KR20050058622A - The duplicating unit of communication channel and the method for operating the duplicated communication channel - Google Patents

Abstract

A communication path redundancy device and a method of operating a redundant communication path that implement physical path IPC redundancy using two Ethernet switches are disclosed. The communication path redundancy device and the redundant communication path operation method may change an already selected IPC path even when a system IPC path fails, and may be connected to an external router to be applied to a scalable router. It is also designed to be developed as a distributed system that separates the function from the packet processing function. In addition, important status information can be exchanged both wired and wireless.

Description

The duplicating unit of communication channel and the method for operating the duplicated communication channel

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a network, and more particularly, to a communication path redundancy apparatus and a method of operating a redundant communication path used in a large capacity router system and broadcasting streaming equipment.

In the case of network equipment used in the related art, it is common to have a centralized distributed single IPC (Inter Processor Communication) structure or two central controllers and a single IPC structure. They have something in common in that they have a single IPC structure.

1 is a block diagram showing the configuration of a network equipment that is conventionally used.

Referring to FIG. 1, a network equipment in use in the related art includes two main processors 101 and 102, an Ethernet switch 103, and a plurality of line card modules 104 to 106.

The two main processors 101 and 102 are dedicated to routing related protocol processing, routing table maintenance, and the like. The Ethernet switch 105 connects the plurality of line card modules 104 to 106 and the two main processors 101 and 102. The plurality of line card modules 104 to 106 perform network interface and forwarding functions.

The configuration of such a conventional system can duplicate the path in a single IPC structure, but the message exchange using an IPC-only radial Ethernet network in the inside is a trend of a recent system in which the use of a network processor is becoming common. In light of this, it is inefficient given system configuration problems and scalable scalability. In addition, when the operation failure occurs in the Ethernet switch 103 embedded in the main controller module may cause a serious problem that the IPC function is paralyzed.

The recent increase in the demand for Internet services has resulted in an increase in the demand for stream-oriented application services such as Voice over Internet Protocol (VoIP) and multimedia services and the demand for mobile Internet services. Has accelerated the surge. Since this increase in services increases the use of high speed switch equipment and high speed router equipment, efficient methods or apparatus for developing such equipment have been studied.

As an example using a conventional technology, a Korean patent (Patent 2002-0040387), "IPC message exchange device and method using an Ethernet switching device," uses an IPC using an Ethernet switching device in an ATM (Asynchronous Transfer Mode) exchange. An apparatus and method are provided. This is to provide an IPC message exchange method using an Ethernet switching scheme in which an Ethernet switching device is embedded in an ATM switch main controller module and a radial Ethernet network for IPC messages is constructed using a back plane for matching each module.

In the case of the conventional invention, when an operation failure occurs in the Ethernet switch for IPC, it causes a fatal result in the routing function transfer. IPC path redundancy may be considered. In addition, due to the capacity of the Ethernet switch for the PC and the number of ports provided, infinite capacity cannot be determined. IPC path redundancy has a problem that can lead to an increase in the failure factor along with the price increase factor of the system of equipment development.

The scalable structure allows the capacity to be easily changed according to the service provisioning capacity of the user on a single platform, enabling expansion from the edge level to the backbone core level and all nodes A scalable router managed in one central table. It is clear from the viewpoint of the present invention that there is a limit to expansion.

The first technical problem to be achieved by the present invention is to provide a communication path redundancy apparatus comprising a main control module of a system having a double path and an Ethernet switch having a double path.

Another object of the present invention is to provide a method for operating the redundant communication path.

Communication path redundancy apparatus according to the present invention for achieving the first technical problem, the first control block, the second control block and the first control block and the second control block and a plurality of line cards connected via Ethernet Equipped.

The plurality of line cards form a first communication path with the first control block and at the same time form the second control block and a second communication path, wherein the first control block and the second control block, The operation information may be shared, and any one communication path may be selected from the first communication path or the second communication path using a protocol between each other, and if not, a communication path that is not selected may be selected later.

For example, if the system operator needs or if a problem occurs in the communication path and the communication path is no longer available, the communication path can be selected later through a certain verification step.

According to another aspect of the present invention, there is provided a method of operating a redundant communication path, the method comprising: exchanging operation information between at least two main processor integrated assemblies, the control block and a plurality of lines; Retrieving at least two communication paths for transmitting and receiving data between the cards, selecting one of the communication paths, and replacing the communication path with one of the other communication paths except for the selected communication path. .

The replacing of the communication path may include a situation in which an error occurs in the communication path while transmitting or receiving data using the selected communication path, and thus no more data can be transmitted. It transmits and receives data by replacing with one of the communication paths.

DETAILED DESCRIPTION In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings that illustrate preferred embodiments of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

2 is a block diagram of a communication path duplication apparatus according to an embodiment of the present invention.

