KR101310335B1 - Rfid reader - Google Patents

Abstract

PURPOSE: A radio frequency identification (RFID) reader is provided to reduce unnecessary resources by including a lightweight application level event (LALE) based on an RFID middleware standards at electronic product code (EPC) global. CONSTITUTION: An RFID module receives tag information from outside and an LALE (200) transmits and receives a command or a performing result of a tag from the RFID module and communicates with a client application programming interface (API) and transmits and receives information for an API spec. The LALE comprises: a logic reader (220) which shares tag correction information of the RFID module for specs; a report manager (230) which makes a result for an operation of the spec and transmits the result to a subscriber; a trigger manager (240) operates and manages start and end conditions which are defined to the spec; a tag interpreter (250) which converts the tag information of the RFID module. [Reference numerals] (100) Client API; (210) LALE service; (220) Logic reader; (230) Report manager; (240) Trigger manager; (250) Tag interpreter; (300) RFID reader; (310) RFID module

Description

ＲＦＩＤ Reader {RFID reader}

The present invention relates to an RFID reader, and more particularly, incorporating lightweight Application Level Events (LALE) into a radio frequency identification (RALE) reader based on RFID middleware standardization in EPC global, for ease of operation, compatibility, and application independence. It relates to an RFID reader that can secure the.

In general, RFID (Radio Frequency Identification) technology stores the item identification information in a very small RFID tag, and the contactless automatic identification that transmits the product and the surrounding environment information to the network at a radio frequency through the antenna and the reader (processing) Technology.

In addition, RFID technology is a promising technology that will lead the future IT (Information Technology) market from the existing people-oriented informatization to goods-oriented. In addition, RFID technology is a next-generation core technology that can be applied to various fields such as information communication, logistics, supply chain, transportation, environment, and security as well as generality that can be easily applied to various fields by different frequency bands.

In the case of such RFID technology, technologies in the field of RFID hardware, such as RFID tags and reader devices, are mainly taking place, but gradually researches on RFID application software and middleware have been actively conducted. ought. If there is no middleware that collects tag data coming into the RFID reader device and processes meaningful information to send to the application, it may be inefficient in terms of hardware device use and application service implementation. In this case, it is called RFID middleware to increase the efficiency of the technology by providing an interface function between the RFID hardware and the application technology.

On the other hand, the EPC (Electronic Product Code) network proposed by EPC global, a de facto international standards organization related to RFID technology, and established as the current standard, tags all objects and objects to track and search objects and track goods movement. It is designed to be. The RFID user can read the RFID tagged object to obtain detailed information related to the object through the EPC network.

1 is a block diagram of a RFID middleware system according to the prior art.

Referring to FIG. 1, the conventional RFID middleware system 100 includes a reader interface processing module 110, a broadcasting processing module 120, an ALE core processing module 130, and an ALE interface 140 module.

The reader interface processing module 110 performs sensor management and connection management to process data sensed from various readers 160 or sensors.

The broadcasting processing module 120 connects the logical leader 220 to be used in the application service to the dynamically generated event queue 250.

The ALE interface module 140 provides an ALE standard interface to an application developer to support various application services, and serves to receive a request specification generated by the application service.

The ALE core processing module 130 performs processing on items specified in the ALE specification, such as request specification analysis, event cycle execution, filtering grouping, and report transmission.

The ALE specification creation module 150 serves to create a specification required by an application service user, and delivers the required specification to the RFID middleware system 100.

2 is a view showing the configuration of an RFID middleware engine system according to the prior art.

Referring to Figure 2, the conventional RFID middleware engine system is a Savant Core (210), ALE Core (230), which is composed of an Adapter (Adapter), Filter (Filter) and Logger (Logger) The monitoring database 222 includes an in-memory database 232.

The savant core unit 210 functions to collect and process tag data from an RFID reader according to the savant specification.

The AEL core portion 230 has a function of working in conjunction with the SABANT core according to the specification of the AL.

The in-memory database unit 232 stores tag data collected by Savant Core so that AEL can process Core.

The monitoring database unit 222 comprehensively aggregates various processes and devices performed by the middleware and the system.

However, in the conventional technology, the ALE middleware requires a separate server because it starts on an edge server (PC), and there are many difficulties in operation because of the large number of interface devices and products. In addition, the high price of the product has hindered the expansion of the product base.

Therefore, the present invention has been made to solve the above-mentioned problems, and its object is to incorporate a lightweight LALE based on the RFID middleware standard in the RFID reader in the RFID reader in an RFID reader and configure the product integrally so that it can be started without an edge server. It is to provide an RFID reader that can reduce resources.

In addition, another object of the present invention is to introduce the advantages of the ALE specification and to configure the product by reducing the weight of the ALE (ALE) to work smoothly in the embedded system RFID that can ensure the ease of work environment, compatibility and application independence To provide a leader.

