KR100705592B1 - Access node and method for sending/receiving packet thereof - Google Patents

Abstract

The present invention relates to an access node including an active module and a standby module, and a packet transmission / reception method of the access node, wherein the active module copies a packet received from a subscriber to a router and a standby module connected to the active module, respectively. Transmits a packet received from a router connected to the active module to the standby module, and the standby module transmits a packet transmitted from the active module to a router connected to the standby module, and from a router connected to the active module The present invention relates to storing information of an address included in a received packet and a packet received from a router connected to the standby module.

Description

ACCESS NODE AND METHOD FOR SENDING / RECEIVING PACKET THEREOF}

1 is a diagram illustrating a configuration of a conventional access node.

2 illustrates a configuration for an access node in accordance with the present invention.

3 is a flowchart illustrating an operation of a packet transmission / reception method of an access node according to the present invention;

The present invention relates to an access node and a packet transmission / reception method of the access node.

In general, an access node is a device that allows at least one subscriber connected to an access node to access a network such as an IP network so that data can be transmitted and received between the network and at least one subscriber.

An example of a configuration for such an access node is shown in FIG. 1.

As shown in FIG. 1, the access node 100 includes an active Main Ethernet Switching Unit (MSU) 110, a standby MSU 120, and a switching controller 130.

The active MSU 110 and the standby MSU 120 are connected to the router 150 and the router 152 included in the IP network, respectively.

The active MSU 110 is connected to the router 150 included in the IP network so that a plurality of subscriptions are connected to the IP network.

The active MSU 110 includes an Ethernet switch 112 and a small form-factor pluggable (SFP) 114.

Ethernet switch 112 receives packets transmitted from multiple subscribers through multiple ports (only Px ports are shown in FIG. 1), and multiplexes packets transmitted from multiple subscribers through multiple ports to P1. The router transmits to the router 150 connected to the SFP 114 through the port.

Meanwhile, the Ethernet switch 112 demultiplexes corresponding packets as packets transmitted from the router 150 are received at the P1 port through the SFP 114, and media access control (MAC) included in the demultiplexed packets. By switching to multiple ports using the address, packets received from router 150 are transmitted to subscribers connected to the multiple ports.

The transfer control unit 130 detects an abnormality in the active MSU 110, and when the abnormality occurs in the active MSU 110, the transfer control unit 130 performs a transfer from the active MSU 110 to the standby MSU 120.

That is, the transfer control unit 130 transfers from the active MSU 110 to the standby MSU 120 when an abnormality occurs in the active MSU 110, thereby providing subscribers connected to the IP network through the active 110. A connection is made to the IP network through the standby MSU 120.

The standby MSU 120 includes an Ethernet switch 122 and an SFP 124.

After the Ethernet switch 122 is switched from the active MSU 110 to the standby MSU 120, the Ethernet switch 122 connects to the router 152 included in the IP network to determine the MAC address of the router 152, and the determined router The MAC address of 152 is stored in a table (not shown) provided.

Thereafter, the Ethernet switch 122 receives the packets transmitted from the multiple subscribers through the multiple ports (only the Py port is shown in FIG. 1), and multiplexes the packets transmitted from the multiple subscribers through the multiple ports. To the router 152 connected to the SFP 124 through the P2 port.

Meanwhile, the Ethernet switch 122 demultiplexes the packets as the packets transmitted from the router 152 are received at the P1 port through the SFP 124, and uses a plurality of MAC addresses included in the demultiplexed packets. By switching to the ports of, the packets received from the router 152 are transmitted to subscribers connected to the multiple ports.

As described above, the access node 100 is connected to the router 150 and the router 152 included in the IP network through the active MSU 110 and the standby MSU 120.

The access node 100 connects to the IP network only through the active MSU 110 and the standby MSU 120 before and after the switching is performed.

