KR101304386B1 - Apparatus and Method for RFID Infrastructure Remote Monitoring - Google Patents

Abstract

According to an embodiment of the present invention, the RFID infrastructure remote control apparatus monitors a remote RFID infrastructure (Infra) including a component for processing global logistics information of an individual article level, and receives monitoring information according to the monitoring. A monitoring information processing unit for processing; A status diagnosis unit for requesting infrastructure status information of the infrastructure and monitoring the infrastructure status information provided by the component according to the request when the monitoring is performed; A failure determination unit that determines a failure of the infrastructure by using at least one of an infrastructure management rule for managing the infrastructure, a diagnosis result of the state diagnosis unit, the monitoring information, and the infrastructure state information; A failure cause analysis unit analyzing a failure cause of the infrastructure according to a determination result of the failure determination unit; And a failure recovery unit for recovering the failure by presenting a solution of the failure cause.

Description

RFP infrastructure remote control device and method {Apparatus and Method for RFID Infrastructure Remote Monitoring}

Embodiments of the present invention relate to an RFID infrastructure remote control apparatus and method. More specifically, it monitors RFID infrastructures installed remotely, for example, Radio Frequency Identification Reader, Middleware, and Electronic Product Code Information Services (EPCIS) devices, to prevent failures in the event of a failure. The present invention relates to an RFID infrastructure remote control device and method for quickly restoring to maintain continuous and stable synchronization of logistics information at an individual item level.

The contents described in the following sections provide background information related to the embodiments of the present invention, but it does not constitute a prior art.

In general, an RFID tag (Radio Frequency Identification Tag) is an integrated circuit (IC) chip capable of contactless wireless data transmission and reception, which contains information on the entire process of product production, distribution, storage, and consumption. The RFID reader reads the RFID information and processes the read information in connection with the information processing system to provide various additional services.

Such RFID technology, for example, attaches an RFID tag to a logistics in an international logistics transaction, receives EPC (Electronic Product Code) information corresponding to logistics identification information from an RFID tag, and manages the flow of logistics. It is used for.

However, in the event of a failure of an information processing system including an RFID reader in a specific place or a specific area, the logistics information at the level of individual goods, such as the manual operation of the operator or related personnel, must be made in order to grasp information on specific logistics in the conventional logistics management system. There was a problem that can not be confirmed continuously and stably.

An embodiment of the present invention is to provide an RFID infrastructure remote control apparatus and method for detecting a problem in advance through the real-time monitoring of the RFID infrastructure or to solve the problem quickly in the event of a failure.

The RFID infrastructure remote control apparatus according to the embodiment of the present invention performs monitoring for a remote RFID infrastructure (Infra) including a component (component) for processing global logistics information of the individual item level, monitoring according to the monitoring A monitoring information processor configured to receive and process information; A status diagnosis unit for requesting infrastructure status information of the infrastructure and monitoring the infrastructure status information provided by the component according to the request when the monitoring is performed; A failure determination unit that determines a failure of the infrastructure by using at least one of an infrastructure management rule for managing the infrastructure, a diagnosis result of the state diagnosis unit, the monitoring information, and the infrastructure state information; A failure cause analysis unit analyzing a failure cause of the infrastructure according to a determination result of the failure determination unit; And a failure recovery unit for recovering the failure by presenting a solution of the failure cause.

In addition, the RFID infrastructure remote control method according to an embodiment of the present invention performs the monitoring of the remote RFID infrastructure including a component for processing global logistics information of the individual article level, receiving and processing the monitoring information according to the monitoring Making; Requesting infrastructure status information of the infrastructure during the monitoring, and diagnosing the status of the infrastructure by receiving the infrastructure status information provided by the component according to the request; Determining a failure of the infrastructure by using at least one of an infrastructure management rule for managing the infrastructure, a diagnosis result of the state diagnosis unit, the monitoring information, and the infrastructure state information; Analyzing a cause of failure of the infrastructure according to a result of the determination; And providing the component with a solution to the cause of the failure to recover from the failure of the infrastructure.