According to an apparatus of the present invention for achieving the above object, an RFID reader interworking with the ALE (Interface ALE) interface to transmit and receive information of the tag, RFID reader for receiving the tag information from the outside; And a light weighted LA that transmits and receives a command or an execution result of a tag from the RFID module, communicates with a client API, and transmits and receives information on an API specification. It provides, the RFID reader.

Preferably, the LALE is an LALE service that communicates with the external client API and handles external requests and responses thereto; A logic reader that logically processes a physical reader and shares tag collection information of the RFID module with respect to a plurality of specifications; A report manager for producing a result of the specification operation and transmitting the result to a subscriber; A trigger manager for manipulating and managing a start condition and an end condition defined in the specification; And a tag analyzer for converting tag information of the RFID module.

The LALE supports StartTrigger and RepeatPeriod properties, which are start conditions of ECSpec, and supports Duration, StableSetInterval, and WhenDataAvailable properties, which are end conditions.

The LALE service is characterized by using an XML parser and TCP / IP protocol.

The logical reader logically processes the physical reader based on the EPC global ALE 1.1.1 Logical Reader API specification to ensure independence between the upper component of the LALE and the lower reader component of the serial port.

According to the present invention as described above, it is possible to start without an edge server by configuring the product integrally by embedding a lightweight LALE based on the RFID middleware standards in the RFID reader in the EPC global, it is possible to reduce unnecessary resources.

In addition, according to the present invention it is possible to ensure the ease of use, compatibility and application independence by introducing the advantages of the ALE specification and by configuring the product by lightening the ALE to operate smoothly in the embedded system.

Therefore, the present invention can reduce the size of the product and facilitate maintenance by incorporating a lightweight ALE with a standardized interface in the RFID reader to form an integrated product.

1 is a view showing the overall configuration of the RFID / USN integrated middleware device according to the prior art,
2 is a view showing the overall configuration of the RFID middleware engine system according to the prior art,
3 is an overall configuration diagram of an RFID reader according to an embodiment of the present invention;
4 is a block diagram of an RFID reader according to another embodiment of the present invention;

It is to be understood that the words or words used in the present specification and claims are not to be construed in a conventional or dictionary sense and that the inventor can properly define the concept of a term in order to describe its invention in the best possible way And should be construed in light of the meanings and concepts consistent with the technical idea of the present invention.

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

3 is an overall configuration diagram of an RFID reader according to an embodiment of the present invention.

As shown in FIG. 3, the configuration of the present invention includes an external client application program interface (API) 100; A light weight ALE (LALE) 200 having an interface for communicating with the client API 100 and being lightweight based on an ESP global specification that is defined as an RFID middleware standard for transmitting and receiving information on an API specification; And an RFID reader 300 which transmits and receives a command or a result of a tag through serial communication with the LALE 200.

The client API 100 refers to a user interface that directly receives functions by calling functions specified in the ALE Reader API and the Logical Reader API based on Transmission Control Protocol (TCP).

The LALE 200 represents a lightweight ALE (Lightweight ALE), a middleware standard that replaces the Savant of the existing Auto-ID as an official standard of EPC global that specifies only the external interface without specifying the internal structure and implementation technology. The basic functions are to receive data, delete received data, filter the read data, count, count, group, and report data.

In the present invention, it is a component developed based on the EPC global ALE 1.1.1 Read API specification, and is installed and operated as a service on the Android operating system (OS).

Here, the EPC global ALE 1.1.1 Read API specification refers to an xml document that describes information for receiving and reporting the EPC data read by the RFID reader 300 in a format desired by the client (user) in the event cycle.

In addition, the start condition of the ECSpec in the LALE 200 supports the StartTrigger and RepeatPeriod attributes, and the end condition includes Duration, StableSetInterval, and Data Available. WhenDataAvailable) property. It also supports INCLUDE / EXCLUDE Filter, Group Filter, CURRENT / ADDITION / DELETION ReportsSet. It also supports Spec-driven methods such as Subscriber, Poll, and Immediate.

Preferably, the LALE 200 includes a LALE service 210, a light weight ALELR 220, a report manager 230, a trigger manager 240, and a tag. It further comprises an interpreter (Lightweight TDT) (250).

The LALE service 210 is a component for external communication, processes an external request and a response thereto, and is composed of an XML parser and a TCP / IP communication component.

In particular, each command requested from the outside is developed in a Chain of Responsibility pattern, and is configured to be easily expanded in future commands.

The logical reader 220 is a component based on the EPC global ALE 1.1.1 Logical Reader API specification, and logically processes a physical reader so that the lower level of the upper component (ALE) and the serial port of the LALE are logically processed. It ensures independence between reader components, shares RFID tag collection information for various specifications, and serves as an interface to physical reader operations.

Here, the logical reader API may be matched one-to-one with a physical leader as a unit of a leader operated by ALE, and a plurality of logical readers may be used as one logical leader.

The report manager 230 refers to a component that creates a result of the operation of the specification and transmits the report to subscribers related thereto.

