KR100655910B1 - method for processing RF ID multi-protocol and RF ID multi-protocol reader - Google Patents

Abstract

The disclosed RF ID multiprotocol processing method and the RF ID multiprotocol reader apparatus scan a protocol of the RF ID tag in which an RF ID reader is located in a read area, and the RF ID tag according to the protocol scanned in the scanning step. It consists of a method and configuration for accessing the information and processing the data.

The RF ID multi-protocol processing method and the RF ID multi-protocol reader device having such a configuration can access information of a plurality of RF ID tags operating in different protocols, such as traffic card, logistics management, ID card, etc. It can provide the foundation to build integrated system of the system, and it can provide the effect that the improvement and expansion of the established RF ID system can be easily done at low cost.

RF ID, Protocol, Reader, Tag, Index, Protocol Scan

Description

Method for processing RF ID multi-protocol and RF ID multi-protocol reader}

1 is a block diagram of an RF ID multi-protocol reader device according to an embodiment of the present invention.

FIG. 2 is a diagram illustrating an index table stored in an RF ID tag read by the RF ID multiprotocol reader device of FIG. 1; FIG.

3 is a flowchart illustrating a method for processing an RF ID multi-protocol according to an embodiment of the present invention.

<Description of Symbols for Major Parts of Drawings>

102 ... Antenna 104 ... Memory

106 ... Modulator 107 ... Frequency Generator

108 ... demodulator 110 ... control unit

The present invention relates to an RF ID multi-protocol processing method and an RF ID multi-protocol reader apparatus, and more particularly, to an RF ID multi-protocol processing method for accessing information of a plurality of RF ID tags operating with different protocols. And an RF ID multi-protocol reader device.

In general, RF ID (RF ID: Radio Frequency Identification) is a contactless RF reader / writer (power reader / writer) transmits power to the RF ID tag that is a data transmission medium, using the transmitted power to process data and mutual It refers to a technology that makes contactless data transmission.

 An RF ID device is composed of an RFID reader, a host computer and an RFID tag called a transponder. Explain the operation process of RF ID device briefly. If the RFID tag with ID and data is stored in the electromagnetic field while the antenna of the RFID reader emits radio waves, the RFID tag is activated to display the ID and data of the RFID reader. Transmit to the antenna.

The antenna of the RFID reader converts the ID transmitted from the RFID tag into a data signal and transmits the ID signal to the computer, and the computer provides the necessary service in comparison with a previously stored database.

RF ID technology is a contactless technology that eliminates the defects of existing barcode and magnetic card devices and replaces them, and its range of application is gradually increasing due to the ease of use and the advancement of the technology. Typical reader's transmitting frequency ranges from 125KHz to 2.4GHz, and the recent 13.56MHz frequency band has become a standard in the RFID field.

The RF ID technology is widely used in public transportation, ticketing, access control, animal recognition, electronic locks, container recognition, sports games, industrial automation, medical field and goods / logistics management.

Articles of the problems of conventional RF ID technology. An example of a logistics management system will be described. Article using RF ID. The logistics management system installs an RF ID tag on an object to be managed, reads the information recorded in the installed RF ID tag, and manages a movement path, contents, and production information of the object to be managed.

By the way, the article using the conventional RF ID. In the logistics management system, the RF ID tag and the reader for reading the information of the RF ID tag are selected and constructed at the same time. Therefore, after the system is constructed, it is impossible to change the RF ID tag to support the new protocol.

In other words, the conventional RF ID reader only supports the selected RF ID tag when the system is built. Therefore, only the RF ID tag supported by the RF ID reader should be used. In order to replace the RF ID tag as necessary, There is a problem that the overall improvement work and the RF ID reader must be replaced together. This requires additional cost to replace the built-in RF ID, and requires much review to improve the built system and to build the initial system.

In addition, the conventional RF ID reader operates only within the range of protocols that can be supported during initial deployment, and since compatibility with the new RF ID tag is not considered at all, it cannot effectively cope with the emerging standard and non-standard protocol market. There is this.

The present invention was created to solve the above problems, and improved RF ID multi-protocol processing method and RF ID multi-protocol reader apparatus to access information of a plurality of RF ID tags operating in different protocols (protocol) To provide that purpose.

In the RF ID multi-protocol processing method of the present invention for achieving the above object, in the RF ID multi-protocol processing method in which the RF ID reader accesses information of a plurality of RF ID tags operating in different protocols, a) scanning by the RF ID reader to scan a protocol of the RF ID tag located within a read area; And b) a data processing step in which the RF ID reader accesses the information of the RF ID tag according to the protocol scanned in the scanning step.