According to an embodiment of the present invention, for example, real-time monitoring of the RFID infrastructure in which logistics transactions are made in the central control center during international logistics transactions may enable continuous and stable synchronization of global logistics information at the level of individual goods.

1 is a view showing a RFID infrastructure remote control system according to an embodiment of the present invention,
2 is a block diagram showing the structure of the RFID infrastructure remote control device of FIG.
3 is a diagram illustrating a method for remotely controlling an RFID infrastructure of the system of FIG. 1;
4 is a view showing a method of driving the RFID infrastructure remote control device of FIG.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are assigned to the same components as much as possible even though they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In addition, in describing the component of this invention, terms, such as 1st, 2nd, A, B, (a), (b), can be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected to or connected to the other component, It should be understood that an element may be "connected," "coupled," or "connected."

1 is a view showing an RFID infrastructure remote control system according to an embodiment of the present invention, Figure 2 is a block diagram showing the structure of the RFID infrastructure remote control device of FIG.

1 and 2, the RFID infrastructure remote control system according to an embodiment of the present invention includes an infrastructure status information provider 100, the communication network 110 and the RFID infrastructure remote control device 120.

Here, the infrastructure state information provider 100 includes an RFID reader 101 and an EPCIS device 105 installed in each region or each place, and includes a middleware device 103 and the like. The RFID reader 101 reads the product information from the tag provided in the individual article, and the middleware device 103 filters and collects a large amount of tag data collected from the plurality of RFID readers 101. It manages the tag data flow between the RFID reader 101 and the application application, the EPCIS device 105, the event information associated with the EPC in the RFID tag attached to the product and the attribute information that can interpret the information To provide services.

For example, if the RFID reader 101 of the infrastructure status information provider 100 located in a specific region or a specific place in Australia has been read out for the individual item, the EPCIS device 105 may store the relevant information, for example, a middleware device (eg, a middleware device). After receiving and processing through 103, the individual item related information may be provided to the RFID infrastructure remote control device 120 via the communication network 110. The RFID infrastructure remote control device 120 monitors the RFID infrastructure by receiving status information by requesting a connection or operation state of the RFID reader 101, the middleware device 103, and the EPCIS device 105.

The communication network 110 is preferably an internet network according to an embodiment of the present invention, and may be referred to collectively as a wired and wireless communication network.

The RFID infrastructure remote control device 120 monitors the operating states of the RFID infrastructure, that is, the RFID reader 101, the middleware device 103, and the EPCIS device 105, which are provided nationwide or globally, to prevent failures in advance. In the event of a failure, recover quickly. To this end, the RFID infrastructure remote control apparatus 120 may include a display unit 121 and a control system unit 123. The display unit 121 may be installed in a central control center for monitoring the RFID infrastructure for each base. It may be made of a screen or a computer monitor, the control system unit 123 communicates with the infrastructure state information provider 100 to control to display the logistics information, such as individual goods on the display unit 121.

In more detail, as shown in FIG. 2, the control system unit 123 according to the embodiment of the present invention may include a traffic processing unit 200 and an infrastructure state checking unit 210. Here, the traffic processing unit 200 may include a control unit (not shown) and an interface unit. The control unit controls overall signals or data processed by the control system unit 123, and the interface unit may interoperate with the communication network 110. It serves as an interface. The interface unit may perform a process such as information conversion in the process. In addition, the infrastructure status checker 210 may include a monitoring information processor 211, a status diagnosis unit 213, a failure determination unit 215, a failure cause analysis unit 217, and a failure recovery unit 219. .

For example, the monitoring information processing unit 211 receives and processes the infrastructure state information on the RFID infrastructure configuration information, the operation state, the processing state and network connection state of the individual items, and the like for the infrastructure state information provider 100, and the processed information is traffic The display unit 121 may be provided to the display unit 121 under the control of the processor 200. Here, the configuration information is information on which component of the infrastructure state information provider 100 includes a component, that is, any component among the RFID reader 101, the middleware device 103, and the EPCIS device 105. For example, when the service provider includes only the RFID reader 101 and the EPCIS device 105 in addition to the middleware device 103 when the infrastructure is configured, information on this is shown.