Accordingly, when an error occurs in the router 150 and the router 152 connected to the active MSU 110 and the standby MSU 120, transmission and reception of data is performed between the access node 100 and the IP network before and after the switching is performed. By not being able to make it normally, it is difficult to secure reliability in the IP network configuration.

In addition, the Ethernet switch 122 of the standby MSU 120 connects to the router 152 to determine the MAC address of the router 152 when the switchover to the standby MSU 120 occurs due to an error of the active MSU 110. And, the MAC address of the found router 152 is stored in a table provided.

The standby MSU 120 cannot receive packets received from the IP network while storing the MAC addresses of the routers 152 and the MAC addresses of the routers 152 obtained by the Ethernet switch 122 in the table.

In particular, it takes a few seconds or more to complete the transfer from the active MSU 110 to the standby MSU 120.

This causes a problem in that reliability of a voice service that needs to be transmitted and received within 150 to 250 ms, such as a VoIP service between a subscriber terminal connected to an access node 100 and a terminal connected to an IP network, may not be secured.

Accordingly, the present invention is to solve the above problems, the access node performing the reception of data from the IP network through two links, and the transmission of data to the IP network through one link and the access node To provide a packet transmission and reception method of the.

An access node including an active module and a standby module according to an aspect of the present invention for achieving the above object, wherein the active module is a copy of the packet received from the subscriber side to the router and the standby module connected to the active module, respectively Send a packet received from a router connected to the active module to the standby module; The standby module transmits a packet transmitted from the active module to a router connected to the standby module, and receives information on an address included in a packet received from a router connected to the active module and a packet received from a router connected to the standby module. Save each.

The address information included in the packet received from the router connected to the active module and the packet received from the router connected to the standby module is a packet received from the subscriber side of the standby module when the standby module is switched to the active state. It may be a MAC (Media Access Control) address of a router connected to the active module required for transmission to a router connected to the active module and a router connected to the standby module and a MAC address of a router connected to the standby module.

The active module and the standby module each include a switch unit and an optocoupler; The switch unit included in the active module copies the packet received from the subscriber side of the active module and transmits the packet to the optocoupler and the standby module included in the active module; The optocoupler included in the active module transmits a packet transmitted from a switch unit included in the active module to a router connected to the active module, and copies the packet received from the router connected to the active module to include in the active module. To the switched switch unit and the standby module; The optocoupler included in the standby module transmits a packet transmitted from a switch unit included in the active module to a router connected to the standby module, and copies the packet received from the router connected to the standby module to include in the standby module. To the switched switch unit and the switch unit included in the active module; The switch unit included in the standby module stores an address included in an optocoupler included in the active module and a packet respectively transmitted from the optocoupler included in the standby module.

The switch unit included in the active module transmits the packet received from the optocoupler included in the active module and the optocoupler included in the standby module to the subscriber.

The access node according to the present invention includes an extension self including an active subscriber extension unit and a standby subscriber extension unit; And gigabit Ethernet connected to the active subscriber extension unit and the standby subscriber extension unit, respectively, and copy the packets received from the subscriber side of the active subscriber extension unit to the active module and the standby module, respectively, and receive from the active module. The ESU may further include an Ethernet stacking unit (ESU) for copying the received packet to the active subscriber extension unit and the standby subscriber extension unit.

According to an aspect of the present invention, there is provided a method for transmitting and receiving a packet of an access node duplexed by an active module and a standby module connected to different routers, wherein the active module copies the received packet from the subscriber side, respectively. Transmitting to a router connected to an active module and the standby module; And the standby module transmits a packet transmitted from the active module to a router connected to the standby module.

According to another aspect of the present invention, a packet transmitting / receiving method of an access node duplexed with an active module and a standby module connected to different routers may include receiving a packet received from a router connected to the active module. Transmitting to the standby module; And the standby module stores the information included in the packet received from the router connected to the active module and the address included in the packet received from the router connected to the standby module.

Hereinafter, an access node and a packet transmission / reception method of the access node according to the present invention will be described in detail with reference to the accompanying drawings.

