KR20100128880A - Active radio frequency identification multi hop relay system and tags recognition method - Google Patents

Abstract

PURPOSE: An active radio frequency identification multi hop relay system and a tag recognizing method are provided to relay RF signal transceiving between an RFID reader and tags through at least one relay tag, thereby increasing a recognition distance of the RFID reader. CONSTITUTION: At least one RFID reader(110) generates an RF signal necessary for tag recognition. At least one first area relay tag(131~133) is located within the first recognition distance. If the RF signal is received from the RFID reader, the first area relay tag transmits the RF signal to the second area tag(122~127) out of the first recognition distance. If tag data is received from the second area tag, the first area relay tag transmits the tag data to the RFID reader.

Description

Active Radio Frequency IDentification multi hop relay system and tags recognition method

The present invention relates to an active RFID multi-hop relay system and a tag recognition method thereof, and more particularly, to an active RFID multi-hop relay system and a tag recognition method for increasing a recognition distance of an RFID reader. will be.

The RFID system is a non-contact recognition system that attaches a small tag to various items and transmits and processes information of an object and surrounding environment information at a radio frequency. The process of recognizing the tag by the RFID reader is performed in a manner in which the tag receiving the signal responds when the RFID reader outputs a radio signal through the antenna.

1 is a view showing an RFID system according to the prior art. Referring to FIG. 1, the RFID system 10 includes an RFID reader 11 and first to fourth tags 12, 13, 14, and 15.

When the RFID reader 11 transmits an RF signal requesting tag information, the tag located within the recognition distance A of the RFID reader 11 reads the tag data and transmits the tag data to the RFID reader 11. . Specifically, the RF signal generated by the RFID reader 11 is transmitted only to the first tag 12 and the second tag 13 located within the recognition distance A. FIG. As a result, the RFID reader 11 receives only the tag data of the first tag 12 and the second tag 13 and attaches to the third tag 14 and the fourth tag 15 not located within the recognition distance A. FIG. It will not be recognized. As described above, there is a problem that the tag recognition rate is low depending on the recognition distance limit of the RFID reader 11. Therefore, a method of improving the tag recognition rate by increasing the recognition distance of the RFID reader 11 is required.

The present invention is to solve the above problems, an object of the present invention, by providing a RFID reader and at least one relay tag for relaying the transmission and reception of RF signals for at least one tag, thereby increasing the recognition distance of the RFID reader The present invention relates to an active RFID multi-hop relay system and a tag recognition method capable of improving a tag recognition rate.

RFID system according to an embodiment of the present invention for achieving the above object, a plurality of tags attached to a predetermined recognition target, and storing tag data, at least for generating an RF signal required for the tag recognition At least one RFID reader and a first recognition distance recognizable by the RFID reader, and when the RF signal is received from the RFID reader, the second area tag located outside the first recognition distance among the plurality of tags. The at least one first area relay tag transmits an RF signal and transmits the tag data to the RFID reader when tag data is received from the second area tag.

In addition, the first area tag located within the first recognition distance among the plurality of tags may read stored tag data and transmit the read tag data to the RFID reader.

The active RFID multi-hop relay system further includes at least one or more second area relay tags that transmit and receive signals with the first area relay tag and are located within a second recognition distance that the first area relay tag can recognize. can do.

Here, when the RF signal is received from the first area relay tag, the second area relay tag is transmitted to a tag located outside the second recognition distance among the plurality of tags, and when tag data is received from the third area tag. The first area relay tag may be transmitted.

The first and second area relay tags may include a reader transceiver for transmitting and receiving signals to and from the RFID reader, a relay tag transceiver for transmitting and receiving signals to and from another area relay tag, a tag transceiver for transmitting and receiving signals to and from the at least one tag, and When tag data is received through a tag transceiver, the storage unit may include a storage unit for storing the tag data and a power supply unit for supplying power.

The RFID reader may store the tag data when tag data is received from the first area relay tag or the first area tag.

The RF signal includes a wake-up signal for switching the plurality of tags from a sleep mode to a wake-up mode, a tag data request signal for requesting tag data stored in the plurality of tags, and the plurality of tags. Preferably, the tag is any one of sleep signals for switching from the wakeup mode to the sleep mode.

