KR100371139B1 - Crosspoint Element for ATM Switching Apparatus - Google Patents

Abstract

The present invention provides a system for performing functions such as an Asynchronous Transfer Mode (ATM) -LAN switching system in a private network, an ATM local exchange in an public network, an ATM access node, and an ATM cross connector. The present invention relates to a crosspoint element structure for an ATM switch that is not only used for configuration but also applicable to a system requiring an ATM switching function. The present invention relates to a cell copy function and a cell copy function to provide a multicasting function. By simultaneously processing the routing function in one network, it reduces the type of network required to configure the switching device, as well as the complex and large table configuration required for the control between the copy network and the routing network like the existing switching device. Has the property of excluding.

Description

Crosspoint Element Structure for ATM Switch {Crosspoint Element for ATM Switching Apparatus}

The present invention provides a system for performing functions such as an Asynchronous Transfer Mode (ATM) -LAN switching system in a private network, an ATM local exchange in an public network, an ATM access node, and an ATM cross connector. The present invention relates to a crosspoint element structure for an ATM switch that is not only used for configuration but also applicable to a system requiring an ATM switching function.

In general, since a service in a B-ISDN network environment coexists with data having real-time service and non-real-time service attributes, an ATM switching function of a fixed length packet is essential to provide this.

Basically, the switching function provides a switching path from n inputs to m outputs so that data can be transferred between arbitrary input / output ports without any loss of data.

The simplest structure for this is the cross point structure. When expanding switching capacity, shared memory and shared bus structures require new implementations or separate control devices, while crosspoint structures have the advantage of being without special functionality.

1A shows a general switch structure, in particular, extracts an ATM cell from a transmitted physical medium, classifies the cell using an identifier for the connection information, and provides an interface for switching in the switch fabric. It consists of a switch fabric (SF) that provides exchange services by providing a physical delivery path to a line interface card (LIC) and an output LIC that is desired to be delivered between them.

In addition, a call processor (CP) for call control and connection management for channels connected to the LIC, OAM (Operation and Administration) and SMP (System Management) for managing ATM network maintenance and switching system maintenance, etc. Processor).

In order to overcome the limitations of the general switching structure described above, many studies on the ATM switch structure have been conducted and some of the proposed switch structures have been commercialized and sold.

However, most of them have been implemented in a shared memory scheme, a shared media scheme using a high-speed bus, and a fully coupled architecture having a crosspoint switch scheme.

In particular, it is necessary to provide a separate function or identifier for a function of replicating a cell in a multicasting service, and it is difficult to control congestion occurring in any switching path generated when a large switch is implemented. In addition, the problem of the waste of resources such that the duplicated at the input or duplicated m time slots to be duplicated at the output for any m cell duplication is proposed as a problem.

In order to solve such a problem, the proposed technique is a cross point switch method using the configuration of the cross point switch element shown in FIG. 1B.

In the conventional structure using the above-described cross-point switch method, it is configured as shown in FIG. 2, but 'Vitesse' and 'TriQuent' introduce high-speed cross-point switches, but switch in individual ATM cell units. For this purpose, there is a separate control block on the outside to receive all routing output addresses from all input ports and operate only when the switching element is controlled on / off. Therefore, there is an obstacle in speeding up.

In addition, even in the implementation, the on / off control element having an internal tri-state is not used, and the MUX is used to design the multi-stage multiplexing portion.

As a result, there is an advantage of eliminating the delay reduction and the fanout problem of the chip, but the number of passes increases too much in the actual layout, so that the area for the metal channel is occupied more than the gate area.

An object of the present invention for solving the above problems is to configure a cross-point network switch for an ATM switch for a switch implementation having a self-routing function instead of the switching function by the existing external routing control unit To provide a crosspoint element structure.

In addition, the present invention avoids wasting a separate time slot when duplicating cells without requiring a separate function for cell duplication, that is, even if the corresponding output port is congested, without storing m cells therein. It is to provide a crosspoint element structure for an ATM switch to maintain a cell.

Figure 1a is an illustration of a general switch structure,

1B is a conceptual diagram illustrating a cross point switch structure

2 is a cross point switch structure

3 is a crosspoint element configuration for an ATM switch

4 is a timing diagram of a cross point element.

