KR100353866B1 - Atm cell multiplexing equipment of dsl subscriber multiplexing interface module - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to an asynchronous transmission mode cell multiplexing device.

2. The technical problem to be solved by the invention

The present invention is intended to accommodate a number of digital subscriber line subscribers, and to be installed in the switching system so that the maintenance control module inside the system can control or know the status through the subscriber switch network and the connected switch network.

3. Summary of Solution to Invention

The present invention is connected to 16 asynchronous transmission mode layer processing unit, one asynchronous transmission mode layer processing unit is connected to a 16-board digital subscriber line subscriber processing unit that processes 8 channels of digital subscriber line subscriber unit per board, It is connected to the switch network module through internal module connection (IMI) and local timing clock (LTSI) for data connection to provide symmetrical and asymmetric asynchronous transmission mode service to digital subscriber line subscribers.

4. Important uses of the invention

The present invention is used in subscriber registration module of digital subscriber line in ATM switching system.

Description

ATM CELL MULTIPLEXING EQUIPMENT OF DSL SUBSCRIBER MULTIPLEXING INTERFACE MODULE}

The present invention provides a digital subscriber line multiplexer that can be mounted in an asynchronous transfer mode switching system to accommodate multiple remote subscribers using a universal digital subscriber line (xDSL) in an asynchronous transfer mode (ATM) switching system. An asynchronous transmission mode cell multiplexing device of a matching module.

Since the asynchronous transmission mode cell multiplexing device of the conventional digital subscriber line subscriber multiplexing matching module is connected to the digital subscriber line subscriber processing unit via a bus, the number of subscribers that can be connected is limited due to the limitation of the bus length to be connected. In addition, as a type of equipment which is not mounted in the exchanger and is different in shape from the exchanger, it can be connected only outside the exchanger. Therefore, as the number of digital subscriber line subscribers increases, multiple cell multiplexing devices must be used, and since they are connected to the outside of the exchange, there is a problem in that the operation and maintenance devices in the system are not controlled or the status is unknown.

Accordingly, the present invention devised to solve the problems of the prior art as described above, multiplexing the multiple asynchronous transmission mode layer processing apparatus once more to accommodate a large number of digital subscriber line subscribers, it is mounted in the switching system subscribers It is an object of the present invention to provide an asynchronous transmission mode cell multiplexing device of a digital subscriber line subscriber multiplexing matching module that can be controlled by a maintenance control module inside a system or know a state through a switch network.

1 is a block diagram of a general Asynchronous Transfer Mode (ATM) exchange system.

Figure 2 is a block diagram of a digital subscriber line subscriber multiplexing matching module to which the present invention is applied.

Figure 3 is a block diagram of an asynchronous transmission mode cell multiplexing apparatus according to the present invention.

* Explanation of symbols for the main parts of the drawings

41: central control unit 42: clock signal matching unit

43: state matching unit 44: lower link matching unit

45: lower link control unit 46: transceiver cell multiplexer

47: receiving cell processing unit 48: transmitting cell processing unit

49: switch link matching unit

In order to achieve the above object, the present invention provides an asynchronous transmission mode cell multiplexing device connected to an asynchronous transmission mode layer processing apparatus of a subscriber switch network module and a digital subscriber line subscriber multiplexing matching module in an asynchronous transmission mode switching system. Central control means connected to provide a control signal to the local bus and communicate with an upper processor using a control cell; Clock signal matching means for receiving a local timing clock from the subscriber switch network module, providing a clock signal in a device through the local bus, and providing a module timing clock to the asynchronous transmission mode layer processing apparatus; State matching means for storing state information of the asynchronous transmission mode layer processing apparatus and transferring the state information through the local bus; Lower link matching means connected to the asynchronous transfer mode layer processor through a local internal module connection to perform matching, decoding and coding of the received data; A sublink control having a plurality of transmitting cells and a receiving cell packet (FIFO), converting a received cell and storing the received cell in the receiving cell pico, or converting a cell stored in the transmitting cell pico and transmitting the converted cell to the lower link matching means. Way; Transmitting / receiving cell multiplexing means for reading and multiplexing cells stored in each of the receiving cell packets, demultiplexing cells input from the transmitting cell processing means, and storing the multiplexed cells in the respective transmitting cell packets of a corresponding link; Reception cell processing means for processing a cell multiplexed by the transmission / reception cell multiplexing means; Transmission cell processing means for processing a cell to be transmitted and providing it to the transmission / reception cell multiplexing means; And switch link matching means connected to the subscriber switch network module through an internal module connection.

