected by the electromagnetic wave reflector is installed at two or more positions capable of amplifying the received power of the tag by satisfying Snell's law while being in phase with the straight wave. The method of claim 1, wherein the position of the electromagnetic wave reflector; And the reader antenna and the tag are installed at the same height, and the distance orthogonal to the straight path between the reader antenna and the tag of the electromagnetic wave reflector is equal to the height of the reader antenna and the tag. The method of claim 1, wherein the electromagnetic wave reflector; RFID system, characterized in that consisting of Fe, Ag, Al, Ni, Au or alloys thereof.

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