The status diagnosis unit 213 collects the status information provided from the plurality of infrastructure status information providers 100, for example, the failure alert notification information among the status information, when the infrastructure status information is requested, and the infrastructure status of the infrastructure status information provider 100. May be diagnosed, and the diagnosis result may be provided to the failure determining unit 215. For example, the status diagnosis unit 213 may receive the status information provided by the plurality of infrastructure status information providers 100 to determine that the infrastructure status information provider 100 of the specific region has provided the failure alert notification information. In addition, the infrastructure status is diagnosed based on the information provided by the infrastructure status information provider 100 of a specific region in which the failure alert notification information is provided. In this case, as a result of diagnosis, the state diagnosis unit 213 outlines the stabilization state of the current system, such as the infrastructure state of the specific infrastructure state information provider 100 'good', 'possible failure', 'failure occurs', and the like. You will be able to diagnose. In addition, in this process, the status diagnosis unit 213 may indicate that the infrastructure state of the region is very unstable according to the diagnosis result by displaying 'red' on the display unit 121, and the display unit 121 in a safe state. ) Can be represented by the notation 'blue'.

The failure determining unit 215 intensively monitors the infrastructure state information provider 100 having a failure or the infrastructure state information provider 100 having the possibility of failure based on the diagnosis result of the state diagnosis unit 213. Determine disability judgments. To this end, the failure determination unit 215 receives and analyzes the status information, the failure alert notification information, the diagnosis result, and the infrastructure related management rules provided by the infrastructure status information provider 100 which may have a failure or possibility in real time, and based on this. The final disability judgment can be made. For example, if a primary failure or failure is primarily determined, but the management rules for managing the infrastructure are referenced, and there is no clear basis for this, the final failure determination may be withheld.

The failure cause analysis unit 217 analyzes the cause of the failure when the failure decision is finally made according to the determination result of the failure determination unit 215, and if it is determined that the failure may occur, what is the cause of the cause? Will be specifically identified. For example, if a failure occurs, it may be determined in more detail whether it is a cause in a network or a problem in a specific component of the infrastructure state information provider 100. In addition, if it is determined by the surrounding infrastructure situation, if there is a possibility that a failure occurs in a specific infrastructure status information provider 100, the cause for this can also be identified. For example, if you are going through Tokyo to form a logistics network between Seoul and Sydney, if there is a problem with the network or equipment in Sydney, it can be determined that there is a possibility of failure in the infrastructure status information provider 100 in Sydney. In addition, the failure cause analysis unit 217 may determine the possibility of failure according to the surrounding circumstances.

The failure recovery unit 219 may provide an appropriate recovery solution to the infrastructure state information provider 100 according to the determination result of the failure cause analysis unit 217. In an embodiment of the present invention, the recovery solution is meant to include providing failure prevention information when there is a possibility of failure. For example, if a problem occurs in a specific component of the specific infrastructure state information provider 100 as a result of the failure cause analysis unit 217, the disaster recovery unit 219 repairs or replaces any part of the corresponding component. It can provide information on whether it can be normalized, and if the problem is related to the network, it may be possible to normalize the operation by resetting the bypass path. To this end, the disaster recovery unit 219 may provide a related solution by the operator's management, or may automatically search for and provide information managed separately in a database.

The control system unit 123 according to an embodiment of the present invention may be referred to as a Global Logistics Information Synchronization RFID Infrastructure Management System (GLIS-RIM). The GLIS-RIM performs intelligent RFID infrastructure real-time remote management and prevents RFID infrastructure failure. It can consist of embedded software for automatic identification and data capture (AIDC) device integration and RFID middleware real-time remote management software for real-time detection. GLIS-RIM detects the abnormal state of the systems by remotely monitoring the operating state and network connection state of the RFID reader 101, the middleware device 103, and the EPCIS device 105 in real time. Provide the function. In addition, it analyzes the various types of detected RFID infrastructure anomalies and provides the ability to recognize the exact failure situation and establish a recovery plan for it, and to perform failure recognition / recovery autonomously based on recovery policies and rules. Provide the function. Furthermore, it can be linked with GLIS-MEP (Global Logistics Information Synchronization Management & Enforcement Point) to detect logistics information synchronization errors due to RFID infrastructure failure.

