KR100594983B1 - Method for communication between optical network units in broadband passive optical network - Google Patents

Abstract

The present invention provides a method for communication between optical network equipment of a broadband passive optical network, comprising: a first step of determining which packet is received when a packet is received; If the received packet is an ATM packet, checking a VID in a MAC address table to determine whether it is a VID for communication between optical communication network devices, and forwarding the received ATM packet to perform communication between optical communication devices; If the received packet is an Ethernet packet, a third step of forwarding the received Ethernet packet using the VID is configured to include Ethernet communication between all subscribers connected to the optical network equipment using the VID of the VLAN. You can do it.

Description

Method for communication between optical network units in broadband passive optical network

1 is a block diagram of a conventional optical line terminal,

2 is a block diagram of a conventional broadband passive optical network,

3 is a flowchart illustrating a communication method between optical communication network equipment in a broadband passive optical network according to the present invention;

FIG. 4 is a detailed flowchart of the second step ST12 in FIG. 3,

FIG. 5 is a detailed flowchart of the third step ST13 in FIG. 3,

6 is a block diagram of a broadband passive optical network to which the present invention is applied;

7 is a diagram showing a configuration example of a MAC address table used in the present invention;

8 is a diagram showing an example of the configuration of a VLAN table used in the present invention.

Explanation of symbols on the main parts of the drawings

10: optical line terminal 11: control unit

12: switch fabric 13: Ethernet port

14: ATM port 20: the first optical network equipment

21: ATM port 22 ~ 24: switch

30 second optical network equipment 31 ATM port

32 to 34: switch

The present invention relates to a communication method of a broadband passive optical network (B-PON), and in particular, an optical network unit (ONU) using a VLAN ID (VID) of a virtual local area network (VLAN). The present invention relates to a communication method between optical network equipment of a broadband passive optical network suitable for enabling Ethernet communication between all subscribers connected to the network.

In general, Asynchronous Transfer Mode (ATM) is determined by ITU-T (formerly CCITT) as the transmission method of Broadband Integrated Services Digital Network (B-ISDN) in 1988. Being a transmission, exchange technology. This is a method of dividing all information into fixed length blocks called ATM cells and transmitting them sequentially. Such ATM is a dedicated-connection switching technology that divides digital data into 53 bytes of cells or packets and transmits them through a medium using digital signal technology. One cell is individually processed asynchronously with respect to the other cells and placed in a queue for multiplexing for circuit sharing.

The header contains a Virtual Channel Identifier (VCI) for identifying the connection to which the cell belongs, a Virtual Path Identifier (VPI), and a Cell Loss Priority indicating whether the cell should be discarded during congestion. , CLP), cell information identification (Payload Type, PT) for distinguishing network control information, header error detection and control (Header Error Control, HEC), and the like. The feature of ATM multiplexing is that the multiplexing efficiency is higher than that of partitioning due to statistical multiplexing, and the transmission band allocated to individual communication can be freely set.

ATM operates on digital transmission infrastructure such as PDH (Plesiochronous Digital Hierarchy), SDH (Synchronous Digital Hierarchy), and SONET (Synchronous Optical Network). You can do it. As a proposal for accessing information superhighways in a general home, there is a method using hybrid mode optical fiber. The hybrid mode optical fiber is used for analog channel and digital MOD for analog broadcasting TV. It is divided into ATM digital channels for digital services such as (Movie-On-Demand), interactive TV, and video phone. This is possible by using WDM (Wavelength Division Multiplexing) to allow analog and digital channels to use different wavelengths. In this method, ATM traffic is transmitted over a passive optical network (PON), so it is called ATM over PON (APON).

Broadband Passive Optical Network (B-PON) is also a system that transmits signals to end users through optical fiber networks. The system uses either Fiber To The Curb (FTTC), Fiber To The Building (FTTB) or Fiber To The Home (FTTH), depending on where the B-PON is terminated. ) And the like.

