KR20070056815A - Rfid system - Google Patents

Abstract

An RFID system is provided to remarkably improve communication between a reader and a tag by performing the communication in synchronization with a hopped frequency of the reader among available hopped channels of all frequency bands in a predetermined time through an RFID protocol. A receiver(110) receives an RF signal from the reader. A signal processor(130) transmits the received RF signal to a transmitter(150) by synchronizing with a communication frequency channel of the received RF signal, and includes frequency generators(131a-131n), phase fixing loops(132a-132n), switches(133a-133n), and the first and second mixer(134a,134n). A controller(135) generates a frequency selection signal for selecting the frequency channel coherent to the hopped frequency of the reader by receiving an output signal of the first and second mixer, and transmits the frequency selection signal to the tag. The transmitter transmits the output signal of the first controller to the tag through the frequency channel used in the switches.

Description

Radio Frequency Recognition System {RFID SYSTEM}

1 is a block diagram showing the basic configuration of an RFID system according to the prior art.

2 is a block diagram showing the operation of the RFID system according to the prior art.

3 is a view showing the configuration of an embodiment according to the present invention.

4 is a view showing in detail the configuration of the high frequency radiation device shown in FIG.

5 is a view showing the configuration of another embodiment according to the present invention.

6 is a view showing in detail the configuration of the intelligent high frequency radiation device shown in FIG.

<Description of Symbols for Main Parts of Drawings>

10: reader 50: tag

70: high frequency radiation device 70a: intelligent high frequency radiation device

157, 216, 221, 242, and 264: first to fourth bandpass filters

131a-131n, 251a-251n: Frequency Generator

132a-132n, 252a-252n: phase locked loop

Mixer: 134a, 134n, 151a, 151n, 212a, 212n, 224a, 224n, 254a, 254n, 261a, 261n

135, 230 control unit 133a-133n, 253a-253n switch

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio frequency identification (RFID) system, and to a radio frequency identification system capable of performing communication between a reader and a tag in synchronization with a hopping frequency of a reader.

In general, Radio Frequency IDentification (RFID) inputs identification information unique to the smallest IC chip and uses RF to recognize, track, and manage the object or animal to which the chip is attached. Says technology. Such an RFID system is composed of an RFID tag (Tag or Transponder) to which unique identification information is input and attached to an object or animal, and a reader (Reader or Interrogator) to read or write the identification information of the tag without contact. An information processing apparatus such as a computer is connected to the reader to process data collected from a tag.

1 is a block diagram showing the basic configuration of an RFID system according to the prior art. As shown, the tag 5 is a passive tag which does not have a power supply by itself, and is composed of a small semiconductor IC chip and an antenna, in which an RF circuit, logic, and memory are embedded. These tags 5 have various sizes and shapes. The reader 1 includes a transmitter for transmitting an RF signal of a specific frequency band to the tag 5, a receiver for receiving a signal transmitted from the tag 5, and an antenna for transmitting and receiving the signal.

And, Figure 2 is a block diagram showing the basic operation of the RFID system according to the prior art. As shown, the reader 1 transmits an RF signal of a predetermined frequency band including a high frequency carrier signal and a predetermined question signal. When the tag 5 is located in the electromagnetic field of the reader 1 formed by the RF signal, the tag 5 receives the operating power required to operate the IC chip from the high frequency carrier signal of the reader 1. That is, the high frequency carrier signal transmitted from the reader 1 generates alternating current in the antenna of the tag, and the generated alternating current is rectified and used as electrical energy for the IC chip. In addition, the tag 5 modulates the received RF signal and reflects the data stored in the tag 5 based on the received RF signal, and transmits the response signal to the reader 1 as a response signal.

As described above, the conventional RFID system performs information transmission between the reader 1 and the tag 5 as well as power transmission for activating a passive tag.

That is, since the reader needs to supply the energy necessary to operate the tag, the transmission power of the reader must be greatly increased in order to secure sufficient recognition distance and achieve high functionality. As the transmission power of the reader increases, interference between adjacent readers is increased. There was a problem happening. Various techniques have been attempted to solve this problem, and one of them is a technique for radiating a high frequency to a tag 5, which is a high output power transmission that is activated by the reader 1 and does not have information related to communication. The RF shower system 7 technology is disclosed in detail in Korean Patent Publication No. 05-32533.

In addition, Korean Patent Laid-Open Publication No. 05-271000 discloses in detail an intelligent high-frequency radiating device for transmitting information of a tag stored in advance to a reader according to a reader's request.

