KR20040026536A - Ethernet interface apparatus function with controlling bandwidth and method thereof - Google Patents

Abstract

PURPOSE: An Ethernet interface apparatus having a bandwidth control function and its method are provided to minimize a frame loss in an Ethernet network by defining a traffic variable and applying the variable to every network element to control the bandwidth. CONSTITUTION: When an Ethernet frame reaches an Ethernet interface apparatus from a subscriber terminal(100), an MAC band controller determines whether the Ethernet frame satisfies a PER(Peak Ethernet Rate)(101). If the Ethernet frame satisfies the PER, the MAC band controller outputs the frame to a Tx Ethernet frame buffer and updates a PER algorithm(102). If the Ethernet frame does not satisfy the PER, the MAC band controller determines whether the Ethernet frame satisfies an EBR(Excess Burst Rate)(103). If the Ethernet frame satisfies the EBR, the MAC band controller performs a shaping function and updates the PER algorithm(104). If the Ethernet frame does not satisfy the EBR, the MAC band controller performs a polishing/scheduling function without updating the PER algorithm(105).

Description

Ethernet interface apparatus with method and controlling bandwidth and method

The present invention relates to an Ethernet interface device and method having a bandwidth control function, comprising: an Ethernet frame on an Ethernet interface used by a network node to provide end-to-end bandwidth control services to Ethernet service subscribers (Ethernet-Π and IEEE802.1Q). The present invention relates to an Ethernet interface device and a method having a bandwidth control function.

1 is a conceptual diagram illustrating a general Ethernet bandwidth control service in a public network.

1, subscribers 1 to 4 are connected to Ethernet switches A to G and Ethernet network 7 through 100Base or 1000Base based Ethernet interfaces 5 and 6, and users are connected to the public network. Ethernet service will be used at the interface speed contracted by the operator.

Here, the Ethernet interfaces 5 and 6 transmit frames only in the form of bursted traffic when transmitting frames from subscribers 1 to 4.

In addition, the Ethernet interface (5, 6) is to support the arbitrary bandwidth (for example, 3 Mbps or 5 Mbps) from the network node to the user service, the Ethernet for traffic that exceeds any bandwidth corresponding to the characteristics of the traffic, regardless of the characteristics of the traffic Discard the frame.

The graph of FIG. 1 schematically illustrates this, indicating that the Ethernet traffic transmitted from the subscribers 1 to 4 discards the traffic beyond the contract bandwidth after the bandwidth processing in the Ethernet network element.

In the conventional Ethernet interface control method, frames beyond the bandwidth contracted by the subscriber with the public network operator may be discarded to partially satisfy the bandwidth contract with the subscriber. However, since frames discarded in the Ethernet network are retransmitted in the upper layer (TCP / IP) and the application service layer, there is a problem that the service quality and network efficiency are reduced due to the frame loss.

The present invention was created to solve the above problems, and defines a traffic variable for controlling the end-to-end bandwidth of the Ethernet subscriber, and applies the variable to all network elements to control the bandwidth to reduce the frame loss in the Ethernet network. The goal is to minimize

1 is a conceptual diagram illustrating a public network providing a general Ethernet bandwidth control service.

2 is a diagram illustrating a frame structure including an Ethernet-Π frame type and an IEEE802.1Q-based Virtual Local Area Network (VLAN) field for providing an Ethernet service according to the present invention.

3 is a block diagram of an Ethernet interface device having a bandwidth control function according to the present invention.

4 is a flowchart of an Ethernet interface method having a bandwidth control function according to the present invention.

An Ethernet interface device having a bandwidth control function of the present invention for achieving the above object is, by using the interface means for transmitting and receiving the Ethernet frame from the terminal of the service subscriber and the Ethernet frame applied from the interface means The MAC processing unit performing media access control for the MAC, the buffering means for buffering and transmitting the Ethernet frame authorized from the MAC processing unit to the MAC processing unit, and the Ethernet frame buffered by the buffering means are set to the maximum service bandwidth set by the contract with the subscriber. It is characterized in that it is provided with a pulseband control unit for determining whether or not to satisfy the burst traffic size and selectively perform the polishing, scheduling, and shaping according to the result.

In addition, the Ethernet interface method having a bandwidth control function of the present invention for achieving the above object, to determine whether the Ethernet frame transmitted from the subscriber terminal meets a predetermined maximum service bandwidth to transmit the Ethernet frame if satisfied And a second step of determining whether or not the Ethernet frame satisfies a predetermined burst traffic size by performing shaping when the Ethernet frame satisfies a predetermined burst traffic and by performing polishing and scheduling when the Ethernet frame is not satisfied.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment of the present invention.