B-PON consists of one Optical Line Termination (OLT) installed in a telecommunications company and a number of Optical Network Equipment (ONU) installed near the subscriber, usually up to 32 ONUs with one OLT. Can be connected to. In the B-PON, "Passive" means that once a signal begins to pass through the network, no more power energy or active electronics are needed for optical transmission. B-PON can be used as a trunk between large-scale systems, such as cable TV systems, and residential Ethernet networks using nearby buildings or coaxial cables.

Ethernet is the most widely installed local area network technology and is defined as a standard in the Institute of Electrical and Electronics Engineers (IEEE) 802.3. Local area networks (LANs) typically use coaxial cables or specially graded unshielded twisted pairs.

The most commonly installed Ethernet system is called 10BASE-T and provides a transmission rate of 10 Mbps. All devices are cabled and competitively accessed using the Carrier Sense Multiple Access with Collision Detection (CSMA / CD) protocol. Fast Ethernet and 100BASE-T provide up to 100 Mbps and are commonly used as the backbone of local area networks to support workstations with 10BASE-T cards. Gigabit Ethernet is around 1,000 Mbps, supporting higher levels of backbone speed.

This allows B-PON to use 100 Mbps Ethernet ports and Gigabit Ethernet ports.

In the B-PON structure, Ethernet is broadcast to all ports inside the optical network equipment, and communication from the optical network equipment to the adjacent optical network equipment through the optical line terminal is impossible.

Therefore, Ethernet communication in the B-PON structure has been inefficiently evaluated. As an improvement, the security function has been enhanced by using VLANs in the optical network equipment. Internal communication was not possible.

1 is a block diagram of a conventional optical line terminal.

Here, reference numeral 10 is an optical line terminal (OLT), 11 is a control unit for controlling the operation of the optical line terminal 10 is composed of a chip such as MPC8260, 12 is a field programmable gate array (FPGA) The switch fabric consists of a switch fabric, 13 is a gigabit 100-megabit Ethernet port, 14 is an ATM port.

Thus, the optical line terminal 10 may provide an ATM function through a network interface, and may provide a time division multiplexing (TDM) function for providing a voice service.

2 is a block diagram of a conventional broadband passive optical network.

Where reference numeral 20 is a first optical network equipment (ONU), 21 is an ATM port attached to the first optical network equipment 20, 30 is a second optical network equipment, and 32 is a second optical network equipment 30 ATM port attached to).

Thus, a plurality of optical network equipment (ONU) 20, 30 is installed in a subscriber dense area, and a VDSL (Very High-speed Digital Subscriber Line) is connected to the subscriber through the optical network equipment (20, 30). Digital subscriber line). In the optical network equipment 20, 30, data and voice signals transmitted through the VDSL are separated from the copper line, data is multiplexed and transmitted to the optical line terminal (OLT) 10, and the voice is transmitted through the V5.x interface. Provides an integrated service delivered from the optical line terminal 10 to the exchange.

The optical line terminal 10 provides an ATM function through a network interface using an ATM port 14, processes a channel change signal and a connection control / management signal for a broadcast type video service, and provides a point-to-multipoint point of an ATM layer. It can provide point-to-multipoint connection function.

In addition, the optical network equipment 20, 30 provides an ATM connection function using the ATM ports 21, 31, and provides channel change signal and access control / management signal processing function as necessary, It can also provide point-to-multipoint connectivity.

Meanwhile, the subscriber's signal transmitted through the first optical network equipment 20 is transmitted through the ATM port 21 of the first optical network equipment 20 and the ATM port 14 of the optical line terminal 10. Is sent to 10.

Also, the Ethernet frame transmitted to the optical line terminal 10 through the Ethernet port 13 transmits the ATM 14 of the optical line terminal 10 through the port so that the first and second optical communication network equipment 20 ( It is sent to the desired subscriber via ATM port 21, 31 of 30.

However, this conventional technology has the following problems.

That is, when a subscriber belonging to the first optical communication network equipment 20 wants to communicate with the subscriber belonging to the second optical communication network equipment 30, there is a problem that communication is impossible.

