KR20030079311A - Method for point-to-point emulation n gigabit ethernet passive optical network - Google Patents

Abstract

PURPOSE: A point-to-point emulation method in a GE-PON(Gigabit Ethernet Passive Optical Network) is provided to offer an Ethernet frame structure for peer-to-peer transmission in a GE-PON system and to embody point-to-point emulation by using the Ethernet frame structure. CONSTITUTION: In a PON structure that consists of one OLT(Optical Line Termination)(30) and a plurality of ONUs(Optical Network Units)(32a-32d), the OLT(30) comprises an 802.3 PHY(PHYsical) field, an 802.3 MAC(Media Access Controller) field, a bridge(60), and a PON ONU MUX/DEMUX block(70). The bridge(60) has ports(61-64) respectively mapped to ONUs 1 through n for point-to-point emulation and a normal port(65) to process not a PON tagging Ethernet frame but an existing Ethernet frame. The PON ONU MUX/DEMUX block(70), when an Ethernet frame is transmitted from the OLT to an ONU, sets the Ethernet type as a PON Ethernet tagging frame, and sets an allocated ONU ID to an ONU ID tag. In case that an Ethernet frame is transmitted from an ONU to the OLT, the PON ONU MUX/DEMUX block(70) checks whether the Ethernet type is set as a PON Ethernet tagging frame. Each ONU(32a-32d) comprises an 802.3 PHY field, an 802.3 MAC field, a PON ONU ID filtering block(50), and an LLC(Logical Link Control)(40).

Description

Point-to-point emulation method for Gigabit Ethernet passive optical subscriber network {METHOD FOR POINT-TO-POINT EMULATION N GIGABIT ETHERNET PASSIVE OPTICAL NETWORK}

The present invention relates to optical networks, and more particularly to a Gigabit Ethernet Passive Optical Network (GE-PON).

Passive optical subscriber network is a subscriber network structure that forms a distributed topology of tree structure by connecting multiple optical network units (ONU) to one optical line termination (OLT) using 1 × N optical distribution network (ODN). . Recently, the International Telecommunication Union-Telecommunication sect (ITU-T) has standardized the ITU-T G.982, ITU-T G.983.1, and ITU-T G. standards for Asynchronous Transfer Mode-Passive Optical Network (ATM-PON) systems. Documented as 983.3. In addition, the IEEE 802.3ah TF defined by the Institute of Electrical and Electronics Engineers (IEEE) is in the process of standardizing a passive optical subscriber network system based on Gigabit Ethernet.

Transmission capacity in ATM-PON and Ethernet passive optical subscriber network systems, as discussed in standard organizations such as ITU-T and IEEE 802.3, depends on the format of the data carried on two different wavelengths between the OLT and the ONU. In other words, the downlink transmission from the OLT at the telephone station to the subscriber ONU is carried by transmitting an ATM cell or Ethernet frame on a signal of 1550 nm (or 1490 nm) wavelength. Uplink transmission to the telephone-side OLT is discussed in the international organizations ITU-T and IEEE 802.3 on how to transmit data on 1310 nm wavelength signals.

In addition, point-to-point Gigabit Ethernet and ATM-PON MAC technologies have already been standardized, and their contents are described in IEEE 802.3z and ITU-T G.983.1. In addition, US Patent No. 5,978,374, which was invented by Gigad Ghaib et al. And issued a patent dated November 2, 1999, discloses the MAC technology in ATM-PON in detail. have.

1 is a diagram illustrating a relationship between a conventional 802.3 Ethernet and an 802.1D bridge.

As the 802.1D is developed under the assumption that the Ethernet medium shares a single physical transmission medium with a plurality of communication stations, the Ethernet frame transmitted from a subscriber station belonging to one region connected to the bridge in FIG. Sent to all subscriber stations in other regions connected to the bridge. Therefore, depending on the nature of the shared medium, the bridge receives all Ethernet frames. A bridge receiving a frame received at each port stores a destination address and a source address in a table. Through this process, the address assigned to each port is learned, and after receiving the frame, the bridge receiving the frame transmits the frame only to the port to which the destination address is assigned and does not transmit the frame to other ports. The collision phenomenon can be reduced.

An operation when the bridge receives a predetermined frame is classified into the following case.