On the other hand, the tag recognition method of the active RFID multi-hop relay system according to an embodiment of the present invention, the RF signal generated by the RFID reader for tag recognition, located within a first recognition distance that the RFID reader can recognize A first step of transmitting to a first area tag and a first area relay tag, a second step of transmitting the RF signal to a second area tag in which the first area relay tag is located outside the first recognition distance, and the first step A third step of transmitting tag data read from an area tag to the RFID reader, a fourth step of transmitting tag data read from the second area tag to the first area relay tag, and a first of receiving the tag data And a fifth step of the area relay tag transmitting the tag data to the RFID reader.

In this case, the second step is the RF to the second area relay tag, the first area relay tag is located outside the first recognition distance and within a second recognition distance that can be recognized by the first area relay tag. It may include transmitting a signal.

In the tag recognition method of the present invention, a sixth step of transmitting the RF signal to a third area tag in which the second area relay tag receiving the RF signal is located outside the second recognition distance, is read from the third area tag. The method may further include a seventh step of transmitting the tagged data to the second area relay tag, and an eighth step of transmitting the second area relay tag to the first area relay tag when the tag data is received.

The third step may include storing the tag data when the tag data transmitted from the first area tag is received by the RFID reader.

On the other hand, the fifth step may include the step of storing the tag data in the RFID reader tag data transmitted from the first area relay tag.

The RF signal includes a wake-up signal for switching the plurality of tags from a sleep mode to a wake-up mode, a tag data request signal for requesting tag data stored in the plurality of tags, and the plurality of tags. Preferably, the tag is any one of sleep signals for switching from the wakeup mode to the sleep mode.

According to the present invention, it is possible to increase the recognition distance of the RFID reader by relaying RF signals between the RFID reader and the plurality of tags using at least one relay tag. Accordingly, the tag recognition rate of the RFID reader can be improved by transmitting an RF signal to a tag that is outside the recognition distance of the RFID reader through the relay tag, receiving tag data from the RFID tag, and transmitting the tag data to the RFID reader.

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

2 is a diagram illustrating an active RFID multi-hop relay system according to an embodiment of the present invention. The active RFID multi-hop relay system 100 shown in FIG. 2 includes an RFID reader 110, first to seventh tags 121, 122, 123, 124, 125, 126, and 127 and first to first agents. And four relay tags 131, 132, 133, and 134.

In the active RFID multi-hop relay system 100 shown in FIG. 2, RF signals and data transmission and reception operations may be performed by supplying power to the first to seventh tags 121 to 127. Active RFID multi-hop relay system 100 of this nature is the RFID reader 110, the first to seventh tag (121 to 127), and the first to the first through the wireless interface standard of ISO / IEC 18000-7 Wireless communication between the fourth relay tags 131 to 134 is performed.

The RFID reader 110 transmits an RF signal to an RFID tag (hereinafter referred to as a "tag") attached to a predetermined article and collects tag data from the tag, thereby recognizing a tag located nearby. In this case, the tag data refers to the tag itself ID and information (article name, article identification number, article location), etc. on the article to which the tag is attached, and may include all information about the article and the tag.

On the other hand, in the RFID multi-hop relay system 100, the RFID reader 110 generates and transmits an RF signal. In this case, the RF signal is a wake-up signal for switching the first to seventh tags 121 to 127 from a sleep mode to a wake-up mode, and the first to seventh tags 121 to 127. ) May be any one of a tag data request signal for requesting tag data stored in the CDMA signal and a sleep signal for switching the first to seventh tags 121 to 127 from a wakeup mode to a sleep mode.

The RFID reader 110 generates an RF signal and transmits the RF signal to the first area tag and the first area relay tag located within the first recognition distance A that the RFID reader 110 can recognize. In this case, the first recognition distance A is a distance at which the RFID reader 110 can recognize a tag (or a relay tag) located nearby, that is, an RF signal is transmitted to the tag (or a relay tag) so that the tag can be recognized from the tag. The distance within which a response signal can be received.

