KR20130018092A - Active ip-rfid system accepting ip core function, device and method thereof - Google Patents

Abstract

PURPOSE: An active IP(Internet Protocol)-RFID(Radio Frequency Identification System) capable of accepting internet protocol core functions for improving the performance of an RFID system, a device thereof and a method thereof are provided to introduce an IP which is not yet applied to current RFID systems, thereby presenting a new paradigm for the RFID field. CONSTITUTION: An active IP-RFID system(10) includes a user terminal(400), an IP network(300), an IP core support reader(100), and an IP core support tag(200). The IP core support reader and the IP core support tag are able to compose an RFID network(201). The user terminal performs IP-based communications with the IP network. The IP core support reader is able to perform IP-based communications with the IP network. The IP core support reader converts an IP packet delivered through the IP network into a packet which accommodates IP core functions applicable to the IP core support tag. [Reference numerals] (300) IP network

Description

Active IP-RFID system accepting IP core function, device and method

The present invention relates to packet forwarding between heterogeneous networks, and more particularly, to an active IP-RFID system, apparatus for accommodating IP core functions for supporting signaling based on a packet with an IP core applied between an IP network and an RFID network, and It is about a method.

In the wireless sensor network, the problem of non-IP was recognized and researches were actively applied. As a result, the 6LoWPAN working group was established. 6LoWPAN technology is a technology for efficiently and securely delivering large size IP packets through IEEE 802.15.4 technology, which has a relatively low data transmission rate, and is mainly used in the USN field, and aims for multi-hop. In addition, since it wants to accept IP mechanism such as address setting method, it is inefficient and inefficient to apply to low power-oriented embedded devices. In particular, when applying to Just 1-Hop-based RFID system, there is a problem that consumes a lot of power and time to set the network and address. This problem is very fatal in the RFID system assuming long-term mobility, the application of the conventional 6LoWPAN technology to the RFID system can cause a lot of problems in reality.

1 schematically illustrates a configuration of a conventional IP-RFID system 1.

Referring to FIG. 1, the conventional IP-RFID system 1 includes a tag owner terminal 2, an IP network 3, a web server 4, a reader 5, and a tag 6. In the conventional IP-RFID system 1, when the reader 5 scans the tag 6 to collect tag information, the tag information is transmitted to the destination set in the tag 6, that is, the web server 4. For this reason, the tag holder terminal 2 uses a method of receiving tag information by connecting to a web server 4 or the like connected to the reader 5 managing the tag 6. However, this method is vulnerable to security because it needs to share information that the tag owner does not want to share, such as tag information or tag checking time, to the reader 5 and the web server 4 connected to the reader 5. There is a problem. In addition, there is a problem that the management point of the tag 6 is transferred to the reader 5 and the web server 4 manager rather than the tag owner.

The present invention is to solve the above problems, by combining the minimum IP Framework to be applied to the RFID system to enable efficient IP communication with the user terminal, as well as utilizing the global unique ID that the tag has The present invention provides an active IP-RFID system, apparatus, and method for accommodating IP core functions that support communication between a user terminal and a tag without requiring additional addressing.

In addition, the present invention provides an active IP-RFID system, apparatus, and method for accommodating IP core functions that enable a powered reader to perform various functions that a TAG should perform, thereby improving the performance of the overall RFID system. In providing.

In addition, the present invention solves the problem of transmitting the tag information to only one destination, which was an existing problem of RFID, by inputting the address of the user terminal to the TAG as a destination address, and enables direct communication with the user terminal to secure the information. An active IP-RFID system, device, and method are provided to accommodate IP core functions that can improve performance and reliability.

The present invention also provides an active IP-RFID system, apparatus, and method for supporting low power communication and IPSec, and accommodating IP core functions capable of enhancing communication security.