GLIS-RIM's subsystems include intelligent AIDC device management components, RFID reader management components (RIM-RMCs), RFID middleware management components (RIM-MMCs), and EPCIS management components (RIMs). -ISMC: RIM-EPCIS Management Component, RIM-RMCC: RIM-RFID Infra Remote Management & Control Component, RIM-PMC: RIM-Policy-based Management & Control Component). At this time, the management target component of GLIS-RIM is RIM-RMC, RIM-MMC, RIM-ISMC, and may include a network connection state. Here, the RIM-RMCC may correspond to the infrastructure state check unit 210 of FIG. 2, and thus the monitoring information processor 211, the state diagnosis unit 213, the failure determination unit 215, and the failure cause analyzer 217 and the failure recovery unit 219 may be included.

The RIM-RMC collects statistical information related to the operation state and operation of the RFID reader 101, detects an abnormal state defined by the administrator, generates alarm information, and delivers the alarm information to the RIM-MMC and the RIM-RMCC. In principle, RMC only supports communication with the RIM-MMC. Alarm delivery to the RIM-RMCC and RIM-RMC control by the RIM-RMCC must be performed via the RIM-MMC. In this case, the alarm may be directly transmitted to the RIM-RMCC only when the alarm of the RMC cannot be delivered to the RIM-RMCC due to a failure of the RIM-MMC. In addition, the RIM-MMC collects statistical information related to the operation state and operation of the RFID middleware device 103, detects an abnormal state defined by the administrator, generates information, and delivers the information to the RIM-RMCC. RIM-ISMC collects statistical information related to operation status and operation of Capture I / F and Query I / F of EPCIS device 105, and generates information by detecting abnormal status prescribed by the administrator. It is then preferred to deliver it to the RIM-RMCC.

RIM-RMCC detects RFID infrastructure failures based on abnormal status information and network connection status information collected from RIM-RMC, RIM-MMC, and RIM-ISMC and pinpoints the cause of failure. If recoverable RFID infrastructure failure can be repaired according to a preset automation rule, automatic recovery is controlled by controlling RIM-RMC, RIM-MMC, and RIM-ISMC. Be sure to carry out the recovery process. It also reports fault conditions to GLIS-MEP to detect logistical synchronization errors in global supply chain management (SCM) using a faulty RFID infrastructure and to predict the supply chain that is expected to fail.

Looking at the above function in more detail with reference to Figure 2, the monitoring information processing unit 211 is to determine the RFID middleware, EPCIS status monitoring information for each management component, that is, RIM-RMC, RIM-MMC, RIM Intelligent AIDC device status monitoring can receive requests from RIM-MMC through RMC-MMC's network connectivity, data collection operations, data processing operations, and data report delivery behavior monitoring rather than requesting RMC directly. In addition, status monitoring for configuration information, operation, processing, and network connection of RFID middleware, and status monitoring request for operation, processing, and network connection of EPCIS are possible.

Also, when the RFID infrastructure failure alert is received from the RIM-RMC, RIM-MMC, and RIM-ISMC, the status diagnosis unit 213 transmits the RFID infrastructure from each management component to the RFID infrastructure for the purpose of determining whether the RFID infrastructure has failed. In order to diagnose the current state of the system, and to diagnose the state of the intelligent AIDC device, the RMC can ping test the RFID reader 101, telnet access, and send a command to check the RFID state to the RFID reader 101, and RFID middleware. In order to diagnose the condition, the RIM-MMC may perform a method of calling Poll or Immediate to the RFID middleware device 103.

