KR20100106805A - Method for managing system of rfid - Google Patents

Abstract

PURPOSE: A method for operating a system of RFID is provided to successively transmit a transmission-start command and a transmission-end command to RFID readers respectively, thereby reducing a communication load between RFID readers and a server computer. CONSTITUTION: A server computer successively transmits a transmission-start command and a transmission-end command to each RFID reader based on transmission time allocate to each RFID(S303,S306,S312,S307,S311,S318,S322). Each RFID reader receives tag information from RFID tags from time when the transmission-end command is received to time when the transmission-start command is received. Each RFID reader transmits the tag information of a tag memory to the server computer from the time when the transmission-start command is received to time when the transmission-end command is received.

Description

Method of managing system of RFID

The present invention relates to a method of operating a system of RFID, and more particularly, to a method of operating a system of RFID, in which a server computer and a plurality of RFID readers communicate with each other. will be.

In a typical RFID system, each RFID reader receives tag information while communicating with a plurality of RFID tags, and transmits the received tag information to a server computer. .

1 shows a system of a typical RFID.

Referring to FIG. 1, each of the RFID readers 111a through 111m receives tag information from tags 121a through 121n and 191a through 191n of a plurality of RFIDs, thereby communicating a communication network 2. Is transmitted to the server computer (3).

2 shows a method of operating a system of a conventional RFID (RFID). More specifically, FIG. 2 shows a method of operating a system of RFID (RFID) for reducing overlap of communication load in a low level reader protocol (LLRP). 1 and 2, a method of operating a conventional RFID system (RFID) is described as follows.

First, the server computer 3 transmits an ON signal to the first readers 111a to 111m (step S201). Accordingly, the first reader receives the tag information from the tags 121a to 121n or 191a to 191n of the RFID and transmits it to the server computer 3 (step S202).

Next, the server computer 3 transmits an Off signal to the first reader (step S203). Accordingly, the first reader stops receiving and transmitting tag information. In other words, the actual operating time T1a of the first reader is the time from when the On signal from the server computer 3 is received to the time when the Off signal is received.

Next, the server computer 3 transmits an ON signal to the second readers 111a to 111m (step S204). Accordingly, the second reader receives the tag information from the tags 121a to 121n or 191a to 191n of the RFID and transmits it to the server computer 3 (step S205).

Similarly, the server computer 3 transmits an Off signal to the second reader (step S206). Accordingly, the second reader stops receiving and transmitting tag information. That is, the actual operating time T2a of the second reader is the time from when the On signal from the server computer 3 is received to the time when the Off signal is received.

The above steps apply equally to other leaders.

Here, as shown in FIG. 2, if only the first and second readers exist, the time from when the first reader receives the off signal to when the second reader receives the off signal Only the unrecognized time T1d of the first reader will be used.

However, in most cases, since the plurality of readers 111a to 111m communicate with the server computer 3, the unrecognizable time T1d of one leader becomes relatively long.

Accordingly, according to the method of operating the RFID system, the overlap of communication load between the readers 111a to 111m of the RFIDs and the server computer 3 can be reduced. On the other hand, there is a problem that each of the RFID readers 111a through 111m may miss tag information from the tags 121a through 121n or 191a through 191n of the RFID.

The object of the present invention is not only to efficiently reduce the overlap of communication load between a plurality of RFID readers and a server computer, but also to ensure that each of the RFID readers It is to provide a method of operating a system of RF ID (RFID) that can not miss the tag information from the tags.

The present invention provides a method of operating a system of RFIDs (RFIDs) in which a server computer and a plurality of RFID readers communicate, comprising steps (a) to (c).

In the step (a), the server computer issues a transfer-start command and a transfer-end command according to a transmission time allocated to each of the readers of the plurality of RFIDs. Send to each of them sequentially.

In step (b), each of the plurality of RFID readers receives the tag information from the tags of the RFID from the time of receiving the transmission-stopping command to the time of receiving the transmission-starting command. Store in tag memory.

In the step (c), the tag information stored in the tag memory is stored during the transmission time from the time when each of the readers of the plurality of RFIDs receives the transmission-start command to the time when the transmission-end command is received. While transmitting to the server computer, tag information is received from the tags of the RFID and stored in the sub-buffer.