In addition, the first area tag refers to all tags located within the first recognition distance A. In FIG. 2, the first tag 121 may correspond. In addition, the first area relay tag also means all relay tags located within the first recognition distance A, and the first relay tag 131, the second relay tag 132, and the third relay tag 133 correspond to each relay tag. can do.

Meanwhile, when an RF signal is received, the first tag 121 corresponding to the first area tag performs an operation corresponding thereto. For example, when the RF signal is a wakeup signal, the first tag 121 switches from the sleep mode to the wakeup mode, and when the RF signal is the tag data request signal, the tag data stored in the first tag 121. Read and transmit it to the RFID reader (110). In addition, when the RF signal is a sleep signal, the first tag 121 switches from the wakeup mode to the sleep mode. As such, the RFID reader 110 and the first tag 121 transmit and receive RF signals without a separate relay tag to perform 1-hop communication.

When the RF signal is received, the first to third relay tags 131 to 133 corresponding to the first area relay tag are located outside the first recognition distance A and within the second recognition distances B, C, and D. To the second area tag. That is, it transmits to tags located in an area between the first recognition distance A and the second recognition distances B, C, and D.

In this case, the second recognition distance and the second area tag may vary according to the relay tag. In detail, the second recognition distance of the first relay tag 131 is an area B, and the second area tag of the first relay tag 131 is a second tag 122 located within the second recognition distance B. FIG. . In addition, the second recognition distance of the second relay tag 131 is a region C, and the second region tag of the second relay tag is the third and fourth tags 123 and 124 positioned within the second recognition distance C. FIG. . The second recognition distance of the third relay tag 131 is a region D, and the second region tag of the second relay tag is a fifth tag 125 located within the second recognition distance D. FIG.

When the second to fifth tags 122 to 125 receive an RF signal from each of the first area relay tags, the second to fifth tags 122 to 125 may perform operations corresponding thereto. If the RF signal is a tag data request signal, the second to fifth tags 122 to 125 read the stored tag data and transmit the stored tag data to the first area relay tag. Accordingly, two-hop communication of the RF signal between the RFID reader 110 and the second to fifth tags 122 to 125 located outside the first recognition distance A using the first area relay tag. As a result, the recognition distance of the RFID reader 110 may be increased.

In addition, when the RF signal is received, the first to third relay tags 131 to 133 corresponding to the first area relay tag are located outside the first recognition distance A and the second recognition distances B, C, and D. It transmits to the 2nd area relay tag located in the inside. In FIG. 2, the fourth relay tag 134 may correspond to the second region relay tag.

When the fourth relay tag 134 receives an RF signal from the third relay tag 133 corresponding to the first region relay tag, the fourth relay tag 134 is located in an area that can be recognized by the fourth relay tag 134. Send to tag. That is, the data is transmitted to tags located outside the second recognition distance D and located within the third recognition distance E. FIG.

The sixth tag 126 and the seventh tag 127 may correspond to the third area tag. As such, by using the third and fourth relay tags 133 and 134 to relay the RF signal between the RFID reader 110 and the sixth and seventh tags 126 and 127 in three-hop communication, the RFID reader It is possible to increase the recognition distance of 110.

Meanwhile, the RFID reader 110, the second to seventh tags 122 to 127, and the first to fourth relay tags 131 to 134, which perform one-hop communication, two-hop communication, and three-hop communication, use TDMA. (Time Division Multiple Access) / TDD (Time Division Duplex) scheme is used.

3 is a block diagram illustrating a configuration of a first relay tag according to an embodiment of the present invention. Referring to FIG. 3, the first relay tag 131 includes a reader transceiver 131a, a relay tag transceiver 131b, a tag transceiver 131c, a storage 131d, and a power supply 131e.

The reader transceiver 131a receives an RF signal from the RFID reader 110 or transmits tag data to the RFID reader 110.

In addition, the relay tag transceiver 131b transmits and receives an RF signal to and from another relay tag located within a recognizable recognition distance. The tag transceiver 131c transmits / receives an RF signal with at least one tag located within a recognition distance that can be recognized by the first relay tag 131.