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

1 is a configuration diagram of a general asynchronous transmission mode switching system to which the present invention is applied, which is composed of one central switching subsystem 2 and a plurality of local switching subsystems 1.

Local switching subsystem 1 provides STM-1 (155 Mbps) subscribers, DS3 (45 Mbps) subscribers, DS1 (1.5 Mbps) subscribers, DS1E (2 Mbps) subscribers, and universal digital subscriber line subscribers (52 Mbps to 1 Mbps, 13 Mbps to 64 kbps). Relay line matching module (12) and subscriber matching module (11) for connecting subscriber matching module (11), STM-1 (155Mbps) relay line and STM-4 (622Mbps) relay line to subscriber switch network. The alarm of each module in the subscriber switch network module 13 and the local switching subsystem 1 connecting the relay line matching module 12 and the subscriber control module 14 to the connection switch network module 21, Subscriber control module 14 for maintenance control and call connection control. The connection between each module and the subscriber switch network 13 is made through an inter module interface (IMI), and the number of connected IMIs varies depending on the speed of the subscriber or the relay line.

The central switching subsystem 2 interconnects the local switching subsystems 1 and performs overall control of the system. The central switching subsystem 2 generates a synchronization clock for synchronization of the entire switching system network. 13) and the internal switch module timing clock (IMTI: Inter Module Timing Interface) and the central timing clock (CTSI) are supplied to the connected switch network module 21 and the maintenance control module 23, respectively. The network switch module 22 and the subscriber switch network module 13 are connected to each other, the connection switch network module 21 having a connection with the maintenance control module 23, the maintenance control function and operation management of the entire exchange system. It consists of a maintenance control module 23 to perform a function, the connection between each module and the connection switch network module 21 is made through an internal module connection (IMI).

Fig. 2 is a block diagram of a digital subscriber line subscriber multiplexing matching module of a local switched sub system to which the present invention is applied, which is an asynchronous transmission mode cell multiplexer (31) of the present invention, and up to 16 asynchronous transmission mode layer processing apparatuses (32). -1 to 32-16), consisting of up to 16 digital subscriber line subscriber processing units 33-1 to 33-16, accommodating up to 1024 digital subscriber line subscribers, and processing asynchronous transmission mode cells to process digital subscribers. It provides high speed asynchronous transmission mode data service to circuit subscriber.

The asynchronous transmission mode cell multiplexing device 31 transmits and receives 234.7474 Mbps differential signal serial data to and from the subscriber switch network module 13 through an internal module connection (IMI). The local timing clock (LTSI: Local Timing Signal Interface (LTSI)) is 46.94943. The MHz clock is received from the subscriber switch network module 13. It is also in communication with the maintenance control module 23 of the central exchange subsystem to receive central control. Communication with 16 asynchronous transmission mode layer processing devices transmits and receives 234.7474 Mbps differential signal serial data through Local Internal Module Access (LIMI), and multiplexes these data to the subscriber switch network module (13). It also does the reverse. The 46.94943 MHz clock, which is a Module Timing Signal Interface (MTSI) received from the subscriber switch network module 13, is synthesized, buffered, and supplied to 16 asynchronous transfer mode layer processors. In addition, the function alarm signals FA1 to FA16 and the hernia alarm signals OA0 to OA16 of the asynchronous transfer mode layer processor are inputted from the asynchronous transfer mode layer processor, and their hernia alarm signal (Off_Alm) and the function alarm signal ( Fun_Alm) outputs to the alarm collecting device.

The asynchronous transmission mode layer processor 32-1 transmits and receives 234.7474 Mbps differential signal serial data through the asynchronous transmission mode cell multiplexer 31 and LIMI, and transmits and receives cells with the digital subscriber line subscriber processor 33-1. Communicate via bus and control signal bus. The transmit / receive cell bus transmits the transmit cell 16-bit data and the transmit cell start signal to the digital subscriber line subscriber processor. Receiving cell 16-bit data and receiving cell start signal from digital subscriber line subscriber processing unit and receiving cell signal request signal from 16 digital subscriber line subscriber processing unit Cell line permission signal is sent to subscriber line subscriber processor. The control signal bus sends and receives address signals, data signals, address valid signals, data valid signals, and data read / write signals to access both ports in the digital subscriber line subscriber processing unit. A main clock (23.4747 MHz) for synchronizing clocks in the module and a cell bus clock (11.7373 MHz) for synchronizing transmit / receive cell buses are supplied to the digital subscriber line subscriber processing unit. Also, the function alarm signal and hernia alarm signal of each digital subscriber line subscriber processing device are inputted from the digital subscriber line subscriber processing device, and the function alarm signal and the hernia alarm signal OA are output to the asynchronous transmission mode cell multiplexer. Do it.

