KR100747984B1 - Rfid reader and method for reading rfid tags with different protocols - Google Patents

Abstract

A multi-protocol RFID reader and a method thereof are provided to realize a fast response speed while supporting a multi-protocol by preferentially reading RFID using the most frequently used protocol among a plurality of protocols based on a priority table and reduce gap between reading times using each protocol by alternatively reading the RFID with the protocols having a different frequency band. An HF(High Frequency) circuit(106) exchanges information with an RFID tag through an HF band and processes a signal transceived in the HF band. A UHF(Ultrahigh Frequency) circuit(109) exchanges the information with the RFID tag through a UHF band and processes the signal transceived in the UHF band. A controller(103) repeats a process for reading the RFID tag by reading the top priority protocol of the priority table and reading the RFID tag by reading the next priority protocol if the RFID tag is not read by the top priority protocol. If the RFID tag is read, the controller processes the information read from the RFID tag and repeats the process after adjusting the priority.

Description

Multiprotocol RFID reader and its method {RFID reader and method for reading RFID tags with different protocols}

1 is an internal configuration diagram of an RFID reader of the present invention.

2 is a view showing an output timing diagram of a data signal according to each protocol in the RFID reader of the present invention.

3 is a flowchart illustrating a multi-protocol processing procedure of an RFID reader.

4 is a view showing a form for adjusting the priority, FIG. 4 (a) shows a circular queue and FIG. 4 (b) shows priority among protocols loaded in the circular queue. Figure 4 (c) is a view showing a state in which the priority of the protocol rearranged according to the frequency.

<Explanation of symbols on main parts of the drawings>

103-control unit 106-HF circuit unit

109-UHF circuit section

The present invention relates to a multiprotocol RFID reader and a method thereof.

An RFID (Radio Frequency Identification) tag is an electronic system attached to (embedded) an object or a person, and is generally composed of an electronic chip (ubiquitous chip) for granting a computing function and an antenna for granting a wireless communication function. In an RFID system, data stored in an RFID tag is read by an RFID reader and provided to a host system (data center or database) through a network, and the host system recognizes and judges this to provide an appropriate service.

Normally, the RFID system operates in a frequency range of 2 MHz to 14 MHz (HF), 850 MHz to 950 MHz (UHF), or 2.3 GHz to 2.6 GHz (microwave). Various protocols exist depending on the frequency band used.

In the conventional RFID reader, multi-protocol reading is possible only in some HF (13.56 MHz) bands, and even in the UHF (900 MHz) bands, the protocol response in the corresponding bands is possible only by changing settings externally. There was a problem that the response speed is lowered, and there is a problem that multi-read is not possible in protocols of different frequency bands.

An object of the present invention is to provide a multi-protocol RFID reader capable of multi-reading in different frequency bands and a method thereof.

It is still another object of the present invention to provide a multiprotocol RFID reader and a method for supporting multiprotocol while improving recognition rate and haptic response speed.

The multi-protocol processing method in the multi-protocol-readable RFID reader of the present invention determines a protocol to be used to read RFID using a priority table that records the priority of each protocol. First, the protocol of the highest priority is read from the priority table and the RFID is read as the protocol. If RFID is not read according to this protocol, the above procedure is repeated after reading the next priority protocol in the priority table. When RFID is read according to this protocol, the above process is repeated after processing the read tag information and adjusting the priority. In this case, the protocol includes protocols of different frequency bands, and the frequency band may include a UHF (900 MHz) band and an HF (13.56 Hz) band.

Priority adjustment is adjusted by loading the read protocols into a circular queue and placing the highest number of protocols loaded into the circular queue as the highest priority protocol. Alternatively, the read protocol may be adjusted by loading it into a circular queue and prioritizing the protocols in the order of the number of protocols loaded in the circular queue. Alternatively, it is possible to increase the frequency of the read protocols by one, and then rearrange and adjust the priority of each protocol according to the frequency of each protocol. At this time, the priority is preferably configured so that the protocol of the HF band and the protocol of the UHF band appear alternately. In this case, when the priority is readjusted, the priority of protocols in the same frequency band is readjusted.