According to the method of operating the system of the RFID of the present invention, the server computer issues a transfer-start command and a transfer-end command according to the transmission time allocated to each of the readers of the plurality of RFIDs. It sequentially transmits to each of the readers of the plurality of RFIDs. This can reduce the overlap of communication load between the RFID readers and the server computer.

Further, according to the operating method of the system of the RFID of the present invention, each of the readers of the plurality of RFID (RFID), while transmitting the tag information stored in the tag memory to the server computer, RF Tag information is received from tags of the ID (RFID) and stored in the sub-buffer. Accordingly, each of the readers of the RFID may not miss the tag information from the tags of the RFID.

Figure 3 shows a method of operating a system of RF ID (RFID) according to an embodiment of the present invention. In FIG. 3, only the first leader and the second leader are shown, but the operating method for them is applied to other leaders sequentially. 1 and 3, a method of operating an RFID ID system according to an embodiment of the present invention will be described.

Each of the readers 111a to 111m of the RFIDs RFID tags RFIDa of the RFIDs from the time when the transmission-end command is received from the server computer 3 to the time when the transmission-start command is received. The tag information is received from 121n or 191a to 191n and stored in the tag memory 241a of FIG. 5 (steps S301 and S302).

The first reader is stored in the tag memory (241a in FIG. 5) during the transfer time from the time when the transfer-start command is received from the server computer 3 (step S303) to the time when the transfer-end command is received (step S306). The tag information from the tags 121a to 121n or 191a to 191n of the RFID (RFID), and transmits the tag information to the server computer 3 (step S304) to the sub-buffer (241b in FIG. 5). Save (step S305).

Next, the second reader reads the tag memory (241a in FIG. 5) during the transfer time from the time when the transfer-start command is received from the server computer 3 (step S307) to the time when the transfer-end command is received (step S311). Is sent to the server computer 3 (step S308), the tag information is received from the tags 121a to 121n or 191a to 191n of the RFID, and the sub-buffer (FIG. 5). 241b) (step S311). Here, the first reader receives the tag information from the tags of the RFID (RFID) from the time when the transfer-end command is received (step S306) to the time when the transfer-start command is received (step S312). 241a) (step S311).

Next, the first reader (replaces the third reader, the fourth reader, and the like with only the first reader and the second reader for the sake of simplicity of FIG. 3) receives a transfer-start command from the server computer 3 (step S312 The tag information stored in the tag memory (241a in FIG. 5) is transmitted to the server computer 3 (step S313) during the transfer time from the time point to the time when the transfer-end command is received (step S317). Tag information is received from the tags 121a to 121n or 191a to 191n of the RFID) and stored in the sub-buffer 241b of FIG. 5 (step S314). Here, the second reader receives the tag information from the tags of the RFID (RFID) from the time when the transfer-end command is received (step S311) to the time when the transfer-start command is received (step S318). 241a) (step S315).

Accordingly, the overlap of communication load between the plurality of RFID readers 111a to 111m and the server computer 3 can be effectively reduced, and the RFID 111 readers 111a to 111m. ) May not miss tag information from tags 121a through 121n or 191a through 191n of the RFID.

On the other hand, when the second reader stores the tag information in step S302, it is assumed that too much tag information is stored and information is accumulated in the tag memory 241a of FIG. do. Here, the second reader requests the server computer 3 to extend the transmission time when the memory capacity exceeds a certain amount, that is, when the storage capacity of the tag memory 241a exceeds the allowable capacity (step S302).

Accordingly, the server computer 3 extends and resets the transmission time of the second reader, that is, the reader of the RFID that requests the transmission time extension.

Next, the second reader receives the tag memory (241a in FIG. 5) for the transfer time from the time when the transfer-start command is received from the server computer 3 (step S318) to the time when the transfer-end command is received (step S322). Is sent to the server computer 3 (step S319), the tag information is received from the tags 121a to 121n or 191a to 191n of the RFID, and the sub-buffer (FIG. 5). 241b) (step S320). Here, it can be seen that the transmission time of the second reader has been extended (see S320 of FIG. 3).

Therefore, the overlap of the communication load between the readers of the plurality of RFIDs and the server computer can be reduced more efficiently.

On the other hand, the first reader receives the tag information from the tags of the RFID (RFID) from the time of receiving the transfer-end command (step S317) to the time of receiving the transfer-start command and stores it in the tag memory (241a of FIG. 5). (Step S321).