In addition, it should be noted that the same reference numerals are given to the same elements, although belonging to different drawings for convenience of understanding.

2 is a diagram illustrating a configuration of an access node according to an embodiment of the present invention.

As shown in FIG. 2, the access node according to the present invention includes an extension shelf 200, a main shelf 210, and optocouplers 260 and 272.

The extended shelf 200 extends the number of subscribers to connect to the main shelf 210 and includes an active MSU 202 and a standby MSU 204.

The active MSU 202 and the standby MSU 204 are each connected by Gigabit Ethernet to the Ethernet Stacking Unit (ESU) 220 in the main shelf 210.

The active MSU 202 and the standby MSU 204 receive the same packet transmitted from the ESU 220, and only one MSU selectively transmits the packet to the ESU 220 when transmitting the packet to the ESU 220. do.

For example, when a packet is sent to the ESU 220 by the active MSU 202, the standby MSU 204 is disabled and the packet is sent to the ESU 220 by the standby MSU 204. Active MSU 202 is disabled.

The main shelf 210 includes an ESU 220, a transfer control unit 230, a main MSU 240, and a second MSU 250.

The ESU 220 includes the SFPs 222 and 224 and the transmission control unit 226, and detects a failure of the connection between the expansion shelves 200 and performs a switching on the link with the expansion shelves 200.

At this time, the SFP 222 is connected to the active MSU 202 in the expansion shelf 220 by Gigabit Ethernet, and the SFP 224 is connected to the standby MSU 204 in the expansion shelf 220 by Gigabit Ethernet.

The transmission control unit 226 copies the packets provided to the first MSU 240 and the second MSU 250 in the main shelf 210 and through the SFP 222 and the SFP 224, respectively. 202 and the standby MSU 204.

On the other hand, the transmission control unit 226 copies only the packets received from the MSU 202 that is active in the extended shelf 200 and provides them to the first MSU 240 and the second MSU 250 in the main shelf 210.

That is, the transmission control unit 226 copies only the packets received from the MSUs that are active in the extended self 200 and provides them to the first MSU 240 and the second MSU 250, and the active 240 and the second MSU 250. The packet is then sent to the active MSU 202 and the standby MSU 204 in the expansion shelf 200 via the SFP 222 and SFP 224.

On the other hand, the transmission control unit 226 detects a failure for the connection between the extended self through the SFPs 222 and 224, and transfers the link to the connection between the extended self that has not occurred.

The main MSU 240 includes an Ethernet switch 242 and two SFPs 244 and 246.

Ethernet switch 242 has a number of ports (only Px ports shown in FIG. 2) required for connection with subscribers and ports P3 and P4 for connecting to two SFPs 244, 246, respectively. Here, the Px port is connected to the ESU 220.

The SFP 244 is connected to the first optical coupler 262 and the second optical coupler 264 in the optocoupler unit 260, and is connected to port P3 of the Ethernet switch 242.

On the other hand, the SFP 246 is connected to the third optical coupler 272 and the fourth optical coupler 274 in the optical coupler 270, and is connected to the port P4 provided in the Ethernet switch 242.

An operation of the first MSU 240 having such a configuration will be described.

The Ethernet switch 242 copies the packets received from the ESU 220 connected to the Px pod and through the ports P3 and P4 in the first optocoupler 262 and the optocoupler 270 in the optocoupler 260 respectively. To the third optocoupler 272.

On the other hand, the Ethernet switch 242 is a packet received at the port P3 through the second optical coupler 264 and the SFP 244 in the optical coupler 260 and the fourth optical coupler 274 in the optical coupler 270. And a packet received at the port P4 through the SFP 246 to the subscriber side through a plurality of ports connected to the subscriber side. In this case, the packet received at the port P3 is a packet transmitted from the router 280, and the packet received at the port P4 is a packet transmitted from the router 282.

For example, the Ethernet switch 242 provides the packet received at the port P3 through the second optical coupler 264 and the SFP 244 in the optocoupler unit 260 to the ESU 220 through the port Px. .