The storage unit 131d stores data generated in the process of relaying an RF signal between the RFID reader 110 and the tags. In particular, the storage unit 131d may store the tag data received from the relay tag transceiver 131b or the tag data received from the tag transceiver 131 before transmitting to the RFID reader 110.

The power supply unit 131e supplies power to the reader transceiver unit 131a, the relay tag transceiver unit 131b, the tag transceiver unit 131c, and the storage unit 131d so that the first relay tag 131 transmits and receives an RF signal. And to proceed with the operation to save.

In FIG. 3, only the configuration of the first relay tag 131 illustrated in FIG. 2 is illustrated and described. However, the configuration of the second to fourth relay tags 132 to 134 may also be the same as that of the first relay tag 131. Can be designed.

4 is a diagram illustrating a tag recognition method of an active RFID multi-hop relay system according to an embodiment of the present invention. Specifically, FIG. 4 is a diagram for describing a tag recognition method according to 1-hop and 2-hop communication in an RFID multi-hop relay system, which will be described with reference to FIG. 2.

One-hop communication refers to a communication structure between the RFID reader 110 and the first area tag located within the first recognition distance A without a separate relay tag. In the configuration in which 1-hop communication is applied in FIG. 2, there may be a combination of the RFID reader 110 and the first tag 121.

Two-hop communication refers to a communication structure for relaying an RF signal between the RFID reader 110 and a second area tag located outside the first recognition distance A using the first area relay tag. In FIG. 2, a configuration in which 2-hop communication is applied includes a combination of an RFID reader 110-a first relay tag 131-a second tag 122, an RFID reader 110-a second relay tag 132- 3 tag 123 combination, RFIF reader 110-second relay tag 132-fourth tag 124 combination and RFID reader 110-third relay tag 133-fifth tag 125 combination This can be.

In FIG. 4, two-hop communication of a combination of an RFID reader 110, a first relay tag 131, and a second tag 122 will be described. In addition, the following description is equally applicable to other combinations of two-hop communication.

In FIG. 4, the RF signal transmitted from the RFID reader 110 is transmitted to the first area tag and the first area relay tag, and the RF signal transmitted to the first area relay tag is transmitted to the second area tag. The operation thereof will be described in detail.

The RFID reader 110 may recognize a tag by requesting tag data from surrounding tags and collecting tag data. To this end, the RFID reader 110 first generates a wakeup signal and transmits the wakeup signal to the first tag 121 and the first relay tag 131 located within the recognizable first recognition distance A. FIG.

Thereafter, the RFID reader 110 transmits a tag data request signal to the first tag 121 and the first relay tag 131. In this case, the first tag 121 is located within the first recognition distance A and performs one-hop communication with the RFID reader 110. Therefore, when the wakeup signal and the tag data request signal are received from the RFID reader 110, the first tag 121 switches from the sleep mode to the wakeup mode. The first tag data is read according to the tag data request signal and transmitted to the RFID reader 110 as the first area tag data. In this case, the RFID reader 110 operates in the first and second area tag data reception modes for receiving the first area and the second area tag data. Accordingly, the RFID reader 110 may recognize the first tag 121 by receiving the first area tag data.

Meanwhile, the first relay tag 131 performs two-hop communication for relaying an RF signal between the second tag 122 positioned outside the first recognition distance A and the RFID reader 110. Accordingly, the first relay tag 131 sequentially transmits the wakeup signal and the tag data request signal received from the RFID reader 110 to the second tag 122.

The second tag 122 is located within the second recognition distance B that the first relay tag 131 can recognize, and sequentially wakes up the signal and the tag data request signal from the first relay tag 131. Receive. The second tag 122 switches from the sleep mode to the wakeup mode according to the wakeup signal, and reads out the second tag data stored in its own memory according to the tag data request signal. In this case, while the second tag data is read from the second tag 122, the first relay tag 131 operates in a mode for receiving tag data of the second area tag.

Thereafter, the second tag 122 transmits the read second tag data to the first relay tag 131. When the second tag data of the second tag 122 is received in the first relay tag 131 by the above process, the first relay tag 131 stores the received second tag data and then the second area tag. The data is transmitted to the RFID reader 110. Accordingly, the RFID reader 110 may recognize the second tag 122 by receiving the second area tag data.