4 illustrates an internal configuration of the reader 111a to 111m of the RFID of FIG. 1 for applying the operating method of FIG. 3.

Referring to FIG. 4, an RFID reader according to an embodiment of the present invention communicates with an RFID tag, and includes a transmitter 251 to 256, 22 and 21, and a receiver ( 261 to 265q, 22 and 21, and a control unit 24.

The transmitters 23, 251 to 256, 22, and 21 transmit the tag command data from the controller 24 to the tags of the RFID.

The receivers 23, 261 to 265q, 22, and 21 convert the received signals from the RFID tags into Q signals Sbq and I signals Sbi of different phases, and provide them to the controller 24. do.

The oscillator 23 included in the transmitter or receiver generates an oscillation signal Mfc having a variable frequency for frequency hopping according to the control signal Scon from the controller 24.

The first and second analog-to-digital converters 265q and 265i included in the receiver convert the signals Saq and Sai from the receivers 261 to 264q into digital signals Scq and Sci to control the controller 24. ).

The control unit 24 transmits the tag command data Sdt and the power signal to the tag of the RFID while generating control signals Scon in the respective units. The data Scq of the Q signal and the data Sc of the I signal from the receivers 261 to 265q are decoded and transmitted to a server computer (not shown).

The digital-analog converter 251 included in the transmitter converts the tag command data Sdt from the controller 24 into an analog signal Sat. The base frequency filter 252 included in the transmitter passes only the signal of the base frequency in order to remove noise of the transmission signal Sat from the digital-analog converter 251.

The base frequency amplifier 253 included in the transmitter amplifies the transmission signal Sbt from the base frequency filter 252. In the up-mixer 254 included in the transmitting unit, the frequency of the transmitting signal Sbt from the base frequency amplifier 253 is present in accordance with the oscillating signal Mfc of the variable frequency from the oscillating unit 23. Adjust to the radio frequency to be used. That is, if the frequency of the transmission signal Sbt from the base frequency amplifier 253 is fb, and the frequency of the oscillation signal Mfc from the oscillator 23 is fm, it is determined from the up-mixer 254. The frequency ff of the transmission signal Sht is obtained by the following equation (1).

ff = fb + fm

In Equation 1, the frequency fm of the oscillation signal Mfc from the oscillator 23 is obtained by Equation 2 or Equation 3 below.

fm = fmp + fn

fm = fmp-fn

In Equations 2 and 3, fmp denotes the frequency of the oscillation signal Mfc in the previous period. fn indicates the interval frequency to be increased or decreased in accordance with the adaptive frequency hopping algorithm.

The radio frequency amplifier 255 included in the transmission unit primarily amplifies the power of the transmission signal Sht from the up-mixer 254. The power amplifier 256 included in the transmitter finally amplifies the power of the transmission signal Sht from the radio frequency amplifier 255. The transmission signal Sht from the power amplifier 256 is transmitted to the tag of the RFID through the circulator 22 and the transmission / reception antenna 21.

On the other hand, the balun BALUN 261 included in the receiving unit may receive the received signals of the circulator 22 and the first signal Sh + having a different phase (in this embodiment, having a phase difference of 180 ^o (π) from each other). The signal is converted into the second signal Sh-.

A 90 ^° phase shifter 266 included in the receiver shifts the phase of the oscillation signal Mfc from the oscillator 23 by 90 ^° .

The down-mixer 262q for the Q signal included in the receiver is configured to convert a first signal Sh + and a second signal Sh- from the balun BALUN 261 into a 90 ^° phase shifter 266. According to the oscillation signal from), it is converted into a base frequency Q + signal (Sq +) and Q- signal (Sq-).

The down mixer 262i for the I signal included in the receiver bases the first signal Sh + and the second signal Sh- from the balun BALUN 261 on the basis of the oscillation signal Mfc from the oscillator 23. Converts to I + signal (Si +) and I- signal (Si-) of frequency.

That is, if the frequencies of the first signal Sh + and the second signal Sh- from the balun BALUN 261 are ff and the frequency of the oscillation signal Mfc from the oscillator 23 is fm, the Q signal is used. The frequency fb of the Q receive signals Sq + and Sq- from the down-mixer 262q and the I receive signals Si + and Si- from the down-mixer 262i for the I signal are It is obtained by the following equation (4).

fb = ff-fm

In Equation 4, the frequency fm of the oscillation signal Mfc from the oscillator 23 is obtained by Equations 2 and 3 above.