The first case is when the destination address of the received frame is not found in the address table. This is an address that does not exist or that has never received a frame using this address, that is, it has not been learned. In this case, the bridge cannot determine which port to send to, so it sends the frame to all ports except the port on which the frame was received.

In the second case, there is an address in the table, but this frame is discarded if the port assigned to this address is the same as the received port. This means that the traffic has already been sent to the destination, thereby reducing unnecessary traffic.

The third is that the bridge sends this frame to the port assigned to the destination address, even if the address is in the table and the address is not assigned to the receiving port.

In FIG. 1, when the subscriber station a in the region A transmits the Ethernet frame to the same subscriber station b, the Ethernet frame is also transmitted to the bridge according to the characteristics of the shared medium, and the bridge has the same port assigned the destination address of the Ethernet frame. Area A discards the frame without transmitting the Ethernet frame.

2 is a block diagram of a conventional GE-PON system.

The GE-PON system consists of one OLT 20, multiple ONUs 22a, 22b, 22c and an Optical Distribution Network 26. The OLT 20 is located at the root of the tree structure and plays a central role in providing information to each subscriber of the access network. The downstream data frame transmitted from the OLT 20 is distributed to ONUs 22a, 22b and 22c as shown in three examples, and vice versa upstream from ONUs 22a, 22b and 22c. ODN 26 is connected to multiplex the data frame and transmit to OLT 20. The ONUs 22a, 22b and 22c receive the downlink data frame and provide it to the end users 24a, 24b and 24c and output the data output from the end users 24a, 24b and 24c into the uplink data frame. 26) to the OLT 20. The end users 24a, 24b, and 24c shown in three examples refer to various types of subscriber network terminators that can be used in a PON including a network terminal (NT).

In FIG. 2, unlike the shared medium, the Ethernet frame transmitted from the end user 1 24a to the other end user 2 24b is transmitted only to the OLT 20 and not to the end user 2 24b.

However, since the OLT bridge does not transmit the Ethernet frame downward to the end user 24b as described above, Ethernet frame loss occurs. Therefore, in order to enable peer-to-peer transmission in a PON based on a point-to-multipoint structure, it is necessary to develop a technology for compatibility with an Ethernet PON medium and an existing bridge.

Accordingly, an object of the present invention is to provide an Ethernet frame structure that enables peer-to-peer transmission in a Gigabit Ethernet PON system and a method for implementing point-to-point emulation using the same.

Another object of the present invention is to provide an Ethernet frame structure for compatibility with an existing bridge in an Ethernet PON structure and a method for implementing point-to-point emulation using the same.

In order to achieve the above object, the operation method of the Ethernet passive optical subscriber network configured including an OLT and a plurality of ONUs connected to the OLT,

Allocating a predetermined port of the OLT to each ONU;

Outputting an Ethernet frame destined for a predetermined ONU through a port assigned to the ONU when the Ethernet frame is received by the OLT;

Generating a PON tagged Ethernet frame by inserting an ONU ID assigned to the port into the Ethernet frame;

And outputting the PON tagged Ethernet frame through a port connected to the ONU.

1 is a diagram illustrating a relationship between a conventional 802.3 Ethernet and an 802.1D bridge;

2 is a block diagram of a passive optical subscriber network system,

3 illustrates a passive optical subscriber tagging Ethernet frame format according to the present invention;

4 is a view showing the configuration of an Ethernet passive optical subscriber network system according to the present invention;

5 is a diagram illustrating a downlink Ethernet frame transmission procedure from an OLT to an ONU;

6 is a diagram illustrating an uplink Ethernet frame transmission procedure from an ONU to an OLT.

7 is a diagram illustrating an uplink Ethernet frame transmission procedure from an ONU to an OLT.

8 is a diagram illustrating a downlink Ethernet frame transmission procedure from an OLT to an ONU;

FIG. 9 is a diagram illustrating an uplink / downlink Ethernet frame transmit / receive procedure when a subscriber station a in a region transmits an Ethernet frame to a subscriber station b in the same region.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals have the same reference numerals as much as possible even if displayed on different drawings. In the following description, numerous specific details such as components of specific circuits are shown, which are provided to help a more general understanding of the present invention, and it is understood that the present invention may be practiced without these specific details. It will be self-evident to those of ordinary knowledge. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

3 illustrates a passive optical subscriber tagging Ethernet frame format according to the present invention, wherein a six-byte destination address field 100 indicating an address of a destination to which a data field of a frame is to be transmitted, and a source from which a frame is sent. The configuration of a six-byte source address field 101 representing an address, a two-byte length / Ethernet type field 102, a data field 103, and a frame check field 104 is described. Same as a normal Ethernet frame.