First, a public network operator and a subscriber perform service traffic negotiation. The service traffic negotiation may be changed at each subscription or use. In this case, the variables that can be used are defined as Peak Ethernet Rate (PER), Average Ethernet Rate (AER), and Excess Burst Rate (EBR).

First, the PER defines the maximum service bandwidth that a user can send, which can be equal to the interface speed. The AER defines an average bandwidth of a user's service usage time, and defines a contract rate that a subscriber wants to receive service. Here, AER is defined based on 1518 byte packet.

In addition, EBR defines the burst traffic size of the user, which defines a reference size of bandwidth as 1518 bytes. The EBR is defined as the inverse of the number of packets transmitted per second and the actual number of packets transmitted by an application service at the corresponding interface speed. The smaller the packet size, the larger the EBR becomes.

For example, if you want to provide 3Mbps Ethernet service between Ethernet subscribers A-A ', PER is defined as interface speed, AER is defined as 3Mbps, EBR is 1 for general data traffic, and voice level (128 bytes is used). ), About 10.4 can be used.

Therefore, after contracting the traffic with the subscriber by defining the above variables, the allocation of the corresponding resources is performed through the Ethernet interface device of FIG.

FIG. 2 illustrates a frame structure including an Ethernet-Π frame type and a Virtual Local Area Network (VLAN) field based on Institute of Electrical and Electronics Engineers (IEEE) 802.1Q according to the present invention.

First of all, an Ethernet-? Frame includes a six-byte destination address portion, a six-byte source address portion, a two-byte Ethernet form portion, a 46-1500 byte data portion, and a six-byte frame check portion (FCS). Sequence).

In addition, a frame including a VLAN field includes a 6-byte destination address portion, a 6-byte source address portion, a 4-byte VLAN field, a 2-byte Ethernet form portion, a 46-1500 byte data portion, and 6 bytes. It consists of a frame check unit.

FIG. 3 is a block diagram of an Ethernet interface device having a bandwidth control function according to the present invention. In the case where traffic having burst characteristics having a frame of the type shown in FIG. 2 is introduced from a subscriber to an Ethernet network, FIG. Subscriber traffic is controlled in the (network element).

Looking at the configuration, the present invention is the encoder (Encoder) 10, the interface unit 11, the decoder (Decoder) 12, the MAC (Media Access Control) processing unit 13, management and statistics A processing unit 14, a Tx (transmit) Ethernet frame buffer 15, an Rx (receive) Ethernet frame buffer 16, and a MAC band control unit 17 are provided.

First, the encoder 10 performs line coding 8B / 10B on an Ethernet frame transmitted to the subscriber through the MAC processor 13 and outputs the same to the interface unit 11. The MAC processing unit 13 processes the MAC address used by the data link layer in the local area network and outputs it to the Rx Ethernet frame buffer 16.

The frame processed by the MAC processing unit 13 is buffered through the Rx Ethernet frame buffer 16 and input to the MAC band control unit 17.

Here, the frame processed by the MAC processing unit 13 is applied to the management and statistical processing unit 14 and used as data for statistical processing of the MAC address band requested from the subscriber.

If the frame buffered through the Rx Ethernet frame buffer 16 satisfies the PER variable condition, the MAC band controller 17 transmits the frame and updates the PER algorithm. If the transmitted frame satisfies the EBR variable condition, shaping is performed and the PER algorithm is updated.

Here, shaping is a function that satisfies the performance and quality and maximizes the efficiency of the network by changing the traffic characteristics of the Ethernet frame stream in the Ethernet network. When shaping is performed, the average value of the frame delay of Ethernet traffic is slightly increased, but the frame loss rate can be minimized.

If the transmitted frame does not satisfy both the PER and EBR variable conditions, it performs polishing and scheduling without updating the PER algorithm to match the network speed.

Here, the polishing is a function of discarding the amount of traffic over the contracted bandwidth when traffic over the bandwidth contracted with the subscriber enters the network. Therefore, the congestion state at the node can be quickly alleviated to minimize the propagation of the congestion state to the network.

In addition, scheduling is a scheme for resolving contention with other traffic streams in a corresponding interface when transmitting traffic, and thus, it is possible to prevent the transmitted traffic from colliding with other streams by setting time priority between queues. .

