KR100306476B1 - System of Interfacing the ATM Network - Google Patents

Abstract

The present invention relates to an Asynchronous Transfer Mode (ATM) network matching system, and more particularly, to apply an ATM cell bus of Synchronous Transport Module 1 (STM1) speed for ATM circuit emulation in a voice processing block. It relates to an ATM network matching system.

The system of the present invention includes a CAM for receiving a latched value and checking whether it is equal to a preset internal value and outputting the address of a lookup table for converting a cell header; A VPI / VCI lookup table for updating VPI / VCI according to the address of a lookup table applied from the CAM; Demultiplexing an effective ATM cell transmitted from an ATM network, latching a cell header including VPI / VCI to the CAM, and performing a voice processing unit or higher protocol on the corresponding ATM cell according to the updated VPI / VCI in the VPI / VCI lookup table An ATM cell switch unit configured to multiplex an ATM cell applied from a corresponding voice processor or a higher protocol performing unit and transmit the multiplexed ATM cell to a corresponding ATM network; And an ATM cell bus matching unit for interfacing ATM cell transmissions between the voice processing unit and the ATM cell switch unit.

Description

ATM network matching system {System of Interfacing the ATM Network}

The present invention relates to an ATM network matching system, and more particularly, to an ATM network matching system adapted to apply an ATM cell bus of STM1 (Synchronous Transport Module 1) speed for ATM circuit emulation (Circuit Emulation) in a voice processing block.

In the prior art, an ATM network matching system having an open structure is multiplexed to distinguish between an ATM network connection unit 11, an ATM signal protocol cell, and a voice cell. A demultiplexer 12, a SAR function 13 for disassembling and assembling the corresponding ATM cell, and a TDM matching unit 14 for allocating external voice processing blocks and fixed-speed channels. ) And a VPI that stores a compact PCI matching unit 15 for communication with a higher function unit for signal protocol processing, a CPU 16, a packet memory 17, and preset VPI and VCI values. / VCI lookup table 18 is included.

The ATM network connection unit 11 includes a PHY function unit 11-1, and a transmission method of a digital signal level 1 (DS1) and a lesiochronous digital hierarchy (PDH) series of the DS3 and a synchronous digital hierarchy (SDH) series of the STM1. It is connected to the multiplexing / demultiplexing unit 12 in a UTOPIA (Universal Test & Operations PHY Interface for ATM) standard independent of the physical layer.

The multiplexer / demultiplexer 12 includes a demultiplexer 12-1 and a multiplexer 12-2 to distinguish between a signal cell and a voice cell for receiving and transmitting ATM cells. Processing is performed by the demultiplexer 12-1 and processed by the multiplexer 12-2 at the time of transmission.

The SAR function unit 13 includes the first and second SAR processors 13-1 and 13-2 to perform a service classification, that is, an AAL1 cell for signaling and an AAL5 cell for signaling. Each independently performs disassembly and assembly of cells.

The TDM matching unit 50 emulates an ATM cell with a TDM upon reception and performs an inverse transformation that emulates a TDM with an ATM cell when transmitting, and processes a speech synthesis block, a speech, a compression, and the like. Connect the line.

The compact PCI matching unit 60 provides a high speed transmission path for delivering a higher function unit, a control, and a packet to perform a signaling protocol.

The operation of the ATM network matching device having the above-described configuration will be described by dividing the operation path to the TDM matching unit and the transmission path corresponding to the reverse direction.

First, as to the reception path, when the STM1 frame, which is a structured ATM cell frame in the ATM network, is received by the PHY function 11-1 of the ATM network connection 11, the synchronization and inverse of the frame is performed. After scrambling, a valid cell is identified and extracted after checking the boundary of the cell and error checking of the header using the Virtual Container Pointer (VC4) (AU4 (Administrative Unit 4) in the STM1 frame. do.

Each valid cell is inputted to the demultiplexer 12-1 through a UTOPIA connection, and the values of VPI and VCI, which are set in the VPI / VCI lookup table 18 by the signal protocol, are inputted by the voice cell and the signal cell. It is divided by and transmitted to the SAR function unit 13 in hardware.

Accordingly, the SAR processors 13-1 and 13-2 in the SAR function unit 13 perform an assembling process into a packet data unit (SAR-PDU) after checking the ATM cell order and correcting header errors. do.