This is because when the subscriber belonging to the first optical network equipment 20 wants to communicate with the subscriber belonging to the second optical network equipment 30, the Ethernet frame sent by the subscriber belonging to the first optical network equipment 20 is the first optical network. The ATM port 21 and the optical line terminal 10 of the equipment 20 are transmitted to the optical line terminal 10 through the ATM port 14, the optical line terminal 10 is the first optical network equipment 20 Ethernet frame sent by the subscriber belonging to the) is to be sent only to the network through the Ethernet port 13, it was not possible to communicate with the subscriber belonging to the second optical network equipment (30).

If the optical line terminal 10 sends an Ethernet frame through the ATM port 14 for communication, the Ethernet frame is sent to the first optical network equipment 20 rather than the second optical network equipment 30. This causes a problem in the recognition of the MAC (Media Access Control) address of the first optical network equipment 20.

Here, the MAC address is an address used by the MAC layer of the data link layer and refers to a hardware address of the network card, and is the same as an Ethernet address or a token ring address. The hardware address assigned by the network card manufacturer is a universally administered address (UAA), and every network card has a unique value.

Therefore, the conventional technology has solved the security problem between the subscribers by granting the VID (VLAN ID) to the optical network equipment 20, 30 in the B-PON structure, but still different from the optical network equipment 20 (30) Since Ethernet communication between subscribers is impossible, there is a problem that Ethernet communication is inefficient in the B-PON structure.

Accordingly, the present invention has been proposed to solve the above-mentioned conventional problems, and an object of the present invention is to provide a broadband passive network capable of enabling Ethernet communication between all subscribers connected to optical communication network equipment using a VLAN VID. The present invention provides a communication method between optical communication network equipment of an optical network.

In order to achieve the above object, an optical communication network equipment communication method of a broadband passive optical network according to an embodiment of the present invention,

A first step of determining which packet is received when a packet is received; If the received packet is an ATM packet, checking a VID in a MAC address table to determine whether it is a VID for communication between optical communication network devices, and forwarding the received ATM packet to perform communication between optical communication devices; If the received packet is an Ethernet packet, the technical configuration includes performing a third step of forwarding the received Ethernet packet using a VID.

Hereinafter, an embodiment according to the present invention, a technical concept of a communication method between optical communication network equipment of a broadband passive optical network will be described with reference to the accompanying drawings.

3 is a flowchart illustrating a communication method between optical communication network equipment in a broadband passive optical network according to the present invention.

As shown therein, a first step ST11 of determining which packet is received when a packet is received; If the received packet is an ATM packet, it checks the VID (VLAN ID) in the MAC address table to determine whether it is a VID for communication between the optical communication network equipments 20 and 30, and forwards the received ATM packet to the optical communication equipment. A second step ST12 for communicating; If the received packet is an Ethernet packet, a third step (ST13) of forwarding the received Ethernet packet using the VID is performed.

FIG. 4 is a detailed flowchart of the second step ST12 in FIG. 3.

As shown therein, when the ATM packet is received, the eleventh step ST21 to ST23 records source information in the MAC address table and determines whether the destination address of the MAC address table of the ATM packet is broadcast; A twelfth step (ST24) of determining whether a corresponding address exists by checking a MAC address table if the destination address is unicast; A thirteenth step of checking the MAC address table and discarding the packet if the source and destination VPI / VCI are the same or different VID if the corresponding address is present (Hit); ST25); If the destination address is broadcast or if the corresponding address is not checked by checking the MAC address table (Not Hit), the VID is checked to determine whether it is a VID for communication between the optical communication network devices 20 and 30. Step ST26; A fifteenth step (ST27) of checking the VID and forwarding the packet only to the Ethernet port 13 if it is not a VID for communication between the optical network equipment (20) (30); If the VID is checked to be a VID for communication between the optical network equipment 20 and 30 (VID> 16), a VPI / VCI ATM port 14 that is not the same as the source VPI / VCI among the ports registered in the VLAN table is checked. A sixteenth step ST28 for forwarding to the Ethernet port 13 is performed.

In the 14th step ST26, when the VID is 1 to 16, the VID is determined to be internal communication, and when the VID is 17 or more, the VID is determined to be a VID for communication between the optical network equipment 20 and 30. do.