Referring to FIG. 2, the communication path duplication apparatus includes a first control block 210, a second control block 220, and a plurality of line cards 231 to 234.

The plurality of line cards 231 to 234 form a first communication path with the first control block 210 and simultaneously form a second communication path with the second control block 220. Here, the first communication path includes a first main processor module 211, a first Ethernet control device 215, a first Ethernet switch 214, and a plurality of line cards 231 to 233, and a second communication. The path includes a second main processor module 221, a fourth Ethernet control unit 225, a second Ethernet switch 224, and a plurality of line cards 231 to 233.

Particularly, the first control block 210 and the second control block 220 share operation information with each other, and use any one of the first communication path or the second communication path using a protocol between each other. It is designed to select and to select the communication path which is not selected at a later time.

The first control block 210 includes a first main processor module 211, a first wireless module 212, a first state inspection module 213, a first Ethernet switch 214, and three Ethernet controllers 215. To 217).

The first main processor module 211 is responsible for data transmission and reception with the plurality of line cards 231 to 233.

In the first wireless module 212, one terminal is connected to the first main processor module 211 and the other terminal is connected to an antenna, thereby wirelessly providing information about a state of the first main processor module 211. Send it out.

The first state inspection module 213 has one terminal connected to the first main processor module 211 and the other terminal connected to the second state inspection module 223 constituting the second control block 220. The state of the first communication path is monitored and the second state inspection module 223 communicates with the second state inspection module 223 to determine whether to authorize transmission and reception of data to the first communication path.

The first Ethernet switch 214 switches data transmission and reception between the plurality of line cards 231 to 233 and the first ethernet controller 215, and in some cases, the plurality of line cards 231 to 233 and the second control. Switch data transmission and reception between the fifth Ethernet controller 226 constituting block 220.

The first Ethernet control device 215 has one terminal connected to the first main processor module 211 through a shared bus (dual line) and the other terminal connected to the first Ethernet switch 214 to share with Ethernet. Enables data transmission and reception between buses.

The second Ethernet control apparatus 216 may include a second Ethernet switch configured to connect one terminal to the first main processor module 211 through the shared bus and the other terminal to configure the second control block 220. 224 may be connected to and transmit data between the plurality of line cards 231 to 233 and the first main processor module 211 through the second Ethernet switch 224.

The third Ethernet control device 217 is connected to the first main processor module 211 through a shared bus (dual line), and the other terminal of the sixth Ethernet configuring the second control block 220. It is connected to the control device 227 provides a passage for transmitting and receiving the operation information of the first control block 210 and the second control block 220 with each other.

The second control block 220 includes a second main processor module 221, a second wireless module 222, a second state inspection module 223, a second Ethernet switch 224, and three Ethernet controllers 225. To 227).

The second main processor module 221 is responsible for data transmission and reception with the plurality of line cards 231 to 233.

In the second wireless module 222, one terminal is connected to the second main processor module 221 and the other terminal is connected to the antenna, thereby wirelessly providing information about the state of the second main processor module 221. Send it out.

The second state inspection module 223 has one terminal connected to the second main processor module 221 and the other terminal connected to the first state inspection module 213 constituting the first control block 210. The second communication path is monitored, and the first state inspection module 213 communicates with the first state inspection module 213 to determine whether to authorize transmission and reception of data to the second communication path.

The second Ethernet switch 224 switches data transmission and reception between the plurality of line cards 231 to 233 and the fourth Ethernet controller 225, and in some cases, the plurality of line cards 231 to 233 and the first control. Switch data transmission and reception between the second Ethernet control device 216 constituting block 210.

The fourth Ethernet controller 225 has one terminal connected to the second main processor module 221 through a shared bus (dual line) and the other terminal connected to the second Ethernet switch 224 to share with Ethernet. Enables data transmission and reception between buses.

The fifth Ethernet control apparatus 226 may include a first Ethernet switch configured to connect one terminal to a second main processor module 221 through the shared bus and the other terminal to constitute a first control block 210. 214 may be used to transmit and receive data between the plurality of line cards 231 to 233 and the second main processor module 221 through the first Ethernet switch 224.

The sixth Ethernet control device 227 has one terminal connected to the second main processor module 221 through a shared bus (dual line), and the other terminal constitutes the first control block 210. It is connected to the control device 217 to provide a passage for transmitting and receiving the operation information of the first control block 210 and the second control block 220 with each other.

Each of the line cards 231 to 233 is a local processor module 234 that is responsible for data transmission and reception with two main processor modules 210 and 220, and one terminal is a local processor module 234 through a shared bus (dual line). 7th Ethernet controller 235 connected to the first Ethernet switch 214 via Ethernet and one terminal connected to the local processor module 234 through a shared bus (dual line). The other terminal has an eighth Ethernet control device 236 connected to the second Ethernet switch 224 via Ethernet.