In addition, the PON tagged Ethernet frame of the present invention includes an Ethernet type field 110 and a tag field 120.

The tag field 120 attaches the ONU ID assigned to the bridge port 121 to the tag for OLT downlink transmission, and inserts the local ONU ID to the tag for uplink transmission, and the Ethernet type field is PON. This field is used to define PON Ethernet type by newly defining the unused Ethernet type among Ethernet type to classify tagging Ethernet frame.

4 is a block diagram showing the configuration of an Ethernet PON system according to an embodiment of the present invention.

In a PON structure consisting of one OLT 30 and a number of ONUs 32a through 32n, the OLT 30 has an 802.3 physical (HY) field, an 802.3 media access control (MAC) field, a bridge 60 and a PON ONU ID. MUX / DEMUX block 70 is included. The ports of the bridge 60 are ports 61 to 64 mapped to each ONU (ONU1 to ONUn) for point-to-point emulation, and normals for processing existing Ethernet frames rather than PON-tagged Ethernet frames. normal) port 65. If the total number of ONUs is n, the number of ports is n + 1.

The PON ONU ID MUX / DEMUX block 70 functions to set the Ethernet type to the Ethernet type that specifies the PON Ethernet tagging frame when transmitting from OLT to ONU, and to set the ONU ID assigned to the port in the ONU ID tag. And when transmitting from ONU to OLT, it checks whether Ethernet type is set as PON Ethernet tagging frame.

Each of the plurality of ONUs 32a through 32n includes an 802.3 PHY, 802.3 MAC, PON ONU ID filtering block 50 and a logical link control (LLC) 40.

When transmitting from OLT to ONU, PON ONU ID filtering block 50 checks the Ethernet type and, if it is selected as PON Ethernet tagging frame, checks ONU ID TAG and transmits only Ethernet frames matching local ONU ID to LLC layer. And a frame that does not match is discarded. In case of transmission from ONU to OLT, Ethernet type is set to Ethernet type that specifies PON Ethernet tagging frame, and ONU ID tag is set to ONU ID assigned to port and inserted into Ethernet frame. PON-tagged Ethernet frame.

5 illustrates a downlink Ethernet frame transmission procedure from the OLT to the ONU. When the Ethernet frame is received by the OLT bridge 60, the destination address is viewed and transmitted to the PON ONU ID MUX / DEMUX block 70 through the port assigned thereto. The MUX / DEMUX block 70 sets the Ethernet type to the Ethernet type that specifies the PON Ethernet tagging frame, sets the ONU ID assigned to the port in the ONU ID tag, and inserts it into the Ethernet frame. Create a tagged Ethernet frame.

FIG. 6 shows that an Ethernet frame transmitted from an ONU to an OLT is received as a PON ONU ID MUX / DEMUX block through an 802.3 MAC and a PHY layer of an OLT.

The PON ONU ID MUX / DEMUX block that receives the Ethernet frame checks the ONU ID tag and transmits it to the bridge through the ONU ID port when the Ethernet type is set to PON Ethernet tagging frame. It also deletes the tag before the bridge transmission and recalculates the FCS to restore the existing Ethernet frame sent by OMU LLC. On the other hand, if the Ethernet type of the Ethernet frame received in the MUX / DEMUX block is not an OPN Ethernet tagging frame, the Ethernet frame is transmitted to the bridge through the normal port.

7 shows an Ethernet frame transmission procedure from ONU to OLT.

When the Ethernet layer is transmitted from the upper layer, LLC, to the PON ONU ID filtering block, the filtering block sets the Ethernet type to the Ethernet type that specifies the Ethernet type as the PON Ethernet tagging frame, and sets the local ONU ID to the ONU ID tag to set the existing Ethernet frame. Insert in

8 illustrates a procedure in which an Ethernet frame transmitted downlink from the OLT to the ONU is received by the PON ONU ID filtering block through the 802.3 MAC and the PHY of the ONU.

