KR20030057807A - ATM SAR Apparatus for Processing AAL1, AAL2, AAL5 - Google Patents

Abstract

PURPOSE: An ATM(Asynchronous Transfer Mode) SAR(Segmentation And Reassembly) apparatus for processing AAL1(ATM Adaptation Layer), AAL2, and AAL5 is provided to process various kinds of upper application data in order to meet a desired system by using an internal switch. CONSTITUTION: In an ATM network(10), physical layer data are changed to ATM layer data through an ATM framer(210), then loaded to a UTOPIA(Universal Test and Operation Interface for ATM) bus and then transmitted to an ATM switch(220). The ATM switch(220) discriminates whether it is a service for providing AAL1, AAL2, and AAL5 on the basis of VPI/VCI(Virtual Path Identifier/Virtual Channel Identifier) information in the transmitted ATM layer. When it is an AAL service, data are transmitted to an AAL1 SAR(230) and when it is an AAL2 or AAL5 service, data are transmitted to an AAL2/5 switch(220).

Description

ATM SAR Apparatus for Processing AAL1, AAL2, AAL5}

The present invention relates to an apparatus for processing Asynchronous Transfer Mode (ATM) Segmentation And Reassembly (SAR), and in particular, to process data of AAL1, AAL2, AAL5 by using an internal switch to fit various types of higher application data to a desired system. It relates to a device for processing.

ATM Adaptation Layer (AAL) is a layer for matching and coordinating data units of various upper applications with ATM cell information of an ATM layer. The AAL is configured depending on the upper application and provides different classes for different types of services in the ATM network. AAL1 uses a CBR method that can be useful for data that requires continuous bandwidth such as real-time voice, and AAL2 / 5 uses a VBR method that can have flexibility in a packet-switched method where traffic is frequently changed.

The conventional ATM system is composed of an ATM switch device 100, an AAL1 SAR device 110, and an AAL2 / 5 SAR device 120 as shown in FIG.

Referring to FIG. 1, the ATM switch device 100 switches a cell at the ATM layer, the AAL1 SAR device 110 performs SAR processing of the AAL1 layer, and the AAL 2/5 SAR device 120 is ALL 2 /. SAR processing of five layers. Each device-specific configuration consists of ATM Framers (101, 103, 104, 111, 121) and VPI / VCI (Virtual Path Identifier /) that translate the physical layer of the ATM network and the Universal Test & Operation Interface for ATM (UTOPIA) bus. ATM switch 102 for switching the direction of ATM cells according to Virtual Channel Identifier information, Time Slot Interchanger 114 for switching the corresponding channel of UTOPIA bus, and ATM AAL1 or AAL2 / There are AAL1, 2/5 SARs 112, 122, which analyzes 5 cells, and a PCI bridge 124, which interfaces with the PCI bus and the data on the local bus. In addition, there are controllers 105, 113, and 123 that control internal devices for each device 100, 110, and 120.

The reception of data in an ATM network is as follows.

Referring to FIG. 1, data of a physical layer in an ATM network 10 enters an ATM primer 101 and is loaded on a UTOPIA bus to an ATM layer, and based on VPI / VCI information in an ATM layer, an ATM switch ( In 102, ATM cells are switched for each channel according to the switch table. This can be seen in the manner that the type of service for each channel is determined and reported to the ATM switch 102 before the ATM data is received and the value determined in the call setup of the ATM. Data of the ATM layer separated for each channel is transmitted to the AAL1 SAR device 110 or the AAL2 / 5 SAR device 120 through the OPTICAL line to the physical layer through the ATM primers 103 and 104. The data transmitted to the physical layer is again transmitted to the AAL1 SAR 112 and the AAL2 / 5 SAR 122 via the ATM primers 111 and 121 of the respective devices 110 and 120. The AAL SAR 112 converts a cell of an ATM layer into an AAL1 layer and loads the channel on a local stream line for transmission. The voice data carried on the local stream line for each channel is converted into a desired channel through the time slot interchanger 114 and then carried on a TDM bus. Voice data transmitted through the TDM bus is transmitted to another device capable of processing voice.

Meanwhile, the AAL2 / 5 SAR 122 converts an ATM cell into an AAL2 or AAL5 layer according to the type of a service already determined through VPI / VCI, and transmits the same on a local bus. The PCI bridge 124 carries data on the local bus and transmits the data. Data on the PCI bus is sent to other devices running higher-level applications.

Transmission to the ATM network is reversed from reception.

Audio or video data created by higher-level applications is transmitted over the TDM bus or PCI bus. Voice data entering the TDM bus is transmitted to the AAL1 SAR 112 via the local stream line via the time slot interchange 114. Then, the AAL1 SAR 112 converts the received voice data into an ATM cell and transmits it to the ATM primer 111 through the UTOPIA bus. Meanwhile, data transmitted through the PCI bus is transmitted to the AAL2 / 5 SAR 122 via the PCI bridge 124. The AAL2 / 5 SAR 122 then converts the transmitted data into an ATM cell and transmits it to the ATM primer 121. The ATM cells are transmitted to the ATM primers 103 and 104 of the ATM switch device 100 through the respective ATM primers 111 and 121, and the VPI / VCI is transmitted through the corresponding channels by the ATM switch 102, respectively. After conversion, it is sent to the ATM primer 101. The ATM primer 101 converts data of the ATM layer coming into the UTOPIA interface into a physical layer and transmits the data to the ATM network 10.