The first Ethernet switch 214 and the second Ethernet switch 224 further include one terminal, respectively, and the additional terminals 218 and 228 are the first control block 210 and the second control block 220. It is connected externally to enable expansion of Ethernet switch.

3 is a flowchart illustrating a method of operating a redundant communication path according to an embodiment of the present invention.

Referring to FIG. 3, the method of operating the redundant communication path may include: exchanging operation information between at least two main processor integrated assemblies (310), between the control block and the plurality of line cards; Retrieving at least two communication paths for transmitting and receiving data, selecting one of the communication paths (320), and newly selecting one of the other communication paths except for the selected communication path to transmit data, or A step 330 of replacing a communication path for reception.

In particular, in the step 330 of replacing the communication path, an error occurs in the communication path while transmitting or receiving data using the selected communication path, so that the data can no longer be transmitted or the system operator arbitrarily changes. In addition, the data transmission and reception is replaced with one of the other communication paths.

The step 320 of selecting a communication path includes monitoring a state of the control block 321, giving a standby state 322, notifying 323, and self-testing the communication path 324. It is provided.

In step 321 of monitoring the status of the control block, the status of the control block is checked to monitor whether there is an error.

The step 322 of granting the standby state grants master authority to one control block among at least two or more control blocks and gives a standby state to the remaining control blocks.

In step 323, the control block granted the master authority notifies the plurality of line cards that they are the master.

In the self-testing step 324, the communication path between the local processor module included in each line card and the main processor module of the control block given master authority is self-tested.

As a result of the self-test 325 of the communication path, when a failure in which data cannot be transmitted / received through the tested communication path is detected, a control including a communication path in which there is no abnormality among the communication paths including the control block given the standby state. The above steps are repeated again from the step of granting the master authority or the waiting state until the block is detected.

The step 330 of replacing the communication path may include: operating the system 331 when the self test 324 of the communication path is determined to be suitable for transmitting and receiving data through the tested communication path, and the communication. And determining whether or not an abnormality has occurred in the communication path while transmitting or receiving data through the path (332).

If the determination result (332) no abnormality occurs (No), the system continues to operate, and when the abnormality occurs and it is determined that no more data can be transmitted and received (Yes) among the control blocks granted the standby state All steps 323 to 332 are performed again from the step 322 of granting the master authority to transmit or receive data by selecting a control block including a communication path suitable for transmitting and receiving data.

In summary, a communication path redundancy apparatus according to an embodiment of the present invention includes a large-capacity router system and broadcasting streaming equipment having two types of Ethernet ports, for example, 1 gigabit and 10 gigabit. In the IPC configuration, two Ethernet switches are provided, and a wireless module for exchanging information between systems is mounted.

The communication path redundancy device includes two main controllers. When one selected main controller operates and one IPC path is used, the other main controller and the other IPC path are in a standby state, which may cause a system failure. If it is designed to be replaced between them.

The operation method of the redundant communication path is a process that must be applied to operate the communication path duplication device.

As described above, the optimum embodiment has been disclosed in the drawings and the specification. Although specific terms have been used herein, they are used only for the purpose of describing the present invention and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

As described above, the communication path duplication apparatus and the method of operating the redundant communication path according to the present invention provide not only the duplication of the main controller of the system but also the duplication of the path providing the IPC. Service delays can be minimized. It can also be used for system control of mutual devices by transmitting system management information wirelessly. Apparatus and method proposed by the present invention is not only applied to a simple redundancy configuration and method, there is an advantage that it is possible to provide a scalable router configuration by facilitating system expansion using the same. Based on these advantages, the present invention increases the stability of the system and can simplify the system configuration further, thereby reducing the overall cost.

BRIEF DESCRIPTION OF THE DRAWINGS In order to better understand the drawings cited in the detailed description of the invention, a brief description of each drawing is provided.

1 is a block diagram showing the configuration of a network equipment that is conventionally used.

2 is a block diagram of a communication path duplication apparatus according to an embodiment of the present invention.

3 is a flowchart illustrating a method of operating a redundant communication path according to an embodiment of the present invention.

