KR20210123583A - Communication method for distribution intelligence communication apparatus using integrated wired and wireless mesh network - Google Patents

Abstract

The present invention relates to a communication method for a communication apparatus of an intelligent distribution system an using integrated wired/wireless mesh network, which increases stability and reliability of a communication section between an intelligent distribution server and a terminal device. According to the present invention, the communication method comprises the following steps: determining, by a control unit of a master, a type of received data when the data is received while a communication apparatus of an intelligent distribution system operates as the master; checking, by the control unit, whether the data is a last hop when the type of the received data is a type of data received from another node; when the data is not the last hop, checking, by the control unit, routing information and transmitting the data to the next node through a radio (RF) mesh network; when the data is a loopback or a heartbeat on the basis of a data type determination result, transmitting feedback to a counterpart node, returning to the start to be switched to a message reception standby state; and when the data is the last hop or when the data type is a distributed network protocol (DNP)/CONFIG message, performing, by the control unit, a process for processing an end message.

Description

Communication method of distribution intelligent communication device using wired/wireless integrated mesh network

The present invention relates to a communication method of a distribution intelligent communication device using a wired/wireless integrated mesh network, and more particularly, an optical modem and a TRS (Trunked Radio System, frequency common communication) modem are integrally configured, so that the MASTER terminal is transmitted from the NMS server. Wired section routing when the data including the information is transmitted to the next node by updating subnet information or dynamically configuring wired/wireless mesh networks through information exchange with other adjacent subnet devices and setting the optimal routing path to the final destination Alternatively, it relates to a communication method of an intelligent distribution communication device using a wired/wireless integrated mesh network, which enables communication between an intelligent distribution system and a terminal device using a wireless Ad-Hoc (or Hopping) function.

In general, a distribution intelligent switchgear terminal unit (FRTU: Feeder Remote Terminal Unit) and a remote server require a communication line for various measurement, control, and event reception. As a method, a communication line of the Digital TRS TMO (Trunked Mode Operation) SDS (Short Data Service) method is used.

In addition, the optical line used in the wired method can further extend the communication line in the corresponding section through wireless communication between the master/slave using the TRS DMO (Direct Mode Operation) method, which is a wireless method. has been extended to 3 lines and is currently being used in the field. In cases where the new switchgear installation place cannot provide optical communication lines (ie, optical line construction is not possible or TMO base station signal shaded areas, etc.) The master modem is installed in the new location, and the slave modem is installed in new locations to extend the line through wireless communication between the master/slave and use it.

As described above, since optical modem (RT) and DMO (Direct Mode Operation) modem using optical line are separately installed and used in the field, there is a problem in performing separate modem installation work and communication status management. In addition, if the space to install the optical modem (RT) and DMO modem according to the site installation conditions is narrow, there are difficulties during installation work. In the event of a disability, there is a difficult problem in resolving the disability. In addition, when the optical modem or DMO modem is disconnected from communication with the remote server, there is a problem that communication is also cut off at the lower slave section.

In addition, the existing communication method is configured so that one master terminal can handle up to three slaves, and the master terminal sends and receives data through optical modem RS-232C communication. Communication interruption occurs in the relevant section due to communication interruption or delay processing due to other reasons. Also, even if the optical modem line is unavailable or the optical modem fails, the corresponding Master/Slave section all fails.

Therefore, in order to solve this problem, an optical complex integrated communication system (ie, a modem device) for power distribution intelligence that integrates an optical modem (RT) and a DMO modem is required.

The background technology of the present invention is disclosed in Korean Patent Application Laid-Open No. 10-2018-0040274 (published on April 20, 2018, intelligent distribution system and its communication method).

According to one aspect of the present invention, the present invention was created to solve the above problems, in which an optical modem and a Trunked Radio System (TRS) modem are integrally configured, so that the MASTER terminal is a network management system (NMS). System) updates subnet information from the server or dynamically configures a wired/wireless mesh network through information exchange with other adjacent subnet devices, sets an optimal routing path to the final destination, and delivers data including the information to the next node To provide a communication method of an intelligent distribution communication device using a wired/wireless integrated mesh network, which enables communication between the intelligent distribution system and the terminal device using the time wired section routing or wireless Ad-Hoc (or hopping) function. There is a purpose.