FIG. 5 is a detailed flowchart of the third step ST13 in FIG. 3.

As shown therein, when the Ethernet packet is received, the twenty-first step (ST31 to ST33) records source information in the MAC address table and determines whether the destination address of the Ethernet packet is broadcast; A twenty-second step (ST34) of determining whether a corresponding address exists by checking a MAC address table if the destination address of the Ethernet packet is unicast; A twenty-third step (ST35) of checking the MAC address table and forwarding to the corresponding port if a corresponding address is present (Hit); If the destination address of the Ethernet packet is broadcast or if the MAC address table is not checked (Not Hit), the Ethernet packet is forwarded to an Ethernet port other than the received port, and the broadcast VPI / VCI and VID values are included in the packet. And a twenty-fourth step ST36 of inserting the VCI and the broadcast VID and forwarding them to all the VPI / VCI ATM ports.

The operation of the communication method between the optical communication network equipment of the broadband passive optical network according to the present invention configured as described above will be described in detail with reference to the accompanying drawings.

First, the present invention intends to perform Ethernet communication between all subscribers connected to the optical network equipment using the VID of the VLAN.

Therefore, in the present invention, all the optical network equipment 20, 30 is assigned the same VID (VLAN ID) as the number of ports, and more VLAN ID is to be used for internal communication between different optical network equipment. Thus, the VLAN protocol processing modified by the present invention is performed by the algorithm determined in the optical line terminal 10.

Since the communication between the optical line terminal 10 and the optical network equipment 20 and 30 in the B-PON uses an ATM frame, an Ethernet frame is carried in an ATM packet for an Ethernet service.

The ATM port 14 of the optical line terminal 10 receives the ATM packet carrying the Ethernet frame from the optical network equipment 20 and 30, and converts the Ethernet frame to the Ethernet port of the optical line terminal 10 through internal conversion. 13) to provide Ethernet service.

And conventionally, the PON structure is a one-to-many communication between the optical line terminal 10 and the optical network equipment 20, 30 to transmit the downstream (Downstream) by broadcast and the upstream (Upstream) by TDM method For this reason, Ethernet communication between subscribers of different optical communication network equipments 20 and 30 is impossible.

In order to solve these problems, in the present invention, the VID used in the optical network equipment 20 and 30 is determined so that all the optical network equipment 20 and 30 use the VID within the same range, and different optical network equipment is used. A VID is determined for communication between the two and the VID is modified to enable communication through the VID.

6 is a block diagram of a broadband passive optical network to which the present invention is applied.

Where reference numeral 10 is an optical line terminal, 13 is an Ethernet port, 14 is an ATM port, 20 is a first optical network equipment, 21 is an ATM port in the first optical network equipment 20, and 22 to 24 are First to third switches in the first optical network equipment 20, 30 is the second optical network equipment, 31 is the ATM port in the second optical network equipment 30, and 32 to 34 are the second optical network equipment. It is the 1st-3rd switch in 30.

And VLAN 1, VLAN 2, VLAN 3, VLAN 4 is a VID for internal communication, VLAN 17 is a VID for communication between the optical network equipment 20,30.

Therefore, VLAN 1, VLAN 2, VLAN 3, and VLAN 4 are VIDs for internal communication, so that even if the VIDs are the same between the optical network equipments 20 and 30, they are not communicated with each other, and VLAN 17 is the optical network equipments 20 and 30. Since the VID is for communication between ports, ports with VID No. 17 can communicate with each other.

The operation of the present invention will be described with reference to FIGS. 4 to 6.

First, when a packet is received, it is determined which packet (ST11).

Thus, if the received packet is an ATM packet, it checks the VID (VLAN ID) in the MAC address table to determine whether it is a VID for communication between the optical network equipment 20 and 30, and forwards the received ATM packet to the optical communication equipment. Communication is performed (ST12).

That is, when the ATM packet is received, the source information is recorded in the MAC address table, and it is determined whether the destination address of the MAC address table of the ATM packet is broadcast (ST21 to ST23).