In addition, various technologies have already been disclosed, such as an arbiter that allows each reader to communicate a frequency of use frequency when the reader needs to execute anti-collision between multiple readers.

However, these various techniques have not been equipped with multiple phase locked loops to synchronize with the hopping frequency of the reader.

The present invention has been made to solve the problems of the RFID system according to the prior art, and a main object of the present invention is to synchronize the hopping frequency of a reader within a predetermined time in an RFID protocol among all frequency band channels of frequency hopping. By transmitting, it is to provide a radio frequency identification system that can significantly solve the communication between the reader and the tag.

In order to achieve the above object of the present invention, the radio frequency identification system according to the present invention,

In the radio frequency identification system that communicates between the reader and the tag,

A first receiver configured to receive an RF signal of the reader;

A first frequency generator including a plurality of frequency generators for generating frequencies in all frequency bands that can be communicated with each other to transmit the received RF signals to the transmitter in synchronization with a communication frequency channel of the RF signal of the first receiver; And a first phase locked loop portion having a plurality of phase locked loops and generating a predetermined frequency phase-locked with respect to the frequencies of the plurality of frequency generators, and a plurality of switches connected to an output side of each of the phase locked loops. And a switch for switching one of the plurality of switches to an ON state according to a frequency selection signal of the controller to pass an output signal of the phase locked loop through a hoped frequency of the reader and a coherent frequency channel. And a first signal mixing the output signal of the first receiver and the output signal of the switch switched to the on state. A signal processing unit including a mixer and a second mixer for mixing an output signal of a phase shifted switching unit and an output signal of the receiving unit;

A control unit for receiving an output signal of each of the first and second mixers, generating a frequency selection signal for selecting a hoped frequency and a coherent frequency channel of the reader, and transmitting an RF signal to a tag;

And a transmitter for transmitting an output signal of the first controller to a tag through a frequency channel used by the switching unit.

Here, the signal processor is connected between the transmitter and the receiver and is included in the radio frequency radiator which waits when the RF signal of the reader is received and emits high frequency which does not contain any information during continuous wave radiation.

The signal processing unit may include a mediation device capable of communicating the plurality of readers by allowing a communication use frequency when a plurality of readers requests them.

Preferably, the radio frequency identification system according to another aspect of the present invention,

A controller for generating and transmitting an RF signal to a tag, receiving and storing an RF signal of a tag in response to the RF signal, and transmitting an RF signal of the stored tag to the reader when requested by a reader;

A first transmitter for transmitting an RF signal generated by the controller to a tag;

A first receiving unit receiving the RF signal of the tag in response to the RF signal of the first transmitting unit through the tag monitoring antenna and transmitting the received RF signal to the second control unit;

A second receiver which receives a question signal of a reader received through a reader monitoring antenna;

In order to output an RF signal of a tag stored in the controller through a frequency channel synchronized with a frequency channel of an RF signal of the reader received through the second receiver, a frequency of all frequency bands including a plurality of frequency generators can be communicated. A phase generator for generating each, a phase locked loop having a plurality of phase locked loops for generating a predetermined frequency based on the frequencies of the plurality of frequency generators, and an output side of each phase locked loop. One of the plurality of switches is turned on according to the frequency selection signal of the controller, and is connected to the hopping frequency of the reader and the coherent frequency channel. A switching unit for passing an output signal, an output signal of the second receiving unit, and the switching unit A first mixer for supplying a demodulation signal generated by mixing output signals to the controller, and a demodulator signal for mixing the output signal of the switching unit whose phase is shifted with the output signal of the second receiver; A signal processor including two mixers,

And a second transmitter to transmit the RF signal of the tag stored in the controller to the reader through a frequency channel synchronized with a frequency channel of the RF signal of the reader through the signal processor.

Here, the signal processing unit, characterized in that it comprises in the intelligent high frequency radiation device for supplying a response signal of a tag stored in advance to the reader when the reader requests.

According to the present invention, a radio frequency identification system radiates an RF signal to a tag in synchronization with a hopping frequency of a reader within a predetermined time in an RFID protocol among all frequency band channels capable of frequency hopping of a reader, thereby minimizing interference of adjacent readers. By reducing this, communication between the reader and the tag can be significantly solved.

Example 1

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the radio frequency identification system according to the present invention.