Meanwhile, the RFID reader 110 transmits a sleep signal to the first tag 121 and the first relay tag 131 to switch the recognized first and second tags 121 and 122 to the sleep mode.

Accordingly, the first tag 121 is switched to the sleep mode. In addition, the first relay tag 131 may transmit the received sleep signal to the second tag 122 so that the second tag 122 is switched to the sleep mode. This process can be one collection round to collect tag data for tag recognition.

In FIG. 4, the first tag 121, the first relay tag 131, and the second tag 122 operate in the standby mode while the transmission / reception or tag data reading operation for the RF signal is not performed.

In FIG. 4, for convenience of description, two-hop communication for one relay tag and one tag is illustrated, but two-hop communication for a plurality of relay tags and a plurality of tags may also be recognized by the same process. . However, when there is a tag that is not recognized by various interference factors among tag data collected from a plurality of tags in the collection round, the recognized tag is put into sleep mode and the collection round is not recognized for the unrecognized tag. You can go back and recognize the tag.

5A and 5B are diagrams for describing a tag recognition method of an active RFID multi-hop relay system according to another exemplary embodiment of the present invention. Specifically, FIGS. 5A and 5B are diagrams for describing a tag recognition method according to 1-hop, 2-hop, and 3-hop communication in an RFID multi-hop relay system.

1-hop communication refers to a communication structure in which an RF signal is transmitted and received between the RFID reader 110 and the first area tag without a separate relay tag. In addition, as mentioned above, 2-hop communication means the communication structure by which an RF signal is relayed by a 1st area relay tag.

The three-hop communication is a communication for relaying an RF signal between the RFID reader 110 and the third area tag located within the third recognition distance E by using the first area relay tag and the second area relay tag. Speak structure. In FIG. 2, the configuration to which 3-hop communication is applied includes a combination of an RFID reader 110, a third relay tag 133, a fourth relay tag 134, a sixth tag 126, and an RFID reader 110. There may be a combination of three relay tags 133-fourth relay tag 134-seventh tag 127.

First, the RFID reader 110 generates a wakeup signal and a tag data request signal as RF signals and sequentially transmits the wakeup signal and the tag data request signal. In this case, the wakeup signal and the tag data request signal are transmitted to the first recognition distance A, and are transmitted to the first area tag and the first area relay tag located within the first recognition distance A. FIG. In FIG. 2, the first area tag corresponds to the first tag 121, and the first area relay tag corresponds to the first to third relay tags 131 to 133. In FIG. 5A and FIG. 5B, it demonstrates using the 3rd relay tag 133 among these relay tags.

The first tag 121 corresponds to the first area tag, and receives the RF signal directly from the RFID reader 110. When the wakeup signal and the tag data request signal are received, the first tag 121 switches from the sleep mode to the wakeup mode. The first tag data is read according to the tag data request signal and transmitted to the RFID reader 110 as the first area tag data. In this case, the RFID reader 110 operates in a first area tag data reception mode for receiving first area tag data.

In addition, when the third relay tag 133 corresponding to the first area relay tag receives the wakeup signal and the tag data request signal from the RFID reader 110, the third relay tag 133 switches from the sleep mode to the wakeup mode. The wakeup signal and the tag data request signal are transmitted to the second area tag and the second area relay tag located within the second recognition distance B that the third relay tag 133 can recognize.

In FIG. 2, the second to fifth tags 125 correspond to the second area tag, and the fourth relay tag 134 to the second area tag. 5A and 5B, the fifth region 125 will be described as the second region tag.

On the other hand, when the fifth tag 125 corresponding to the second area tag receives the wakeup signal and the tag data request signal from the third relay tag 133, the fifth tag 125 switches from the sleep mode to the wakeup mode. The fifth tag data is read according to the tag data request signal and transmitted to the third relay tag 133 as the second area tag data. Thereafter, the third relay tag 133 stores the received second area tag data and transmits the received second area tag data to the RFID reader 110. In this case, the RFID reader 110 operates in the second and third area tag data reception modes for receiving the second area and the third area tag data.