In the communication method of the intelligent distribution communication device using the wired/wireless integrated mesh network according to an aspect of the present invention, in the communication method of the intelligent distribution communication device using the wired/wireless integrated mesh network, when the intelligent distribution communication device operates as a master, data is received, the control unit of the master determining the received data type; checking, by the controller, whether the data is a last hop when the data type is data received from another node; when the data is not the last hop, the controller confirms routing information and transmits the data to the next node through a radio mesh network (RF Mesh Network); As a result of determining the data type, if the data is a loopback (LOOP BACK) or a heartbeat (HEARTBEAT), sending feedback to a counterpart node, returning to the start and switching to a message reception standby state; and when the data is the last hop or the data type is a DNP/CONFIG message, performing, by the controller, a process for processing the end message.

In the present invention, when the intelligent distribution communication device operates as a master, it is characterized in that data is received through an optical network or a wireless network.

In the present invention, the step of the controller determining the received data type is characterized in that it is determined through which network the received data is received.

In the present invention, the loopback (LOOP BACK) is a function of checking whether there is an error in communication between nodes of a subnet, and is characterized in that it is performed according to a set period.

In the present invention, the heartbeat (HEARTBEAT) is characterized in that it is a function of confirming a mutual link for establishing a routing path between all nodes.

In the present invention, the data is characterized in that it is a DNP (Distributed Network Protocol) message.

In the present invention, the step of the control unit performing a process for processing the end message comprises: checking, by the control unit, whether the data is a DNP message; and if the data is not a DNP message, transmitting feedback corresponding to CONFIG setting or status information report to an NMS (Network Management System) server through an optical network, returning to the start and switching to a message reception standby state; characterized in that

In the present invention, the step of the control unit performing a process for processing the end message, the control unit, when the data is a DNP message, the step of checking a source (Source); And as a result of checking the source, if the data is received from a Local FRTU or a Remote Node, transferring the data to a Front End Processor (FEP) server, returning to the start and switching to a message reception standby state; further comprising characterized.

In the present invention, the step of the control unit performing a process for processing the end message includes, as a result of the control unit checking the source, if the data is data received from the FEP, it analyzes the destination address of the data and finally checking whether the destination has the same address as the local FRTU associated with the master itself or whether the remote FRTU (Remote FRTU); And when the destination of the data matches the "Local FRTU" connected to the master itself, transferring the data to the FRTU, returning to the start and switching to a message reception standby state; characterized in that it further comprises.

In the present invention, the step of the control unit performing a process for processing the end message, when the control unit checks the destination of the data and matches the master's own Local FRTU, message collision and transmission delay establishing a routing path and transmitting data to the routing node including this information to prevent the and transmitting the data converted to the node protocol to the next node after repacking the data including the transaction line ID for link management.

In the communication method of the intelligent distribution communication device using the wired/wireless integrated mesh network according to another aspect of the present invention, in the communication method of the intelligent distribution communication device using the wired/wireless integrated mesh network, when the intelligent distribution communication device operates as a slave, data is received, the control unit of the slave determining the data type; as a result of determining the data type, if the data is data received from another node, checking whether the controller is a last hop; when the data is not the last hop, the controller confirms routing information and transmits the data to the next node through a radio mesh network (RF Mesh Network); As a result of determining the data type, if the data is a loopback (LOOP BACK) or a heartbeat (HEARTBEAT), sending feedback to a counterpart node, returning to the start and switching to a message reception standby state; and when the data is the last hop or the data type is a DNP/CONFIG message, performing, by the controller, a process for processing the end message.

In the present invention, when the intelligent distribution communication device operates as a slave, it is characterized in that data is received only through the wireless network.

In the present invention, the data is characterized in that it is a DNP (Distributed Network Protocol) message.

In the present invention, the step of the control unit performing a process for processing the end message comprises: checking, by the control unit, whether the data is a DNP message; and when the data is not a DNP message, transmitting feedback corresponding to the CONFIG setting or status information report to the NMS (Network Management System) server, returning to the start and switching to the message reception standby state; characterized in that it comprises a do.

In the present invention, the step of the control unit performing the process for processing the end message, the control unit, when the data is a DNP message, the step of checking a source (Source); As a result of checking the source, if the data is data received from the FEP, checking the destination address of the data to check whether the final destination matches the local FRTU address associated with the slave itself; and when the destination of the data matches the "Local FRTU" connected to the slave itself, transferring the data to the FRTU, returning to the start and switching to a message reception standby state.