First, Figure 3 is a block diagram showing an embodiment of an RFID system according to the present invention. As illustrated, the RFID system 100 of the present embodiment includes a plurality of readers 10 that transmit and receive RF signals, and RF of a specific frequency band f1 transmitted by the reader R1 among the readers 10. It includes a tag 50 for transmitting its own information by the Backscatterd Modulation method using a signal, and a channel of all frequency bands capable of frequency hopping of the reader R1 and within the predetermined time in the RFID protocol. And a high frequency generating device 70 which emits a high frequency wave containing no communication information to the tag 50 in synchronization with the hopping frequency of the reader R1.

The reader R1 and the tag 50 perform wireless communication using the RF signal f1 of a specific frequency band. The RF signal f1 may be a high frequency wave containing information such as a question signal and a response signal or a pure continuous high frequency wave containing no information.

The radio frequency radiator 70 emits an RF signal to the tag 50 through a frequency channel f1 synchronized with the hopping frequency f1 of the reader R1 and through a frequency channel synchronized with the hopping frequency. Wireless communication is made between the reader R1 and the tag 50.

That is, the high frequency radiation device 70 of the reader R1 through the coherent frequency channel f1 according to the hopping frequency f1 of the reader R1 among the plurality of channels f1-fn. Receives an RF signal and radiates to a plurality of tags 50 a high frequency wave that does not contain relevant information of any communication on the same channel as the received channel.

4 is a view showing in detail the configuration of the high frequency radiation device 70 shown in FIG. However, the illustrated configuration is only schematically presented to aid the understanding of the present invention, and these configurations are not only easily understood by those skilled in the art, but also easily added, deleted, and modified as necessary to some of the technical features of the present invention. Since it is possible to achieve the scope of the present invention is not limited to the illustrated example.

As shown in the drawing, the high frequency radiation device 70 includes all the frequency channels that can communicate with the receiver 110 for receiving an RF signal which is a question signal of the reader 10 received through the reader monitoring antenna ANT1. A signal processor 130 for synchronizing a communication frequency of the RF signal of the receiver 110 with a coherent frequency channel and supplying an output signal of the receiver 110 to a controller 135 to be described later; And a transmitter 150 for radiating an output signal of the signal processor 130 to the tag 50 through a frequency channel synchronized with the signal processor 130.

The receiver 110 removes noise components of a first band pass filter 111 through which the received RF signal of the predetermined frequency band of the reader 10 passes, and an output signal of the first band pass filter 111. The first low noise amplifier 113 and the first automatic gain control amplifier 115 for maintaining the output signal power level of the first low noise amplifier 113.

In addition, the signal processor 130 may include a plurality of frequency generators 131a to 131n and a frequency generator for generating frequencies of all frequency bands that can communicate with each other, and a plurality of phase locked loops 132a to 132n. A phase-locked loop part provided and generating a predetermined frequency that is phase-locked based on the frequencies of the plurality of frequency generators 131a-131n, and a plurality of switches 133a-133n connected to an output side of each phase-locked loop. And a phase-locked loop through one of the plurality of switches switched to an ON state according to a frequency selection signal of the control unit 135 and a coherent frequency channel of the reader 10. A phase shifted 90 degrees with a switching unit for passing an output signal of the first signal, a first mixer 134a for mixing an output signal of the receiver 110 and an output signal of a switch switched to an on state And a second mixer 134n mixing the output signal of the switching unit and the output signal of the receiving unit.

The controller 135 is configured to generate a frequency selection signal corresponding to the determination result after determining the frequency channel of use of the RF signal received through the first mixer 134a. When received, it is provided to output a high frequency RF signal, which is a continuous wave containing no information, and is provided with at least one or more of a conventional microprocessor, a digital signal processor (DSP), an analog control circuit, or digital signal processing dedicated hardware.

The transmitter 150 may include a third mixer 151a for mixing the output signal of the switching unit and the output signal of the control unit 135, an output signal of the switching unit shifted in phase by 90 degrees, and an output of the control unit 135. A fourth mixer 151n for mixing signals, a first driving amplifier 153 for compensating for a conversion loss of an RF signal which is an output signal of the third and fourth mixers 151a and 151n, and the first A first power amplifier 155 for amplifying the output signal of the driving amplifier 153 to a predetermined signal power level, and a second band pass filter 157 for removing high frequency components of the output signal of the first power amplifier 155. ).

Here, the number of the third mixer 151a and the fourth mixer 151n for mixing the demodulation signals I and Q of the control unit 135 with the frequency channels used to output the RF signal is a plurality of tag zones. ) May be provided to match the number of tag zones.

Referring to the operation of the high frequency radiation device 70 provided as described above, the RF signal of the predetermined frequency band f1 supplied from the reader 10 is the first of the receiver 110 through the RF signal receiving antenna ANT1. 1 is supplied to the band pass filter 111.