As described above, in the conventional ATM system, at least an ATM switch device, an AAL1 SAR device, and an AAL2 / 5 SAR device must be configured in order to fully use the services of AAL1, AAL2, and AAL5. Therefore, the conventional system must use a control unit for each device, and must have an ATM primer at the end to transmit data for each device.

Accordingly, an object of the present invention is to provide an apparatus for processing the data processing of AAL1, AAL2, AAL5 to suit the desired system by processing various types of higher application data using an internal switch.

Another object of the present invention is to provide an apparatus for SAR processing of an AAL layer for transmitting and receiving voice, video, and information data in an ATM network providing AAL1, AAL2, and AAL5.

The present invention for achieving these objects is an ATM primer for converting the optical line and UTOPIA bus of the ATM network; An ATM switch for switching the direction of the ATM cell according to the VPI / VCI information; An AAL1 SAR analyzing an ATM AAL1 cell coming in via a UTOPIA bus; A time slot interchanger for switching a local stream line for each channel and a corresponding channel of the TDM bus; An AAL2 / 5 SAR analyzing an ATM AAL2 or AAL5 cell coming in via a UTOPIA bus; And at least a PCI bridge for interfacing the data of the local bus with the PCI bus.

1 is a block diagram of a conventional ATM system.

2 is a block diagram of an ATM SAR apparatus according to the present invention.

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

2 is a block diagram of an apparatus according to the present invention, including an ATM framer 210, an ATM switch 220, an AAL1 SAR 230, a time slot interchanger 240, an AAL2 / 5 SAR 250, and a PCI bridge. 250 and the control unit 270.

Referring to FIG. 2, the ATM primer 210 converts data of the physical layer transmitted from the optical line of the ATM network 10 into an ATM layer and transmits the data to the ATM switch 220 through the UTOPIA bus. The ATM switch 220 switches ATM cells transmitted through the UTOPIA bus according to the VPI / VCI information. AAL1 SAR 230 analyzes the ATM AAL1 cell coming in via the UTOPIA bus. The time slot interchange 240 switches the local stream line for each channel and the corresponding channel of the TDM bus. The AAL2 / 5 SAR 250 analyzes the ATM AAL2 or AAL5 cell. The PCI bridge 260 interfaces with data of the local bus and the PCI bus. The controller 270 controls the operation of each component of the apparatus 200.

Data reception in an ATM network according to an embodiment of the present invention is performed as follows.

Referring to FIG. 2, the data of the physical layer in the ATM network 10 is transferred to the ATM layer via the ATM primer 210 and loaded on the UTOPIA bus to the ATM switch 220. The ATM switch 220 determines whether the service provides AAL1 and AAL2 or AAL5 based on the VPI / VCI information in the transmitted ATM layer. This can be seen in a manner determined by the call setup of the ATM before the reception of ATM data, the type of service for each channel is reported to the ATM switch 220. The ATM switch 220 transmits to the AAL1 SAR 230 for the AAL1 service and to the AAL2 / 5 SAR 250 for the AAL2 or AAL5 service. The AAL1 SAR 230 converts a cell of an ATM layer into an AAL1 layer and loads it on a local stream line for each channel. The voice data carried on the local stream line for each channel is converted into a desired channel through the time slot interchange 240 and transmitted on a TDM bus. Voice data transmitted via the TDM bus is transmitted to another device capable of voice processing. The AAL2 / 5 SAR 250 converts the AAL2 or AAL5 layer into a local bus according to the type of service already determined through the VPI / VCI and transmits it on the local bus. The PCI bridge 260 transfers data on the local bus onto the PCI bus. Data on the PCI bus is sent to other devices running higher-level applications.

On the other hand, data transmission to the ATM network is performed as follows.

Referring to FIG. 2, audio or video data generated by an upper application is transmitted to the apparatus 200 through a TDM bus or a PCI bus. Voice data entering the TDM bus is then transmitted to the AAL1 SAR 230 via the time slot interchanger 240 via the local stream line. The AAL SAR 230 converts the received voice data into an ATM cell by allocating the corresponding VPI / VCI determined at the time of call setup before transmitting the traffic data to the ATM switch 220 through the UTOPIA bus. Alternatively, data transmitted over the PCI bus is sent to the AAL2 / 5 SAR 250 via the PCI bridge 260. Then, the AAL2 / 5 SAR 250 divides each channel according to the type of service set up at the time of call establishment before traffic data transmission, allocates each channel to the corresponding VPI / VCI, converts it into an ATM cell, and transmits the same to the ATM switch 220. The ATM switch 220 converts the data received through the determined VPI / VCI table into the corresponding VPI / VCI and transmits the data to the ATM framer 210. The ATM primer 210 transmits data of the ATM layer coming into the UTOPIA interface to the ATM network 10 as a physical layer.

As described above, the present invention can be implemented by separating ATM cells of various service classes coming from an ATM network in one device.

Therefore, the present invention does not need to use the ATM primer required for the device-by-device connection, thereby reducing the cost, and has the advantage of facilitating the stability and control of the system by unifying the device-specific control unit into one.

Claims (1)

In the AML SL device for processing A1, A2, A5, An ATM primer for converting the optical line and the UTOPIA bus of the ATM network; An ATM switch for switching the direction of the ATM cell according to the VPI / VCI information; An AAL1 SAR analyzing an ATM AAL1 cell coming in via a UTOPIA bus; A time slot exchanger for switching a local stream line for each channel and a corresponding channel of the TDM bus; An AAL2 / 5 SAR analyzing an ATM AAL2 or AAL5 cell coming in via a UTOPIA bus; ATM device for processing the A1, A2, A5, characterized in that it comprises at least a PCI bridge for interfacing the data of the local bus and the PCI bus.