In the present invention, the step of the control unit performing a process for processing the end message includes, when the control unit checks the destination of the data and does not match the slave's own Local FRTU, link management of the data After repacking including the transaction ID for , transmitting data in broadcast form through the wireless mesh network, returning to the start and switching to a message reception standby state; characterized by further comprising.

According to one aspect of the present invention, an optical modem and a TRS modem are integrally configured so that the MASTER terminal updates subnet information from the NMS server or dynamically configures a wired/wireless mesh network through information exchange with other adjacent subnet devices. When the data including the information is transmitted to the next node by setting the optimal routing path to the final destination, the communication between the intelligent distribution system and the terminal is By making it possible to perform, it is easy to install and open on-site sites, and monitoring, status management, and setting management of each site are possible. To improve the stability and reliability of the section.

1 is an exemplary diagram showing a schematic configuration of a distribution intelligent communication device according to an embodiment of the present invention.
2 and 3 are exemplary views showing the configuration of an RF Mesh Network related to an embodiment of the present invention.
4 is a flowchart for explaining a control method of a distribution intelligent communication device according to an embodiment of the present invention.

Hereinafter, an embodiment of a method for controlling a distribution intelligent communication device according to the present invention will be described with reference to the accompanying drawings.

In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of the user or operator. Therefore, definitions of these terms should be made based on the content throughout this specification.

1 is an exemplary diagram showing a schematic configuration of a distribution intelligent communication device according to an embodiment of the present invention. 1 is an exemplary diagram showing the configuration of a master terminal and a slave terminal of the intelligent distribution communication device in this embodiment, and when operating as a slave terminal according to a mode setting (Master or Slave), an optical modem may be excluded.

As shown in FIG. 1 , the intelligent distribution communication device according to an embodiment of the present invention includes a power supply 210 , a digital TRS module 220 , a CPU (or control unit) 230 , a Flash 240 , and an EEPROM. 250 , RS-232C interfaces 291 and 292 , and an optical modem 293 . It may further include a reset switch 260 , a test switch 270 , and an LED 280 .

The power supply 210 receives power from the power supply PWR and provides power suitable for the digital TRS module 220 and other components.

For example, the voltage of the power supply PWR may be 24V, the voltage of power provided to the digital TRS module 220 may be 14VDC, and the voltage of power provided to other components may be 3.3VDC, but is limited thereto. no.

The digital TRS module 220 is a device for processing TRS communication and is controlled by an AT (ATtention Command) command. In addition, a setting may be received from the program port P_Prog and connected to the antenna port (Antenna).

The CPU 230 may control each configuration of the TRS modem and be connected to a debug port P_Debug. Also, it may be connected to a terminal port (P_term) and an optical communication port (P_Opti) through the RS-232C interfaces 291 and 292 and the optical modem 293 .

The Flash 240 may store a history of data transmitted and received by the TRS modem, and the EEPROM 250 may store setting data for communication.

The reset switch 260 is a switch for restarting the TRS modem.

The test switch 270 is a switch for providing a loopback test between TRS modems or performing a self-diagnosis test. For example, the test switch 270 is a switch capable of performing a loopback test for checking a communication link in a subnet including self-diagnosis.

The loopback test may be automatically performed at a periodic time interval independently of the test switch 270 .

The loopback test refers to an operation of communicating with a TRS modem or optical communication terminal other than checking the setting of the digital TRS module or in order to prevent a phenomenon in which communication is disconnected due to an abnormality or other cause of the digital TRS module. The periodic time interval may be set longer than a periodic measurement time (Polling Time) of a Front End Processor (FEP) for intelligent distribution.

The LED 280 includes an LED for indicating an operating state such as a communication state of the TRS modem.

For example, the LED 280 is a PWR (Power), MODE, STA (Status), STBY LED for checking the operation status of the terminal and TXD, RXD, RTS, CTS LED for checking the communication status with the optical modem and FRTU. Consists of.

2 and 3 are exemplary views showing the configuration of an RF Mesh Network related to an embodiment of the present invention. In the existing communication method, one Master terminal and up to three Slave terminals are configured in a Star Topology (radial) form. If communication between Master and Slave is not smooth or communication is cut off or delayed due to other reasons, there is a problem that communication failure may occur at the lower slave location.

