KR100911437B1 - RFID reader duplexing system - Google Patents

Abstract

The present invention doubles the RFID reader and checks whether the RFID reader currently operating in a state of being built through various paths stops the operation of the currently operating RFID reader and operates another RFID reader. The present invention relates to an RFID reader redundancy system that can improve the accuracy and reliability of the RFID reader.

RFID reader redundancy system of the present invention is one middleware; Two or more RFID readers connected to the middleware; And a single redundancy device connected to each of the RFID readers by a transmission and reception antenna for transmitting and receiving RF signals and a communication interface, and selectively connecting the transmission and reception antennas to any one RF block of the RFID reader.

RFID, Reader, Redundant, Stable, Antenna, Power, Transmit

Description

RFID reader duplexing system {RFID reader duplexing system}

The present invention relates to an RFID reader redundancy system, and in particular, checks whether an abnormal RFID reader is currently operating in a state in which a system is constructed by duplexing the RFID reader through various paths and stops the operation of the currently operating RFID reader when an error occurs. The present invention relates to an RFID reader redundancy system that operates another RFID reader.

Generally recognized radio frequency (RFID: R adio F requency Id entification) recognizes the tag is attached to goods, animals, people, and by the non-contact type read information from or writes from a tag with a unique identification information by using a radio frequency , Technology that enables tracking and management. Such an RFID system has a plurality of tags (Electronic Tag or Transponder; hereinafter simply referred to as 'tag') attached to an object or animal with unique identification information and an RFID reader (Reader or Interrogator) for reading or writing the information of the tag. (Hereinafter referred to simply as 'leader'). RFID systems are also classified into mutual induction and electromagnetic waves according to the intercommunication method between the reader and the tag, and are classified into active and passive according to whether the tag operates on its own power. It is divided into short wave, ultra short wave and ultra short wave shape. In accordance with the above classification, various kinds of standards are enacted or in preparation for enactment. On the other hand, such an RFID system is being actively used in logistics and factory automation.

More specifically, a conventional RFID system performs wireless communication with an RFID tag attached to a place of an article and an RFID tag while storing unique information (tag information) of the article, and reads tag information stored in the RFID tag. And middleware that sets various operation matters for the RFID reader, maintains, maintains, and manages it, and collects tag information received from the RFID reader to perform necessary operations.

However, in the conventional RFID system, as described above, the tag information is received by RF communication with the tag, and the means for delivering the received tag information to the middleware is implemented as a single reader. When a problem such as a faulty state or an antenna fastening state occurs, the operation of the system is stopped due to the failure to read necessary information from the tag, thereby degrading the accuracy and reliability of the system.

The present invention has been made to solve the above-described problems, the duplication of the RFID reader in the system is built in the state of the current state of the RFID reader in operation through a variety of paths to check the operation of the currently operating RFID reader when the error occurs The purpose of the present invention is to provide an RFID reader redundancy system that can improve the accuracy and reliability of the system by stopping and operating another RFID reader.

RFID reader redundancy system of the present invention for achieving the above object is one middleware; Two or more RFID readers connected to the middleware; And a single redundancy device connected to each of the RFID readers by a transmission and reception antenna for transmitting and receiving RF signals and a communication interface, and selectively connecting the transmission and reception antennas to any one RF block of the RFID reader.

In the above-described configuration, each of the RFID reader has a function of notifying the middleware by checking whether there is an abnormality of its own hardware or software, and the middleware is currently operating when it is notified of an abnormality from an RFID reader currently operating. A motion stop command is issued to an RFID reader and a motion start command is issued to another RFID reader that is not currently operating. The RFID reader that has received the motion start command connects the transmission / reception antenna to its RF block. Control commands may be issued to the redundant device via an interface.

In contrast, the middleware has a function of periodically transmitting a failure check signal for requesting a predetermined response to the currently operating RFID reader, so that the RFID reader currently operating when the predetermined response is not received from the currently operating RFID reader. And an operation start command to another RFID reader that is not currently operating, and the RFID reader receiving the operation start command connects the communication interface to the RF block to connect its transmit / receive antenna to its RF block. The control command may be issued to the duplication unit through.

On the contrary, the duplexing device has a function of checking whether the intensity of the transmission output of the currently operating RFID reader is less than a predetermined reference value and transmitting the result to the middleware through the currently operating RFID reader. When receiving the fact that it does not meet the predetermined reference value, it gives the operation stop command to the currently operating RFID reader and the operation start command to the other RFID reader which is not currently operating. The received RFID reader may issue a control command to the redundancy device through the communication interface to connect the transmit / receive antenna to its RF block.