The transmission control unit 226 in the ESU 220 copies the packets provided from the Ethernet switch 242 to the active MSU 202 and the standby MSU 204 in the expansion shelf 200 connected to the SFPs 222 and 224, respectively. send.

The Ethernet switch 242 checks the MAC address of the router 280 and the MAC address of the router 282 included in the packets transmitted from the router 280 and the router 282, respectively, and stores them in a table provided.

Meanwhile, the second MSU 250 includes an Ethernet switch 252 and two SFPs 254 and 256, and stands by in a standby state when the first MSU 240 is active.

Hereinafter, the operation of the configuration of the second MSU 250 will be described with reference to the case in the standby state.

Ethernet switch 252 has a number of ports (only Py ports shown in FIG. 2) required for connection with subscribers and ports P5 and P6 for connecting to two SFPs 254 and 256, respectively. Here, the Py port is connected to the ESU 220.

The SFP 254 is connected to the first optical coupler 262 and the second optical coupler 264 in the optocoupler unit 260, and is connected to the port P5 of the Ethernet switch 252.

Meanwhile, the SFP 256 is connected to the third optical coupler 272 and the fourth optical coupler 274 in the optocoupler unit 270, and is connected to the port P6 provided in the Ethernet switch 252.

An operation of the second MSU 250 having such a configuration will be described.

The Ethernet switch 252 receives packets received from the ESU 220 connected to the Py pod through ports P5 and P6, respectively, in the first optocoupler 262 and the third in the optocoupler 270. It is not provided to the optocoupler 272.

On the other hand, the Ethernet switch 252 is a packet received at the port P5 through the second optical coupler 264 and the SFP 254 in the optical coupler 260 and the fourth optical coupler 274 in the optical coupler 270. And a packet received at the port P6 through the SFP 246 to the subscriber side through a plurality of ports connected to the subscriber side.

In this case, the packet received at the port P5 is a packet transmitted from the router 280, and the packet received at the port P6 is a packet transmitted from the router 282.

For example, the Ethernet switch 252 provides the packet received at the port P5 through the second optocoupler 264 and the SFP 254 in the optocoupler unit 260 to the ESU 220 through the port Py.

The transmission control unit 226 in the ESU 220 copies the packets provided from the Ethernet switch 252 to the active MSU 202 and the standby MSU 204 in the expansion shelf 200 connected to the SFPs 222 and 224, respectively. send.

The Ethernet switch 252 checks the MAC address of the router 280 and the MAC address of the router 282 included in the packets transmitted from the router 280 and the router 282, respectively, and stores them in a table provided.

In this case, when the transfer is performed to the second MSU 250 due to an abnormality of the first MSU 240 that is active, the second MSU 252 may determine the MAC addresses of the router 280 and the router 282. You do not have to carry out the process.

Therefore, voice service such as VoIP service between the subscriber side connected to the second MSU 252 and the IP network can be reliably performed.

The transfer control unit 230 checks whether the first MSU 240 is abnormal, and when the first MSU 240 has an abnormality, transfer to the second MSU 250 is performed.

Accordingly, the first MSU 240 switches to the standby state and the second MSU 250 switches to the active state.

The operation of the first MSU 240 in the standby state corresponds to the operation in the standby state of the second MSU 250 described above, and the operation of the second MSU 250 in the active state is active in the first MSU 240. Corresponds to the action in the state. Therefore, description thereof will be omitted.

Meanwhile, the optocoupler unit 260 includes a second optocoupler 262 and a second optocoupler 264.

The input side of the first optocoupler 262 is connected to the SFP 244 provided in the first MSU 240 and the SFP 254 provided in the second MSU 250, and the output side of the first optocoupler 262 is a router. 280 is connected.

The first optocoupler 262 transmits the packet received at the MSU which is active to the router 280.

 For example, as illustrated in FIG. 2, the first optocoupler 262 transmits a packet received by the first MSU 240 that is active to the router 280.