In addition, the multi-protocol read-ready RFID reader of the present invention transmits and receives information through an RFID tag (Tag) through a high frequency band, and a high frequency (HF) circuit unit for processing a signal transmitted in the high frequency band, RFID tag (Tag) Ultra High Frequency (UHF) circuit part that transmits and receives information through the microwave band and processes the signal transmitted in the microwave band, and reads the highest priority protocol from the priority table, and reads the RFID with the corresponding protocol and RFID according to the corresponding protocol. If it is not read, control to repeat the above process after reading the protocol of the next priority in the priority table, and control the process to repeat the above process after processing the tagged information and adjusting the priority when RFID is read by the protocol. It is configured to include a control unit. In this case, the protocol includes protocols of different frequency bands, and the frequency band includes a UHF (900 MHz) band and an HF (13.56 Hz) band.

The control unit controls to adjust the priority by loading the read protocol to the circular queue, and by placing the highest number of protocols loaded in the circular queue as the highest priority protocol, or the read protocol to the circular queue ( It controls to adjust the priority by loading in Circular Queue and prioritizing the number of protocols loaded in Circular Queue. In addition, after increasing the frequency of the read protocol by one, it is possible to control to adjust the priority while relocating the priority of the protocol according to the frequency. At this time, the priority is configured such that the protocol of the HF band and the protocol of the UHF band appear alternately, and when the priority is readjusted, the priority of protocols of the same frequency band is readjusted.

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

1 is an internal configuration diagram of an RFID reader of the present invention, and FIG. 2 is a diagram illustrating an output timing diagram of a data signal according to each protocol in the RFID reader of the present invention.

The RFID reader includes a high frequency (HF) circuit portion, an ultra high frequency (UHF) circuit portion, and a controller.

The HF (High Frequency) circuit unit 106 exchanges information with an RFID tag through a high frequency band and processes a signal transmitted in the high frequency band. At this time, the frequency band of the HF circuit unit is 13.56MHz band can support protocols such as ISO / IEC 14443A / B, 15693, Felica.

 UHF (Ultrahigh Frequency) circuit unit 109 transmits and receives information through the microwave band, and processes the signal transmitted in the microwave band. At this time, the frequency band of the UHF circuit unit is a 900MHz band, it can support protocols such as ISO / IEC 18000-6A / B, EPC Class0, Class 1, Gen 2.

The controller 103 stores and manages a priority table that records the order of protocols to be used when reading the RFID tag. The controller 103 reads the protocol having the highest priority from the priority table, and controls to read the RFID using the protocol. In addition, if the RFID is not read by the corresponding protocol, control is to repeat the above process after reading the protocol of the next priority in the priority table.If the RFID is read by the protocol, the read tag information is processed and priority is adjusted by adjusting the priority. Record on the leaderboards.

Various methods can be used to adjust the priority. For example, the priority can be managed using a circular queue. That is, the controller 103 loads the read protocol into the circular queue each time the RFID tag is read, and sets the priority by setting the highest number of protocols among the protocols loaded in the circular queue as the highest priority protocol. The priority can be adjusted by controlling to adjust, or by loading the read protocols to the annular queue and prioritizing the number of protocols loaded in the annular queue in order.

Alternatively, you can use a table that stores the frequency of each protocol. That is, the controller 103 increases the frequency of the read protocol by one in the frequency table each time the RFID tag is read, and then adjusts the priority while relocating the priority of each protocol according to the frequency of each protocol recorded in the table. It is also possible.

At this time, the priority is preferably configured to appear alternately between the protocol of the HF band and the protocol of the UHF band. In addition, when the priority is readjusted, the protocols of the same frequency band are readjusted. For example, if the first highest priority protocol was the HF band protocol, then the next loaded protocol would be the UHF band protocol and the next loaded protocol would be the HF band protocol, alternating with each band protocol. It is configured to appear. At this time, if the frequency of read protocols is increased, priority is re-adjusted. Protocols in the HF band adjust the priorities of protocols in the HF band, and protocols in the UHF band are readjusted among the protocols in the UHF band. .