According to the RFID reader redundancy system of the present invention, in the state in which the RFID reader is duplicated, the system checks whether the currently operating RFID reader is abnormal through various paths and stops the operation of the currently operating RFID reader. Operating other RFID readers can improve the accuracy and reliability of the system.

Hereinafter, an RFID reader duplication system according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic block diagram for explaining the principle of the RFID reader redundancy system of the present invention. As shown in Figure 1, the configuration of the RFID reader redundancy system of the present invention is largely connected to two or more RFID readers (300-1, 300-2) to one middleware 100, such two RFID The readers 300-1 and 300-2 are again connected in common to a single redundancy device 400, and a transmit / receive antenna 500 is connected to an end of the redundancy device 400.

In the above configuration, the middleware 100 and the two RFID readers 300-1 and 300-2 may be interconnected through serial communication, an Ethernet interface, and USB.

2 is a block diagram according to an embodiment of an RFID reader that can be applied to the RFID reader redundancy system of the present invention. As shown in FIG. 2, in the RFID reader redundancy system of the present invention, each RFID reader radiates an RF signal largely toward the tag, and captures an RF signal emitted by the tag, and a predetermined frequency toward the tag. RF module 320 that transmits an RF signal of a band, for example, UHF (900 MHz) band, various types of received from the middleware 100 while adjusting collision between tags and other readers. The digital module 390 may be configured to perform setting items and control commands, and transmit tag information received by communicating with a tag and various state information checked by the tag to the middleware 100.

In the above-described configuration, the digital module 390 again transmits and receives data with the tag, adjusts collisions with other readers when occupying a frequency for communication with the tag, and listens before talk (LBT) or FHSS ( Frequency Hopping Spread Spectrum) and the DAC block 335, RF module (converts the digital data generated by the modem block 350 to the RF module 320 by converting the digital data generated in the modem block 350, etc.) A power block for providing various operating power to the ADC block 330, the RF module 320, and the digital module 390, which converts the analog signal received from the tag through the 320 into digital data and transmits it to the modem block 350. 345, a basic display I / F block 370 including a basic communication interface for performing communication between the status display block 340 for displaying various states of the RFID reader, the middleware 100, and the duplication apparatus 400. ) And line Option host I / F block 375 with an optional communication interface, tag information is transferred to middleware 100 through basic host I / F block 370 and option host I / F block 375, and The processor block 360 may collectively control each block of the digital module 390 including the modem block 350 according to various settings and commands received from the program or the middleware 100.

The modem block 350 may be implemented as a field programmable gate array (FPGA) or a digital signal processor (DSP). The processor block 360 is a microprocessor 364, for example an ARM9 processor, SDRAM 360, flash ROM 368 and program equipment, which are 32-bit RISC processors for embedded devices developed by Advanced RISC Machine (ARM). JTAG 362 may be included. The basic host I / F block 370 again performs Ethernet communication, serial communication such as RS-232 or RS-422, and universal serial bus (USB) communication between the middleware 100 and the redundancy device 400, respectively. It may consist of an Ethernet port 371, a serial port 372, and a USB port 373. The option host I / F block 375 may further include a wireless LAN (WLAN) unit 376 and a code division multiple access (CDMA) unit 377.

In FIG. 2, reference numeral 325 denotes a power check unit for checking whether or not the power supply of the RF module 320 is abnormal. In the microprocessor 362, the power check unit 325 generates an abnormal power supply from the RF module 320. If you receive this will be reported immediately to the middleware (100). In addition, the microprocessor 362 periodically tests for abnormal memory. For example, the microprocessor 362 periodically records any data, for example, 5555h and AAAAh, after recording arbitrary data in an area of 6000h to 600Fh which is a CPU recording area of the SDRAM 366. By checking whether or not the data has been recorded, it is possible to confirm in software whether the memory is abnormal. In addition, by recording 5555h and AAAAh in a predetermined area of the FPGA constituting the modem block 350, for example, the test area, it may be periodically checked whether the modem block 350 is abnormal. And by reporting the result of the confirmation to the middleware 100, the middleware 100 can take the necessary measures.