The failure determining unit 215 is configured to determine whether or not the RIM-RMCC has an RFID infrastructure failure from the RFID infrastructure failure alarm received from the RIM-RMC, RIM-MMC, or RIM-ISMC, from each management component based on the corresponding RFID infrastructure management rules. Based on the result of the diagnosis of the received RFID infrastructure status, it is determined whether the RFID infrastructure has failed.In this case, the RFID infrastructure failure determination is started from the RFID infrastructure failure alarm received from each component (Push Type), or the RIM-RMCC is sent to each component. Polling Type can be started by monitoring request.

If it is determined that the failure of the RFID infrastructure, the failure cause analysis unit 217 enables the RIM-RMCC to identify the cause of the RFID infrastructure failure based on the RFID infrastructure management rules.

The failure recovery unit 219 recovers the corresponding management component, that is, RIM-RMC, RIM-MMC, RIM-ISMC, network, etc., determined as a failure according to the RFID infrastructure recovery and control policy received from the RIM-PMC. do. In this case, the RIM-RMCC may perform a function of interpreting the RFID infrastructure recovery and control policy message received from the RIM-PMC and converting the corresponding component to execute the recovery and control policy. The RIM-RMCC performs the recovery process according to a predefined recovery rule and generates control commands and delivery information for controlling the management component.

In addition, the RIM-RMCC may further include a service access control unit, a connection / release unit, a management rule setting unit, and a remote control unit. Here, the service access control unit, for example, is related to the service access of the RFID middleware device 103 so as to determine the use authority of a specific service requested by an authenticated user so that only the authorized user can use the service. Database and control API that manages resource, permission, role, and user identity information can be provided. The connection / disconnection is the ability for RIM-RMCC to connect to or disconnect from RIM-RMC, RIM-MMC, and RIM-ISMC to collect RFID infrastructure monitoring information and fault alerts, and to communicate recovery and control rules. Function to connect and disconnect with RIM-PMC to receive control policy, function to connect and disconnect with GLIS-MEP subsystem to deliver it to GLIS-MEP service system when RIM-RMCC determines RFID infrastructure failure, and In order to access and authenticate / authorize RIM-RMCC, it performs connection and disconnection function with GLIS-Sec. Here, GLIS-Sec represents Global Logistics Information Synchronization Security. The management rule setting unit performs a rule setting function for creating, modifying, and deleting an RFID infrastructure management rule for determining whether an RIM-RMCC has an RFID infrastructure failure. In addition, parameter setting and change function for rule setting and rule instance creation, stop, resume, and delete for each RFID infrastructure can be additionally performed. The infrastructure remote controller may perform a function for the RIM-RMCC to set parameters for receiving related information for RFID infrastructure monitoring and remote control, collection conditions, report reporting conditions, and intelligent AIDC device stop and restart.

RIM-PMC provides the ability to define and execute standardized RFID infrastructure management information, or policy models, that can manage and control a variety of RFID systems installed in a global supply chain involving multiple companies in a common way. RIM-PMC provides users with an easy and simple way to manage a variety of heterogeneous RFID infrastructures, while providing the ability to autonomously control the RFID infrastructure at the system level based on PBNM (Policy-Based Network Management) technology. do.

3 is a diagram illustrating a method for remotely controlling RFID infrastructure of the system of FIG. 1.

Referring to FIG. 3 together with FIG. 1, the RFID infrastructure remote control apparatus 120 performs online monitoring of the components of the infrastructure status information provider 100 by connecting online to the infrastructure status information provider 100. Receives the infrastructure status information according to (S301). For example, the RFID infrastructure remote control apparatus 120 is connected online to the RFID reader 101, the middleware device 103, and the EPCIS device 105 to provide component information, operation status, and infrastructure status information about network status. Can be provided.

Subsequently, the RFID infrastructure remote control apparatus 120 uses the infrastructure status information to determine a failure situation such as whether a failure occurs in the components constituting the infrastructure status information provider 100 or whether there is no possibility of failure (S303). . For example, the infrastructure status information provider 100 may provide failure alert notification information together when providing infrastructure status information. The RFID infrastructure remote control apparatus 120 may determine failure states of components by determining failure alert notification information. Could be.

