KR20030029215A - Atm switch - Google Patents

Abstract

PURPOSE: An ATM switch is provided to convert frame headers of AAL2 mini-cells and transmit the cells to a switch fabric from a line interfacing card, and to synthesize the switched mini-cells with AAL2 cells in the switch fabric, thereby reducing an additional cost and easily implementing an AAL2 switching. CONSTITUTION: An input AAL2 frame processor(20) confirms input ATM cells inputted from a physical layer processor(10). If the ATM cells are not AAL2 cells, the input AAL2 frame processor(20) immediately outputs the ATM cells, and if the ATM cells are the AAL2 cells, the input AAL2 frame processor(20) extracts mini-cells to output each mini-cell. An input ATM layer processor(30) inputs the input ATM cells to convert headers by using ATM cell header conversion values designated in a processor(50), and attaches routing tags to the ATM cells in order to be routed in an ATM switch fabric(60), then outputs input ATM routing cells. An ATM switch fabric interface(40) inputs the input ATM routing cells to output the ATM routing cells to the ATM switch fabric(60) according to an ATM cell schedule, and inputs the output ATM routing cells switched from the ATM switch fabric(60) to output the output ATM routing cells.

Description

ATM Switch {ATM SWITCH}

The present invention relates to an ATM switch, and more particularly, to change the frame header of AAL2 minicells to be identical to the conventional ATM cell processing for AAL2 cells in an ATM cell matching unit or line matching card without changing the basic structure of the ATM switch. The invention relates to an ATM switch that converts and transmits it to a switch fabric, and the switch fabric combines the switched minicells into AAL2 cells to minimize the additional cost of AAL2 switch development and to easily implement AAL2 switching.

AAL2 is now emerging in ATM networks in a way that can be applied to ATM cells according to the development of voice compression technology for voice signals requiring real time processing in next generation mobile communication or ATM (Asynchronous Transfer Mode) networks. Voice signal transmission uses ATM Adaptation Layer Type 2 (hereinafter, AAL2: ATM Adaptation Layer Type 2) in which multiple voice signal cells (hereinafter referred to as mini-cells) enter ATM cells.

In particular, in the next generation mobile communication, it is recommended to transmit the voice signal between the base station and the control station using the AAL2 method, and various types of concentrating devices that can reduce the transmission cost by efficiently transmitting the voice signal in the ATM network are currently proposed. have.

A typical ATM switch is composed of a switch fabric unit and an ATM cell matching unit. Here, the switch fabric unit matches the ATM cell matching units to switch fixed size cells, and the ATM cell matching unit receives the ATM cells from the physical transmission medium and passes them through the ATM's general processing to the switch fabric units as fixed size packets. It consists of an input unit and an output unit for converting a fixed-size packet received from the switch fabric unit to an ATM cell and then to the transmission medium.

1 is a diagram illustrating the basic concept of a general ATM switch.

As shown here, as a basic concept of a switch to be implemented in an AAL2 switch system, the ATM switch 2 switches by VPI / VCI (Vertual Path Identifier / Vertual Channel Identifer) of the general ATM cell, and VPI, which is the A value of the input side, is switched. / VCI is converted to A 'on the output side. In addition, B is a typical basic concept that is converted to B 'and switched by VPI / VCI.

2 is a diagram illustrating a switching form of a mini cell and the like in an AAL2 switch in a typical ATM switch system.

As shown here, in the ATM switch system, the AAL2 switch 3 is switched and output for each minicell of the AAL2 cell, and multiple minicell channels (CID: Channel Identification), or CIDs, in the VPI / VCI, the A value of the input side, are output. # 1, CID # 2, CID # 3, and CID # 4 are switched to the output side, so it is switched by CID to A ', B', C 'of VPI / VCI, and CID values are also CID # 1', CID # 2 ', CID # 3', CID # 4 'should be able to be converted. In addition, the input cells of B and C values are also switched by CID to A ', B', and C '.

The ATM switch 2 including the AAL2 switch 4 first determines whether the AAL2 packet is a VPI / VCI, and then the AAL2 packet is switched by CID, and other packets are VPI / VCI switched in a general manner.