On the other hand, the communication method according to this embodiment configures the master terminal and the slave terminal in the form of an RF mesh network, and applies a compression algorithm to all frame data in the wireless section to reduce the data size to increase the transmission speed and efficiently use the radio resources. It is improved so that it can be used and configured to support smooth communication.

For reference, in FIG. 2, End Device means "FRTU", Coordinator means "Master terminal", and Router means "Slave terminal".

The intelligent distribution communication device in which an optical modem and a trunked radio system (TRS) modem according to the present embodiment are integrally configured may operate as a master terminal or a slave terminal.

First, when the distribution intelligent communication device in which the optical modem and the TRS modem are integrated according to this embodiment operates as a master, the dynamic mesh algorithm (Dynamic mesh algorithm) By dynamically integrating the mesh network (RF Mesh Network) by Mesh Algorithm, and using the dynamic frequency allocation through the application of routing technology and the Background Range Scanning function, radio resources are efficiently used and transmission for each section All data is processed so that communication errors and delays between the server and terminal devices do not occur by reducing the data size by applying compression algorithms and fragmentation technology to increase the transmission speed and build reliability.

By analyzing all wired and wireless data received from the Master, the message type and final destination address are analyzed, and it is determined whether to transfer the data to the next node by routing or store and process the data.

In addition, the Master performs the role of a coordinator, but may additionally perform the role of a router or repeater for routing or Ad-Hoc (Hopping) of other nodes of a mesh network. .

A more detailed operation will be described with reference to the flowchart of FIG. 4 .

In addition, when the distribution intelligent communication device in which the optical modem and the TRS modem are integrally configured according to this embodiment operates as a slave, the corresponding resource by referring to the routing path table set by the Master and the dynamically allocated frequency in the RF section Like the Master, data reception is performed through Background Range Scanning so that it can receive data transmitted from multiple adjacent subnets (ie, Master/Slave of adjacent nodes) including its own subnet. do. In addition, even if the link with the master associated with the slave itself is cut off, there is an advantage that communication with the remote server can be continued through other adjacent masters or slaves (Master/Salve).

A more detailed operation will be described with reference to the flowchart of FIG. 4 .

4 is a flowchart for explaining a method of controlling a distribution intelligent communication device according to an embodiment of the present invention.

Referring to FIG. 4 , an intelligent distribution communication device (hereinafter referred to as a master) operating as a master may receive data through an optical network or an air interface mesh network.

Accordingly, when the data is received, the control unit 230 of the master (ie, the intelligent distribution communication device operating as the master) determines the data type (S101). That is, the master determines through which network the received data is received.

As a result of determining the data type (S101), if the data is data received from another node (Hopping in S101), the controller 230 checks whether the data is a LAST HOP (S103). That is, it is checked whether the last hop is indicated by referring to routing information of data received from the other node.

If the data is not the LAST HOP (go Next in S103), the control unit 230 checks the routing information and transmits the data to the next node through the RF Mesh Network (S104), the When the data is LAST HOP (the last hop) (Y in S103), that is, when the last hop is indicated by referring to routing information, the controller 230 moves to “L1” to process the last hop message.

On the other hand, as a result of determining the data type (S101), if the data is LOOP BACK or HEARTBEAT (LOOP BACK/HEARTBEAT in S101), after transmitting (or forwarding) feedback to the counterpart node (S102), "Start" Go back to " and switch to message listening status.

Here, the LOOP BACK is a function of checking whether there is an error in communication between nodes of a subnet and is performed according to a set period. When the control unit 230 receives the corresponding data, it delivers feedback to the corresponding counterpart node, returns to "start", and switches to a message reception standby state. In addition, the heartbeat (HEARTBEAT) is a function of confirming a mutual link for setting a routing path between all nodes, and when the control unit 230 receives the corresponding data, it includes status information and lower slave information connected to the master. Send feedback to , return to "start" and switch to waiting for messages. At this time, the master receives subnet information from the NMS server and updates it, or dynamically configures a wired/wireless mesh network through information exchange with other adjacent subnet devices.

In addition, as a result of determining the data type (S101), if the data type is a DNP/CONFIG message (DNP/CONFIG, or “L1” in S101), the controller 230 first determines that the data is a DNP (Distributed Network Protocol) ) message (S105), if the data is not a DNP message (CONFIG (Local) in S105), feedback corresponding to the CONFIG setting or status information report is provided through an optical network through NMS (Network Management System) It transmits to the server, returns to "start", and switches to the message reception standby state (S113).