Claims (7)

A first control block; A second control block; And And a plurality of line cards connected to the first control block and the second control block via Ethernet, The plurality of line cards, Forming a first communication path with the first control block and simultaneously forming a second communication path with the second control block; The first control block and the second control block, The operation information is shared with each other, and any one communication path is selected from the first communication path or the second communication path by using a protocol between each other, and in some cases, a communication path that is not selected can be selected later. Communication path redundancy device. The method of claim 1, wherein the first control block, A first main processor module responsible for data transmission and reception with the plurality of line cards; A first wireless module having one terminal connected to the first main processor module and the other terminal connected to an antenna so as to wirelessly transmit information about a state of the first main processor module; One terminal is connected to the first main processor module and the other terminal is connected to a second state inspection module constituting the second control block, and monitors the state of the first communication path and checks the second state. A first state inspection module in communication with the module for determining whether to authorize the first communication path to send and receive data; A first Ethernet for switching data transmission and reception between the plurality of line cards and the first Ethernet control device, and switching data transmission and reception between the fifth Ethernet control device constituting the plurality of line cards and the second control block, in certain cases. switch; A first Ethernet control device connected to the first main processor module via a shared bus and the other terminal connected to the first Ethernet switch; A second Ethernet control device connected to the first main processor module through the shared bus and the other terminal connected to a second Ethernet switch constituting the second control block; And One terminal is connected to the first main processor module through the shared bus, and the other terminal is connected to a sixth Ethernet control device constituting the second control block, so that the first control block and the second control block are connected to each other. And a third Ethernet control device for controlling the transmission and reception of operational information of each other, The second control block, A second main processor module responsible for data transmission and reception with the plurality of line cards; A second wireless module having one terminal connected to the second main processor module and the other terminal connected to an antenna to wirelessly transmit information about a state of the second main processor module; One terminal is connected to the second main processor module and the other terminal is connected to a first state inspection module constituting the first control block, and monitors the state of the second communication path and the first state inspection. A second state inspection module, in communication with the module, for determining whether to authorize the second communication path to send and receive data; A second Ethernet for switching data transmission and reception between the plurality of line cards and a fourth Ethernet control device, and switching data transmission and reception between the plurality of line cards and a second Ethernet control device constituting the first control block, in certain cases. switch; A fourth Ethernet control device connected to the second main processor module through a shared bus and the other terminal connected to the second Ethernet switch; A fifth Ethernet control device connected to the second main processor module through the shared bus and the other terminal connected to a first Ethernet switch constituting the first control block; And One terminal is connected to the second main processor module through the shared bus, and the other terminal is connected to a third Ethernet control device constituting the first control block so that the first control block and the second control block are connected. And a sixth Ethernet control device for controlling the transmission and reception of operational information of each other, The line card, A local processor module responsible for transmitting and receiving data with the two main processor modules; A seventh Ethernet controller connected to the local processor module at one terminal via a shared bus and at the other terminal to the first Ethernet switch via Ethernet; And And one terminal connected to the local processor module through a shared bus and the other terminal connected to the second Ethernet switch via Ethernet. The method of claim 1, wherein the first communication path, The first main processor module, the first ethernet controller, the first ethernet switch, and the plurality of line cards; The second communication path, And said second main processor module, said fourth ethernet controller, said second ethernet switch, and said plurality of line cards. The method of claim 2, wherein the first Ethernet switch and the second Ethernet switch, Each terminal further comprises one terminal, wherein the additional terminal is connected to the outside of the first control block and the second control block to enable the expansion of the Ethernet switch. Exchanging operational information between at least two main processor integrated assemblies; Searching for at least two communication paths for transmitting and receiving data between the control block and a plurality of line cards, and selecting one of the communication paths; And And exchanging a communication path for data transmission and reception of one of the other communication paths except the selected communication path, The replacing of the communication path may include a situation in which an error occurs in the communication path while transmitting or receiving data using the selected communication path, and thus no more data can be transmitted or a system operator arbitrarily selects the rest. A method of operating a redundant communication path, characterized in that the communication path of data transmission and reception can be replaced with one of the other communication paths. The method of claim 5, wherein the selecting of the communication path comprises: Monitoring the status of the control block; Granting master authority to one of the at least two control blocks and granting a standby state to the remaining control blocks; The control block granted the master authority notifying the plurality of line cards that they are the masters; And Self-testing the communication path between the local processor module included in each line card and the main processor module of the control block granted the master authority, As a result of the self-test of the communication path, when a failure in which data cannot be transmitted or received is detected through the tested communication path, the control block including the communication path having no abnormality is detected in the communication path including the control block given the standby state. And repeating all the above steps from granting the master authority or granting the standby state until the master authority is set. The method of claim 5, wherein the step of replacing the communication path, Operating a system when it is determined as a result of the self test of the communication path that it is suitable to transmit and receive data through the tested communication path; And Determining whether an abnormality has occurred in the communication path while transmitting or receiving data through the communication path, If the abnormality does not occur as a result of the determination, the system continues to operate, and if it is determined that the abnormality is no longer able to transmit and receive data, a communication path suitable for transmitting and receiving data among the control blocks assigned to the standby state Selecting a control block comprising a; and performing all steps again from the step of granting the master authority to transmit or receive data.