The RF signal receiver 110 passes an RF signal of a predetermined frequency band, and at this time, the frequency channel f1 of the RF signal is one of all hoppable frequency channels f1-fn.

Subsequently, the RF signal passing through the first band pass filter 111 of the receiver 110 is filtered and amplified through the first low noise amplifier 113 and then supplied to the first automatic gain control amplifier 115. The automatic gain control amplifier 115 maintains the power level of the output signal of the first low noise amplifier 113 at a predetermined value, and outputs the output signal of the first automatic gain control amplifier 115 to the signal processor 130. Supplied.

The signal processor 130 transmits an RF signal through a frequency channel f1 coherent with the frequency channel f1 of the RF signal passed through the receiver 110 among a plurality of frequency channels f1-fn. Pass it through.

That is, the plurality of frequency generators 131a-131n of the signal processing unit 130 generate all communicable frequencies f1-fn, and the generated frequencies f1-fn are the generated frequencies f1- fn) is supplied to the plurality of phase locked loops 132a-132n, respectively. That is, the plurality of phase locked loops 132a to 132n generate predetermined frequencies that are phase-locked based on the frequencies generated by the plurality of frequency generators 131a to 131n. The output signals of the plurality of phase locked loops 132a-132n are respectively supplied to the plurality of switches 133a-133n.

One of the plurality of switches 133a-133n is controlled in a closed state according to the frequency selection signal generated by the control unit 135, and a plurality of phase locked loops 132a-132n through the switch controlled in the closed state. A predetermined frequency of one of the predetermined frequencies is output, and the frequency of the selected channel is supplied to the first mixer 134a.

The first mixer 134 mixes the output signal of the switching unit and the output signal of the receiving unit 110 to output a demodulation signal I, and the demodulation signal I is supplied to the control unit 135.

On the other hand, the output signal of the 90-degree phase shifted switching unit is supplied to the second mixer 134n, and the second mixer 134n is connected to the plurality of phase locked loops 132a to 132n through a switch controlled to a closed state. A demodulation signal Q is output by mixing a predetermined frequency selected from a predetermined frequency and an output signal of the receiver 110, and the demodulation signal Q is supplied to the controller 135.

The controller 135 generates a frequency selection signal for selecting a communication frequency and a coherent frequency channel of the output signal of the receiver 110 according to the output signals of the first mixers 134a and 134n. This generated frequency selection signal is supplied to the plurality of switches 133a-133n.

On the other hand, one of the predetermined frequency of the plurality of phase locked loops (139a-139n) output through the switch controlled to the closed state according to the frequency selection signal generated in the control unit 135 is the transmission unit 150 Is supplied to the third mixer 151a.

In addition, the third mixer 151a mixes the output signal of the controller 135 and the frequency passed through one of the switches 133a-133n.

The frequency channel passed through one of the switches 133a to 133n shifted by 90 degrees is supplied to the fourth mixer 151n of the transmitter 150, and the fourth mixer 151n has a phase of 90 degrees. The frequency shifted frequency channel and a high frequency RF signal, which is a continuous wave without any information of the control unit 135, are mixed and supplied to the first driving amplifier 153 of the transmitter 150, and the first driving amplifier 153 is To amplify the modulated RF signal to give an input power of the first power amplifier 155 to be described later, the output signal of the amplified first driving amplifier 153 is supplied to the first power amplifier 155, The first power amplifier 155 amplifies the output signal of the driving amplifier 153 and supplies it to the second band pass filter 157.

The second bandpass filter 157 passes only signals of a desired frequency band among the output signals of the first power amplifier 155, and the output signal of the second bandpass filter 157 is an RF antenna ANT2. Through this, the electrical signal change on the conductor is radiated to the electromagnetic wave in the air. The tag 50 located in the region of the electromagnetic wave among the plurality of tags 50 is activated by receiving a high frequency signal of this RF signal.

Thereafter, wireless communication is performed between the reader 10 and the tag 50, and an RF signal, which is a response signal of the tag 50, is transmitted to the reader 10 through a frequency channel synchronized with the hopping frequency channel. The reader 10 demodulates the reflection modulated RF signal and provides the collected information to a computer or a host server through a network (not shown).

Example 2

5 is a block diagram showing another embodiment of the RFID system according to the present invention. As shown, the RFID system of the present embodiment uses a plurality of readers 10a for transmitting and receiving RF signals and RF signals in a specific frequency band f1 transmitted by the reader R1 among the plurality of readers 10a. Tag 50a for transmitting its own information by the Backscattered Modulation method, and the response signal of the tag 50a is received and stored in advance, and then the response signal of the stored tag at the request of the reader 10a is stored. An intelligent high frequency radiation device 70a for transmitting to the reader.