Active IP-RFID system according to a preferred embodiment of the present invention for achieving the above object is a user terminal for generating and transmitting an IP packet including information for tag information collection or tag information change of the IP core support tag, An IP network for delivering an IP packet transmitted by the user terminal, an IP core support reader connected to the IP network to receive an IP packet transmitted by the user, and converting the received IP packet into a packet accommodating an IP core function; A configuration including an IP core support tag for receiving a packet accommodating the converted IP core function and collecting or changing information according to packet contents is disclosed.

The present invention also provides an IP communication unit that communicates with an IP network, a reader unit that communicates with an IP core support tag, and a packet that accommodates IP core functions transmitted and received based on the reader unit and the delivery control of IP packets transmitted and received based on the IP communication unit. Disclosed is a configuration of an IP core support reader including a control unit that performs delivery control.

Herein, the control unit is an IP packet processing unit for performing an IP packet reception process received by the IP communication unit and an IP packet process to be delivered to the IP network through the IP communication unit, and a packet transmission process for accommodating an IP core function to be transmitted by the reader unit. And a packet processing unit accommodating an IP core function for receiving an IP core function for receiving the IP core function to be received by the reader unit, a packet processing unit for converting the IP packet into a packet accommodating an IP core function and accommodating an IP core function. And a packet converter for converting the IP packet to the IP packet processor and converting the packet to accommodate the IP core function.

In particular, the packet conversion unit extracts ID information of an IP core support tag corresponding to a destination address included in the IP packet, user terminal address information corresponding to a source address information, and command information, and includes the extracted IP information. It can generate a packet that accepts.

In addition, the packet converter extracts ID information of an IP core support tag corresponding to source address information included in a packet accommodating the IP core function, user terminal address information and command information corresponding to destination address information, and extracted information. Generate an IP packet including the

The header of the packet accommodating the IP core function may include a destination address and a source address area, and may further include at least one of a control header, a next header, and a total length area.

The header of the packet following the packet accommodating the IP core function may be an ICMP header, a UDP header, or a TCP header accommodating the IP core function. Here, the ICMP header accommodating the core functions of the IP is composed of Echo Request and Echo Reply, and may include a Type, Identifier, Sequence Number, and Payload area.

The present invention also provides a configuration of an IP core support tag for transmitting and receiving a packet accommodating an IP core function received from an IP core support reader and a packet accommodating at least one transmission IP core function transmitted to the IP core support reader. It starts. The address information of each of the packets accommodating the IP core function for transmission may be set to different destination communication addresses.

The present invention also comprises the steps of the user terminal transmits an IP packet for collecting tag information or tag information change of a specific tag to an IP network, the IP network transmitting the IP packet to a reader to communicate with a specific tag, A conversion step of a reader converting the IP packet into a packet accommodating an IP core function applicable to the tag, and transmitting a packet accommodating the converted IP core function to the tag. The configuration of a method of operating an active IP-RFID system to be accepted is disclosed.

The converting may include extracting user terminal address information corresponding to source information included in the IP packet, extracting tag ID information corresponding to destination address information included in the IP packet, and including the IP packet. The method may include extracting the command information, and generating a packet that accommodates an IP core function including the extracted information.

The generating of the packet accommodating the IP core function may include a header for the packet accommodating the IP core function including a destination address and a source address area, and further including at least one of a control header, a next header, and a total length area. Writing may be included.

The method may further include generating a packet in which the tag receives an IP core function for transmission, delivering a packet that accepts the IP core function for transmission, and the reader accepting the IP core function for transmission. The method may further include converting a packet into an IP packet, and transmitting the converted IP packet to the user terminal through the IP network.

The generating may include writing the user terminal address information as the destination address information by the tag, and writing own ID information as the source information.

The invention also discloses a configuration of a computer readable recording medium having recorded thereon a program for executing the above-described operating method.

As described above, according to an active IP-RFID system and an operation method for accommodating IP core functions according to an embodiment of the present invention, and a reader and a tag supporting the same, the present invention provides an IP RFID system that is not currently applied to an RFID system. By introducing a new paradigm in the RFID field and enabling access to the TAG, which was a limitation of the existing RFID system, a smarter RFID system can be realized.