First, before describing AAL2 mini cell switching, the AAL2 packet structure will be described first in order to obtain an understanding of the AAL2 mini cell structure.

3 is a diagram illustrating the AAL2 packet structure presented in the general ITU-T I.363.2 Recommendation.

As shown here, a 53-byte AAL2 cell consists of a 5-byte ATM cell header and a 48-byte CPS-PDU (Common Part Sublayer-Protocol Data Unit). ATM cell header has various values for ATM cell processing including VPI / VCI, and CPS-PDU consists of 1 byte of Start Filed (STF) and 47 byte CPS-PDU payload to indicate the start of AAL2 frame. have.

At this time, the STF includes a 6-bit Offset Field (OSF) indicating the first start of the AAL2 minicell, a 1-bit Sequence Number (SN) indicating whether the cell is sequentially transmitted, and 1 for monitoring the parity error of the STF field. It consists of bit parity.

The CPS-PDU payload consists of several minicells, which are called CPS-packets, which are three-byte CPS-Packet Header (CPS-PH) and N (N = 45 or 64) byte CPS. It consists of PP (CPS-Packet Payload).

Here, the CPS-PH includes an 8-bit CID (Channel Identification) indicating a mini cell channel number, a 6-bit LI (Length Indicator) indicating a mini cell size, and a 5-bit UUI (User to User) indicating information between users. Indication) and 5-bit HEC (Header Error Control) that detects an x ⁵ + x ² + 1 CRC error for 19 bits of information (CID + LI + UUI) of the CPS-PH.

In this case, multiple CPS packets can be accommodated in the CPS-PDU payload. If the sum of the multiple mini cells accommodated in the CPS-PDU payload is less than 47 bytes, padding data is inserted and fixed to 47 bytes. .

In other words, an AAL2 packet can be formed by binding minicells of variable packet length to an ATM cell fixed at 53 bytes, and these minicells are classified by CID. The error monitoring for these AAL2 packets and minicells is P, HEC. If an error occurs, the packet is discarded and the next packet is monitored again for error.

In addition, if the CPS-PDU payload does not arrive for a certain period of time, the CPS-PDU payload may process the remaining portion as padding data and generate a CPS-PDU payload to create an AAL2 frame, where the user may arbitrarily Can be specified.

As shown in FIG. 3, in order to perform switching for mini cells in an ATM cell packet of 53 bytes, the MAL first recognizes that the AAL2 packet is from the ATM cell through VPI / VCI, and then uses the STF field in the AAL2 frame for the first time. The location of the cells should be checked and the mini cells should be extracted using the LI field, the mini cell size, to switch these mini cells. Here, each mini cell can be distinguished using a CID.

However, the ATM switch fabric is designed to switch ATM cells or fixed cell packets of a certain size, and thus there is a problem in that it is impossible to directly switch the mini cells in the AAL2 packet composed of mini cells of variable size.

In addition, in the ATM cell switching, the technology for switching AAL2 minicells consisting of multiple minicells includes AAL2 switching using a microprocessor in a low-speed ATM signal, but ATM AAL2 minicell processing, CRC processing, channel switching, and channel ID conversion in a microprocessor. It is not easy to process 2.048Mb / s ATM AAL2 cell with current technology because the processing speed is limited, and it can switch up to several dozens or dozens of 2.048Mb / s ATM AAL2 cell but more than 45Mb / s etc. There is a problem that real-time switching for a high speed ATM AAL2 mini cell is impossible.

As such, there is no system considering ATM switch routing overhead for each minicell in the ATM switch, and there is a method of changing the AAL2 minicell to AAL5 to switch to the AAL5 cell, but it is unnecessary for the AAL2 to AAL5 switching. Because of the AAL2 / AAL5 conversion process, there is a problem that a cell delay occurs and an expensive external device, that is, a high speed AAL5 SAR, memory, etc., is required, resulting in an increase in cost.

The present invention was created to solve the above problems, and an object of the present invention is the same as the conventional ATM cell processing for the AAL2 cell in the ATM cell matching unit, that is, the line matching card, without changing the basic structure of the ATM switch. By converting the frame headers of AAL2 minicells to be transmitted to the switch fabric, the switch fabric combines the switched minicells into AAL2 cells to provide an ATM switch that minimizes the additional cost of developing AAL2 switches and makes AAL2 switching easy. have.