If it is determined that a failure has occurred or a failure may occur, the RFID infrastructure remote control apparatus 120 determines a cause of the failure and generates a failure recovery solution (S305). For example, if the failure of the components of the RFID reader 101, the middleware device 103, the EPCIS device 105, etc. may be calculated by querying the RIM-PMC, etc. for the solution to the failure recovery.

After the RFID infrastructure remote control device 120 provides a failure recovery solution to the infrastructure status information provider 100 (S307), the infrastructure status information provider 100 according to the failure recovery solution infrastructure, that is, RFID reader 101 In this case, the state of the components of the middleware device 103 and the EPCIS device 105 and the network between the devices are normalized (S309).

4 is a view showing a method of driving the RFID infrastructure remote control device of FIG.

Referring to FIG. 4 together with FIGS. 1 and 2, the RFID infrastructure remote control apparatus 120 performs monitoring on the RFID infrastructure, for example, and receives infrastructure status information according to a request (S401). Such infrastructure status information may include failure alarm notification information informing of components constituting the RFID infrastructure, that is, the RFID reader 101, the middleware device 103, the EPCIS device 105, and the failure alarm for the network between the devices. have.

Subsequently, the RFID infrastructure remote control apparatus 120 determines failure alert notification information included in the received infrastructure status information or infrastructure status information to determine whether or not a failure occurs in a component or a network between components constituting the RFID infrastructure. It is determined whether or not there is a failure situation (S403).

If it is determined that there is no obstacle (S405), the RFID infrastructure remote control device 120 will continue to monitor the RFID infrastructure, but if it is determined that there is a failure factor (S405), the RFID infrastructure remote control device 120 The cause of the failure is analyzed to generate a failure recovery solution (S407). In this process, the RFID infrastructure remote control apparatus 120 may generate various solutions depending on whether a problem is a component of the RFID infrastructure or a network problem between the components. May be provided or a query may be made to the RIM-PMC to produce a solution.

Afterwards, the RFID infrastructure remote control apparatus 120 provides the calculated failure recovery solution to the RFID component for normalizing the RFID infrastructure (S409). As a result, the components constituting the RFID infrastructure are normalized by performing a disaster recovery according to a disaster recovery solution.

In the above description, all elements constituting the embodiments of the present invention are described as being combined or operating in combination, but the present invention is not necessarily limited to the embodiments. That is, all of the components may be selectively combined to operate in one or more within the scope of the present invention, and those skilled in the art to which the present invention pertains may vary without departing from the essential characteristics of the present invention. Modifications and variations will be possible. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention but to describe the scope of the technical spirit of the present invention by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of the same shall be included in the scope of the present invention.

An embodiment of the present invention is applicable to an RFID infrastructure remote control apparatus and method, and according to an embodiment of the present invention, for example, by enabling real-time monitoring of an RFID infrastructure in which logistics transactions are performed at a central control center during international logistics transactions. Global logistics information synchronization at the level of individual goods will be maintained continuously and stably.

100: infrastructure status information provider 101: RFID reader
103: middleware device 105: EPCIS device
110: communication network 120: RFID infrastructure remote control device
121: display unit 123: control system unit
200: traffic processing unit 210: infrastructure status check unit
211: monitoring information processing unit 213: status diagnostic unit
215: failure determination unit 217: failure cause analysis unit
219: disaster recovery unit

Claims (9)