In addition, when the wakeup signal and the tag data request signal are received from the third relay tag 133, the fourth relay tag 134 sequentially transmits these signals to the third area tag located within the third recognition distance E. FIG. send. In this case, the sixth tag 126 and the seventh tag 127 correspond to the third area tag. Accordingly, the sixth tag 126 and the seventh tag 127 switch to the wake-up mode according to the wake-up signal and the tag data request signal received from the fourth relay tag 134, and respectively, the sixth and seventh tags. Read the data. The sixth tag 126 transfers the read sixth tag data to the fourth relay tag 134 as the third area tag data, and the seventh tag 127 transmits the seventh tag data to the third area tag data. As a result, it transmits to the fourth relay tag 134.

Thereafter, the fourth relay tag 134 transmits the third area tag data for the received sixth and seventh tags 126 and 127 to the third relay tag 133, and the third relay tag 133. Will transmit it back to the RFID reader 110. Through this process, the RFID reader 110 may further include the fifth tag 125 and the sixth tag 126 located outside the first recognition distance A, in addition to the first tag 121 located within the first recognition distance A. FIG. And tag data of each area of the seventh tag 127 to recognize the corresponding tag.

Meanwhile, if the data of the fifth tag 125 and the sixth tag 126 are not collected by the RFID reader 110 due to various interference factors in the above process, the RFID reader 110 may include the fifth tag 125 and the fifth tag. 6 tag 126 is not recognized. Therefore, the sleep signal is transmitted to the recognized first tag 121 and the seventh tag 127. This process can be the first round of collection to collect tag data for tag recognition.

When the first collection round ends, tag data collection of the fifth tag 125 and the sixth tag 126 is restarted through the second collection round illustrated in FIG. 5B.

In the second collecting round shown in FIG. 5B, the tag data request signal generated from the RFID reader 110 is transmitted to the third relay tag 133. The third relay tag 133 may transmit a tag data request signal to the fifth tag 125 and the fourth relay tag 134. Accordingly, the fifth tag 125 reads the fifth tag data and transmits the fifth tag data to the third relay tag 133, and the third relay tag 133 uses the received fifth tag data as the second area tag data. It is possible to transmit to the reader 110.

Meanwhile, the fourth relay tag 134 transmits the received tag data request signal to the sixth tag 126. The sixth tag 126 reads the sixth tag data according to the received tag data request signal and transmits the sixth tag data to the fourth relay tag 134 as third area tag data. Thereafter, the fourth relay tag 134 may transmit the third area tag data to the RFID reader 110 through the third relay tag 133. According to this process, the second collection round proceeds to collect tag data for tags not recognized in the first collection round.

5A and 5B, the first tag 121, the third relay tag 131, the fifth tag 125, the fourth relay tag 134, the sixth tag 126, and the seventh tag 127 are shown in FIG. 5A and 5B. While the transmission / reception or tag data reading operation for the RF signal is not performed, the device operates in the standby mode.

5A and 5B, the RFID reader 110 uses the third relay tag 133 and the fourth relay tag 134 to place the fifth tag 125 located outside the first recognition distance A. FIG. ), By recognizing the sixth tag 126 and the seventh tag 127, the recognition rate of the RFID reader 110 may be increased to improve the tag recognition rate.

Table 1 and Table 2 show 1-hop communication, 2-hop communication, and 3 under the free space path loss channel in the case where the reader sensitivity is -80 dBm and the tag sensitivity is -75 dBm. -Recognition distance of active RFID multi-hop relay system with hop communication. In this case, Table 1 is the recognition distance of the forward link, and Table 2 measures the recognition distance of the reverse link. Here, the forward link refers to a channel for transmitting an RF signal from the RFID reader to the tag, and the reverse link refers to a channel for transmitting an RF signal from the tag to the RFID reader.

division Recognition distance [m] 1-hop 131.550 2-hop 157.746 3-hop 183.942 Relay Tag-Tag Distance 26.196

division Recognition distance [m] 1-hop 198.491 2-hop 224.687 3-hop 250.883 Relay Tag-Tag Distance 26.196

Referring to Table 1 and Table 2, in the conventional 1-hop RFID system in which an RFID reader and a tag directly transmit and receive RF signals without a relay tag, the recognition distance is shorter than that of 2- and 3-hop communication. Can be. As can be seen from Table 1 and Table 2, by using the active RFID multi-hop relay system of the present invention, it is possible to increase the recognition distance between the RFID reader and the tag.