The digital subscriber line subscriber processor 33-1 receives the transmission cell 16-bit data and the transmission cell start signal from the asynchronous transmission mode layer processor 32-1 via the transmission / reception cell bus, and the reception cell 16-bit data and the reception cell. The start signal is sent to the asynchronous transfer mode layer processor 32-1. Further, a cell reception request signal for requesting reception of a cell is sent to the asynchronous transmission mode layer processing apparatus, and a cell reception permission signal is received. Receives an address signal, an address valid signal, a data valid signal, a data read / write signal, and a main clock and a cell bus clock from the asynchronous transfer mode layer processor 32-1 to match both port RAMs through a control signal bus. , Send and receive data signals. It also sends a function alarm signal and hernia alarm signal to the asynchronous transfer mode layer processing apparatus.

3 is a block diagram of an asynchronous transmission mode cell multiplexing apparatus according to the present invention.

The asynchronous transmission mode cell multiplexing device according to the present invention is connected to the subscriber switch network module through an internal module connection (IMI) and local timing clock (LTSI) signals, and is locally local to the asynchronous transmission mode layer processor 32-1. It is connected via the module connection (LIMI) and module timing clock (MTSI) signals.

The overall operation of the asynchronous transmission mode cell multiplexing apparatus according to the present invention is as follows.

The cell input from the asynchronous transmission mode layer processor 32-1 is input to the lower link matching unit 44, and is transmitted and received via the lower link control unit 45 and the receiving cell FIFO unit (not shown). It is input to the cell multiplexer 46. When the transmitting / receiving cell multiplexer 46 multiplexes cells input from 16 asynchronous transmission mode layer processing apparatuses and sends them to the receiving cell processing unit 47, the receiving cell processing unit 47 separates the management cell, the user cell, and the internal control cell. To be stored in each FIFO and delivered. Here, the internal control cell is read and analyzed by the processor (central control unit 41), and the management cell and the user cell are transferred to the switch via the switch link matching unit 49.

The cell input from the switch is input to the transmission cell processing unit 48 via the switch link matching unit 49. The transmitting cell processing unit 48 multiplexes the management cell, the user cell, and the control cell stored in each packet, and inputs the same to the transmission / reception cell multiplexing unit 46. Then, the multiplexed cells are stored in each transmitting cell encapsulation unit and then transferred to the asynchronous transmission mode layer processing apparatus via the lower link control unit 45 and the lower link matching unit 44.

The operation of each functional unit of the asynchronous transmission mode cell multiplexing apparatus according to the present invention performing such an operation will be described in detail.

The central control unit 41 has a 32-bit processor that generates data signal lines, address signal lines, and control signal lines, supplies them to the local bus, and combines these signals to provide information on devices and registers belonging to each part of the cell multiplexer. It has a function to control the entire cell multiplexing device by specifying an address, a ROM for storing a program, a RAM for storing various data, and a nonvolatile memory for storing data to be stored even after power is removed. In addition, the central control unit 41 communicates with a higher processor by using a higher control cell, grasps a state of a subscriber line, reports it to a higher processor, registers and deletes various connections, sets parameters for connections, and sets routing information. Etc., and processes the management cell received from the subscriber. In addition, the central control unit 41 has a clock generator of 50 MHz, buffers and divides the clock generated by the clock generator to supply the local bus, and generates a reset signal at the time of power supply and manual reset by the reset switch. To the local bus. In addition, it provides a terminal connection function for debugging through serial input / output function, and Ethernet matching function for connecting to a network.

The clock signal matching unit 42 receives 46.94943 MHz, which is a local timing clock (LTSI), at an emitter coupled logic (ECL) level from the subscriber switch network module, converts it to 234.7474 MHz, and then converts the lower link control unit 45 to the lower link control unit 45. And the lower link matching section 44, and drive the local timing clock (LTSI) signal again, and supply one-to-one at the ECL level to each asynchronous transfer mode layer processing apparatus. The clock is divided into two and four clocks, and then passed through a clock driver, and then supplied to all devices in the cell multiplexer.