In addition, in the present invention, since the TAG has user terminal information as a destination address, communication is possible directly with the user, and the TAG information is not transmitted to one server, but the information is transmitted to the address of the destination set in the corresponding TAG. It can improve the security and reliability of.

In addition, the present invention can support the TAG has a global unique ID so that it can directly communicate with the user terminal with the ID without additional IP addressing.

In addition, the present invention can be quickly transmitted by compressing the IP packet transmitted from the user terminal into a packet that accommodates the IP core function to the TAG, and can minimize the bottleneck that may occur in the RF section.

In addition, the present invention can improve the low power by simplifying the signal processing function of the TAG is not powered by the reader by converting the packet containing the IP core function transmitted from the TAG to an IP packet to the user terminal.

In addition, the present invention aims at low performance because the TAG does not need to directly accommodate the IP framewrok as the reader converts the IP packet into a packet that accommodates the IP core function and converts the packet that accommodates the IP core function into the IP packet. It can complement the performance of TAG.

In addition, the present invention can ensure IPSec that guarantees end-to-end security between sensor nodes in the sensor network and terminals in the IP network.

In the case of the current Active RFID including the conventional e-Seal, even if various sensing information is additionally transmitted, it is dependent on one server and operates. However, the active IP-RFID that accommodates the IP core function of the present invention includes a communication address of a destination, so that the sensing information can be directly transmitted to the user.

1 is a view showing the configuration of a conventional IP-RFID system.
2 is a diagram schematically showing the configuration of an active IP-RFID system that accommodates IP core functions according to an embodiment of the present invention.
3 is a diagram showing in more detail the configuration of the IP core support reader according to an embodiment of the present invention.
4 is a view showing in more detail the configuration of the control unit of FIG.
5 is a diagram illustrating an IP header structure of a packet accommodating IP core functions according to an embodiment of the present invention.
6 is a view for explaining the structure of the IP Echo Request and Echo Reply Header coming to the next packet of the packet accommodating the IP core function according to an embodiment of the present invention.
7 is a diagram illustrating communication between a user terminal and an IP core support tag according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description and the accompanying drawings, detailed description of well-known functions or constructions that may obscure the subject matter of the present invention will be omitted. In addition, it should be noted that like elements are denoted by the same reference numerals as much as possible throughout the drawings.

The terms or words used in the specification and claims described below should not be construed as being limited to the ordinary or dictionary meanings, and the inventors are properly defined as terms for explaining their own invention in the best way. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention based on the principle that it can. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It is to be understood that equivalents and modifications are possible.

2 is a diagram schematically showing the configuration of an active IP-RFID system 10 that accommodates IP core functions according to an embodiment of the present invention.

Referring to FIG. 2, the active IP-RFID system 10 accommodating the IP core functions of the present invention includes a user terminal 400, an IP network 300, an IP core support reader 100, and an IP core support tag 200. ) May be included. Here, the IP core support reader 100 and the IP core support tag 200 may constitute the RFID network 201.

In the active IP-RFID system 10 accommodating the IP core function of the structure, the user terminal 400 communicates with the IP network 300 based on the IP, and the IP core support reader 100 also uses the IP based. Communication with the IP network 300 may be performed. In particular, the IP core support reader 100 converts an IP packet transmitted through the IP network 300 into a packet accommodating an IP core function applicable to the IP core support tag 200, and then the IP core support tag 200 To pass). The IP core support reader 100 may convert a packet accommodating an IP core function into an IP packet and then transmit the packet to the IP network 300 when collecting tag information of the IP core support tag 200. That is, the active IP-RFID system 10 accommodating the IP core function of the present invention converts the IP packet into a packet accommodating the IP core function, and then applies it to the RFID network 201, and applies the packet accommodating the IP core function to the IP. A packet may be converted into a packet and applied to the IP network 300. Accordingly, by applying to the RFID network 201 based on a framework that is relatively compressed compared to the IP packet, it is possible to support the implementation of the low-performance RFID network 201, and to randomly select the destination address of the packet that accommodates the IP core functions. It is possible to support direct communication between end-to-end by allocating as address information of and assigning a source address as unique information of the IP core support tag 200.