The RF ID multi-protocol reader apparatus of the present invention for achieving the above object, in the RF ID multi-protocol reader apparatus for accessing information of a plurality of RF ID tags operating in different protocols, the RF ID tag An antenna for transmitting power and signals to and detecting a signal transmitted by the RF ID tag; A memory for storing a plurality of protocols including a power supply frequency, a modulation scheme, a bit coding scheme, and data transmission rate information, and providing an index counter corresponding to the protocol; A modulator for modulating a signal to be transmitted to an RF ID tag according to a selected protocol and transmitting the modulated signal to the antenna; A demodulator for demodulating a signal received from the RF ID tag via the antenna as a response to a transmission signal of the modulator; The modulation unit is controlled by one selected from a plurality of protocols stored in the memory, and an attempt is made to establish a communication path with the RF ID tag located in a read area, and the unique path is unique from the RF ID tag with the communication path. After obtaining an identifier (UID), the obtained unique identifier is stored in the index counter, the protocol corresponding to the index counter is checked, and the checked protocol is an RF ID corresponding to the unique identifier stored in the index counter. And a control unit for controlling the modulator and the demodulator to read / write data with respect to a tag.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of an RF ID multi-protocol reader device according to an embodiment of the present invention.

Referring to the drawings, the RF ID multi-protocol reader apparatus according to an embodiment of the present invention comprises an antenna 102, a memory 104, a modulator 106, a demodulator 108 and a controller 110 Can be.

Here, the protocol may be a standard protocol and a non-standard protocol supporting RF ID, and the standard protocol is ISO-15693 or ISO-14443, and the non-standard protocol is I-CODE 1 or It may be a Tag-it HF.

The protocol is preferably configured to include power supply frequency, modulation scheme, bit coding scheme, and data rate information. In the case of ISO-15693, the power supply frequency is 13.56MHz ㅁ 7kHz. In the data transmission from the reader to the tag, the modulation method is 10% ASK or 100% ASK, the bit coding method is 1 of 256 codes (long range mode) or 4 of 1 codes (fast mode), and the data transmission rate is 1.65. Kbit / s (long range mode) or 26.48bit / s (fast mode).

In data transmission from tag to reader, modulation method is load modulation with ASK (423 kHz) or FSK (423/485 kHz) subcarrier, bit coding method is Manchester method, and data transmission rate is 6.62 Kbit / s (long range mode). Or 26.48 Kbit / s.

The ISO-14443, I-CODE 1, and Tag-It HF protocols, like ISO-15693, also include power supply frequency, modulation scheme, bit-coding scheme, and data rate information. This is a known matter and detailed description thereof will be omitted.

The antenna 102 transmits power and signals to an RF ID tag (not shown) and senses the signal transmitted by the RF ID tag.

The memory 104 stores a plurality of protocols including a power supply frequency, a modulation scheme, a bit coding scheme, and data transmission rate information, and provides an index counter corresponding to each protocol.

 Herein, the index counter refers to a memory area allocated corresponding to each protocol, and in one embodiment of the present invention, a unique identifier (UID) of an RF ID tag may be stored. Unique identifiers are described below.

Table 1 exemplifies a case in which an index counter is associated with each protocol.

Index counter protocol One ISO-15693 / FSK / 10% / Fast Mode 2 ISO-15693 / ASK / 100% / Fast Mode 3 ISO-15693 / FSK / 10% / Normal Mode 4 ISO-15693 / ASK / 100% / Normal Mode 5 ISO-14443 / Type A 6 ISO-14443 / Type B 7 ISO-14443 / Type C 8 I-CODE 1 9 Tag-It HF

Referring to Table 1 above, nine index counters are matched with each protocol type. For example, index counter 1 is an area for the protocol of ISO-15693 / FSK / 10% / Fast Mode, and accesses the RF ID tag in the reader's reading area using ISO-15693 / FSK / 10% / Fast Mode. The unique identifier (UID) information of the responding RF ID tag may be stored.

The unique identifier (UID) is an identifier that uniquely identifies a plurality of RF ID tags. The unique identifier constitutes an index table of the RF ID tag along with the protocol type and the tag information.

2 is a diagram illustrating an index table stored in an RF ID tag read by an RF ID multiprotocol reader device according to an embodiment of the present invention. Tag information may include manufacturer, memory capacity, options, and other information.

The modulator 106 modulates a signal to be transmitted to the RF ID tag according to the selected protocol. If the protocol selected by the controller 110 is ISO-15693, the modulator 106 modulates the signal according to the above-described ISO-15693 protocol information such as 13.56 MHz and reads it through the antenna 102. Radiate with an RF ID tag in the area.