The low pass filter 263q for the Q signal included in the receiver removes high frequency noise from the Q + signal Sq + and the Q- signal Sq- from the down-mixer 262q for the Q signal.

Similarly, the low pass filter 263i for the I signal removes high frequency noise from the I + signal Si + and the I- signal Si- from the down mixer 262i for the I signal.

The Q-signal differential amplifier 264q included in the receiver amplifies the difference signal between the Q + signal Sq + and the Q- signal Sq- from the low pass filter 263q for the Q signal to generate the Q signal Saq.

Similarly, the I-signal differential amplifier 264i amplifies the difference signal between the I + signal Si + and the I- signal Si- from the low pass filter 263i for the I signal to generate the I signal Sai.

5 illustrates an internal configuration of the controller 24 of FIG. 4.

4 and 5, the controller 24 includes a digital demodulator 245, a decoder 246, a communication controller 241, an encoder 242, and a digital modulator 243.

The digital demodulator 245 generates the integrated digital signal Dde according to the digital Q signal Scq and the digital I signal Sci from the analog-to-digital converters 265q and 265i. More specifically, according to the digital Q signal Scq and the digital I signal Sci from the analog-to-digital converters 265q and 265i, the positive integrated digital signal or the negative integrated digital signal is continuously generated. .

The decoder 246 decodes the integrated digital signal Dde continuously input from the digital demodulator 245 to continuously generate binary data "1" or "0".

In accordance with the signal Drc from the server computer, the communication control unit 241 performs overall control and transmits the output data Dsen from the decoder 241 to the server computer while communicating with the server computer.

Here, the communication control unit 24 includes a tag memory 241a and an auxiliary buffer 241b. The functions of the tag memory 241a and the sub-buffer 241b are as described with reference to FIG. 3. In addition, a control algorithm of the communication control unit 24 according to the operating method of FIG. 3 will be described with reference to FIG. 7.

The encoder 242 encodes the tag command data Dct from the communication control unit 241.

The digital modulator 243 modulates the tag command data Dit from the encoder in a digital format, and inputs the resulting digital signal Sdt to the transmitters 251 to 256.

FIG. 6 shows a control algorithm of the server computer 3 of FIG. 1 according to the operating method of FIG. 3. 1, 3 and 6, a control algorithm of the server computer 3 of FIG. 1 according to the operating method of FIG. 3 will be described.

First, the server computer 3 sets the transmission time and priority for each of the readers 111a to 111m of the RFID (RFID) (step S601).

Next, the server computer 3 transmits a transfer-start command to the readers 111a to 111m of the RFID corresponding to the priority (step S602).

Next, the server computer 3 receives the tag information packet from the target reader (step S603).

Next, the server computer 3 determines whether there is a transfer-time extension request from another reader (step S604). If there is a transmission-time extension request from another reader, the server computer 3 resets by extending the transmission time of the leader that has made the extension request (step S605).

Steps S603 to S605 are repeatedly performed until the transmission time of the target reader has elapsed (step S606).

Next, when the transmission time of the target reader elapses, the server computer 3 transmits a transfer-end command to the target reader (step S607).

Next, the server computer 3 determines whether the amount of the received tag information packet is less than the lower limit amount (step S608). Here, if the amount of the received tag information packet is less than the lower limit, the server computer 3 resets by reducing the transmission time of the target reader. Accordingly, the overlap of the communication load between the readers 111a to 111m of the RFIDs and the server computer 3 can be reduced more efficiently.

Steps S602 to S609 are repeatedly performed until a termination signal is generated (step S610).

7 illustrates a control algorithm of the communication control unit 241 of FIG. 5 according to the operating method of FIG. 3. 1, 3, 5 and 7, the control algorithm of the communication control unit 241 of FIG. 5 will be described below.

First, the communication control unit 241 receives tag information from each of the tags 121a to 121n or 191a to 191n of the RFID (step S701).

Next, the communication control unit 241 stores the received tag information in the tag memory 241a (step S702).

Next, the communication control unit 241 determines whether the storage capacity of the tag memory 241a exceeds the allowable capacity (step S703). When the storage capacity of the tag memory 241a exceeds the allowable capacity, the communication control unit 241 requests the server computer 3 to extend the transmission time (step S704).