To this end, the IP network 300 is disposed between the user terminal 400 and the IP core support reader 100 to support IP packet transmission and reception. In this case, the IP network 300 may include information corresponding to the unique information of the user terminal 400 and the IP core support tag 200 in the IP packet and transfer the information. That is, the IP network 300 may receive an IP packet having the unique information of the IP core support tag 200 as a destination address from the user terminal 400 and deliver it to the IP core support reader 100. In addition, the IP network 300 may receive an IP packet having the destination address as the IP information of the user terminal 400 from the IP core support reader 100 and transmit the received IP packet to the user terminal 400.

The user terminal 400 is a terminal that can be connected to the IP network 300 and may include a communication module for accessing the IP network 300. In addition, the user terminal 400 may collect the IP core support tag 200 information through the IP network 300. To this end, the user terminal 400 may collect and store unique information of the IP core support tag 200 in advance. Alternatively, the user terminal 400 receives the unique information of the corresponding IP core support tag 200 in the process of assigning the IP core support tag 200 or tags from a separate management device that manages the IP core support tag 200. Unique information can be received and stored.

The user terminal 400 outputs the terminal storage unit for storing the unique information of the IP core support tag 200, the terminal communication unit for accessing the IP network 300, and the tag information of the IP core support tag 200 upon reception. The terminal may include a display unit and a terminal controller configured to control signal transmission and reception for managing the IP core support tag 200 of the present invention. In this case, the terminal display unit may support a touch screen function. Accordingly, the user may control various screens output on the terminal display unit to support the collection and output of the IP core support tag 200 information.

When the user wants to collect tag information or change tag information of the pre-stored IP core support tag 200, the terminal controller of the user terminal 400 provides a menu item for collecting the corresponding tag information or changing the tag information. According to a selection, control for collecting tag information or changing tag information of the IP core support tag 200 may be performed. In this process, the terminal controller controls the terminal communication unit to perform the IP network 300 access, and then the IP address information and the IP core support tag 200 of the IP core support reader 100 scanning the IP core support tag 200. IP packet including the unique information of the) can be generated and delivered to the IP network 300.

The IP packet generated by the user terminal 400 is first delivered to the IP core support reader 100, and the IP core support reader 100 checks the corresponding IP packet to confirm unique information of the IP core support tag 200. . The IP packet is converted into a packet accommodating the IP core function according to the contents described in the corresponding IP packet, that is, the tag information collection or the tag information change, and the packet accommodating the converted IP core function is transferred to the IP core support tag 200. Can support delivery. Meanwhile, in the case of collecting tag information, the IP core support reader 100 converts an IP packet requesting tag information into a packet accommodating an IP core function and delivers the packet to the IP core support tag 200, and the corresponding IP core support tag 200 If the tag information is received in the form of a packet accommodating the IP core function, it may be converted into an IP packet and transmitted to the user terminal 400. At this time, the packet accommodating the IP core function delivered by the IP core support tag 200 includes the address information of the user terminal 400 and is transmitted to the user terminal 400 without a separate server registration process connected to the IP network 300. Can be delivered directly.

When the IP core support tag 200 transmits tag information to a specific user terminal 400, the IP core support tag 200 generates a packet to accommodate the IP core function by writing unique information of the corresponding user terminal 400 as address information, and generates the IP core function. The packet may be delivered to the user terminal 400 through the IP core support reader 100 and the IP network 300. Accordingly, when the IP core support tag 200 writes unique information of each user terminal as address information, the IP core support tag 200 may control to have different destination communication addresses for each packet accommodating each IP core function to be transmitted. The IP core support tag 200 may be attached to a specific article or the like and continuously managed with movement of the article. In this case, the tag information may be updated depending on whether the reader communicates with the information. A form of a packet accommodating an IP core function applied to the IP core support tag 200 will be described later in more detail with reference to FIGS. 5 and 6.