6 is a graph illustrating a recognition distance according to a change in sensitivity of a tag in a forward link according to an embodiment of the present invention. Specifically, FIG. 6 shows the recognition distance according to the signal reception sensitivity of each tag from -80dBm to -60dBm for the RF signal received from the RFID reader in 1-hop communication, 2-hop communication, and 3-hop communication. Is a graph measured.

Referring to FIG. 6, in an active RFID multi-hop relay system, a 1-hop communication in which an RFID reader and a tag directly transmit and receive an RF signal without a relay tag has a recognition distance of about 20 to 200 m at a signal reception sensitivity of -60 dBm to -80 dBm. Has

In the active RFID multi-hop relay system, two-hop communication in which an RFID reader transmits and receives an RF signal with a second area tag located at a distance not recognized by the RFID reader through a first area relay tag is -60 dBm to -80 dBm. It has a recognition distance of about 23 ~ 240m in signal reception sensitivity.

Also, in an active RFID multi-hop relay system, an RFID reader transmits and receives an RF signal to and from a third area tag located at a distance not recognized by the RFID reader and the first area relay tag through the first and second area relay tags. The hop communication has a recognition distance of about 27-280 m at signal reception sensitivity of -60 dBm to -80 dBm.

As described above, it can be seen that in the active RFID multi-hop relay system, the recognition distance on the forward link is longer in 2-hop communication or 3-hop communication than in 1-hop communication. Accordingly, by implementing multi-hop communication using a relay tag, the recognition distance between the RFID reader and the tag can be increased.

7 is a graph illustrating a recognition distance according to a change in sensitivity of a reader in a reverse link according to an embodiment of the present invention. Specifically, in FIG. 7, in the 1-hop communication, the 2-hop communication, and the 3-hop communication, the RFID receiver's signal reception sensitivity with respect to the RF signal received from each tag is changed from -85 dBm to -70 dBm to recognize accordingly. It is a graph measuring distance.

Referring to FIG. 7, in an active RFID multi-hop relay system, a 1-hop communication in which a tag and an RFID reader directly transmit and receive an RF signal without a relay tag has a recognition distance of about 50 to 300 m at a signal reception sensitivity of -70 dBm to -85 dBm. Has

In the active RFID multi-hop relay system, two-hop communication in which a second area tag transmits and receives an RF signal to and from an RFID reader through a first area relay tag recognizes about 65 to 340 m at a signal reception sensitivity of -70 dBm to -85 dBm. Have distance.

In addition, in an active RFID multi-hop relay system, three-hop communication in which a third area tag transmits and receives an RF signal to and from an RFID reader through first and second area relay tags has a signal reception sensitivity of about 80 to about -70 dBm to -85 dBm. It has a recognition distance of 370m.

Likewise, the reverse link of the active RFID multi-hop relay system also shows that the recognition distance between the RFID reader and the tag is increased in 2-hop communication rather than 1-hop communication, and the RFID reader and tag in 3-hop communication rather than 2-hop communication. It can be seen that the recognition distance of the liver has increased.

Meanwhile, as can be seen from Tables 1 and 2 and the graphs of FIGS. 6 and 7, it can be seen that the recognition distance between the RFID reader-tag is shorter in the forward link than in the reverse link. Therefore, in the active RFID multi-hop relay system of the present invention, the recognition distance may be determined by the forward link.

Although the above has been illustrated and described with respect to the preferred embodiments of the present invention, the present invention is not limited to the above-described specific embodiments, it is common in the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

1 is a view showing an RFID system according to the prior art,

2 is a diagram illustrating an active RFID multi-hop relay system according to an embodiment of the present invention;

3 is a block diagram showing a configuration of a first relay tag according to an embodiment of the present invention;

4 is a view for explaining a tag recognition method of an active RFID multi-hop relay system according to an embodiment of the present invention;

5A and 5B are diagrams for describing a tag recognition method of an active RFID multi-hop relay system according to another embodiment of the present invention;

6 is a graph illustrating a recognition distance according to a change in sensitivity in a forward link according to an embodiment of the present invention;

7 is a graph illustrating a recognition distance according to a change in sensitivity in a reverse link according to an embodiment of the present invention.