It is also an object of the present invention to provide an AAL2 switch that can be matched with any commercial ATM device by matching using an utopia level 2 matching technique with an ATM line matching card and an open interface.

1 is a diagram illustrating the basic concept of a general ATM switch.

2 is a diagram illustrating a switching form of a mini cell and the like in an AAL2 switch in a typical ATM switch system.

3 is a diagram illustrating an AAL2 packet structure of a general ITU-T I.363.2.

4 is a block diagram showing an ATM switch according to the present invention.

5 is a diagram illustrating a frame conversion process in an ATM switch according to the present invention.

-Explanation of symbols for the main parts of the drawings-

10: physical layer processing unit 20: input AAL2 frame processing unit

30: input ATM layer processing unit 40: ATM switch fabric matching unit

50: processor 60: switch fabric

70: output AAL2 frame processing unit

80: output ATM layer processing unit

According to the present invention for realizing the above object, in the ATM switch, the AAL2 minicell is converted into the ATM switch routing cell for each minicell at the input side, and then switched to generate the AAL2 frame by binding the minicells of the same VPI / VCI at the output side. It is done.

In addition, the present invention, in the ATM switch, performs an ATM cell processing by matching with the STM-1 frame to output the input ATM cell, and receives the output ATM cell to process the physical layer to match the physical layer STM-1 A physical layer processing unit which generates and outputs an STM-1 frame, and an input AAL2 frame processing unit which checks an input ATM cell inputted from the physical layer processing unit and immediately outputs the non-AAL2 cell, and extracts a minicell and outputs each minicell for each AAL2 cell. And receiving the input ATM cell from the input AAL2 frame processor and converting the header using the ATM cell header conversion value specified by the processor, and outputting the input ATM routing cell by adding a routing tag on the ATM cell so that it can be routed in the ATM switch fabric. ATM cell scheduling by receiving an input ATM routing cell from an input ATM layer processor and an input ATM layer processor According to the ATM switch fabric outputs the input ATM routing cell, the ATM switch fabric matching unit for outputting the output ATM routing cell switched from the ATM switch fabric, and the output ATM routing cell from the ATM switch fabric matching unit to receive the processor to use the processor The output AAL2 frame processing unit and the output AAL2 frame to generate and output the routing cell of the AAL2 frame structure by extracting the minicells and binding the minicells by the same local ID. An output ATM layer processor that receives the output ATM routing cell from the processor, removes the routing tag from the header, generates an output ATM cell, and outputs it to the physical layer processor; a physical layer processor, an input AAL2 frame processor, an input ATM layer processor, and an ATM switch Fabric Matching and Output AAL2 Frames It is connected to a processor bus between the rib and the output ATM layer processing is characterized in that further comprising a processor for performing the initialization and ATM functions of each device.

In the above physical layer processing unit, the STM-1 and ATM cells are matched by a Utopia level 2 matching technology.

The input AAL2 frame processing unit may be configured to map the AAL2 CID to the HEC of the ATM header.

The ATM layer processor may generate an input ATM routing cell by mapping a routing tag required for switch routing, a local ID specifying an output VPI / VCI, and a CID` specifying an output CID to an input ATM routing cell header. It is done.

The output AAL2 frame processing unit may determine whether the output AAL2 frame cell is an AAL2 frame cell using a local ID for determining the output ATM VPI / VCI in the ATM routing cell header.

In addition, the output AAL2 frame processing unit extracts an AAL2 minicell, uses the converted CID` to newly map to the minicell CID, and binds the same local ID CID` to generate an AAL2 frame.

The output ATM layer processor may remove the routing tag and map the output VPI / VCI to the ATM cell header using a local ID.

Referring to the operation according to the present invention made as described above, if there is an AAL2 frame in an ATM cell in a general ATM line matching card, the input AAL2 frame processing unit converts the frame header into ATM routing packets for each AAL2 minicell so that ATM switching is performed. In addition, the AAL2 frame processing unit changes the mini cells of the AAL2 routing packet by VPI / VCI into AAL2 ATM cells to enable the AAL2 switching function in the ATM switch.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. In addition, the present embodiment is not intended to limit the scope of the present invention, but is presented by way of example only and the same parts as in the conventional configuration using the same reference numerals and names.