Here, CONFIG means status information/environment information of the modem.

Meanwhile, when the data is a DNP message (Yes in S105), the controller 230 checks the source (S106).

As a result of checking the source (S106), in the case of data (ie, DNP message) received from the Local FRTU/Remote Node (Local FRTU/Remote Node in S106), the controller 230 controls the data (ie, DNP message) to the FEP (Front End Processor) server (S112), and returns to "start" and switches to a message reception standby state.

Also, as a result of checking the source (S106), if the data (ie, DNP message) is data received from the FEP (Yes in S106, From FEP), the controller 230 controls the data (ie, DNP) message) and check whether the final destination has the same address as the local FRTU associated with it or whether the remote FRTU (Remote FRTU) is (S107).

When the destination of the data (ie, DNP message) matches the "Local FRTU" connected to the master itself (Local FRTU in S107), the controller 230 delivers the data (ie, DNP message) to the FRTU (S111) ), go back to "start" and switch to the message waiting state.

On the other hand, as a result of analyzing the destination of the data (that is, the DNP message) (S107), if it matches the local FRTU, the control unit 230 sets a routing path to prevent message collision and transmission delay, and sets this information and transmits it to the routing node (S109). The "data transmission to the routing node" (S109) refers to a local task for multi-tasking for real-time parallel processing of multiple data in the control unit 230 .

Also, as a process for managing a logical link, the data converted to the Node Protocol is repacked including a transaction line ID for link management, and then the data is transmitted to the next node (S110). At this time, if the routing information cannot be checked, data is transmitted in the form of a broadcast through the RF Mesh Network. This is to prevent communication failure when information is omitted or changed due to new establishment or other reasons.

Referring back to FIG. 4 , the intelligent distribution communication device (hereinafter referred to as a slave) operating as a slave may receive data only through an air interface mesh network.

Accordingly, when data is received, the control unit 230 of the slave (ie, the intelligent power distribution communication device operating as the slave) determines the data type (S101). That is, the slave determines through which network the received data is received.

As a result of determining the data type (S101), if the data is data received from another node (Hopping in S101), the controller 230 checks whether the data is a LAST HOP (S103). That is, it is checked whether the last hop is indicated by referring to routing information of data received from the other node.

If the data is not the LAST HOP (go Next in S103), the control unit 230 checks the routing information and transmits the data to the next node through the RF Mesh Network (S104), the When the data is LAST HOP (the last hop) (Y in S103), that is, when the last hop is indicated by referring to routing information, the controller 230 moves to “L1” to process the last hop message.

On the other hand, as a result of determining the data type (S101), if the data is LOOP BACK or HEARTBEAT (LOOP BACK/HEARTBEAT in S101), after transmitting (or forwarding) feedback to the counterpart node (S102), "Start" Go back to " and switch to message listening status.

Here, the LOOP BACK is a function of checking whether there is an error in communication between nodes of a subnet and is performed according to a set period. When the control unit 230 receives the corresponding data, it delivers feedback to the corresponding counterpart node, returns to "start", and switches to a message reception standby state. In addition, the heartbeat (HEARTBEAT) is a function of confirming a mutual link for setting a routing path between all nodes, and when the control unit 230 receives the corresponding data, state information and slave information included in the same subnet as the master information Sends feedback to the counterpart node, including

In addition, as a result of determining the data type (S101), if the data type is a DNP/CONFIG message (DNP/CONFIG, or “L1” in S101), the controller 230 first checks whether the data is a DNP message. (S105) If the data is not a DNP message (CONFIG (Local) in S105), the feedback corresponding to the CONFIG setting or status information report is transmitted to the NMS (Network Management System) server, returns to "Start" and waits for message reception state (S113).

At this time, in order to transmit data to the NMS server, which is the final destination, the slave converts the data to the node protocol of the wireless section to the master associated with it and transmits the data, or transmits the data through the corresponding route using the existing routing setting table. If routing information is not available, and communication with the master associated with the slave itself is cut off or delayed for other reasons, the slave transmits data in the form of a broadcast through the RF Mesh Network, and the NMS server sends multiple data through the optical network. The data received from the master is processed using the signal selection function.

Here, CONFIG means status information/environment information of the modem.

Meanwhile, when the data is a DNP message (Yes in S105), the controller 230 checks the source (S106).

