KR20020069960A - Atm cell transmission method in atm system using aal2 - Google Patents

Abstract

PURPOSE: A method for transferring ATM cells in an AAL2(ATM Adaptive Layer 2) ATM system is provided to expand a channel indicator to identify an AAL2 sub channel. CONSTITUTION: In an ATM system that has a transmitting node transmitting AAL2 cells and a receiving node receiving AAL2 cells, the receiving node judges whether the information of the maximum multiplexing number is received from the transmitting node. If the information of the maximum multiplexing number is received, the receiving node extracts expansion values for expansion channel indicators from a virtual channel indicator field according to the information of the maximum multiplexing number. Then the receiving node detects channel indicators from mini cells. The receiving node detects the expansion values and the channel indicators corresponding to their respective expansion values. The receiving node combines the expansion values and the channel indicators and creates expansion channel indicators.

Description

Asynchronous transmission mode cell transmission method in asynchronous transmission mode system using asynchronous transmission mode adaptation layer 2 {ATM CELL TRANSMISSION METHOD IN ATM SYSTEM USING AAL2}

The present invention relates to an AAL2 transmission method of an asynchronous transmission mode system using an asynchronous transmission mode adaptive layer 2 format (ATM Adaptive Layer 2: " AAL2 "), wherein the AAL2 is extended by subfield identification field of the AAL2. Relates to a method of transmission.

1A to 1C are diagrams showing the configuration of the Asynchronous Transfer Mode Adaptive Layer 5 format (AAL5) of a general asynchronous transfer mode system. 1A to 1C, an asynchronous transfer mode (hereinafter referred to as "ATM") system generally uses 5 bytes of headers and 58 bytes of payload to transmit data as shown in FIG. 1A. Asynchronous transmission mode is transmitted to the cell of the adaptive layer 5 format (AAL5). The cell header of AAL5 is a UNI header 101 used when transmitting AAL5 between a user and a network as shown in FIG. 1B, and an NNI header 102 used when transmitting AAL5 between a network and a network as shown in FIG. 1C. ; Network to network Interface. When describing the functions of the fields constituting the UNI header 101 and the NNI header 103, Generic Flow Control (hereinafter referred to as "GFC") 103 is used to control the overload condition, virtual path An identifier (virtual path indicator) 104 and a virtual channel indicator (VCI) 105 are used for routing. The payload type PT 106 consists of 3 bits and is used for service adaptation or network maintenance. RES 106 is a reserved bit and CLP 107 has priority information for cell processing. HEC (Header Error Control) 109 is used for transmission error control for the cell header.

In the ATM, the cell having the above-described structure generally has an efficient structure for data transmission, but has an inefficient structure for low-speed and delay-sensitive services such as voice. This generates dummy bits to make a small amount of data into cells of 53 bytes, and the generation of the dummy bits results in a waste of the transmission band.

Recently, ATM Adaptation Layer Format 2 (AAL2) has been standardized to improve the inefficiency caused by transmitting voice in ATM to ATM Adaptation Layer Format 5. AAL2 can vary the length in accordance with the amount of voice data.

FIG. 2 is a diagram illustrating the structure of a general AAL2. FIG. 2A is a diagram illustrating a structure of a minicell, and FIG. 2B is a diagram showing a multiplexed structure of the minicell of FIG. With reference to this, the structure of AAL2 will be described.

The minicell is composed of a channel indicator (CID) 201, a length indicator (LI) 202, a UUI 203, an HEC 204, and a minicell payload 205. The channel identifier 201 is for identifying mini cells of AAL2 multiplexed on one ATM connection as a subchannel identifier. The LI 202 indicates the length of the cell in advance, and the UUI 203 is used in the minicell segmentation process.

Referring to FIG. 2B, a structure of AAL2 in which mini cells are multiplexed will be described. The AAL2 has a cell header 301 having a configuration of FIG. 1B or 1C and a fixed size of 1 byte. When distributed across an ATM cell, the minicell is multiplexed into STFs 302 and minicells specifying an offset at which the minicell is divided. In FIG. 2, the PAD 303 is a dummy bit for filling an ATM cell with 53 bytes. When the AAL2 is used, a plurality of minicells using each CID can be multiplexed and transmitted at a maximum of 2 ⁸ low-speed voices, thereby preventing waste of bands.