At this time, when adjusting the priority, the reason for configuring the HF band protocol and the UHF band protocol alternately is as follows.

As shown in FIG. 2, when transmitting and receiving each data message in one frequency band, a time gap must be provided at the start and end of transmission of respective tags due to the tolerance ranges of the circuit components. . For example, as shown in FIG. 2, there is a problem that a predetermined time difference must be provided until the data transmission in Tag 1 is terminated and new data transmission in Tag 2 is performed, and thus the data transmission speed is lowered. However, if data transmission of Tag 5 in another frequency band starts when Tag 1 data transmission is terminated in one frequency band, a circuit separate from the circuit for the first frequency band is used. This gap can be overcome to improve the data transfer rate. Therefore, it is preferable to configure such that the protocol of the HF band and the protocol of the UHF band appear alternately.

Next, a multiprotocol processing procedure of an RFID reader in a multiprotocol readable RFID reader according to the present invention will be described.

FIG. 3 is a flowchart illustrating a multi-protocol processing process of an RFID reader, and FIG. 4 is a diagram illustrating a form for adjusting priority. FIG. 4A is a diagram illustrating a circular queue. 4 (b) is a diagram showing the prioritization of the protocols loaded in the annular queue, Figure 4 (c) is a view showing the rearrangement of the priorities of the protocols according to the frequency.

If the priority protocol is read from the priority table (step 303), then RFID is read with the protocol (step 306). In this case, depending on whether the RFID is read as a protocol (step 309), if the protocol is not read (no at step 309), the protocol of the next priority in the priority table is read (step 309), and the above process is repeated. If the RFID is read by the corresponding protocol (YES in step 309), the read tag information is processed and the priority is adjusted (step 315), and then the input information is processed and the above process is repeated (step 318). In this case, the protocols may include protocols that operate in different frequency bands, such as the UFH (900 MHz) band and the HF (13.56 Hz) band.

At this time, the priority can be adjusted in various ways. First, there is a method of adjusting the priority using an annular queue as shown in FIG. Circular Queue is a form of data storage. When accessing, such as deleting, adding, or updating, it transforms a queue that is processed from the input information first, and the corresponding input and output are processed. It is a form connected in the form of a circle conceptually as shown in FIG. After the information is processed at a specific location, the indexes of the information to be processed are moved one by one in a counterclockwise direction. Using the annular queue, the protocol read when the priority is adjusted in step 315 is loaded into the circular queue, and the priority is adjusted by putting the highest number of protocols among the protocols loaded in the annular queue as the highest priority protocol. It is.

Alternatively, the priority may be adjusted by loading the protocol read in step 315 into the circular queue and prioritizing the protocols in the order of the number of protocols loaded in the circular queue. In this case, the priority is preferably configured such that the protocol of the HF band and the protocol of the UHF band alternately appear as described above. When the priority is readjusted, the priority of protocols of the same frequency band is readjusted.

For example, as shown in (b) of FIG. 4, the protocol of the HF band is assigned to the odd priority and the protocol of the UHF band is assigned to the even priority. Of course, the reverse arrangement is also possible. Then, as the RFID tag is read out, the frequency of the protocols to be read is changed. Accordingly, when the priority is readjusted, the protocols of the HF band are adjusted and the protocols of the UHF band are adjusted. For example, if the frequency of protocol 6 is greater than that of protocol 1 and protocol 5, then protocol 6 is not replaced with protocol 1, but with protocol 5, which is a protocol in the same UHF band.