The intelligent radio frequency radiator 70a wirelessly communicates with the tag 50a to receive and store a response signal of the tag, and at the request of the reader 10a, a frequency synchronized with the hopping frequency f1 of the reader 10a. Wireless communication with the reader 10a through the channel f1 transmits a response signal of the stored tag to the reader 10a. The reader 10a demodulates the reflection modulated RF signal and provides the collected information to a computer or a host server through a network (not shown).

6 is a view showing in detail the configuration of the intelligent high frequency radiation device 70a shown in FIG. However, the illustrated configuration is only schematically presented to aid the understanding of the present invention, and these configurations are not only easily understood by those skilled in the art, but also easily added, deleted, and modified as necessary to some of the technical features of the present invention. Since it is possible to achieve the scope of the present invention is not limited to the illustrated example.

As shown in FIG. 6, the intelligent high frequency radiation device 70a transmits an RF signal supplied from the controller 235 to be described later to transmit a tag monitoring antenna ANT2 to the tag 50a. And a first receiving unit 220 for receiving a response signal of the tag 50a received through the tag monitoring antenna ANT2, and further, generating the RF signal and generating the first receiving unit 220. The controller 230 stores the response signal of the tag received through the control unit 230 and transmits the response signal of the stored tag to the reader upon request of the reader 10a.

In addition, the intelligent high frequency radiation device 70a receives a question signal of the reader 10a through a hopping frequency channel f1 of the question signal of the reader 10a received through the reader monitoring antenna ANT1. A signal processor for receiving an RF signal which is a question signal of the reader 10a synchronized with the frequency channel f1 of the output signal of the second receiver 240 and the second receiver 240 and supplying the RF signal to the controller 230 ( And a second transmitter 260 which transmits the response signal of the tag stored in the controller 230 to the reader through the frequency channel synchronized with the hopping frequency channel f1.

Here, the reader monitoring antenna ANT1 and the tag monitoring antenna ANT2 are dipole antennas, which are rectifiers in which rectifiers (not shown) are combined. The first and tag monitoring antennas have a structure in which a rectifier diode is connected to a center of a 1/2 wavelength dipole antenna.

The second transmitter 210 may hold the frequency band of the first frequency generator 211 generating the frequency and the frequency of the first frequency generator 211 to be fixed to a predetermined frequency as a reference frequency. locking) a first phase locked loop 212, a first mixer 213a for mixing the frequency of the first phase locked loop and the demodulation signal I of the controller 230, and a 90 degree phase shifted first RF which is an output signal of the second mixer 213n and the first mixer 213a and the second mixer 213n, which are mixed with the frequency of the phase locked loop 212 and the demodulation signal Q of the controller 230. A first drive amplifier 214 for compensating conversion loss of the output signal of the signal, a first power amplifier 215 for amplifying the output signal of the first drive amplifier 214 to a predetermined signal power level, and 1 includes a first bandpass filter 216 that passes only the desired signal of the output signal of the power amplifier 215. And a first coupler 217 that controls the transmission of the first bandpass filter 216 or the reception of an RF signal of a tag.

The second receiver 220 includes a second band pass filter 221 for passing an RF signal of a predetermined frequency band among the RF signals of the tag 50a received through the first coupler 217, and the second band. A first low noise amplifier 222 for filtering the noise component of the output signal of the pass filter 221 and a first automatic gain control amplifier 223 for maintaining the output signal power level of the first low noise amplifier 222. And a third mixer configured to supply a demodulation signal (I) generated by mixing the output signal of the first automatic gain control amplifier 223 and the output signal of the phase locked loop 212 to the controller 230 ( 224a and the demodulation signal Q generated by mixing the output signal of the first automatic gain control amplifier 223 with the output signal of the phase locked loop 212 which is phase shifted by 90 degrees to the controller 230. It is provided with the 4th mixer 224n to supply.

In addition, the second receiver 240 passes the RF signal supplied from the reader 10a or transmits a response signal of the tag to the reader 10a, and the second coupler 241. Filtering the third band pass filter 242 for passing the RF signal of the predetermined frequency band of the RF signal of the reader (10a) received through the) and the noise component of the output signal of the third band pass filter 242 A second low noise amplifier 243 and a second automatic gain control amplifier 245 for amplifying the output signal of the second low noise amplifier 243 to a predetermined power level.