If the destination address is unicast, the MAC address table is checked to determine whether the corresponding address exists (ST24).

The MAC address table is checked and if a corresponding address is present (Hit), if the source and destination VPI / VCI are the same or the VID is different, the packet is discarded. Otherwise, the packet is forwarded to the corresponding port (ST25).

If the destination address is broadcast or if there is no corresponding address by checking the MAC address table (Not Hit), the VID is checked to determine whether it is a VID for communication between the optical communication network equipment 20 and 30 (ST26).

If the VID is not checked and is not a VID for communication between the optical network equipment 20 and 30 (VID <= 16), the packet is forwarded only to the Ethernet port 13 (ST27).

If the VID is checked to be a VID for communication between the optical network equipment 20 and 30 (VID> 16), the VPI / VCI ATM port 14 and the Ethernet port among the ports registered in the VLAN table are not the same as the source VPI / VCI. Forward to (13) (ST28).

If the received packet is an Ethernet packet, the received Ethernet packet is forwarded using the VID (ST13).

When the Ethernet packet is received, the source information is recorded in the MAC address table, and it is determined whether the destination address of the Ethernet packet is broadcast (ST31 to ST33).

If the destination address of the Ethernet packet is unicast, the MAC address table is checked to determine whether the corresponding address exists (ST34).

Check the MAC address table and if there is a corresponding address (Hit), forward it to the corresponding port. Otherwise, perform broadcast packet processing (ST35).

If the destination address of the Ethernet packet is broadcast or if the MAC address table is not found (Not Hit), it is forwarded to an Ethernet port other than the received port, and the VPI / VCI and VID values of the packet are broadcast VPI / VCI, A broadcast VID is inserted and forwarded to all VPI / VCI ATM ports (ST36).

By doing so, if the subscriber belonging to the first optical network equipment 20 wants to communicate with the subscriber belonging to the second optical network equipment 30, the VID and the second optical fiber of the subscriber belonging to the first optical network equipment 20 If the VID of the subscriber belonging to the communication network equipment 30 is 17 or more and the same value, Ethernet communication is possible between the two subscribers.

6, VLAN 1, VLAN 2, VLAN 3, VLAN 4 of the first switch 22 of the first optical network equipment 20, and VLAN 1, VLAN 2, VLAN 17, VLAN of the second switch 23. VLAN 1, VLAN 2, VLAN 3, and VLAN 4 of the fourth and third switches 24 are input to the ATM port 14 of the optical line terminal 10 through the ATM port 21.

And except for VLAN 17 of the second switch 23 having a VLAN value of 17 or more, VLAN 1, VLAN 2, VLAN 3, and VLAN 4 having a VLAN value of 16 or less are used for security purposes and are connected to the network through the Ethernet port 13. Is sent.

Also, VLAN 1, VLAN 2, VLAN 3, VLAN 4, and VLAN 1, VLAN 2, VLAN 17, VLAN 4, and 3 of the first switch 32 of the second optical network equipment 30 VLAN 1, VLAN 2, VLAN 17, and VLAN 4 of the switch 34 are input to the ATM port 14 of the optical line terminal 10 through the ATM port 31.

Except for VLAN 17 of the second and third switches 33 and 34 having a VLAN value of 17 or more, VLAN 1, VLAN 2, VLAN 3, and VLAN 4 having a VLAN value of 16 or less are used for security purposes. 13) is sent to the network.

Thus, the subscriber via VLAN 17 of the second switch 23 of the first optical network equipment 20 and the subscriber via VLAN 17 of the second and third switches 33 and 34 of the second optical network equipment 30. Since the VLAN value is 17 or more and has the same VLAN value, the communication is possible.

That is, when the subscriber transmits the packet through the second switch 23 of the first optical network equipment 20, the ATM port 21 of the first optical network equipment 20 and the ATM port of the optical line terminal 10 ( 14 to the optical line terminal 10. The optical line terminal then forwards the packet and transmits the packet through the ATM port 14 to the ATM port 31 of the second optical network equipment 30. Then, the packet is transmitted through the second and third switches 33 and 34 of the second optical network equipment 30 so that the subscriber belonging to the first optical network equipment 20 and the second optical network equipment 30 belong to the second optical network equipment 30. Communication between subscribers can be performed.