The IP core support reader 100 scans at least one IP core support tag 200 to collect tag information of each IP core support tag 200 or writes schedule information in each IP core support tag 200. It is the configuration to perform. The IP core support reader 100 may perform access to the IP network 300, and thus may have unique IP address information for operating the IP network 300. Particularly, the IP core support reader 100 of the present invention compresses an IP packet received from the IP network 300 into a packet accommodating an IP core function applicable to the IP core support tag 200, and then performs an IP core support tag ( 200). In addition, the IP core support reader 100 may convert a packet accommodating the IP core function received from the IP core support tag 200 into an IP packet and transmit the packet to the IP network 300. The IP core support reader 100 will be described in more detail with reference to FIGS. 3 and 4.

As described above, the active IP-RFID system 10 accommodating the IP core functions of the present invention reconfigures the packet type applied to the tag 200 into the IP core form, while maintaining the low performance of the RFID network 201. IP packet conversion for information delivery to the IP network 300 may be supported so that direct information delivery between the user terminal 400 and the tag 200 may be performed.

3 is a diagram illustrating in detail the configuration of the IP core support reader 100 according to an exemplary embodiment of the present invention, and FIG. 4 is a diagram illustrating the configuration of the controller 160 of FIG. 3 in more detail.

3 and 4, the IP core support reader 100 may include an IP communication unit 110, a reader unit 120, and a controller 160. The controller 160 may include an IP packet processor 161, a packet processor 163, and a packet converter 165 for accommodating an IP core function.

The IP communication unit 110 is a configuration supporting the IP network 300 connection and data transmission and reception of the IP core support reader 100. The IP communication unit 110 receives an IP packet transmitted from the IP network 300 and delivers the received IP packet to the control unit 160. In addition, the IP communication unit 110 transmits the IP packet transmitted from the control unit 160 to the IP network 300. The above-described IP communication unit 110 may be configured with at least one of various communication modules according to the types of communication devices constituting the IP network 300. For example, the IP communication unit 110 may be configured as any one of various communication modules, such as an Ethernet communication module, a Wi-Fi communication module, a 3G communication module, and a 4G communication module, which may be connected to the IP network 300. The IP communication unit 110 may be configured as a communication module according to at least one of a wired communication method and a wireless communication method. Therefore, the IP communication unit 110 of the present invention may be configured as a specific communication module capable of IP packet-based communication as a configuration supporting transmission and reception of IP packets of the IP core support reader 100.

The reader unit 120 is a component for performing communication with the IP core support tags 200. That is, the reader unit 120 may scan the predetermined area to identify at least one IP core support tag 200 disposed in the corresponding area, and receive tag information from the identified IP core support tag 200 or schedule Information may be written to the IP core support tag 200. That is, the reader unit 120 transmits a packet accommodating an IP core function including the ID information of the IP core support tag 200 and information converted into source information to the IP core support tag 200 under the control of the controller 160. Can be. The reader 120 may scan a predetermined area according to a predetermined period or a user request. Here, the IP core support tag 200 writes the source address information included in the packet accommodating the IP core function received from the reader unit 120 as destination address information, and generates a packet accommodating the IP core function for transmission. The reader 120 may be transferred.

The controller 160 controls the power supply of the IP communication unit 110 and the reader unit 120, and controls the IP packet processing of the IP communication unit 110. The controller 160 controls the tag information collection or change information writing of the IP core support tag 200 through the control of the reader 120.

In particular, the IP packet processing unit 161 of the control unit 160 may control the IP packet reception and IP packet transmission of the IP communication unit 110. That is, when the IP communication unit 110 receives the IP packet, the IP packet processing unit 161 checks the received IP packet, and transmits the ID information of the IP core support tag 200 and the IP core support tag 200 to the corresponding IP core support tag 200. Collect source address information. The IP packet processor 161 may transmit the collected ID information, the command, and the source address information of the IP core support tag 200 to the packet converter 165.