4 is a block diagram showing an ATM switch according to the present invention.

The part shown here is a block diagram showing a line matching card of an ATM switch.

As shown here, an ATM cell processing is performed by matching an STM-1 frame to a line matching card of an ATM switch to output an input ATM cell, and receive an output ATM cell to match the physical layer STM-1. The physical layer processing unit 10 is configured to generate and output an STM-1 frame by processing the STM-1 frame.

The matching of the STM-1 and ATM cells is then matched by a utopia level 2 matching technique, eliminating the need for another processing device to match the commercial device.

In this embodiment, PMC-Sierra's PM5349 155 Mb / s physical layer processing device is used as the physical layer processing unit 10.

The input AAL2 frame processing unit 20 checks the input ATM cell received from the physical layer processing unit 10 and immediately outputs the non-AAL2 cell, and extracts the minicells and outputs the minicells for each minicell. In order to receive the input ATM cell from the 20, the header is converted using the ATM cell header conversion value specified by the processor 50, and a routing tag is added to the ATM cell to be routed in the ATM switch fabric 60. An input ATM layer processing unit 30 is configured to output an input ATM routing cell from the input ATM layer processing unit 30, and outputs the input ATM routing cell to the ATM switch fabric 60 according to ATM cell scheduling. It consists of an ATM switch fabric matching unit 40 for receiving and outputting the switched output ATM routing cell from the fabric (60).

Also, it receives the output ATM routing cell from the ATM switch fabric matching unit 40 and checks whether it is an AAL2 routing cell using the processor 50, and outputs it immediately if it is not an AAL2 cell, and extracts a minicell if it is an AAL2 cell. Output AAL2 frame processing unit 70 and output AAL2 frame processing unit 70 to generate and output routing cells of AAL2 frame structure by tying minicells to each other and remove routing tags from headers to remove output ATM cells. An output ATM layer processing unit 80 that generates and outputs to the physical layer processing unit 10 is configured.

And between the physical layer processing unit 10, the input AAL2 frame processing unit 20, the input ATM layer processing unit 30, the ATM switch fabric matching unit 40, the output AAL2 frame processing unit 70, and the output ATM layer processing unit 80; A processor 50 connected to the processor bus 55 to perform initialization and ATM functions of each device is configured as an embedded processor MPC860 for PowerPC.

In the above embodiment, PMC-Sierra's PM7324 ATM layer and OAM processing device are used for the input ATM layer processing unit 30 and the output ATM layer processing unit 80, and the input AAL2 frame processing unit 20 and the output AAL2 frame processing unit 70 are used. ) Used Xilinx's XCV600 600,000-gate FPGA and the ATM switch fabric matching unit 40 used Lucent's LUC4AB01.

A process of performing AAL 2 switching in a line matching card of an ATM switch according to the present invention made as described above will be described below.

After receiving the STM-1 frame from the physical layer processing unit 10, performing ATM TC (Transmission Convergence) sublayer processing, that is, ATM cell processing using HEC, input AAL2 frame processing unit through Utopia level 2 matching. 20).

The input AAL2 frame processing unit 20 first checks whether the input ATM cell is an AAL2 cell, and then, if it is not an AAL2 cell, that is, a cell of AAL5, AAL1, etc., immediately transmits it to the input ATM layer processing unit 30, and in the case of an AAL2 cell, AAL2 frame processing. Extracts the AAL2 minicell and transmits the input ATM cell to the input ATM layer processor 30 for each minicell.

Here, whether or not it is an AAL2 cell, the processor 50 informs the input AAL2 frame processor 20 of the VPI / VCI of the AAL2 cell through the processor bus 55, and the input AAL2 frame processor 20 informs the AAL2 cell of the AAL2 cell using the processor 50. Check it.

The input ATM layer processor 30 processes all aspects of the ATM layer. In particular, in the present invention, the ATM cell header designated by the processor 50 in the PM7324 of PMC-Sierra Inc. is utilized to maximize the ATM cell header conversion of the commercial ATM layer processor. The conversion value is used to convert the entire input ATM cell header in hardware.