The status matching unit 43 is connected to the function alarm status signal FA [1:16] and the hernia alarm status signal OA [1:16] of each asynchronous transmission mode layer processor to be connected, so that the processor asynchronously transmits. Allows you to read the current state of the mode layer processor.

The lower link matching section 44 is matched with 16 asynchronous transmission mode layer processing apparatuses using a local internal module access (LIMI) link form. The block data is decoded by converting serial data received from a lower link (asynchronous transmission mode layer processing unit) into 64 bytes of parallel data using four 4-channel dedicated link chips. The lower link control unit 45 performs decoding. After performing block coding on the parallel data of 64 bytes received by the lower link control unit 45, the serial data is changed to serial data and transmitted to the lower link. The link dedicated chip provides a local loopback function and is controlled by the central controller 41.

The lower link control unit 45 transmits and receives cells in accordance with 16 links, and has 16 transmitting cells and receiving cell packets, and 16 ports operate independently. When the transmit / receive cell multiplexer 46 writes a 56-byte cell added with routing information to the transmit cell packet, it reads it, converts it into a 64-byte cell format, and transmits it to the lower link matching unit 44. When receiving a cell of 64 bytes from 44, it converts into a 54-byte internal cell format, writes it into a receiving cell packet, and transmits / receives the cell multiplexer 46 to read it. Cells transmitted to the lower link include a user cell received from the switch, an internal control cell received from the central control unit 41, and a management (OAM) cell sent from the central control unit 41. The lower link control unit 45 analyzes the value of routing information in the cell, transfers it to the lower link matching unit 44 as it is in the case of a user cell, and calculates a CRC-32 for the payload of the cell if it is an internal control cell. In the case of a management cell, CRC-10 is calculated and inserted.

Transmitting / receiving cell multiplexer 46 multiplexes each cell inputted from each link and accumulated in the receiving cell envelope of lower link controller 45 and demultiplexes the cell input from transmit cell processor 48 to each link. Perform the function of passing. The transmit / receive cell multiplexer 46 prioritizes the cell presence signals of the 16 receiver cell packets in the lower link controller 45 in a round robin manner, and generates a cell read signal for the receiver cell packets in which the cells exist. It reads in 54 byte unit and performs multiplexing function. The multiplexed cell is transmitted to the receiving cell processor 47. At this time, the link number byte is transmitted by converting to the link number the number of readings other than the 53-byte cell. At this time, the cell type of the first byte read from the PPO is read, and if it is an internal control cell, the link number is converted into 16 to 31 where the link does not actually exist to distinguish it from the user cell. In addition, the transmission / reception cell multiplexer 46 receives the 56-byte cell to be transmitted to the lower link control unit 45 from the transmission cell processing unit 48, analyzes the first byte, finds the link number to be sent, and transmits the transmission cell of the corresponding lower link control unit. Write on the cover.

The receiving cell processor 47 analyzes the virtual path identifier (VPI) and the virtual channel identifier (VCI) from the header of the cell to determine whether the cell is for virtual path connection or virtual channel connection, and the virtual path index and virtual connection. Use the identifier to search the connection management table and extract the connection identifier. Then, a 56-byte cell added with 3 bytes of header transformation and routing information is output, and the number of input cells, user parameters, violation or discarded cells, etc. are counted for each connection to the input cell. In addition, a management cell and an internal control cell are stored in separate packets for the processor to read and provide up to 4k connections.

The transmitting cell processor 48 multiplexes a user cell buffer, a management cell, and an internal control cell buffer, analyzes the virtual path identifier and the virtual channel identifier from the header of the multiplexed cell, and determines whether the cell is for virtual path connection or virtual channel connection. Check the connection management table using the virtual path index and the virtual connection identifier, and extract the connection identifier. When there is a management cell transmission request, it reads the connection identifier from the management cell buffer and calculates CRC-10 to output the management cell transmission request and the connection identifier.If the transmitted cell is a user cell, the cell is counted and performance monitoring is performed. Perform. In addition, the transmit cell processor 48 has a register for storing the state of the management cell transmit and receive packets, and provides a maximum of 4k connections.