The packet processor 163 accommodating the IP core function supports the packet accommodating the IP core function delivered by the packet converter 165 to the specific IP core support tag 200 through the reader 120. Configuration. In addition, the packet processing unit 163 accommodating the IP core function checks the packet accommodating the IP core function from the specific IP core support tag 200 received by the reader unit 120 to support the IP core support tag corresponding to the source information. ID information of 200, destination address information, and command information are collected. The packet processor 163 accommodating the IP core function may transmit the ID information, the destination address information, and the command information of the collected IP core support tag 200 to the packet converter 165.

The packet converter 165 converts the IP packet into a packet accommodating the IP core function. In addition, the packet converter 165 may transfer the packet that receives the converted IP core function to the reader 120 through the packet processor 163 that accommodates the IP core function. In this case, the packet converter 165 may generate a packet that accommodates an IP core function including ID information, command, and source address information of the IP core support tag 200 received from the IP packet processor 161. In addition, the packet converter 165 converts the packet that accommodates the IP core function into an IP packet. The packet converter 165 may deliver the IP packet to the IP communication unit 110 through the IP packet processor 161. In this case, the packet converter 165 may generate an IP packet including ID information, destination address information, and command information of the IP core support tag 200 received from the packet processor 163 accommodating the IP core function.

FIG. 5 is a diagram illustrating a header accommodating an IP core function, which is a header of a packet accommodating an IP core function, according to an embodiment of the present invention. FIG. It is a figure for demonstrating.

5 and 6, the header accommodating the IP core function of the present invention is a header packet for the IP core support tag 200 to communicate with the user terminal 400, and includes a destination address and a source address area. And at least one of a control header, a next header (NH), and a total length area. For example, the header of the packet accommodating the IP core function is composed of Control Header, Next Header (N-H), Total Length, Destination Address, and Source Address.

Control Header is composed of 1 byte combined with Next Header. The control header includes a field for controlling the IP core support tag 200, a version, a traffic class, and a flow label.

Next Header is a field for representing the header following the header to accommodate the IP core function. The next header is composed of UDP, ICMP or TCP. That is, the header following the header accommodating the IP core function may be a UDP header, an ICMP header or a TCP header.

The Total Length field is a field indicating the payload length of the header following the header accommodating the IP core function. The Destination Address field is a field indicating destination address information, that is, user terminal 400 address information. Finally, ID information of the IP core support tag 200 is written in the Source Address field.

If the ICMP Header is specified in the Next Header of the header accommodating the IP core function, it means that the packet of FIG. 6 is added after the header accommodating the IP core function described in FIG. 5 and transmitted. ICMP Header consists of Echo Request and Echo Reply, and consists of Type, Identifier, Sequence Number and Payload.

The Type field is a field for identifying whether an ICMP header is an Echo Request packet or an Echo Reply packet. Identifier is a field for checking the origin of the packet, and Sequence Number is a field indicating how many times the Echo Request packet or the Echo Reply packet is transmitted according to the Identifier value. The payload field stores an arbitrary value for confirming that the packet is properly transmitted.

If the UDP Header is specified in the Next Header of the header accommodating the IP core function, this means that the UDP header currently used in the IP network 300 is added after the header accommodating the IP core function and transmitted.

The IP core support reader 100 receives the packet accommodating the IP core function, converts the packet into an IP packet form used in the IP network 300, and transmits the packet to the user terminal 400 or uses the IP network 300. It receives the IP packet and converts it into a packet that accommodates the IP core function and transmits it to the IP core support tag 200.

When the IP network 300 is configured with IPv6, the header for accommodating the IP core function may be changed to the IPv6 header. That is, a Version, Traffic Class, Flow Label, Payload Length, Hop Limit, and Source Address, which are not included in the header for accommodating the aforementioned IP core functions, may be added. These values can be generated by the IP core support reader 100 because they are used as fixed values in the Active IP-RFID system 10 that accommodates the IP core functions. In the case of Echo Request and Echo Reply in the IPv6 network, the IP core support reader 100 may generate Code and Checksum values.