In addition, a routing tag is added over the ATM cell so that it can be routed in the ATM switch fabric 60. The input ATM routing cell with this routing tag is sent to the ATM switch fabric matching unit 40 so that the input ATM routing cell transmits to the ATM switch fabric 60 in accordance with ATM cell scheduling.

Meanwhile, the ATM switch fabric matching unit 40 receives the output ATM routing cell switched from the ATM switch fabric 60 and transmits the output ATM routing cell to the output AAL2 frame processor 70.

Here, the ATM routing cell header has a local ID that determines the output ATM VPI / VCI. The local ID can be used to determine the output VPI / VCI value to determine whether it is an AAL2 frame cell.

The output AAL2 frame processor 70 first checks whether the output ATM routing cell is an AAL2 routing cell with a local ID. If it is not an AAL2 frame cell, the output AAL2 frame processor 70 immediately transmits the output ATM routing cell to the output ATM layer processor 80. In this case, after performing AAL2 frame processing, the AAL2 mini cells are extracted, the mini-cells are grouped by the same local ID, and an output ATM routing cell having an AAL2 frame structure is generated and transmitted to the output ATM layer processing unit 80.

Here, the processor 50 may inform the output AAL2 frame processor 70 of the output AAL2 routing cell via the processor bus 55 using the processor 50 to determine whether the output AAL2 routing cell is the output AAL2 routing cell. Check the output AAL2 routing cell at.

The output ATM layer processing unit 80 generates the output ATM cell by removing the routing tag from the output ATM routing cell header, and also outputs the output ATM cell that has performed the output VPI / VCI conversion using the local ID to the physical layer processing unit 10. Send.

The physical layer processing unit 10 generates an STM-1 frame by processing the physical layer to match the output ATM cell with the physical layer STM-1 frame.

5 is a diagram illustrating a frame conversion process in an ATM switch according to the present invention.

As shown here, the ATM cell 15 output from the physical layer processing unit 10 is a CPS, which is a three-word ATM cell header and a 24-word payload including NDF (New Data Flag) such as VPI / VCI / HEC. It consists of PDUs.

An AAL2 frame is accommodated in a CPS-PDU, which can accommodate multiple AAL2 minicells, including an STF field of 1 byte. Here, the first mini cell can be found using the STF field.

In this embodiment, an example in which two mini cells are accommodated will be described. However, each of the mini cells is divided into CID # 1 and CID # 2.

The input AAL2 frame processing unit 20 generates a mini cell for each CID, and reference numeral 22 denotes a frame conversion process related to CID # 1 and 24 for CID # 2.

In the ATM cell header, since the HEC is used only in the physical layer processing unit 10 and has no meaning else, the CID # 1 and the CID # 2 are mapped to the HEC header area.

In addition, the input ATM layer processing unit 30 generates a routing tag necessary for routing the ATM switch and a local ID for output VPI / VCI conversion using VPI / VCI, CID # 1, and CID # 2 to generate an input ATM routing cell ( 32, 34) to CID # 1, CID # 2, CID # 2, CID # 2 to convert the CID # 1, CID # 2 to the output CID to the input ATM routing cell (32, 34) header.

The ATM routing cells 32 and 34 converted as described above are passed through the ATM switch fabric matching unit 40, the ATM switch fabric 60, and the ATM switch fabric matching unit 40, such as the output ATM routing cells 42 and 44. It is switched and delivered.

The output AAL2 frame processor 70, which receives the switched output ATM routing cells 42 and 44, extracts the AAL2 minicells and newly maps them to the minicell CIDs using the converted CIDs # 1 and CID # 2. In the case of output VPI / VCI, that is, when the local IDs are the same, CAL # 1 and CID # 2 are bundled to generate an AAL2 frame 75.

Here, the STF field of the AAL2 frame 75 is newly generated by the output AAL2 frame processing unit 70 for each local ID.

The output ATM layer processing unit 80 generates an output ATM cell 85 by mapping the output VPI / VCI to the output ATM cell header using the local ID and removing the routing tag. This output ATM cell 85 processes the HEC header for use in the physical layer.