The signal processor 250 includes a second frequency generator provided with a plurality of frequency generators 231a-231n and a plurality of phase locked loops 252a-252n similarly to the signal processor 130 illustrated in FIG. 4. And a phase fixing loop portion, a switching portion provided with a plurality of switches 253a to 253n, a fifth mixer 254a, and a sixth mixer 254n.

In addition, the controller 230 receives demodulated signals (I and Q signals) received through the fifth mixer 254a and the sixth mixer 254n, and determines a frequency band for use of the received demodulated signal. It is provided to generate a frequency selection signal corresponding to the determination result, and is provided to transmit the response signal of the tag 50a stored in advance to the reader (10a) upon request of the reader (10a), a conventional microprocessor, a digital signal processor ( DSP), analog control circuits or at least one of the digital signal processing dedicated hardware.

In addition, the controller 230 further includes a second transmitter 260 which transmits the response signal of the stored tag to the reader 10a.

The second transmitter 260 may include a seventh mixer 261a that mixes an output signal of the switching unit and an output signal of the controller 230, an output signal of the switching in which the phase is shifted by 90 degrees, and the controller 230. An eighth mixer 261n for mixing the output signals of the second and second drive amplifiers 262 for compensating for the conversion loss of the RF signal which is an output signal of the seventh and eighth mixers 261a and 261n, A second power amplifier 263 that amplifies the output signal of the second driving amplifier 262 to a predetermined signal power level, and removes a high frequency component of the output signal of the second power amplifier 263 and then removes the second coupler ( And a fourth band pass filter 264 supplied to the reader 10a through 241.

Here, the number of the first mixers 213a to the eighth mixers 261n for mixing the demodulation signals I and Q of the control unit 135 with the frequency bands used to output the RF signal is a plurality of tag zones. ) May be provided to match the number of tag zones.

Referring to the operation of the radio frequency identification system having the intelligent radio frequency radiator 70a provided as described above, the controller 230 generates demodulation signals I and Q for receiving the response signal of the tag 50a. .

On the other hand, the first frequency generator 211 oscillates the use frequency, the oscillated use frequency is supplied to supply to the phase-locked loop 212, the phase-locked loop 212 is a reference frequency to the oscillated use frequency To the output frequency of the VCO (not shown). Subsequently, the output signal of the phase locked loop 212 is mixed based on the demodulation signal I of the controller 230 and the first mixer 213a, and the phase locked loop 212 shifted in phase by 90 degrees. ) Is mixed based on the demodulation signal Q of the controller 230 and the second mixer 213n.

RF signals, which are output signals of the first mixer 213a and the second mixer 213n, are supplied to the first driving amplifier 214 of the first transmitter 210, and the first driving amplifier 214 is described later. Amplifying the modulated RF signal to give an input power of the first power amplifier 215, the output signal of the amplified first drive amplifier 214 is supplied to the first power amplifier 215, the first The power amplifier 215 amplifies the output signal of the first driving amplifier 214 and supplies it to the first bandpass filter 216.

The first bandpass filter 216 passes only signals of a desired frequency band among the output signals of the first power amplifier 215, and the output signal of the second bandpass filter 217 is the first coupler 217 and the first bandpass filter 217. The tag monitoring antenna ANT2 radiates the change of the electrical signal on the lead to electromagnetic waves in the air. The tag 50a located in the region of the electromagnetic wave among the plurality of tags 50a receives a modulated RF signal.

Meanwhile, among the plurality of tags, the tag 50a receiving the electromagnetic wave transmits a response signal to a question signal supplied from the controller 230 of the intelligent high frequency radiation device 70a, and responds to the transmitted tag 50a. The RF signal, which is a signal, is supplied to the second band pass filter 221 of the first receiver 220 through the tag monitoring antenna ANT2 and the first coupler 217 of the intelligent high frequency radiation device 70a, and the second The band pass filter 221 passes an RF signal of a predetermined frequency band among the RF signals of the tag 50a.

Subsequently, the RF signal passing through the second band pass filter 221 is filtered and amplified by the first low noise amplifier 222 and then supplied to the first automatic gain control amplifier 223, and the first automatic gain control amplifier 223 maintains the power level of the output signal of the first low noise amplifier 222 at a predetermined value, and the output signal of the first automatic gain control amplifier 222 is the third mixer 224a and the fourth mixer ( 224n).