In this case, the first SAR processor 13-1 processes the voice of AAL1. Since 64 (Kbps) voice channels are multiplexed in a structured data transfer (SDT) scheme in one cell, the first SAR processor 13-1 processes the voice in AAL1. A pointer field is used to identify the boundary of the 'n × 64 (Kbps) (n ?? 2)' structured data.

In addition, the TDM matching unit 14 determines a time slot in the TDM for each channel in the SAR-PDU and assigns a channel to a computer telephony bus, which is allocated to the corresponding CT bus. Each voice channel is transmitted to a voice processing unit that processes voice synthesis, compression, and recognition to perform dual tone multifrequency (DTMF) recognition, voice playback, and recording.

On the other hand, in the case of the signaling protocol processing path, the ATM network access protocol is UNI (User to Network Interface), and the signal cell extracted by the demultiplexer 12-1 is the second SAR processor 13- of AAL5. After 2) performs cell assembly, Signaling AAL (SAAL) signal processing is performed, and UNI signal processing is transmitted to the upper functional unit through the compact PCI bus, and a series of protocol processes are performed.

Secondly, when referring to the transmission path, the process proceeds in the reverse order of the above-described process. When a plurality of voice channels are received from the voice processing block through the CT bus to the TDM matching unit 14, the VC (Virtual Connection) is the same. The channels are filled with the same ATM cell and transmitted to the multiplexer 12-2.

Accordingly, the multiplexer 12-2 performs a priority control on the signal AAL5 cell and the voice cell received from the compact PCI bus, and then multiplexes the physical layer.

However, the ATM cell passing through the demultiplexer 12-1 is converted into TDM and then transmitted through the CT bus. In a system in which the voice processing blocks connected to the CT bus are implemented in the same chassis. There is no problem.

However, when the voice processing blocks are implemented in different chassis and the distance between them is very long, there are many problems due to the electrical characteristics. That is, one system has a voice processing block composed of several chassis and the ATM network connection The implementation is quite difficult when using the B-ISDN User Part (B-ISUP) protocol, a Network to Network Interface (NNI).

As a result, in the conventional technology, when implementing a system having multiple voice processing blocks, each chassis must be configured as an independent chassis, and the B-ISUP protocol must be implemented in an independent chassis, so that signal processing and management are complicated and errors occur. There was a problem that the problem is difficult to solve.

In order to solve the problems described above, the present invention provides a circuit for converting or inverting a voice signal of an ATM cell unit into a TDM method in a voice trunking and signal processing apparatus in an open network ATM network matching system. By using emulation function, cell switch function to each independent voice processing block, and NNI access protocol, by implementing intelligent voice processing system in ATM network for commercialization of International Mobile Telecommunication (IMT-2000), voice and non- Its purpose is to support multimedia services of voice and to facilitate the open structure of CTI (Computer Telephony Integration) systems and the development of similar systems in the future.

1 is a block diagram illustrating a conventional Asynchronous Transfer Mode (ATM) network matching system.

2 is a block diagram illustrating an ATM network matching system according to an embodiment of the present invention.

3 is a block diagram illustrating a connection structure of an ATM network matching system of FIG. 2;

Explanation of symbols on the main parts of the drawings

21: ATM network connection

21-1, 30-1: PHY (Physical) function

22: ATM cell switch

23: Segmentation and Reassembly function

23-1, 23-2: SAR Processor

24: TDM (Time Division Multiplexing) Matching Part

25: Compact PCI Matching Unit

26: central processing unit (CPU)

27: Packet Memory

28: Virtual Path Identifier (VPI) / Virtual Channel Identifier (VCI) Look-up Table

29: CAM (Content Addressable Memory)

30: ATM cell bus matching unit

The ATM network matching system according to an embodiment of the present invention for achieving the above object is a CAM that receives the latched value and checks whether it is equal to a preset internal value and outputs the address of the lookup table to convert the cell header. and; A VPI / VCI lookup table for updating VPI / VCI according to the address of a lookup table applied from the CAM; Demultiplexing an effective ATM cell transmitted from an ATM network, latching a cell header including VPI / VCI to the CAM, and performing a voice processing unit or higher protocol on the corresponding ATM cell according to the updated VPI / VCI in the VPI / VCI lookup table An ATM cell switch unit configured to multiplex an ATM cell applied from a corresponding voice processor or a higher protocol performing unit and transmit the multiplexed ATM cell to a corresponding ATM network; And an ATM cell bus matching unit for interfacing ATM cell transmissions between the voice processing unit and the ATM cell switch unit.