Here, the subscribers support TCP / IP-based XML ECReports as subscribers directly receiving ECReports, which is a result of running ECSpec.

In addition, by default, three Notification Workers run on each thread for reporting. Only protocol types that can be registered as Subscribers are supported. It also waits for at least 2 seconds if the subscriber is not connected and processes the next report transmission if it is not connected.

The trigger manager 240 refers to a set of timers and supporting components for driving start and end conditions defined in the ALE Spec.

At this time, StartTrigger, RepeatPeriod, and EmptyStartTrigger attributes are supported as start conditions supported by the ALE Spec. TableSetInterval property is supported, and DataAvailable occurs when collecting tags on SpecInstance, so it is implemented in LALE 200 instead of here.

The tag interpreter (Lightweight TDT) 250 is an EPC Gen2 tag interpreter supporting Sgtin-96 / 198 and gid-96, and implements a mutually convertible URI expression such as EPC-TAG / EPC-PURE / RAW / DECIMAL. In order to implement a lightweight embedded implementation, only the core is implemented and used, and no external reference API is implemented.

The RFID reader 300 is a component for implementing a protocol and API for communicating with an RFID module 310 that receives tag information from the outside, and includes a serial communication component, a RAW protocol parser, and the like. It directly implements decimal numbers, string conversions, and various operation commands.

In this case, since the RFID module 310 cannot simultaneously process instructions, the RFID module 310 is implemented based on a single tone, and the performance between the RFID module processor and the OS processor has a minimum process idle time (depending on the 1ms to 100ms instruction) for each instruction. Try to compensate the car. Also, to reduce power consumption and reader load, specifications such as EC Spec are operated only when operated by external request, and otherwise stand by.

The RFID reader according to the present invention configured as described above is configured to be equipped with a lightweight LALE in the RFID reader 300 so as to be suitable for providing the following services (functions).

First, the function supported by the EPCglobal ALE Read API can be lightened to be suitable for the RFID reader 300 and miniaturized to support the embedded application.

Second, the function supported by the EPCglobal ALE Logical Reader API can be lightened to fit the RFID reader 300 and miniaturized to support the application of the embedded.

Third, the function supported by the EPCglobal TDT may be lightened to fit the RFID reader 300 and may be miniaturized to support the embedded application.

Fourth, external communication and report transmission can be supported using XML protocol based on TCP / IP.

Fifth, based on TCP / IP, but similar to HTTP, all protocols have a request / response structure, and requests and responses transmitted after accessing the RFID reader 300 are provided. When it's done, we have a structure to disconnect the connection.

Therefore, the present invention having such a function can secure the convenience of the work environment, compatibility, and application independence by introducing the advantages of the ALE specification and configuring the product by lightening the ALE to operate smoothly in an embedded system.

4 is a block diagram of an RFID reader according to another embodiment of the present invention.

As shown in FIG. 4, the present invention provides an external client API 100 by incorporating an integrated RFID reader 300 having a lightweight LALE 200 integrated with a capturing application 400 or a tag protocol 500. It is also possible to configure a system for transmitting tag information with the.

In this case, the capturing application 400 captures tag information of the RFID reader 300 and transmits a stored application. The tag protocol 500 refers to a tag-only protocol to which UHF Class 1 Gen 2 is applied. .

While specific embodiments of the invention have been described and shown above, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Such modified embodiments should not be understood individually from the technical idea or viewpoint of the present invention, but should be included in the claims attached hereto.

100: Client API 200: Lightweight ALE (LALE)
210: LALE service
220: light weight ALELR
230: Report Manager
240: Trigger Manager
250: Tag interpreter (Lightweight TDT)
300: RFID reader 310: RFID module

Claims (6)

In the RFID reader which is connected to the interface with the ALE (ALE) to transmit and receive the tag information,
RFID module for receiving tag information from the outside; And
And a light weighted LA (LALE) that transmits and receives a command or an execution result of a tag from the RFID module, communicates with a client API, and transmits and receives information on an API specification.
The LALE is
An LALE service which communicates with the client API and processes external requests and responses thereto;
A logic reader that logically processes a physical reader and shares tag collection information of the RFID module with respect to a plurality of specifications;
A report manager for producing a result of the specification operation and transmitting the result to a subscriber;
A trigger manager for manipulating and managing a start condition and an end condition defined in the specification; And
And a tag analyzer for converting tag information of the RFID module.
delete The method of claim 1,
The LALE is based on the EPC global ALE 1.1.1 Read API specification, RFID reader. The method of claim 1,
The LALE supports StartTrigger and RepeatPeriod properties, which are start conditions of EC Spec, and supports Duration, StableSetInterval, and WhenDataAvailable properties, which are end conditions. The method of claim 1,
The LALE service uses an XML parser and TCP / IP protocol. The method of claim 1,
The logical reader is a RFID reader that logically processes a physical reader based on the EPC global ALE 1.1.1 Logical Reader API specification to ensure independence between the upper component of the LALE and the lower reader component of the serial port.

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