The frame whose bandwidth is controlled by the MAC band controller 17 is buffered by the Tx Ethernet frame buffer 15 and output to the MAC processor 13. The decoder 12 decodes the Ethernet frame transmitted from the subscriber station through the interface unit 11 and outputs the decoded Ethernet frame to the MAC processor 13.

4 is a flowchart illustrating a control process of the MAC band controller 17 according to the present invention.

First, when an Ethernet frame arrives at the Ethernet interface device from the subscriber station (step 100), the MAC band controller 17 determines whether the received Ethernet frame satisfies the PER. (Step 101).

If the arrived Ethernet frame satisfies the PER, the arrived frame is output to the Tx Ethernet frame buffer 15 and the PER algorithm is updated (step 102). On the other hand, the MAC band controller 17 satisfies the PER. If not, it is determined whether the EBR is satisfied (step 103).

If the received Ethernet frame satisfies the EBR, the shaping function is performed and the PER algorithm is updated (step 104). On the other hand, the MAC band controller 17 does not update the PER algorithm if the received Ethernet frame does not satisfy the EBR. To perform the polishing / scheduling function without the step (step 105).

As described above, the present invention enables the subscriber to provide the desired bandwidth (unit of 1Mbps) in the network for the end-to-end Ethernet service between subscribers in the Ethernet network without limiting the speed of the interface.

In addition, it is possible to reduce the frame loss, improve the quality of service and at the same time maximize the use of network resources through efficient operation in the network.

Therefore, it is possible to give statistical multiplexing function to each traffic, thereby greatly reducing the congestion at the link or node level of the Ethernet network, thereby providing the effect of smoothly managing and operating the traffic.

Claims (9)

Interface means for transmitting and receiving an authorized Ethernet frame from a terminal of a service subscriber; A MAC processor for performing media access control for a local area network using an Ethernet frame applied from the interface means; Buffering means for buffering and transmitting the Ethernet frame applied from the MAC processing unit to the MAC processing unit; The MAC which determines whether the buffered Ethernet frame buffered Ethernet frame satisfies a predetermined maximum service bandwidth and burst traffic size due to the contract with the subscriber and selectively performs polishing, scheduling, and shaping according to the result. Ethernet interface device having a bandwidth control function characterized in that the band control section. The method of claim 1, wherein the interface means A decoder configured to decode the Ethernet frame applied from the terminal of the service subscriber and output the decoded Ethernet frame to the MAC processor; An encoder for encoding the Ethernet frame applied from the MAC processing unit and outputting the encoded Ethernet frame to a terminal of the service subscriber; And Ethernet interface device having a bandwidth control function characterized in that it comprises an interface for transmitting and receiving data with the terminal of the service subscriber. The method of claim 1, wherein the buffering means A received Ethernet frame buffer which buffers the Ethernet frame applied from the MAC processor and outputs the buffered Ethernet frame to the MAC band controller; And And an outgoing Ethernet frame buffer configured to buffer the Ethernet frame applied from the MAC band controller and output the buffered Ethernet frame to the MAC processor. The method of claim 1, And a management and statistics processing unit for storing data for statistical processing of the MAC address band requested from the subscriber based on the frame processed by the MAC processing unit. The pulse band control of claim 1, wherein And a variable for a maximum service bandwidth that the subscriber can transmit, an average bandwidth of service usage time, and the burst traffic size is preset. The method of claim 5, wherein the pulse band control unit When the transmitted Ethernet frame satisfies the maximum service bandwidth, the Ethernet frame is transmitted, shaping is performed when the burst traffic size is satisfied, and polishing and scheduling are performed when the burst traffic size is not satisfied. Ethernet interface device with bandwidth control. Determining whether the Ethernet frame transmitted from the subscriber station satisfies a preset maximum service bandwidth and transmitting the Ethernet frame if the Ethernet frame is satisfied; Determining whether or not the Ethernet frame satisfies a predetermined burst traffic size and performing shaping when the Ethernet frame satisfies a predetermined burst traffic; and performing polishing and scheduling when the Ethernet frame does not satisfy the Ethernet frame. Interface method. 8. The method of claim 7, wherein the first step is And updating the algorithm of the maximum service bandwidth variable if the transmitted ethernet frame satisfies the maximum service bandwidth. 8. The method of claim 7, wherein the second step is And updating the algorithm of the burst traffic size variable if the transmitted Ethernet frame satisfies the burst traffic size.