Here, the ATM cell transmitted to the voice processor is outputted by changing only the VPI / VCI value to a destination without being converted into the TDM method by the ATM cell switch unit, and is emulated by TDM in the voice processor. Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

ATM network matching system according to an embodiment of the present invention, as shown in Figure 2, ATM network connection unit 21, ATM cell switch unit 22, SAR function unit 23, TDM matching unit 24 ), The compact PCI matching unit 25, the CPU 26, the packet memory 27, the VPI / VCI lookup table 28, the CAM 29, and the ATM cell bus matching unit 30. It is made to include.

The ATM network connection unit 21 includes a PHY function unit 21-1 to process generation and decomposition of a 622 (Mbps) class STM4 frame, which is a structured data frame transmitted and received with an ATM network. It performs functions related to ATM cell transmission itself, such as restoring clock of ATM network side, synchronization of frames, header error checking, extraction of valid cell, and to secure access of various physical layers. ) Supports the UTOPIA Level-1 specification.

The ATM cell switch unit 22 has a multiplexing and demultiplexing function related to an ATM network side and a switching function for distributing ATM cells to a plurality of system chassis having a voice processing unit. The demultiplexing function is a UTOPIA connection unit of a physical layer. When an ATM cell is received, the AMS cell distinguishes between a signaling cell and a voice cell, and the multiplexing function plays a role of setting and outputting priority when the signaling cell and the voice cell are transmitted to the ATM network.

The SAR function unit 23 is divided into two functional units, namely, a first SAR processor 23-1 of AAL1 and a second SAR processor 23-2 of AAL5. ) Performs the disassembly and assembly of the voice cell, and the second SAR processor 23-2 is responsible for disassembling and assembling the cell for signaling protocol processing.

Although the TDM matching unit 24 is not a main specification in the present invention, when the system has a single voice processing unit, the TDM matching unit 24 should be connected to the corresponding voice processing unit and the CT bus in one system chassis so that it can be selectively used. It is provided. The CT bus follows the ECTF H.110 specification, and the clocks used for the CT bus are 2 (MHz), 4 (MHz) and 8 (MHz), with 1024 64 (Kbps) voice channels provided in both directions. It is done.

The compact PCI matching unit 25 is a transmission path for transmitting and receiving high speed data with a higher control function unit to perform a protocol using a SAR-PDU that is disassembled and assembled in the second SAR processor 23-2. To provide. Here, the upper control function unit is a separate function module that is separated like the voice processing unit, and is not shown in the drawings for convenience of description.

The CPU 26 transmits the PDUs stored in the packet memory 27 through the compact PCI bus so that the upper control function unit can process the NNI protocol B-ISUP.

The packet memory 27 stores PDUs applied from the SAR processor 23.

The VPI / VCI lookup table 28 generates a new VPI / VCI according to the address of the lookup table applied from the CAM 29 to allow the ATM cell bus matching unit 30 to pass through the ATM cell switch unit 22. Or transmits the cell to the SAR function unit 23.

The CAM 29 receives the latched value from the ATM cell switch unit 22 and checks whether there is the same value among contents stored and stores the address of the lookup table to convert the header of the cell into the VPI / Output to the VCI lookup table 28.

The ATM cell bus matching unit 30 includes a PHY function unit 30-1 to provide a transmission path for ATM cells input and output between the ATM cell switch unit 22 and the voice processing unit. (Mbps) speed.

Referring to the operation of the ATM network matching system according to an embodiment of the present invention.

First, an ATM network matching system according to an embodiment of the present invention is installed in a system for intelligent services including voice, data storage, playback, and integrated messaging processing in an ATM network used as a core network of IMT-2000. As shown in FIG. 3, the system 42 of the present invention is connected to the ATM network 41 in an STM1 manner, and has a plurality of separate voice processing units 43-1 to 43-n and higher protocols. It is also connected to the execution unit 44, and the connection standard with the corresponding functional units 43-1 to 43-n, 44 is made of an open structure adopting standard methods such as the H.110 CT bus and the compact PCI bus of ECTF. .

First, in the case of the reception path, when the STM4 frame of the 622 (Mbps) speed of the SDH series is received from the ATM network 41, the PHY function unit 21-1, which is the physical layer of the ATM network connection unit 21, receives the corresponding message. After the frame synchronization and descrambling are processed, the boundary of the valid cell is checked using the pointer of the virtual container (VC) in the frame, and the valid cell is identified and extracted.