Next, the communication control unit 241 determines whether a transfer-start command has been received from the server computer 3 (step S705). The above steps S701 to S704 are repeatedly performed until the transfer-start command is received from the server computer 3. When the transfer-start command is received from the server computer 3, the following steps are continued.

First, the communication control unit 241 transmits one tag information of the tag memory 241a to the server computer 3 (step S706).

The communication control unit 241 also receives tag information from the tags 121a to 121n or 191a to 191n of any RFID (step S707). The communication control unit 241 also stores the received tag information in the sub-buffer 241b (step S708).

The above steps S706 to S708 are repeatedly performed until a transfer end command is received from the server computer 3 (step S709). That is, the transmitting step of the tag information and the receiving step of the tag information are alternately performed.

When the transfer end command is received from the server computer 3, the communication control unit 241 moves the tag information stored in the sub-buffer 241b to the tag memory 241a (step S710).

All the above steps are repeatedly performed until the end signal is generated (step S711).

As described above, according to the operating method of the system of the RFID according to the present invention, the transmission-start command and the transmission by the server computer according to the transmission time allocated to each of the readers of the RFID Send a shutdown command sequentially to each of the readers of the plurality of RFIDs; This can reduce the overlap of communication load between the RFID readers and the server computer.

In addition, according to the operating method of the system of the RFID of the present invention, each of the readers of a plurality of RFID (RFID), while transmitting the tag information stored in the tag memory to the server computer, RFID ID (RFID) Tag information is received from the tags and stored in the sub-buffer. Accordingly, each of the readers of the RFID may not miss the tag information from the tags of the RFID.

Possible use in general wireless communication systems.

1 is a diagram illustrating a system of a general RFID (RFID).

2 is a timing diagram illustrating a method of operating a conventional RFID system.

3 is a timing diagram illustrating a method of operating a system of RF IDs according to an embodiment of the present invention.

FIG. 4 is a block diagram illustrating an internal configuration of a reader of RFID of FIG. 1 for applying the operating method of FIG. 3.

5 is a block diagram illustrating an internal configuration of a controller of FIG. 4.

6 is a flowchart illustrating a control algorithm of the server computer of FIG. 1 according to the operating method of FIG. 3.

7 is a flowchart illustrating a control algorithm of the communication controller of FIG. 5 according to the operating method of FIG. 3.

 <Explanation of symbols for the main parts of the drawings>

121a through 121n, 191a through 191n, tags of RFID,

111a to 111m ... leaders of RFID

24 ... control unit, 241 ... communication control unit.

Claims (6)

In a method of operating a system of RF ID (RFID) in which a server computer and a plurality of RFID readers communicate with each other, (a) the server computer sequentially transmits a start-start command and a transfer-end command to each of the readers of the RFIDs according to a transmission time allocated to each of the readers of the RFIDs. Transmitting to; (b) Each tag reader of the plurality of RFIDs receives tag information from tags of the RFID from the time of receiving a transmission-ending command to the time of receiving a transmission-starting command and stores the tag information in a tag memory. Making; And (c) tag information stored in the tag memory is transmitted to the server computer during a transmission time from the time when the readers of the plurality of RFIDs receive the transmission-start command to the time of the transmission-end command. A method of operating a system of an RFID which receives tag information from tags of an RFID and transmits the tag information to an auxiliary buffer while transmitting. The method of claim 1, wherein in step (b), A method of operating an RFID system in which an RFID reader having a storage capacity of the tag memory exceeding an allowable capacity is requested to extend the transmission time to the server computer while storing tag information. The method of claim 2, wherein in step (b), And the server computer extends and resets the transmission time of the RFID reader requesting the transmission time extension. The method of claim 1, wherein in step (c), Transmitting one tag information of the tag memory to the server computer; And And receiving tag information from a tag of an RFID, and storing the tag information in the sub-buffer alternately. The method of claim 1, wherein in step (b), When each of the readers of the RFID receives a transfer-end command, the tag information stored in the auxiliary buffer is moved to the tag memory, and the tag information is received from the tags of the RFID. Operating system of RFID to store in the tag memory. The method of claim 1, wherein in step (c), And if the amount of tag information packets received from the reader of one RFID is less than the lower limit, the server computer resets by reducing the transmission time of the target reader.

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