7 is a view for explaining a method of operating an active IP-RFID system that accommodates IP core functions according to an embodiment of the present invention.

Referring to FIG. 7, a plurality of user terminals 400 may be provided, and each of the user terminals 400 may access the IP network 300. Thereafter, each user terminal 400 may transmit an IP packet including the IP core support tag 200 information to be managed by the user terminal 400 to the IP network 300 in step 501. Then, the IP network 300 may deliver the corresponding IP packet to the specific IP core support reader 100 based on the IP address information written in the corresponding IP packet in step 503. To this end, each user terminal 400 includes the ID information of the IP core support tag 200 and the address information of the IP core support reader 100 communicating with the IP core support tag 200 when transmitting the IP packet. An IP packet may be generated and delivered to the IP network 300. Then, the IP network 300 searches for the target IP core support reader 100 based on the address information of the IP core support reader 100 included in the corresponding IP packet, and supports the IP packet based on the search result. It may be delivered to the reader (100).

Upon receiving the IP packet, the IP core support reader 100 checks the ID information of the IP core support tag 200 included in the IP packet, and corresponds to the ID information and source address information of the IP core support tag 200. A packet generation that accommodates an IP core function including address information and command information of the terminal 400 is performed. That is, the IP core support reader 100 may perform packet conversion in step 505. In step 507, the IP core support reader 100 scans a predetermined area and delivers a packet accommodating a corresponding IP core function to a specific IP core support tag 200.

Meanwhile, when the IP core support tag 200 transmits data to the IP core support reader 100, the IP core support tag 200 may deliver the IP core support tag 100 in the form of a packet accommodating an IP core function as described in step 509. The user terminal 400 corresponding to the address may include address information and command information. In step 511, the IP core support reader 100 may control to convert a packet that accommodates an IP core function into an IP packet. In addition, the IP core support reader 100 may check the destination address information of the IP packet converted from the packet accommodating the IP core function in step 513 so that the IP core support reader 100 may be directly transmitted to the user terminal 400 without going through a separate server. have.

As described above, the active IP-RFID system 10 accommodating the IP core functions according to the embodiment of the present invention and the components constituting the system 10 perform data transfer based on the IP network 300, but do not provide RFID. The network 201 supports direct information transfer between the user terminal 400 and the IP core support tag 200 by applying a packet in the form of an IP core.

An active IP-RFID system operating method for accommodating IP core functions according to the present invention may be implemented in a software form readable by various computer means and recorded on a computer readable recording medium. Here, the recording medium may include program commands, data files, data structures, and the like, alone or in combination. Program instructions recorded on the recording medium may be those specially designed and constructed for the present invention, or they may be of the kind well-known and available to those having skill in the computer software arts. For example, the recording medium may be magnetic media such as hard disks, floppy disks and magnetic tapes, optical disks such as Compact Disk Read Only Memory (CD-ROM), digital video disks (DVD), Magnetic-Optical Media, such as floppy disks, and hardware devices specially configured to store and execute program instructions, such as ROM, random access memory (RAM), flash memory, and the like. do. Examples of program instructions may include machine language code such as those generated by a compiler, as well as high-level language code that may be executed by a computer using an interpreter or the like. Such hardware devices may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be apparent to those skilled in the art. In addition, although specific terms are used in the specification and the drawings, they are only used in a general sense to easily explain the technical contents of the present invention and to help the understanding of the present invention, and are not intended to limit the scope of the present invention.