The third mixer 224a outputs a demodulated signal I in which the output signal of the phase locked loop 212 and the output signal of the first automatic gain control amplifier 222 are mixed, and the demodulated signal I Is supplied to the controller 230, and the controller 230 stores the demodulated signal I.

In addition, the fourth mixer 224n outputs a demodulation signal Q obtained by mixing the output signal of the phase locked loop 212 and the output signal of the first automatic gain control amplifier 222 which are phase shifted by 90 degrees. The demodulation signal Q is supplied to the control unit 230, and the control unit 230 stores the demodulation signal Q.

That is, the controller 230 stores demodulation signals I and Q for the RF signal that is a response signal of the tag.

On the other hand, the RF signal of the predetermined frequency band f1 supplied from the reader 10a through the reader monitoring antenna ANT1 is passed through the second coupler 241 by the third band pass filter of the second receiver 240. Supplied to 242.

The second receiver 240 passes an RF signal of a predetermined frequency band, and at this time, the frequency channel f1 of the RF signal is one of all hoppable frequency channels f1-fn.

Subsequently, the RF signal passing through the third band pass filter 241 of the second receiver 240 is filtered and amplified through the second low noise amplifier 242 and then supplied to the second automatic gain control amplifier 243. The second automatic gain control amplifier 243 maintains the power level of the output signal of the second low noise amplifier 242 at a predetermined value, and the output signal of the second automatic gain control amplifier 243 is the signal processor 250. Supplied to.

The signal processor 250 performs RF through a coherent frequency channel f1 and a frequency channel f1 of the RF signal passing through the second receiver 240 among a plurality of frequency channels f1 -fn. Pass the signal.

That is, the plurality of frequency generators 251a-251n of the signal processing unit 250 generate all of the communicable frequencies f1-fn, and the generated frequencies f1-fn are the generated frequencies f1-f. fn) is supplied to a plurality of phase locked loops 252a to 252n, respectively. That is, the plurality of phase locked loops 252a to 252n generates predetermined frequencies that are phase locked based on frequencies generated by the plurality of frequency generators 251a to 251n. The output signals of the plurality of phase locked loops 252a through 252n are respectively supplied to the plurality of switches 253a through 253n.

One of the plurality of switches 253a-253n is controlled in a closed state according to the frequency selection signal generated by the controller 230, and a plurality of phase locked loops 252a-252n through the switch controlled in the closed state. A predetermined frequency of one of the predetermined frequencies is output, and the frequency of this selected channel is supplied to the fifth mixer 254a.

The fifth mixer 254 mixes the output signal of the switching unit and the output signal of the third receiver 240 to output a demodulation signal I, and the demodulation signal I is supplied to the control unit 230.

On the other hand, the output signal of the switching unit which is phase shifted by 90 degrees is supplied to the sixth mixer 254n, and the sixth mixer 254n is provided with a plurality of phase locked loops 252a through 252n through a switch controlled in a closed state. The demodulated signal Q is output by mixing the selected one of the predetermined frequencies of the output signal of the third receiver 240 and the demodulated signal Q, and the demodulated signal Q is supplied to the controller 230.

The controller 230 selects a communication frequency and a coherent frequency channel of the output signal of the third receiver 240 according to the output signals of the fifth and sixth mixers 254a and 254n. A selection signal is generated, and the generated frequency selection signal is supplied to the plurality of switches 253a-253n.

The controller 230 outputs a response signal of a tag stored in advance in response to a question signal of the reader.

That is, one predetermined frequency selected from among the predetermined frequencies of the plurality of phase locked loops 252a through 252n output through the switch controlled to the closed state according to the frequency selection signal generated by the controller 230 is the second transmitter ( 260 is supplied to the seventh mixer 261a.

In addition, the seventh mixer 261a mixes the output signal of the controller 230 and the frequency passing through one of the switches 253a-253n.

The frequency channel passing through one of the switches 253a to 253n shifted in phase by 90 degrees is supplied to the eighth mixer 261n of the second transmitter 260, and the eighth mixer 261n is in phase The frequency channel shifted by 90 degrees and the output signal of the controller 230 are mixed and supplied to the second drive amplifier 262 of the second transmitter 260, and the second drive amplifier 262 is a power amplifier (described later). Amplifying the modulated RF signal to give an input power of 263, the output signal of the amplified second drive amplifier 262 is supplied to a second power amplifier 263, the second power amplifier 263 Amplifies the output signal of the second driving amplifier 262 and supplies it to the fourth band pass filter 264.