<Explanation of Signs of Major Parts of Drawings>

100: active RFID multi-hop system 110: RFID reader

121, 122, 123, 124, 125, 126, 127: tags

131, 132, 133, 134: relay tag

Claims (13)

A plurality of tags attached to a predetermined recognition object and storing tag data; At least one RFID reader generating an RF signal necessary for the tag recognition; And The RF signal is located within a first recognition distance that the RFID reader can recognize, and when the RF signal is received from the RFID reader, the RF signal is transmitted to a second area tag located outside the first recognition distance among the plurality of tags. And at least one first area relay tag to transmit to the RFID reader when tag data is received from the second area tag. The method of claim 1, And a first area tag located within the first recognition distance among the plurality of tags reads the stored tag data and transmits the stored tag data to the RFID reader. The method of claim 1, Active RFID multi-hop further comprises at least one second area relay tag, which transmits and receives a signal with the first area relay tag and is located within a second recognition distance that can be recognized by the first area relay tag. Relay system. The method of claim 3, The second area relay tag, When the RF signal is received from the first area relay tag, the RF signal is transmitted to a tag located outside the second recognition distance among the plurality of tags, and when tag data is received from the third area tag, the RF signal is transmitted to the first area relay tag. Active RFID multi-hop relay system, characterized in that. The method of claim 3, The first and second area relay tags, A reader transceiver for transmitting and receiving a signal to and from the RFID reader; A relay tag transmitting / receiving unit which transmits / receives a signal with another area relay tag; A tag transceiver for transmitting and receiving signals with the at least one tag; A storage unit which stores the tag data when tag data is received through the tag transceiver; And Active RFID multi-hop relay system comprising a power supply for supplying power. The method of claim 3, The RFID reader, The tag data is stored when the tag data is received from the first area relay tag or the first area tag, the active RFID multi-hop relay system. The method of claim 1, The RF signal is, A wake-up signal for switching the plurality of tags from a sleep mode to a wake-up mode, a tag data request signal for requesting tag data stored in the plurality of tags, and a wake-up of the plurality of tags Active RFID multi-hop relay system, characterized in that any one of the sleep signal for switching from mode to sleep mode. A first step of transmitting an RF signal generated by an RFID reader to a first region tag and a first region relay tag located within a first recognition distance that the RFID reader can recognize for tag recognition; A second step of transmitting the RF signal to a second area tag in which the first area relay tag is located outside the first recognition distance; Transmitting tag data read from the first area tag to the RFID reader; Transmitting a tag data read from the second area tag to the first area relay tag, and And a fifth step in which the first area relay tag receiving the tag data transmits the tag data to the RFID reader. The method of claim 8, The second step, Transmitting the RF signal to a second area relay tag, wherein the first area relay tag is located outside the first recognition distance and within a second recognition distance that can be recognized by the first area relay tag. Tag recognition method of an active RFID multi-hop relay system, characterized in that. 10. The method of claim 9, A sixth step of transmitting the RF signal to a third area tag in which the second area relay tag receiving the RF signal is located outside the second recognition distance; A seventh step of transmitting tag data read from the third area tag to the second area relay tag; And And an eighth step of transmitting the second area relay tag to the first area relay tag when the tag data is received. The method of claim 8, The third step, And storing the tag data when the tag data transmitted from the first area tag is received by the RFID reader. The method of claim 8, The fifth step, And tag data transmitted from the first area relay tag to store the tag data in the RFID reader. The method of claim 8, The RF signal is, A wake-up signal for switching the plurality of tags from a sleep mode to a wake-up mode, a tag data request signal for requesting tag data stored in the plurality of tags, and a wake-up of the plurality of tags Tag recognition method of an active RFID multi-hop relay system, characterized in that any one of the sleep signal for switching from the mode to the sleep mode.

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