The input side of the second optocoupler 264 is connected to the router 280, and the output side of the second optocoupler 264 is an SFP 244 provided in the first MSU 240 and an SFP provided in the second MSU 250. (254).

The second optocoupler 264 copies the packets received from the router 280 and provides them to the SFP 244 provided in the first MSU 240 and the SFP 254 provided in the second MSU 250, respectively.

The optocoupler 270 includes a third optocoupler 272 and a fourth optocoupler 274.

The input side of the third optocoupler 272 is connected to the SFP 246 provided in the first MSU 240 and the SFP 256 provided in the second MSU 250, and the output side of the third optocoupler 272 is a router. 282 is connected.

The third optocoupler 272 transmits the packet received at the MSU that is active to the router 282.

 For example, as illustrated in FIG. 2, the third optocoupler 272 transmits a packet received by the first MSU 240 that is active to the router 282.

The input side of the fourth optocoupler 274 is connected to the router 282, and the output side of the fourth optocoupler 274 is provided in the SFP 246 provided in the first MSU 240 and the SFP provided in the second MSU 250. Connected to 256.

The fourth optocoupler 274 copies the packets received from the router 282 and provides them to the SFP 246 provided in the first MSU 240 and the SFP 256 provided in the second MSU 250, respectively.

3 is a flowchart illustrating an operation of a packet transmission / reception method of an access node according to the present invention.

The packet transmission / reception method of the access node illustrated in FIG. 3 is performed on the first MSU 240, the second MSU 250, the optocoupler 260, and the optocoupler 270 as shown in FIG. 2.

Hereinafter, a packet transmission / reception method of an access node using the first MSU 240 will be described.

The Ethernet switch 242 of the first MSU 240 checks whether it is in an active state (S300). If it is active, it checks whether a packet to be transmitted from the subscriber side to the IP network is received (S302).

When the packet to be transmitted to the IP network is received from the subscriber side, the Ethernet switch 242 copies the packet and passes through the SFP 244 and the SFP 246 connected to the ports P3 and P4, respectively. The first optical coupler 260 and the third optical coupler 272 in the optical coupler unit 270 are transmitted to the router 280 and the router 282 (S304).

On the other hand, when the Ethernet switch 242 does not receive the packet transmitted from the subscriber side to the IP network, the packet is transmitted through the router 280 and the router 282 through the SFP 244 and the SFP 246, respectively, to the port P3. And whether it has been received at P4 (S306).

If there is a packet received at the ports P3 and P4, the Ethernet switch 242 provides the packet to the subscriber (S308).

At this time, the Ethernet switch 242 stores the MAC addresses included in the packets received at the ports P3 and P4 in a table provided.

 The Ethernet switch 242 uses the MAC addresses stored in the table, so that when the first MSU 240 switches from the active state to the standby state, the Ethernet switch 242 determines the MAC addresses of routers connected to the IP network. You can skip the process.

On the other hand, the Ethernet switch 242 checks the standby state when not in the active state, and the ports P3 and P4 from the router 280 and the router 282 through the SFP 244 and the SFP 246 when it is not the active state. It is checked whether a packet has been received at step S310.

If there are received packets at the ports P3 and P4, the Ethernet switch 242 provides the corresponding packets to the subscriber (S312).

At this time, the Ethernet switch 242 stores the MAC addresses included in the packets received at the ports P3 and P4 in a table provided.

 The Ethernet switch 242 uses the MAC addresses stored in the table, so that when the first MSU 240 switches from the standby state to the active state, the Ethernet switch 242 determines the MAC addresses of routers connected to the IP network. The process for this can be omitted.

On the other hand, the Ethernet switch 242 checks whether a packet to be transmitted from the subscriber side to the IP network has been received in the standby state (S314).

If the packet received by the IP network is received from the subscriber side in the standby state, the Ethernet switch 242 blocks the packet from being transmitted to the IP network (S316).