In addition, as shown in (c) of FIG. 4, after increasing the frequency of the protocol read in step 315, it is possible to adjust the priority while rearranging the priority of the protocols according to the frequency. In other words, when RFID is read according to a specific protocol, the frequency of the corresponding protocol is increased by one and accumulated, and the cumulative frequency is rearranged and adjusted in order of highest order. For example, as shown in (c) of FIG. 4, if the frequency of protocol 1 is 100, the frequency of protocol 2 is 15, and the frequency of protocol 9 is 20, protocol 1 having a frequency of 100 is the first priority and has a frequency of 20. Coordination is made by placing Protocol 9 as the second priority and Protocol 2 as the third priority. Also in this case, it is preferable to adjust the ranking of protocols of the same frequency band.

As mentioned above, although this invention was demonstrated to the several example, this invention is not limited to a specific Example. Those skilled in the art will appreciate that various modifications and changes can be made without departing from the spirit of the invention.

The present invention reads RFID using the most frequently used protocol among the plurality of protocols first by using a priority table, and thus has an effect that the response speed is increased while supporting multi-protocol. In addition, since RFID is read using alternating frequency band protocols, the gap between read times using each protocol can be reduced.

Claims (16)

An RFID reader capable of multiprotocol reading, A first step of reading the highest priority protocol from the priority table; A second step of reading RFID by the corresponding protocol; A third step of repeating the process from the second step after reading the protocol of the next order in the priority table if the RFID is not read as the corresponding protocol; A fourth step of repeating the process from the first step after processing the read tag information and adjusting the priority when RFID is read by the corresponding protocol; Multi-protocol processing method of the RFID reader comprising a. The method of claim 1, Wherein said protocol comprises protocols of different frequency bands. The method of claim 2, The frequency band is a multi-protocol processing method of the RFID reader comprising a UHF (900MHz) band and HF (13.56Hz) band. The method of claim 1, Priority adjustment in the fourth stage, Loading the read protocol into a circular queue, Placing the highest number of protocols among the protocols loaded in the annular queue as the highest priority protocol; Multi-protocol processing method of the RFID reader comprising a. The method of claim 1, Priority adjustment in the fourth step, Loading the read protocol into a circular queue, The multi-protocol processing method of an RFID reader which assigns priority in order of the number of protocols loaded in a circular queue. The method of claim 1, Priority adjustment in the fourth step, And increasing the frequency of the read protocols by one, and then rearranging the priority of each protocol according to the frequency. The method according to any one of claims 4 to 6, The priority is configured to appear alternately between the protocol of the HF band and the protocol of the UHF band. The method of claim 7, wherein When the priority is readjusted, priorities of protocols of the same frequency band are readjusted. An HF (High Frequency) circuit unit for transmitting and receiving information to and from an RFID tag through a high frequency band, and processing a signal transmitted in a high frequency band; Ultra high frequency (UHF) circuit unit for transmitting and receiving information through the RFID tag and the microwave band, and processing the signal transmitted in the microwave band, Read the protocol of the highest priority from the priority table, if the RFID is read by the protocol and if the RFID is not read by the protocol, control to repeat the above process after reading the protocol of the next priority in the priority table, and the RFID with the protocol A control unit which controls to repeat the above process after processing the read tag information and adjusting the priority when is read; Multiprotocol RFID reader comprising a. The method of claim 9, Wherein said protocol comprises protocols of different frequency bands. The method of claim 10, The frequency band includes a UHF (900MHz) band and HF (13.56Hz) band. The method of claim 9, The control unit controls to adjust the priority by loading the read protocol to the circular queue (Queue), and by placing the highest number of protocols loaded in the circular queue as the highest priority protocol. The method of claim 9, The control unit controls to adjust the priority by loading the read protocol to the circular queue (U) and prioritizes the order of the number of protocols loaded in the circular queue. The method of claim 9, The control unit increases the frequency of the read protocol by one, and then controls to adjust the priority while relocating the priority of the protocol according to the frequency. The method according to any one of claims 12 to 14, Wherein the priority is configured to alternate between the protocol of the HF band and the protocol of the UHF band. The method of claim 15, When the priority is readjusted, the protocols of the same frequency bands are readjusted prior to each other.

Images