3 is a block diagram of a duplexing device according to an embodiment of an RFID reader duplexing system of the present invention. As shown in FIG. 3, the redundancy device 400 in the RFID reader redundancy system of the present invention includes a communication interface such as each of the RFID readers 300-1 and 300-2 and a serial port or a USB port. 440 is connected to transmit and receive various status information or control commands. The redundancy device 400 includes a switch 420 and a switch driver driving the switch antenna 420 to selectively connect the transmit / receive antenna 500 to the RF module 320 of each of the RFID readers 300-1 and 300-2. The switch driver 430 is controlled according to a control command received from the RFID readers 300-1 and 300-2 through the communication interface 440 and the communication interface 440 to transmit and receive the antenna 500. 1) or the control unit 410 for alternatively connecting to the reader 2 (300-2).

In the above-described configuration, the switch 420 may be implemented as an electronic switch or a relay, and the controller 410 may be implemented by a conventional microprocessor or the like.

Figure 4 is a block diagram of a duplexing device according to another embodiment of the RFID reader redundancy system of the present invention, the same reference numerals are given to the same parts as the configuration shown in Figure 3 and a detailed description thereof will be omitted. As shown in FIG. 4, the duplexing apparatus 400 ′ according to the present embodiment further includes a transmission output detector 460 for detecting an output strength of an RF signal transmitted through the transmission / reception antenna 500. When the transmission output detected by the transmission output detection unit 460 does not meet the predetermined reference value, the operation 410 issues an operation stop command to the reader currently operating through the communication interface 440, and at the same time to another reader. An operation start command is issued, and a control signal is output to the switch driver 430 to connect the transmission / reception antenna 500 to another reader (a leader instructing operation start).

In the drawing, reference numeral 450 denotes an antenna connection check unit for checking whether the transmit / receive antenna 500 is normally connected. The control unit 410 indicates that the transmit / receive antenna 500 is not normally connected from the antenna connection check unit 450. If you are notified of the fact, indicate it to the user.

5 is a flowchart illustrating the operation of the RFID reader redundancy method according to an embodiment of the present invention. As shown in FIG. 5, first, in step S10, the reader 1 300-1 periodically checks the operating states of various hardware and software, that is, whether the power supply of the RF block 320 is normal, memory, or FPGA. It is checked whether it is in normal operation, and in step S14, it is determined whether or not an abnormality has occurred as a result of this check.

As a result of the determination in step S14, when no abnormality has occurred, the process returns to step S10. When the abnormality has occurred, the process proceeds to step S14 to notify the middleware 100 that the abnormality has occurred. Then, the middleware 100 performs an operation stop command to the reader 1 300-1 by performing step S16, and simultaneously performs an operation start command to the reader 2 300-2 by performing step S18. By this command, the reader 1 300-1 stops the operation, while the reader 2 300-2 performs step S20 to start the operation.

On the other hand, even in this state, since the transmission and reception antenna 500 is connected to the reader 1 (300-1) side, it should be switched to the reader 2 (300-2) side, for this purpose, the reader 2 (300-2) is step S22 To give the switch switching command to the redundancy device (400). Then, the redundant apparatus 400 performs step S24 to switch the transmit / receive antenna 500 to the reader 2 (300-2) side and simultaneously perform the step S26 to notify the reader 2 (300-2) of the fact, Reader 2 300-2 performs step S28 again to notify the middleware 100 of this fact.

6 is a flowchart illustrating the operation of the RFID reader redundancy method according to another embodiment of the present invention. As shown in FIG. 6, in step S40, the middleware 100 periodically transmits a failure check signal to the reader 1 300-1 to determine whether the reader has failed, and again in step S42, the reader 1 ( From 300-1, it is checked whether a normal response according to a predetermined appointment has been reached. As a result of the check in step S42, when the normal response has been reached from the leader 1 300-1, the process returns to step S40, whereas when the normal response has not been reached, step S44 is performed to the reader 1 300-1. Simultaneously with the operation stop command, step S46 is performed to issue an operation start command to the reader 2 (300-2). Since steps S48 to S56 are the same as steps S20 to S28 of FIG. 5, a detailed description thereof will be omitted. The method of the present embodiment can be applied to a system in which the reader is not provided with a power check unit, and can also be applied to the duplexing apparatus shown in FIG.