A monitoring information processing unit for monitoring a remote RFID infrastructure (Infra) including a component for processing global logistics information of an individual article level, and receiving and processing the monitoring information according to the monitoring;
Requesting infrastructure status information for the remote RFID infrastructure during the monitoring, and receiving the infrastructure status information from a plurality of infrastructure status information providers according to the request to diagnose the status of the remote RFID infrastructure and generate a diagnostic result State diagnosis unit;
Based on the diagnosis result of the state diagnosis unit, the possibility of failure of the infrastructure of any one of the infrastructure state information providers among the plurality of infrastructure state information providers is primarily determined by using the monitoring information and the infrastructure state information, and then referring to the state via the logistics network. Disability determination unit for determining the final failure;
A failure cause analysis unit analyzing a failure cause of the infrastructure of the any one infrastructure state information provider according to a determination result of the failure determination unit;
Interact with the policy-based RFID infrastructure autonomous control system (RIM-PMC: RIM-Policy-based Management & Control Component) to interpret the infrastructure recovery and control policy messages received from the RIM-PMC to recover the failure. A failure recovery unit providing a solution to any one of the infrastructure state information providers ; And
The remote control unit performs a parameter setting function for receiving the relevant information for the monitoring and remote control, collecting conditions, report reporting conditions, and stopping and restarting the provided Automatic Identification and Data Capture (AIDC) device .
Including ,
In order to detect logistic information synchronization errors due to RFID infrastructure failures, it connects with GLIS-MEP (Global Logistics Information Synchronization Management & Enforcement Point) to report the failure status to the GLIS-MEP and to use the global SCM (Supply Chain) RFID infrastructure remote control device for detecting the synchronization information synchronization error in the (Management Management) and predict the supply chain that is expected failure . The method of claim 1, wherein the component,
An RFID reader for reading the logistics information by performing radio frequency identification (RFID) communication; And
EPCIS device that receives and processes the electronic product code (EPC) information read by the RFID reader, and provides the event information associated with the EPC in the RFID tag and the attribute information related service for interpreting the event information.
RFID infrastructure remote control device comprising a. The method of claim 2,
The component further includes a middleware device,
And the middleware device connects the RFID reader and the EPCIS device to each other to relay the EPC information. The method of claim 3,
At least one of the RFID reader, the middleware device and the EPCIS device includes an infrastructure state information processor,
The infrastructure state information processing unit RFID infrastructure remote control apparatus, characterized in that for providing the infrastructure state information according to the request. The method of claim 1,
And the monitoring information comprises at least one of configuration information of the component, operation state information of the component, and connection state information of the network between the components. The method of claim 1,
The RIM-PMC provides a standardized RFID infrastructure remote control apparatus for providing management and control of a plurality of RFID systems in a common way . Performing monitoring on a remote RFID infrastructure (Infra) including a component for processing global logistics information of an individual article level, and receiving and processing the monitoring information according to the monitoring;
Requesting infrastructure status information for the remote RFID infrastructure during the monitoring, and receiving the infrastructure status information from a plurality of infrastructure status information providers according to the request to diagnose the status of the remote RFID infrastructure and generate a diagnostic result step;
As a result of the diagnosis, the possibility of failure of the infrastructure of any one of the infrastructure status information providers among the plurality of infrastructure status information providers is primarily determined by using the monitoring information and the infrastructure status information, and then the status is referred to the log network network. Determining a failure;
Analyzing the cause of the failure of the infrastructure of any one of the infrastructure state information providers according to the result of determining the failure;
Interact with the policy-based RFID infrastructure autonomous control system (RIM-PMC: RIM-Policy-based Management & Control Component) to interpret the infrastructure recovery and control policy messages received from the RIM-PMC to recover the failure. Providing a solution to any one of said infrastructure status information providers ; And
Performing a parameter setting function for receiving relevant information for monitoring and remote control, collecting conditions, report reporting conditions, and stopping and restarting the provided automatic identification and data capture (AIDC) device .
Including,
Global SCM (Supply Chain Management) that reports the failure status to the GLIS-MEP and uses the failure infrastructure in connection with GLIS-MEP (Global Logistics Information Synchronization Management & Enforcement Point) to detect errors in logistics information caused by RFID infrastructure failure. RFID infrastructure remote control method for detecting the synchronization error in the logistics information and predict the supply chain chain failure is expected . The method of claim 7, wherein
Receiving and processing the monitoring information according to the monitoring,
And displaying the processed monitoring information on a display unit. The method of claim 7, wherein
Providing the component of the cause of the failure to the component,
And querying a policy-based RFID infrastructure autonomous control system (RIM-PMC: RIM-PMC) based on the cause of the failure to calculate the solution.

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