The demodulator 108 demodulates the signal received from the RF ID tag through the antenna 102 as a response to the transmission signal of the modulator 106. The RF ID tag in response to the transmission signal of the modulator 106 becomes an RF ID tag operating in the protocol used by the modulator 106. In other words, the RF ID tag responding when the modulator 106 transmits a signal according to the ISO-15693 protocol becomes an RF ID tag operating in the ISO-15693 protocol.

The modulator 106 and the demodulator 108 further include a frequency generator 107 for generating a carrier wave. The frequency generator 107 generates a carrier defined in the protocol selected by the controller 110, and when the protocol selected by the controller 110 is ISO-15693, the frequency generator 107 generates a carrier of 13.56 MHz frequency.

The control unit 110 controls the modulation unit 106 with one selected from a plurality of protocols stored in the memory 104, attempts to set up an RF ID tag and a communication path located in the read area, and the communication path is After obtaining a unique identifier (UID) from the set RF ID tag through the demodulator 108, the obtained unique identifier is stored in an index counter.

The control unit 110 checks the protocol corresponding to the index counter, and reads / writes data with respect to the RF ID tag corresponding to the unique identifier stored in the index counter. The control unit 106 and the demodulation unit 108 are controlled.

As a result, the RF ID multi-protocol reader according to an embodiment of the present invention can access information of a plurality of RF ID tags operating in different protocols. The operation of the RF ID multiprotocol reader will be described in more detail in the following RF ID multiprotocol processing method.

The control unit 110 may further include an interface unit 120 connected to an external computer, a display unit 122 displaying a state of a reader device externally, and a power management unit 124 providing operating power of the reader device. have.

The RF ID multi-protocol reader device according to an embodiment of the present invention transmits only a power amplifier 126, a carrier, and a modulated signal that control the output of a modulated signal through the modulator 106. A narrow band band pass filter 128 for filtering the signal, a gain controller 130 for converting the received signal into a demodulated range signal, and a signal received from the RF ID tag. It is preferred to further include a low noise amplifier 132 for amplifying and a wide band ban pass filter 134 for receiving signals from various types of RF ID tags.

In this case, the controller 110 may control the power amplifier 126 and the gain adjuster 130 to adjust the output modulation degree and the input sensitivity according to the RF ID tag type. The components such as the narrowband bandpass filter 128, the low noise amplifier 132, and the wideband bandpass filter 134 are similar to those of operating in a general wireless communication system, and thus detailed description thereof will be omitted.

The RF ID multi-protocol reader device according to the embodiment of the present invention may further include an impedance matching unit 136 in order to minimize the constraints according to the characteristics of the antenna 102.

Hereinafter, an RF ID multiprotocol processing method according to an embodiment of the present invention will be described. The plurality of protocols stored in the memory 104 are nine protocols described in Table 1, and the RF ID tag will be described with an example of supporting I-CODE 1 among the nine protocols.

3 is a flowchart illustrating an RF ID multi-protocol processing method according to an embodiment of the present invention.

Referring to the drawings, the RF ID multi-protocol processing method according to an embodiment of the present invention may include a scanning step (S100) and a data processing step (S200).

The scanning step (S100) is a step in which the RF ID reader scans the protocol of the RF ID tag located in the read area.

In this step, the controller 110 attempts to set an RF ID tag and a communication path located in the read area as one protocol selected from a plurality of protocols stored in the memory 104. The method of selecting one protocol among a plurality of protocols is preferably sequential, but is not limited thereto, and may be another selection method such as random.

When the control unit 110 selects a protocol through a sequential method, the control unit 110 first performs the procedure of ISO-15693 / FSK / 10% / Fast Mode protocol, ISO-15693 / ASK / 100% / Fast Mode, etc. Therefore, the modulator 106 or the like is controlled to attempt communication with the RF ID tag in the read area.

In this embodiment, since the RF ID tag conforms to the I-CODE 1 protocol, the RF ID reader has no response until the controller 110 attempts to communicate with the RF ID tag according to the seventh ISO-14443 / Type C protocol. You will not receive.

When the controller 110 attempts to communicate with the RF ID tag according to the 8th I-CODE 1 protocol, the control unit 110 matches the protocol followed by the RF ID tag. Therefore, the control unit 110 establishes a communication path with the RF ID reader and the RF ID tag. do.

When the communication path is established with the RF ID tag, the RF ID reader obtains a unique identifier (UID) from the RF ID tag through the established communication path, and stores the obtained unique identifier in the index counter. As such, the RF ID reader acquires a protocol and unique identifier that can access any RF ID tag located within the read area.

The protocol scan step S110 may be made of a separate protocol scan routine. The protocol scan routine includes protocol selection step S112, unique identifier acquisition step S114, index counter increment step S115 (index counter initial value = 0), unique identifier storage step S116, and index counter return step S118. It can be made, including.