7 is a flowchart illustrating an operation of an RFID reader duplication method according to another embodiment of the present invention, and shows a duplication method that may be performed by the duplication apparatus shown in FIG. 4. In the present embodiment, the reader 1 300-1 is also operating as described above. As shown in Fig. 7, according to the present embodiment, in step S60, the duplication apparatus 400 'detects the transmission output of the reader 1 300-1, and again in step S62, the detected transmission output is the predetermined reference value. Judge whether or not As a result of the determination in step S62, when the transmission output of the reader 1 300-1 is equal to or greater than the predetermined reference value, the process returns to step S60, whereas when the transmission output of the reader 1 300-1 fails, the process occurs in the reader 1 300-1 by performing step S64. Notify the facts. Then, the reader 1 300-1 that has received such a notification performs the step S66 to notify the middleware 100 of this fact. In response, the middleware 100 performs the step S68 to the reader 1 300-1. At the same time as the operation stop command is issued, operation S70 is issued to the reader 2 (300-2). Hereinafter, since step S72 to step S80 are the same as step S20 to step S28 of FIG. 5, a detailed description thereof will be omitted.

The RFID reader redundancy system of the present invention is not limited to the above-described embodiments, and can be modified and implemented in various ways within the scope of the technical idea of the present invention.

1 is a schematic configuration diagram for explaining the principle of the RFID reader redundancy system of the present invention;

2 is a block diagram according to an embodiment of an RFID reader that can be applied to the RFID reader redundancy system of the present invention;

3 is a block diagram of a duplexing device according to an embodiment of an RFID reader duplexing system of the present invention;

4 is a block diagram of a duplexing device according to another embodiment of an RFID reader duplexing system of the present invention;

5 is a flow chart for explaining the operation of the RFID reader redundancy method according to an embodiment of the present invention;

6 is a flow chart for explaining the operation of the RFID reader redundancy method according to another embodiment of the present invention;

7 is a flowchart illustrating the operation of an RFID reader redundancy method according to another embodiment of the present invention.

*** Explanation of symbols for the main parts of the drawing ***

100: middleware, 300, 300-1, 300-2: RFID reader,

310: antenna, 320: RF module,

330: ADC block, 335: DAC block,

340: status display block, 345: power block,

350: FFGA block, 352: modem section,

354: SDRAM, 360: processor block,

362: JTAG, 364: processor,

366: SDRAM, 368: Flash ROM,

370: basic host I / F block, 371: Ethernet port,

372: serial port, 373: USB port,

375: optional host I / F block, 376: WLAN,

377: CDMA, 390: Digital Module

400, 400 ': redundancy device, 410: control unit,

420: switch, 430: switch drive unit,

440: communication interface, 440: transmission output detection unit,

450: antenna connection check unit, 500: transmit and receive antenna

Claims (4)

delete One middleware; Two or more RFID readers connected to the middleware; A transmit and receive antenna for transmitting and receiving an RF signal, and Is connected to each of the RFID reader by a communication interface, and comprises a single redundancy device for alternatively connecting the transmitting and receiving antenna to any one RF block of the RFID reader, Each of the RFID reader has a function of notifying the middleware by checking whether its own hardware or software is abnormal, When the middleware is notified of the abnormality from the currently operating RFID reader, the middleware issues an operation stop command to the currently operating RFID reader, and issues an operation start command to another RFID reader not currently operating. And the RFID reader receiving the operation start command issues a control command to the duplexing device through the communication interface to connect the transmitting / receiving antenna to its RF block. One middleware; Two or more RFID readers connected to the middleware; A transmit and receive antenna for transmitting and receiving an RF signal, and Is connected to each of the RFID reader by a communication interface, and comprises a single redundancy device for alternatively connecting the transmitting and receiving antenna to any one RF block of the RFID reader, The middleware has a function of periodically transmitting a failure check signal for requesting a predetermined response to the currently operating RFID reader, and stops operating the currently operating RFID reader when receiving a predetermined response from the currently operating RFID reader. At the same time as the command is issued to the other RFID reader that is not currently operating, And the RFID reader receiving the operation start command issues a control command to the duplexing device through the communication interface to connect the transmitting / receiving antenna to its RF block. One middleware; Two or more RFID readers connected to the middleware; A transmit and receive antenna for transmitting and receiving an RF signal, and Is connected to each of the RFID reader by a communication interface, and comprises a single redundancy device for alternatively connecting the transmitting and receiving antenna to any one RF block of the RFID reader, The duplexing device has a function of confirming whether the intensity of the transmission output of the currently operating RFID reader is less than a predetermined reference value and transmitting it to the middleware through the currently operating RFID reader. When the middleware receives the fact that the strength of the transmission output does not reach a predetermined reference value, the middleware issues an operation stop command to the RFID reader currently operating and at the same time gives an operation start command to another RFID reader not currently operating. , And the RFID reader receiving the operation start command issues a control command to the duplexing device through the communication interface to connect the transmitting / receiving antenna to its RF block.

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