The switch link matching unit 49 writes the 56-byte user cell to which the routing information is added is written in the user cell reception packet in the reception cell processing unit 47 or the upper control cell directed to the switch is written in the upper transmission control cell packet. After reading and multiplexing the data, the data is converted into a 64-byte cell format and transmitted to the subscriber switch network module. When the 64-byte cell is received from the subscriber switch network module, the cell is converted into an internal cell format of 54 bytes. Write to the user cell transmission packet in the), and if the upper control cell inputted from the switch, write to the upper reception control cell packet.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the technical spirit of the present invention. It will be apparent to those of ordinary knowledge.

The present invention configured as described above is capable of accessing 1024 digital subscriber line subscribers per asynchronous transmission mode cell multiplexer of the digital subscriber line subscriber multiplexing matching module under the control of the maintenance control module in the asynchronous transmission mode switching system. The digital subscriber line subscriber can provide high speed asynchronous transmission mode data service.

Claims (6)

In the asynchronous transmission mode cell multiplexer connected to the asynchronous transmission mode layer processing unit of the subscriber switch network module and the digital subscriber line subscriber multiplexing matching module in the asynchronous transmission mode switching system, Central control means connected to a local bus to provide a control signal to the local bus and communicate with an upper processor using a control cell; Clock signal matching means for receiving a local timing clock from the subscriber switch network module, providing a clock signal in a device through the local bus, and providing a module timing clock to the asynchronous transmission mode layer processing apparatus; State matching means for storing state information of the asynchronous transmission mode layer processing apparatus and transferring the state information through the local bus; Lower link matching means connected to the asynchronous transfer mode layer processor through a local internal module connection to perform matching, decoding and coding of the received data; A sublink control having a plurality of transmitting cells and a receiving cell packet (FIFO), converting a received cell and storing the received cell in the receiving cell pico, or converting a cell stored in the transmitting cell pico and transmitting the converted cell to the lower link matching means. Way; Transmitting / receiving cell multiplexing means for reading and multiplexing cells stored in each of the receiving cell packets, demultiplexing cells input from the transmitting cell processing means, and storing the multiplexed cells in the respective transmitting cell packets of a corresponding link; Reception cell processing means for processing a cell multiplexed by the transmission / reception cell multiplexing means; Transmission cell processing means for processing a cell to be transmitted and providing it to the transmission / reception cell multiplexing means; And Switch link matching means connected to the subscriber switch network module through an internal module connection Asynchronous transmission mode cell multiplexing apparatus comprising a. The method of claim 1, The clock signal matching means, It receives 46.94943MHz clock, which is a local timing clock, from the subscriber switch network module at an emitter combined logic (ECL) level, converts the signal to 234.7474MHz, and supplies it to the sublink control means and the sublink matching means, and drives the local timing clock. And providing an emitter combined logic level to each of the asynchronous transfer mode layer processing units. The method of claim 1, The lower link matching means, It is matched with a plurality of asynchronous transfer mode layer processing apparatus through local internal module connection (LIMI), and converts serial data received from the asynchronous transfer mode layer processing apparatus into parallel data using four 4-channel link dedicated chips. Decoding block coding is performed to transfer the data to the sublink control means, and after performing block coding on the parallel data received from the sublink control means, converting the serial data into serial data and transmitting the serial data to the asynchronous transmission mode layer processing apparatus. And a local loopback function. The method of claim 1, The lower link control means, 16 transmitting cells and receiving cell capturing, wherein the transmitting and receiving cell multiplexing means reads the cell stored in the transmitting cell, converts it into a cell format of 64 bytes, and transmits it to the lower link matching means, and the lower link matching means. Converting the 64-byte cell received from the cell into a 54-byte internal cell format, storing it in the received cell packet, and calculating and inserting a CRC-32 or CRC-10 for the payload of the cell according to the cell format. An asynchronous transmission mode cell multiplexing device. The method of claim 1, The receiving cell processing means, Analyzing the virtual path identifier and the virtual channel identifier from the header of the cell transmitted from the transmitting / receiving cell multiplexing means, searching the connection management table using the analyzed information, extracting the corresponding connection identifier, and converting and routing the header. Providing a cell to which information is added to the switch link matching means, and counting the number of input cells, user parameters, violations or discarded cells for each connection to an input cell; Device. The method of claim 1, The transmission cell processing means, A user cell buffer, a management cell, and an internal control cell buffer are multiplexed, the virtual path identifier and the virtual channel identifier are analyzed from the header of the multiplexed cell, the connection management table is searched, and a connection identifier is obtained using the retrieved information. And extracting, calculating and transmitting a CRC-10 for a management cell, counting the number of user cells, and performing performance monitoring.