AAL2 uses the multiplexing effect by multiplexing multiple subchannels on one ATM connection. In general, by using more subchannels, the multiplexing effect becomes larger. However, since CID values used as subchannel identifiers are limited to 256, there may be cases where a sufficient effect is not seen.

Accordingly, an object of the present invention is to provide a method for extending a channel identifier for identifying a subchannel in an asynchronous transmission mode adaptation layer 2.

Another object of the present invention is to provide a method for extending the channel identifier by using the virtual channel identifier and / or payload type field of the cell header of the asynchronous transmission mode adaptation layer 2 as an area for indicating the channel identifier. .

In order to achieve the above object, the present invention provides a channel extension method of an originating node in an asynchronous transmission mode system having an outgoing node transmitting an asynchronous transmission mode adaptation layer 2 and a receiving node receiving the asynchronous transmission mode adaptation layer 2. Determining whether there is a channel to be allocated when the asynchronous transmission mode adaptive layer 2 is connected, and if there is no channel to allocate, transmitting the maximum number of multiplexing information that can be multiplexed to a cell of the asynchronous transmission mode adaptive layer 2 to the receiving node; And receiving the asynchronous transmission mode adaptation layer 2 cell by setting extended channel identifiers with extension values for each of the minicells multiplexed in a virtual channel identifier region according to the maximum multiplexing information and a channel identifier for each minicell. Characterized in that the process is sent to the node.

In order to achieve another object of the present invention, the present invention provides a reception node in an asynchronous transmission mode system having an originating node for transmitting an asynchronous transmission mode adaptation layer 2 having an extended channel identifier and a receiving node for receiving the asynchronous transmission mode adaptation layer 2. In the extended channel extraction method of a node, determining whether the maximum multiplexed number information is received from the originating node, and if the maximum multiplexed number information is received, expanding values for the extended channel identifiers according to the maximum multiplexed number information. Extracting from a virtual channel identifier region, detecting channel identifiers from the minicell, detecting channel identifiers corresponding to each of the extension values and the extension values, each of the extension values and the corresponding channel Process of generating extended channel identifiers by combining the identifiers Characterized by a made of an.

Is a cell structure of a general asynchronous transmission mode.

1B is a diagram showing a first structure of a general asynchronous transmission mode cell.

Figure 1c shows a second structure of a general asynchronous transmission mode cell.

Figure 2a is a diagram showing a minicell structure of AAL2 in a typical asynchronous transmission mode system.

Figure 2b is a view showing a structure in which the mini-cell of AAL2 is multiplexed in a general asynchronous transmission mode system.

3 is a diagram illustrating an asynchronous transmission mode cell transmission procedure between a sending node and a receiving node according to an embodiment of the present invention.

4 is a diagram illustrating a method for extending a subchannel identifier of an originating node according to an embodiment of the present invention.

5 is a diagram illustrating a method for detecting an extended subchannel identifier of a receiving node according to an embodiment of the present invention;

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

First, in adding the reference numerals to the components of each drawing, the same components have the same reference numerals as much as possible even if displayed on different drawings. In describing the present invention, when 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.

The present invention can be utilized when the VCI and PT are not used for cell routing in the network and cannot be changed in the network, such as the "Transparent Virtual Path Service" proposed in the asynchronous transport mode forum (UNum Recommendation UNI4.0). Be careful.

In the present invention, the calling party (hereinafter referred to as "calling node") transmits the maximum multiplexing number (Mux_No: the maximum number of minicells that can be inserted into one cell) according to whether or not the channel identifier is insufficient when establishing an AAL2 connection. According to the number of multiplexing, the minicell is further multiplexed by the extended number of eCIDs using the extended number of CIDs (hereinafter, referred to as "eCID"), and the receiving side (hereinafter referred to as "receiving node") is the maximum multiplexing. After receiving the number Mux_No, it is determined whether there is an extended eCID according to the maximum multiplexing number, and the multiplexed minicells are separated from the received AAL2 according to the determination.