Then, the ATM physical layer processing unit 10 receiving the output ATM cell 85 generates the STM-1 frame by processing the physical layer to match the physical layer STM-1 frame.

As described above, when there is an AAL2 frame in an ATM cell in a general ATM line matching card, an AAL2 switch is implemented by having an AAL2 frame processor to perform frame header conversion on each device so that ATM switching is performed for each AAL2 minicell.

The ATM AAL2 cell on the input side is converted into ATM routing packets for each minicell, and the output side enables the AAL2 switching function on the ATM switch by binding the minicells of the AAL2 routing packet by VPI / VCI to AAL2 ATM cells.

As described above, the present invention converts the frame headers of AAL2 minicells to be transmitted to the switch fabric so that the ATM cell matching unit, that is, the line matching card, is identical to the existing ATM cell processing without changing the basic structure of the ATM switch. In the switch fabric, the combined minicells can be synthesized into AAL2 cells to minimize the additional cost of AAL2 switch development and to easily implement AAL2 switching.

Also, when converting the frame header, FPGA is used to process the AAL2 mini cell at the input side as a routing cell in hardware and AAL2 processing at the output side for each VPI / VCI. There is an advantage to implement AAL2 switching.

Claims (7)

In an ATM switch, an AAL2 minicell is converted into an ATM switch routing cell for each minicell at an input side and switched, and then an AAL2 frame is generated at the output side by binding minicells of the same VPI / VCI. In the ATM switch, Physical processing to generate and output STM-1 frame by processing the physical layer to match the STM-1 frame, perform ATM cell processing to output the input ATM cell, and receive the output ATM cell and match the physical layer STM-1. A layer processing unit, An input AAL2 frame processor that checks the input ATM cell received from the physical layer processor and immediately outputs the non-AAL2 cell; and extracts the minicell and outputs each minicell for each AAL2 cell; An input for receiving an input ATM cell from the input AAL2 frame processor and converting a header using an ATM cell header conversion value specified by a processor, and outputting an input ATM routing cell by adding a routing tag on the ATM cell so that the header can be routed in the ATM switch fabric. ATM layer processing unit, Receives an input ATM routing cell from the input ATM layer processing unit, outputs an input ATM routing cell to the ATM switch fabric according to ATM cell scheduling, and matches an ATM switch fabric that receives and outputs an output ATM routing cell switched from the ATM switch fabric. Wealth, It receives the output ATM routing cell from the ATM switch fabric matching unit and checks whether it is an AAL2 routing cell using a processor, and outputs it immediately if it is not an AAL2 cell. In the case of an AAL2 cell, it extracts minicells and binds minicells by the same local ID to form an AAL2 frame structure. An output AAL2 frame processor for generating and outputting a routing cell of An output ATM layer processor that receives an output ATM routing cell from the output AAL2 frame processor, removes a routing tag from a header, generates an output ATM cell, and outputs the output ATM cell to the physical layer processor; The physical layer processing unit, the input AAL2 frame processing unit, the input ATM layer processing unit, the ATM switch fabric matching unit, the output AAL2 frame processing unit, and the output ATM layer processing unit are connected by a processor bus to perform initialization and ATM functions of each device. Processor ATM switch, characterized in that further comprises. The ATM switch of claim 2, wherein the input AAL2 frame processor maps an AAL2 CID to an HEC of an ATM header. The method of claim 2, wherein the ATM layer processing unit maps an input ATM routing cell by mapping a routing tag required for switch routing, a local ID specifying an output VPI / VCI, and a CID` specifying an output CID to an input ATM routing cell header. ATM switch, characterized in that to produce. 3. The ATM switch of claim 2, wherein the output AAL2 frame processor checks whether the output AAL2 frame cell is an AAL2 frame cell using a local ID that determines the output ATM VPI / VCI in the ATM routing cell header. The ATM of claim 2, wherein the output AAL2 frame processing unit extracts an AAL2 minicell, newly maps to the minicell CID using the converted CID ′, and generates an AAL2 frame by binding CIDs having the same local ID. switch. 3. The ATM switch of claim 2, wherein the output ATM layer processor removes a routing tag and maps the output VPI / VCI to an ATM cell header using a local ID.