7 is a diagram showing an example of the configuration of the MAC address table used in the present invention.

Here, the MAC address is a source Ethernet address of data received through each port, VPI / VCI is VPI / VCI of data input to the ATM port, VID is VLAN ID, and a value of '0' in the port is an optical line terminal ( 10 may indicate ATM port 14, a '1' value may indicate a gigabit Ethernet port, and a '2' value may indicate a 100M Ethernet port.

So if the MAC address is "00: 01: 02: 03: 04: 00", you can set VPI to 0, VCI to 1, VID to 15, and port number to 0.

8 is a diagram showing an example of the configuration of a VLAN table used in the present invention.

Therefore, every Ethernet packet used in the ATM section has a VID field.

VID 1 ~ 16 is used for security, VID 17 ~ 4096 is used for communication between the optical network equipment (20, 30).

So, if VID is 17, VPI is 1 and VCI is 1, then port 15 is allocated.

As described above, the present invention enables Ethernet communication between all subscribers connected to the optical network equipment using the VID of the VLAN.

Although the preferred embodiment of the present invention has been described above, the present invention may use various changes, modifications, and equivalents. It is clear that the present invention can be applied in the same manner by appropriately modifying the above embodiments. Accordingly, the above description does not limit the scope of the invention as defined by the limitations of the following claims.

As described above, the communication method between the optical network equipment of the broadband passive optical network according to the present invention has the effect of enabling the Ethernet communication between all subscribers connected to the optical network equipment by using the VID of the VLAN. do.

In addition, VLAN supports only up to 4096. By defining VID used in optical network equipment, all optical network equipment uses the same VID, so one optical line terminal can provide VLAN function for 4096 or more subscribers. There is also an effect.

Claims (4)

A first step of determining which packet is received when a packet is received; If the received packet is an ATM packet, checking a VID in a MAC address table to determine whether it is a VID for communication between optical communication network devices, and forwarding the received ATM packet to perform communication between optical communication devices; And if the received packet is an Ethernet packet, including the third step of forwarding the received Ethernet packet using a VID. The method of claim 1, wherein the second step, An eleventh step of recording source information in a MAC address table when an ATM packet is received, and determining whether a destination address of the MAC address table of the ATM packet is broadcast; If the destination address is unicast, checking a MAC address table to determine whether a corresponding address exists; Checking the MAC address table and if there is a corresponding address, discarding the packet if the source and destination VPI / VCI are the same or different VID, and forwarding to the corresponding port; A fourteenth step of determining whether the destination address is broadcast or checking the MAC address table and checking the VID to determine whether the destination address is a VID for communication between the optical network equipment; Checking the VID and forwarding a packet only to an Ethernet port if the VID is not a VID for communication between the optical communication network devices; And checking the VID and forwarding to the VPI / VCI ATM port and the Ethernet port which are not the same as the source VPI / VCI among the ports registered in the VLAN table if the VID is for communication between the optical network devices. A communication method between optical network equipment of a broadband passive optical network. The method of claim 2, wherein the fourteenth step is When the VID is a value of 1 to 16, it is determined as a VID for internal communication, and when the VID is 17 or more, the VID is determined as a VID for communication between the optical network devices. . The method of claim 1, wherein the third step comprises: A twenty-first step of recording source information in a MAC address table when an Ethernet packet is received and determining whether a destination address of the Ethernet packet is broadcast; If the destination address of the Ethernet packet is unicast, checking a MAC address table to determine whether a corresponding address exists; Twenty-third step of checking the MAC address table and forwarding to the corresponding port if there is a corresponding address; If the destination address of the Ethernet packet is broadcast or if there is no corresponding address by checking the MAC address table, it is forwarded to an Ethernet port other than the received port. And a twenty-fourth step of inserting a VID and forwarding it to all the VPI / VCI ATM ports.

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