The fourth bandpass filter 264 passes only signals of a desired frequency band among the output signals of the second power amplifier 263, and the output signal of the fourth bandpass filter 264 is the second coupler 241 and The reader monitoring antenna (ANT2) radiates changes in electrical signals on the conductors to electromagnetic waves in the air.

That is, the RF signal which is a response signal of the tag 50a stored in the controller 230 is transmitted to the reader 10a through a frequency channel synchronized with the hopping frequency channel, and the reader 10a is subjected to the reflection modulation. Demodulate the RF signal and provide the collected information to a computer or host server over a network (not shown).

As described above, the radio frequency identification system according to the present invention radiates the reader's RF signal to the tag by synchronizing with the channel of the reader's hopping frequency within a predetermined time in the RFID protocol among all the frequency band channels of the reader's frequency hopping. In this way, interference between adjacent readers can be prevented at the output of the transmission power of the reader, thereby achieving an effect that the communication between the reader and the tag can be performed drastically.

As such, those skilled in the art to which the present invention pertains may understand that the present invention may be embodied in other specific forms without changing to the technical concept or essential features of the present invention. Therefore, the above-described embodiments are to be understood in all respects as illustrative and not restrictive. The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. .

Claims (5)

In the radio frequency identification system that communicates between the reader and the tag, Receiving unit for receiving the RF signal of the reader; A first frequency generator including a plurality of frequency generators for generating frequencies in all frequency bands that can be communicated with each other in order to transmit the received RF signals to the transmitter in synchronization with a communication frequency channel of the RF signal of the receiver; A first phase locked loop unit having a plurality of phase locked loops for generating a predetermined frequency based on the frequencies of the plurality of frequency generators, and a plurality of switches connected to an output side of each of the phase locked loops; And a switching unit configured to switch one of the plurality of switches to an ON state according to a frequency selection signal of the controller to pass an output signal of the phase locked loop through a hoped frequency of the reader and a coherent frequency channel. And a first horn mixing the output signal of the first receiver and the output signal of the switch switched to an on state. Group, the signal processor including a second mixer for mixing an output signal phase of the output signal switching unit and the receiving unit shifts; A control unit for receiving an output signal of each of the first and second mixers, generating a frequency selection signal for selecting a hoped frequency and a coherent frequency channel of the reader, and transmitting an RF signal to a tag; And a transmitter for transmitting an output signal of the first controller to a tag through a frequency channel used by the switching unit. The apparatus of claim 1, wherein the signal processor is connected between a transmitter and a receiver to wait when an RF signal of the reader is received, and to include a high frequency radiator that emits a high frequency wave that does not include any information when radiating a continuous wave. Radio frequency identification system, characterized in that. The radio frequency identification system according to claim 1, wherein the signal processing unit is included in an arbitration apparatus capable of communicating a plurality of readers by allowing a communication use frequency when a plurality of readers requests them. In the radio frequency identification system that communicates between the reader and the tag, A controller for generating and transmitting an RF signal to a tag, receiving and storing an RF signal of a tag in response to the RF signal, and transmitting an RF signal of the stored tag to the reader when requested by a reader; A first transmitter for transmitting an RF signal generated by the controller to a tag; A first receiving unit receiving the RF signal of the tag in response to the RF signal of the first transmitting unit through the tag monitoring antenna and transmitting the received RF signal to the second control unit; A second receiver which receives a question signal of a reader received through a reader monitoring antenna; In order to output an RF signal of a tag stored in the controller through a frequency channel synchronized with a frequency channel of an RF signal of the reader received through the second receiver, frequencies of all frequency bands including a plurality of frequency generators A frequency generator for generating each of the plurality of phase locked loops, the phase locked loop having a plurality of phase locked loops for generating a predetermined frequency based on the frequencies of the plurality of frequency generators, and an output side of the respective phase locked loops. The phase locked loop is provided with a plurality of switches connected to the one of the plurality of switches in an on state according to a frequency selection signal of the controller, through a hopped frequency of the reader and a coherent frequency channel. A switching unit configured to pass an output signal of the switching unit, an output signal of the second receiving unit and the switching unit A first mixer for supplying a demodulation signal generated by mixing output signals to the controller, and a demodulator signal for mixing the output signal of the switching unit whose phase is shifted with the output signal of the second receiver; A signal processor including two mixers, And a second transmitter to transmit the RF signal of the tag stored in the controller to the reader through a frequency channel synchronized with a frequency channel of the reader's RF signal through the signal processor. The radio frequency identification system according to claim 4, wherein the signal processing unit is included in an intelligent high frequency radiation device which supplies a response signal of a tag stored in advance to a reader when a reader requests it.

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