Although a method of transmitting and receiving a packet of an access node according to the present invention has been described with reference to the first MSU 240, it should be noted that the above description applies equally to the second MSU 250.

Therefore, a description of the packet transmission and reception method by the second MSU 250 will be omitted.

As described above, according to the packet transmission and reception method of the access node and the access node according to the present invention, the active MSU by omitting the MAC address detection process of the routers included in the IP network of the standby MSU when switching to the active state of the standby MSU, Due to this problem, voice service such as VoIP service can be performed without interruption when switching to standby MSU.

In addition, according to the packet transmission and reception method of the access node and the access node according to the present invention, by simultaneously receiving the packet transmitted from the IP network to the active MSU and standby MSU and by transmitting the packet received from the subscriber side to the IP network through the active MSU As a standby MSU performed due to a router connected to the active MSU, data can be transmitted and received between the subscriber side and the IP network regardless of switching.

Claims (8)

An access node comprising an active module and a standby module, The active module copies the packets received from the subscriber side and transmits the received packets to the router connected to the active module and the standby module, and transmits the packets received from the router connected to the active module to the standby module; The standby module transmits a packet transmitted from the active module to a router connected to the standby module, and receives information on an address included in a packet received from a router connected to the active module and a packet received from a router connected to the standby module. Access nodes that store each. The method of claim 1, The address information included in the packet received from the router connected to the active module and the packet received from the router connected to the standby module is a packet received from the subscriber side of the standby module when the standby module is switched to the active state. An access node (MAC) address of a router connected to the active module and a MAC address of a router connected to the standby module and required for transmission to a router connected to the active module and a router connected to the standby module. The method of claim 1, The active module and the standby module, Each including a switch unit and an optocoupler; The switch unit included in the active module copies the packet received from the subscriber side of the active module and transmits the packet to the optocoupler and the standby module included in the active module; The optocoupler included in the active module transmits a packet transmitted from a switch unit included in the active module to a router connected to the active module, and copies the packet received from the router connected to the active module to include in the active module. To the switched switch unit and the standby module; The optocoupler included in the standby module transmits a packet transmitted from a switch unit included in the active module to a router connected to the standby module, and copies the packet received from the router connected to the standby module to include in the standby module. To the switched switch unit and the switch unit included in the active module; And a switch unit included in the standby module stores an address included in a packet transmitted from an optocoupler included in the active module and an optocoupler included in the standby module. The method of claim 3, The switch unit included in the active module, An access node for transmitting a packet received from an optocoupler included in the active module and an optocoupler included in the standby module to a subscriber side. The method of claim 1, An extension self including an active subscriber extension unit and a standby subscriber extension unit; Wow The active subscriber extension unit and the standby subscriber extension unit are respectively connected to each other by Gigabit Ethernet, and the packet received from the subscriber side of the active subscriber extension unit is copied to the active module and the standby module, respectively, and received from the active module. And an Ethernet stacking unit (ESU) for copying a packet to the active subscriber extension unit and the standby subscriber extension unit. In the packet transmission and reception method of an access node duplexed by an active module and a standby module, each connected to a different router, Copying, by the active module, a packet received from a subscriber side to a router and a standby module connected to the active module, respectively; Wow And transmitting, by the standby module, a packet transmitted from the active module to a router connected to the standby module. In the packet transmission and reception method of an access node duplexed by an active module and a standby module, each connected to a different router, The active module transmitting a packet received from a router connected to the active module to the standby module; Wow And storing, by the standby module, information stored in a packet received from a router connected to the active module and an address included in a packet received from a router connected to the standby module. The method of claim 7, wherein The address information included in the packet received from the router connected to the active module and the packet received from the router connected to the standby module is a packet received from the subscriber side of the standby module when the standby module is switched to the active state. And a media access control (MAC) address of a router connected to the active module and a MAC address of a router connected to the standby module, which are required to be transmitted to the router connected to the active module and the router connected to the standby module.

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