The valid cell is input to the ATM cell switch unit 22 via the UTOPIA bus. The ATM cell switch unit 22 performs a demultiplexing function to distinguish between the voice cell and the signal cell.

At this time, the classification of the AAL type according to the service class is made by the values of VPI and VCI assigned by the NNI signaling protocol, and the values of the corresponding VPI and VCI are updated in the VPI / VCI lookup table 28 so as to update the ATM. The cell switch unit 22 is used to classify ATM cells when performing the demultiplexing function.

In other words, when a cell is input to the ATM cell switch unit 22 from a UTOPIA bus, the ATM cell switch unit 22 performs a demultiplexing function to obtain a 4 (Byte) value including the VPI / VCI of the cell header. It latches and inputs the latched value to the CAM 29.

When the same value is found among the contents of the CAM 29, the CAM 29 outputs the address of the lookup table for converting the corresponding header to the VPI / VCI lookup table 28, and the VPI / VCI lookup. In the table 28, a new VPI / VCI is generated as a result value, and the cell is transferred to the voice processing units 43-1 to 43-n through the ATM cell bus matching unit 30 through the ATM cell switch unit 22. The cell is transmitted to the second SAR processor 23-2 of the SAR function unit 23 through the ATM cell switch unit 22.

The ATM cells transmitted to the voice processing units 43-1 to 43-n are outputted by changing only the VPI / VCI value to the corresponding destination without converting the ATM cell switch unit 22 into the TDM scheme.

On the other hand, in the conventional case, the cell is directly emulated with a TDM to transmit the cell to the voice processing unit of another chassis. This requires a conversion of the TDM back to the cell, which causes a delay and degrades quality.

Thus, in the present invention, the voice processing units 43-1 to 43-n emulate ATM cells by TDM.

In addition, when the assembly process is completed in the second SAR processor 23-2, the cell transmitted to the second SAR processor 23-2 of the SAR function unit 23 receives the second SAR processor 23-. 2) the PDU is stored in the packet memory 27, and the CPU 26 stores the PDU in the packet memory 27 through the compact PCI bus so that the upper protocol execution unit 44 can process the B-ISUP, which is an NNI protocol. Send the stored PDUs.

In particular, in the B-ISUP protocol processing, a structure consisting of a single network connection is easy. In the ATM network, the system 42 of the present invention to be connected to the ATM switch is considered as one signaling point and this is one signal point. It can be seen that network matching occurs at the connection point. That is, the system 42 of the present invention integrates ATM network matching into one and provides simplicity of control and convenience of management.

Secondly, in the case of the transmission path, the above-described process is performed in reverse order. The ATM cell switch unit 22 performs a multiplexing function, prioritizes and multiplexes a signal cell and a voice cell, and the PHY is a physical layer. It is delivered to the ATM network through the function unit 22-1. Here, the voice cell is designed to have a high priority, but is not limited thereto.

As described above, in order to develop an intelligent messaging system for commercialization of IMT-2000, the present invention accommodates ATM network matching unit, which is a core network matching standard, and supports voice and non-voice multimedia services, CT bus, and compact. The adoption of the PCI bus has recently responded to the trend of open structuring of CTI systems and can easily approach the development of similar systems in the future.

Claims (2)

A CAM for receiving a latched value and checking whether the latched value is the same as an internal preset value to output a address of a lookup table for converting a cell header; A VPI / VCI lookup table for updating VPI / VCI according to the address of a lookup table applied from the CAM; Demultiplexing an effective ATM cell transmitted from an ATM network, latching a cell header including VPI / VCI to the CAM, and performing a voice processing unit or higher protocol on the corresponding ATM cell according to the updated VPI / VCI in the VPI / VCI lookup table An ATM cell switch unit configured to multiplex an ATM cell applied from a corresponding voice processor or a higher protocol performing unit and transmit the multiplexed ATM cell to a corresponding ATM network; ATM cell bus matching unit for interfacing ATM cell transmission between the voice processing unit and the ATM cell switch unit. The method of claim 1, The ATM cell transmitted to the voice processor is outputted by changing only the VPI / VCI value to a destination without being converted into the TDM scheme by the ATM cell switch unit, and is emulated by TDM in the voice processor. .