The PON ONU ID filtering block that receives the Ethernet frame checks the Ethernet type and, if it is selected as a PON Ethernet tagging frame, checks the ONU ID tag and transmits only the Ethernet frame matching the local ONU ID to the LLC layer. The frame performs filtering by discarding the frame. Prior to transmission to the LLC layer, the tag is deleted and the FCS is recalculated to restore the existing Ethernet frame transmitted by the OLT bridge. If the Ethernet type of the Ethernet frame received through the filtering block is not a PON Ethernet tagging frame, the Ethernet frame is transmitted to the LLC as it is.

FIG. 9 is a flowchart illustrating the above-described uplink / downlink Ethernet frame transmission / reception procedure of FIGS. 6 to 9 when the subscriber station a in the region A transmits the Ethernet frame to the same subscriber station b. Reference numerals 6 to 9 show the flowcharts of Figs. 6 to 9.

First, when the Ethernet frame is transmitted from the LLC layer of the ONU to the PON ONU ID filtering block (81), the filtering block is set to the Ethernet type that specifies the Ethernet type as the PON Ethernet tagging frame, and the local ONU ID is set to the ONU ID tag. Insert 82 into the existing Ethernet frame, and then transmits uplink to the OLT.

When the PON ONU ID MUX / DEMUX block receiving the Ethernet frame (71) is set to the PON Ethernet tagging frame (72), the PON ONU ID MUX / DEMUX block examines the ONU ID tag to determine the corresponding ONU ID port (73). The tag is deleted and the FCS is recalculated (74) and sent to the bridge.

When the Ethernet frame is received by the OLT bridge (61), the destination address is checked and transmitted via the corresponding port (62) to the PON ONU ID MUX / DEMUX block. The MUX / DEMUX block sets the Ethernet type to the Ethernet type that specifies the PON Ethernet tagging frame, sets the ONU ID assigned to the port in the ONU ID tag (63), and then transmits the data downward to the ONU.

The PON ONU ID filtering block that receives the Ethernet frame from the OLT (91) checks the Ethernet type and sets the PON Ethernet tagging frame (92) to check the ONU ID tag to tag only the Ethernet frames that match the local ONU ID. Are deleted, the FCS is recalculated (93) and transmitted to the LLC layer, and the discrepancies are discarded (94).

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. For example, in the above-described embodiment, the case in which the bridge is in the OLT has been described as an embodiment, but the bridge may be outside. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, the present invention proposes a PON Ethernet tagging frame and a point-to-point emulation process for 802.1D bridge compatibility with a Gigabit Ethernet passive optical subscriber network, thereby enabling peer-to-peer transmission without changing the existing 802.1D bridge. There is an advantage.

Claims (3)

In the operating method of the Ethernet passive optical subscriber network configured to include an OLT and a plurality of ONUs connected to the OLT, Allocating a predetermined port of the OLT to each ONU; Outputting an Ethernet frame destined for a predetermined ONU through a port assigned to the ONU when the Ethernet frame is received by the OLT; Generating a PON tagged Ethernet frame by inserting an ONU ID assigned to the port into the Ethernet frame; And outputting the PON-tagged Ethernet frame through a port connected to the ONU. In the operating method of the Ethernet passive optical subscriber network configured to include an OLT and a plurality of ONUs connected to the OLT, Allocating a predetermined port of the OLT to each ONU; Restoring an existing Ethernet frame by deleting a tag from a frame received by the OLT and recalculating an FCS; If the type of the frame received in the OLT is set to a PON Ethernet tagging frame, checking the ONU ID tag and transmitting the same to the bridge through the corresponding ONU ID port; Point to point of the Gigabit Ethernet passive optical subscriber network characterized in that the step of transmitting the Ethernet frame to the bridge through the normal port when the type of the frame received in the OLT is not set to a PON Ethernet tagging frame Emulation method. In the operating method of the Ethernet passive optical subscriber network configured to include an OLT and a plurality of ONUs connected to the OLT, Allocating a predetermined port of the OLT to each ONU; Deleting the tag from the frame received by the ONU and recalculating the FCS to restore the existing Ethernet frame; If the Ethernet frame is set to PON Ethernet tagging frame, Gigabit includes checking the ONU ID tag and transmitting only the Ethernet frame matching the local ONU ID to the LLC layer, and discarding the non-matching frame. Point-to-point emulation method for Ethernet passive optical subscriber networks.