3 is a diagram illustrating that the originating node 411 transmits the maximum multiplexing count information to the receiving node 421 in step 401 and transmits AAL2 according to the maximum multiplexing count information in step 402 according to an embodiment of the present invention. to be. If the cell header is 5 bytes and the header 3 bytes of the mini cell are considered, a maximum of 11 minicells can be inserted into one cell, so the Mux_No value does not exceed 11.

4 is a diagram illustrating a method of inserting an eCID of an originating node 411 according to an embodiment of the present invention. Hereinafter, referring to FIG. 4, the originating node 411 transmits the Mux_No when establishing an AAL2 connection, and then, when forming a cell, the VCI region is larger than or equal to Mux_No among N (1, 2, 4, 8, 16, and the smallest. Value). This is because the VCI consists of 16 bits, so only 1, 2, 4, 8, and 16 can be divided. Each divided region includes ID values for identifying subchannels together with CIDs 506, CIDs 507, and CIDs 508, eCIDs 503, eCIDs 504 and eCIDs 505. Use them. In the example of FIG. 4, when Mux_No is 4, N is equal to or greater than 8 of 1, 2, 4, 8, and 16, and is 4, which is smaller than 4, 8, or 16. Therefore, since the VCI is composed of 16 bits, when the VCI is divided into 4, the bits added to configure the eCID become 4 bits (hereinafter, the bits used to express the eCID are referred to as "extension values or e"). Therefore, as shown in FIG. 4, the eCID is represented by 8 bits for representing the original CID plus 4 bits. As a result, the number of subchannels multiplexed using the eCID is extended to 2 ^{(8 + 4)} .

Generalizing this is as follows.

eCID count = 2 ^ (8 + 16 / N)

The extended value e representing the eCID is inserted into the VCI region in the cell header and transmitted to the receiving node 421.

5 is a diagram illustrating a method of extracting an extended value e of a receiving node and generating an eCID.

When the originating node multiplexes and transmits the minicells using the eCID by the above method, the receiving node obtains an N value from the maximum multiplex information Mux_No, and uses the obtained N value of the VCI used in the extended CID. The bits are known. Therefore, the extended values e of the VCI region of the received AAL2 header are separated using N as shown in 601 of FIG. 5, and the CID 603, CID 605, and CID 609 are separated from the minicell, respectively, and expanded. Each of the values e, 601-1, 601-2, and 601-3 and each of the corresponding CID values, the CID 603, the CID 605, and the CID 609 are combined to generate an eCID. The receiving node 421 processes the minicells using the eCID.

As described above, since the channel identifier can be extended and used on the AAL 2, the minicells can be multiplexed more.

Claims (2)

In the channel expansion method of the originating node in an asynchronous transmission mode system having an outgoing node transmitting an asynchronous transmission mode adaptive layer 2 and a receiving node receiving the asynchronous transmission mode adaptive layer 2, Determining whether there is a channel to be allocated in the asynchronous transmission mode adaptive layer 2 connection; If there is no channel to be allocated, transmitting the maximum number of multiplexing information that can be multiplexed to a cell of the asynchronous transmission mode adaptation layer 2 to the receiving node; The extended channel identifier is set by adding extension values for each of the minicells multiplexed in the virtual channel identifier region according to the maximum multiplexing information and the channel identifier in each minicell to set the asynchronous transmission mode adaptation layer 2 cell to the receiving node. Characterized in that the transmission process. In the extended channel extraction method of the receiving node in an asynchronous transmission mode system having an outgoing node transmitting an asynchronous transmission mode adaptation layer 2 having an extended channel identifier and a receiving node receiving the asynchronous transmission mode adaptation layer 2, Determining whether the maximum number of multiplexing information is received from the originating node; Extracting extended values for extension channel identifiers from a virtual channel identifier region according to the maximum multiplexing count information, when the maximum multiplexing count information is received; Detecting channel identifiers from the minicell, Detecting the extension values and channel identifiers corresponding to each of the extension values; And combining the respective extended values with the corresponding channel identifiers to generate an extended channel identifier.