The index counter increment step S115 may be located after the unique identifier storage step 116, where the initial value of the index counter is preferably 1. In the index counter returning step (S118), a result of accessing the RF ID tag using the selected protocol is returned (index counter in which the UID is stored).

In the protocol scan routine, if the protocol selected by the RF ID reader and the protocol followed by the RF ID tag do not match, the RF ID reader cannot obtain the unique identifier of the RF ID tag, so the value stored in the index counter is 0 or null. Becomes

If the protocol selected by the RF ID reader and the protocol followed by the RF ID tag match, the RF ID reader obtains a unique identifier of the RF ID tag, stores it in an index counter, and returns it to the main routine.

At this time, the RF ID controller 110 checks whether there is a value (here UID) stored in the index counter returned from the protocol scan routine (S120), and if there is no value corresponding to the unique identifier in the index counter, the protocol scan routine is executed again. If there is a value corresponding to the unique identifier in the index counter, it is preferable to proceed to the next step.

The data processing step (S200) is a step in which the RF ID reader accesses the information of the RF ID tag according to the protocol scanned in the scanning step.

In this step, the RF ID reader checks the protocol type corresponding to the index counter (S210). For example, if the index counter 8 is returned from the protocol scan routine, and the unique identifier of the RF ID tag is stored in the index counter, the protocol followed by the RF ID tag is I-CODE 1 stored in the eighth position in memory. Able to know.

Finally, the RF ID reader is a checked protocol type (in this case, I-CODE 1 protocol) that reads data from or writes data to or from the RF ID tag corresponding to the unique identifier stored in the index counter. (S220).

In other words, the RF ID reader obtains the unique identifier of the RF ID tag in the read area and the protocol information followed by the RF ID tag through the index counter.

This allows the RF ID reader to access the information of a plurality of RF ID tags operating in different protocols.

As described above, the RF ID multi-protocol processing method and the RF ID multi-protocol reader apparatus of the present invention can access information of a plurality of RF ID tags operating in different protocols. It provides the foundation to build integrated system such as card and provides the effect that the improvement and expansion of the established RF ID system can be easily done at low cost.

It is to be understood that the invention is not limited to that described above and illustrated in the drawings and that many more modifications and variations are possible within the scope of the following claims.

Claims (8)

In the RF ID multi-protocol processing method for accessing information of a plurality of RF ID tags operating in different protocols, a) a scan step in which an RF ID reader scans a protocol of the RF ID tag located in a read area; b) a data processing step in which the RF ID reader accesses the information of the RF ID tag according to the protocol scanned in the scanning step, Step a) a1) attempting to establish a communication path with the RF ID tag located in a read area in one of the protocols selected from among the plurality of protocols; a2) obtaining a unique identifier (UID) from an RF ID tag having a communication path established in step a1); And a3) storing the unique identifier obtained in step a2) in an index counter, Step b) b1) checking a protocol type corresponding to the index counter; And b2) reading / writing data to an RF ID tag corresponding to a unique identifier stored in the index counter, using the checked protocol type; The protocol is one selected from a plurality of protocols consisting of a standard protocol and a non-standard protocol, The unique identifier is an identifier that uniquely identifies the RF ID tag, and configures an index table of the RF ID tag along with a protocol type and tag information. And the index counter corresponds to one protocol selected from the protocol group. The method of claim 1, The protocol is an RF ID multi-protocol processing method comprising a power supply frequency, a modulation scheme, a bit coding scheme, and data rate information. delete delete delete delete delete An RF ID multiprotocol reader apparatus for accessing information of a plurality of RF ID tags operating in different protocols, An antenna for transmitting power and signals to the RF ID tag and sensing a signal transmitted by the RF ID tag; A memory for storing a plurality of protocols including a power supply frequency, a modulation scheme, a bit coding scheme, and data transmission rate information, and providing an index counter corresponding to the protocol; A modulator for modulating a signal to be transmitted to an RF ID tag according to a selected protocol and transmitting the modulated signal to the antenna; A demodulator for demodulating a signal received from the RF ID tag via the antenna as a response to a transmission signal of the modulator; And The modulation unit is controlled by one selected from a plurality of protocols stored in the memory, and an attempt is made to establish a communication path with the RF ID tag located in a read area, and the unique path is unique from the RF ID tag with the communication path. After acquiring an identifier (UID), the obtained unique identifier is stored in the index counter, and the protocol corresponding to the index counter is checked. With the checked protocol, an RF corresponding to the unique identifier stored in the index counter is obtained. A control unit controlling the modulator and the demodulator to read / write data with respect to an ID tag; RF ID multi-protocol reader device characterized in that comprises a.

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