As a result of checking the source (S106), if the data (ie, the DNP message) is data received from the FEP (Yes in S106, From FEP), the controller 230 determines the destination address of the DNP data. Analyze and check whether the final destination matches the local FRTU associated with it and the address (S107).

If the destination of the data (ie, DNP message) matches the "Local FRTU" connected to it (Local FRTU in S107), the controller 230 transmits the data (ie, DNP message) to the FRTU (S111) , go back to "start" and switch to the message waiting state.

On the other hand, if the result of analyzing the destination of the data (that is, the DNP message) (S107) does not match the local FRTU, the corresponding operation is not expected to be performed when operating in the slave mode, but for other reasons (data loss, As a supplement to the occurrence of deformation or omission, etc.), the data is repacked including the transaction ID for link management, and then the data is transmitted (S109, S110) in the form of a broadcast through the RF Mesh Network, and as "Start" Go back and switch to message listening state.

As described above, in this embodiment, the optical modem and the TRS modem are integrally configured so that the MASTER terminal updates subnet information from the NMS server or dynamically configures a wired/wireless mesh network through information exchange with other adjacent subnet devices and finally Set the optimal routing path to the destination and use the wired section routing or wireless Ad-Hoc (or Hopping) function to communicate between the intelligent distribution system and the terminal device when data including the corresponding information is delivered to the next node. By doing so, it is easy to install and open on-site locations, and monitoring, status management, and setting management of each location are possible. By applying wired/wireless integrated mesh network algorithm and data compression technology, the It has the effect of improving reliability.

As described above, if the integrated modem according to this embodiment is developed, a monitoring function that could not be managed before is added, and in case of failure, it is possible to expect rapid cause analysis, reduction of obstacles, simplifying the purchase procedure, reducing purchase cost, and saving space. have. It is also applicable to AWB of the DMO method that does not go through a base station.

As described above, the present invention has been described with reference to the embodiment shown in the drawings, but this is merely exemplary, and various modifications and equivalent other embodiments are possible therefrom by those of ordinary skill in the art. will understand the point. Therefore, the technical protection scope of the present invention should be defined by the following claims. Implementations described herein may also be implemented as, for example, a method or process, an apparatus, a software program, a data stream, or a signal. Although discussed only in the context of a single form of implementation (eg, only as a method), implementations of the discussed features may also be implemented in other forms (eg, in an apparatus or a program). The apparatus may be implemented in suitable hardware, software and firmware, and the like. A method may be implemented in an apparatus such as, for example, a processor, which generally refers to a computer, a microprocessor, a processing device, including an integrated circuit or programmable logic device, or the like. Processors also include communication devices such as computers, cell phones, portable/personal digital assistants (“PDAs”) and other devices that facilitate communication of information between end-users.

210: power supply 220: digital TRS module
230: CPU or control unit 240: Flash
250: EEPROM 260: reset switch
270: test switch 280: LED
291, 292: RS-232C interface 293: Optical modem

Claims (16)