Claims (16)

A user terminal for generating and transmitting an IP packet including information for collecting tag information or changing tag information of an IP core support tag;
An IP network for delivering an IP packet transmitted by the user terminal;
An IP core support reader connected to the IP network to receive an IP packet delivered by the user and convert the received IP packet into a packet accommodating an IP core function;
An IP core support tag for receiving a packet accommodating the converted IP core function and collecting or changing information according to packet contents;
Active IP-RFID system to accommodate the IP core function, characterized in that it comprises a. An IP communication unit for communicating with an IP network;
A reader unit for communicating with the IP core support tag;
A control unit configured to control transmission of an IP packet transmitted / received based on the IP communication unit and control of transmission of a packet accommodating an IP core function transmitted / received based on a reader unit;
IP core support reader, characterized in that it comprises a. The method of claim 2,
The control unit
An IP packet processing unit for performing an IP packet reception process received by the IP communication unit and an IP packet process to be delivered to the IP network through the IP communication unit;
A packet processing unit for receiving an IP core function for performing a packet transmission process for receiving an IP core function to be transmitted by the reader unit and a packet receiving process for receiving an IP key function for the reader unit to receive;
A packet converter converting the IP packet into a packet accommodating an IP core function and transmitting the packet to the packet processor accommodating the IP core function, and converting the packet accommodating the IP core function into an IP packet processor;
IP core support reader, characterized in that it comprises a. The method of claim 3,
The packet converter
Extracts ID information of an IP core support tag corresponding to a destination address included in the IP packet, user terminal address information corresponding to a source address information, and command information, and receives a packet accommodating an IP core function including the extracted information. Generating an IP core support reader. The method of claim 3,
The packet converter
IP ID including the ID information of the IP core support tag corresponding to the source address information included in the packet accommodating the IP core function, the user terminal address information and the command information corresponding to the destination address information, and the extracted IP packet including the extracted information. Generating an IP core support reader. The method of claim 1,
The header of the packet to accommodate the IP core function
And a destination address area and a source address area, and further comprising at least one of a control header, a next header, and a total length area. The method according to claim 6,
And a header of a packet following the packet accommodating the IP core function is an ICMP header, a UDP header, or a TCP header accommodating the IP core function. The method of claim 7, wherein
ICMP header to accommodate the core functions of the IP
An IP core reader that consists of an Echo Request and Echo Reply and includes a Type, Identifier, Sequence Number, and Payload area. A packet for receiving an IP core function received from an IP core support reader;
A packet accommodating at least one transmitting IP core function transmitted to the IP core support reader;
IP core support tag to send and receive. 10. The method of claim 9,
The address information of each packet that accommodates the transmission IP core function is
IP core support tag, which can be set to different destination communication addresses. Transmitting, by the user terminal, an IP packet for collecting tag information or changing tag information of a specific tag to an IP network;
The IP network transmitting the IP packet to a reader in communication with a particular tag;
A conversion step of the reader converting the IP packet into a packet accommodating an IP core function applicable to the tag;
Transmitting a packet accommodating the converted IP core function to the tag;
Active IP-RFID system operation method for accommodating the IP core function comprising a. The method of claim 11,
The conversion step is
Extracting user terminal address information corresponding to source information included in the IP packet;
Extracting tag ID information corresponding to destination address information included in the IP packet;
Extracting command information included in the IP packet;
Generating a packet containing an IP core function including the extracted information;
Active IP-RFID system operation method for accommodating the IP core function comprising a. The method of claim 12,
Generating a packet to accommodate the IP core function
Writing a header for a packet containing an IP core function including a destination address and a source address area, and further including at least one of a control header, a next header, and a total length area;
Active IP-RFID system operation method for accommodating the IP core function comprising a. The method of claim 11,
A generation step of generating, by the tag, a packet containing the IP core function for transmission;
Delivering a packet accommodating the transmission IP core function to a reader;
Converting, by the reader, a packet containing the IP core function for transmission into an IP packet;
Transmitting the converted IP packet to the user terminal through the IP network;
Active IP-RFID system operation method for accommodating the IP core function characterized in that it further comprises. 15. The method of claim 14,
The generating step
Writing, by the tag, user terminal address information as destination address information;
Writing its ID information as source information;
Active IP-RFID system operation method for accommodating the IP core function comprising a. The computer-readable recording medium which recorded the program which performs the operation method of any one of Claims 11-15.

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