In the communication method of a distribution intelligent communication device using a wired/wireless integrated mesh network,
When the intelligent distribution communication device operates as a master, when data is received, the control unit of the master determines the received data type;
checking, by the controller, whether the data is a last hop when the data type is data received from another node;
when the data is not the last hop, the controller confirms routing information and transmits the data to a next node through a radio mesh network (RF Mesh Network);
As a result of determining the data type, if the data is a loopback (LOOP BACK) or a heartbeat (HEARTBEAT), sending feedback to a counterpart node, returning to the start and switching to a message reception standby state; and
When the data is the last hop or when the data type is a DNP/CONFIG message, the controller performs a process for processing the end message. communication method.
According to claim 1, When the distribution intelligent communication device operates as a master,
A communication method of a distribution intelligent communication device using a wired/wireless integrated mesh network, characterized in that data is received through an optical network or a wireless network.
The method of claim 1, wherein the determining of the received data type comprises:
A communication method of a distribution intelligent communication device using a wired/wireless integrated mesh network, characterized in that it is determined through which network the received data is received.
The method of claim 1, wherein the loopback (LOOP BACK),
A communication method of a distribution intelligent communication device using a wired/wireless integrated mesh network, characterized in that it is performed according to a set period as a function of checking whether there is an abnormality in communication between nodes of a subnet.
According to claim 1, wherein the heartbeat (HEARTBEAT),
A communication method of a distribution intelligent communication device using a wired/wireless integrated mesh network, characterized in that it is a function to check a mutual link for setting a routing path between all nodes.
According to claim 1, wherein the data,
A communication method of a distribution intelligent communication device using a wired/wireless integrated mesh network, characterized in that it is a DNP (Distributed Network Protocol) message.
The method of claim 1, wherein the step of the controller performing a process for processing the end message comprises:
the control unit,
checking whether the data is a DNP message; and
When the data is not a DNP message, sending feedback corresponding to CONFIG setting or status information report to an NMS (Network Management System) server through an optical network, returning to the start and switching to a message reception standby state; A communication method of a distribution intelligent communication device using a wired/wireless integrated mesh network, characterized in that.
The method of claim 7, wherein the step of the controller performing a process for processing the end message comprises:
the control unit,
if the data is a DNP message, checking a source; and
As a result of checking the source, if the data is received from a Local FRTU or a Remote Node, transferring the data to a Front End Processor (FEP) server, returning to the start and switching to a message reception standby state; characterized by further comprising A communication method of a distribution intelligent communication device using a wired/wireless integrated mesh network.
The method of claim 8, wherein the step of the controller performing a process for processing the end message comprises:
the control unit,
As a result of checking the source, if the data is data received from the FEP, analyzing the destination address of the data and checking whether the final destination has the same address as the local FRTU associated with the master itself or a remote FRTU (Remote FRTU) ; and
When the destination of the data matches the "Local FRTU" connected to the master itself, transferring the data to the FRTU, returning to the start and switching to a message reception standby state; Wired/wireless integrated mesh network further comprising: A communication method of a distribution intelligent communication device using
The method of claim 9, wherein the step of the controller performing a process for processing the end message comprises:
the control unit,
As a result of checking the destination of the data, if it matches the master's own Local FRTU, setting a routing path to prevent message collision and transmission delay and transmitting data to the routing node including this information; and
Distribution intelligent communication using a wired/wireless integrated mesh network, characterized in that it further comprises; repacking the data converted to the node protocol, including the transaction line ID for link management, and then transmitting the data to the next node How the device communicates.
In the communication method of a distribution intelligent communication device using a wired/wireless integrated mesh network,
When the intelligent distribution communication device operates as a slave, when data is received, the control unit of the slave determines the data type;
as a result of determining the data type, when the data is data received from another node, checking whether the controller is a last hop;
when the data is not the last hop, the controller confirms routing information and transmits the data to the next node through a radio mesh network (RF Mesh Network);
As a result of determining the data type, if the data is a loopback (LOOP BACK) or a heartbeat (HEARTBEAT), sending feedback to a counterpart node, returning to the start and switching to a message reception standby state; and
When the data is the last hop or when the data type is a DNP/CONFIG message, the controller performs a process for processing the end message. communication method.
12. The method of claim 11, wherein when the intelligent distribution communication device operates as a slave,
A communication method of a distribution intelligent communication device using a wired/wireless integrated mesh network, characterized in that data is received only through a wireless network.
The method of claim 11, wherein the data,
A communication method of a distribution intelligent communication device using a wired/wireless integrated mesh network, characterized in that it is a DNP (Distributed Network Protocol) message.
The method of claim 11, wherein the step of the controller performing a process for processing the end message comprises:
the control unit,
checking whether the data is a DNP message; and
When the data is not a DNP message, transmitting feedback corresponding to CONFIG setting or status information report to an NMS (Network Management System) server, returning to the start and switching to a message reception standby state; characterized in that it comprises a A communication method of a distribution intelligent communication device using a wired/wireless integrated mesh network.
The method of claim 14, wherein the step of the controller performing a process for processing the end message comprises:
the control unit,
if the data is a DNP message, checking a source;
As a result of checking the source, if the data is data received from the FEP, checking the destination address of the data to check whether the final destination matches the local FRTU address associated with the slave itself; and
When the destination of the data matches the "Local FRTU" connected to the slave itself, transferring the data to the FRTU, returning to the start and switching to a message reception standby state; Wired/wireless integrated mesh network, characterized in that it further comprises A communication method of a distribution intelligent communication device using
The method of claim 15, wherein the step of the controller performing a process for processing the end message comprises:
the control unit,
As a result of checking the destination of the data, if it does not match the slave's own Local FRTU, the data is repacked including the transaction ID for link management, and then the data is transmitted in the form of a broadcast through the wireless mesh network. and returning to the start and switching to a message reception standby state.

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