A feature of the present invention for achieving the above object is an output port address input terminal, input cell address input terminal, synchronous pulse input terminal which are input ports in a 2x2 switch element structure for constituting an ATM switch having an M × M switch element structure. And a routing status input stage, a data input stage, an output transfer input stage, and an output group output stage address output stage, a routing status output stage, a synchronous pulse output stage, a data output stage, a bypass output stage, and an address conversion output stage. And a logical multiplication means, a flip-flop, an address corrector, a tri-state buffer, and a logical sum means. The address comparator may include address information of a predetermined output port inputted to the output group address input terminal and an input cell address input terminal. The output port address information requesting the routing included in the header of the input cell is compared to determine whether there is a match. The multiplication means outputs the connection state information by ANDing the inverse value of the routing state information of the immediately above switch element in the same column input to the routing state input terminal and the output of the address comparator. Synchronize the connection state information of the means to the synchronization signal pulse inputted to the synchronization pulse input terminal, and the address corrector receives the input cell address input terminal and the output group address input terminal, and receives the connection state information of the logical multiplication means. If it is a condition, the output port address information input to the input cell address input terminal is corrected and output to the address translation output terminal. Bypass to the bypass output stage or output to the data output stage, the logic sum means And the logical sum output of the comparison path setting status information and the address of the switch elements in the column immediately above the same input to the path setting input terminal, and outputs to the routing state output stage.

The present invention reduces the type of network required to configure a switching device by accommodating a copy function of a cell to provide a multicasting function and simultaneously processing a copy function and a routing function of a cell in a single network. Eliminating the construction of complex and bulky controls required between the radiant network and the routing network, such as switching devices;

The line interface card of the switch recognizes the cell and performs a series of procedures such as usage parameter control (UPC) to interpret the connection identifier for the promised traffic and add the desired output port bit address to the routing tag in the cell header. The output of the routing state output stage is input to the routing state input stage of the next switch element structure. If the value is '0', it indicates that the routing of the previous switch element structure is not performed. Indicates that the switch element structure or the current switch element structure has already been routed. The address comparator 1 outputs a value of '1' if the two address information inputs match, and '0' if it does not match. Outputs a value, and the tri-state buffer 5 performs data path setting when the input value is '1' and inputs the data to the data input terminal. The output to the data output terminal, and if '0', rather than the route setting data input to the data input terminal thereby by-pass the by-pass output.

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

In an embodiment of the present invention, a routing crossbar switching block (RCSU) is composed of 16 × 16 switching elements (RCEUs) as shown in FIG. 1B of the accompanying drawings.

It contains 256 Routing Crossbar Switch Blocks (RCEUs) consisting of approximately 74 gates, and includes a tri-state buffer (TRI BUF) to enable expansion of series connections, so it consists of 19,367.4 gates.

3 is a crosspoint element structure for an ATM switch according to the present invention, which shows a configuration for a 2 × 2 switch element and expands it to form a square crosspoint element structure of 16 × 16 or 32 × 32 type. .

First, input / output ports (AGN, RGN, SIN, DI, QI, GIN, AI, SOUT, MGN, DO, and GO) shown in FIG. 3 are classified as follows. One) Pin name I / O classification Explanation AGN (15: 0) input Assigned output Group address Number (16bits) RGN (15: 0) input Request output Group address Number (16bits) SIN input Status Input from upper switch element DI (7: 0) input Data Input from Input ports or left element QI (7: 0) input Data Input from lower element GIN input Latch enable for latch-up of matching status AI (15: 0) Print Bypass of Assigned output Group address Number SOUT Print Status output QO (7: 0) Print Data output to output ports MGN (15: 0) Print Modified Group address number (16bits) DO (7: 0) Print Bypass Data Input from Input ports or left element GO Print Bypass Latch enable for latch-up of matching status Referring to the configuration of FIG. 3, a portion denoted by reference number AGN (15: 0) is an input terminal of an output group address, and indicates output port grouping address information input from an external output address allocator. Depending on the required operating speed, it can be composed of multiple bit groups for parallel processing.

In addition, the reference number AI (15: 0) indicates the output terminal of the output group address, the information is passed to the next switch element through the switch element, the content is the same as the input terminal AGN (15: 0) of the output group address, the internal When configured as a hardmark, it is connected by a direct bus.

In addition, reference numeral Sin (Status in) indicates the routing state of the immediately above switch element in the same row as the routing state input signal. When the logic state of the signal is 1, the path is already set in the upper switch element.

A signal corresponding to the path setting state input signal Sin is sent as a switch setting element in the same column as the bottom row based on the path setting state input signal Sin and its own path setting state as a path setting state output signal (Sout: Status out) signal. If the logical state of the signal is 0, it means that there is no path setting in the upper switch element.

In addition, the input cell address indicated by the reference number RGN (15: 0) is a flag indicating the routing tag state of the desired output port of the input cell. The first row of switch elements are transferred from the ATM cell to the block managing the output routing tag. It receives an input and then the switch elements receive input directly from the left switch element. Each switch element examines this address and attempts to set the path if the corresponding output port is 1 and if it is 0, it does nothing and transfers the value to its right switch element. If routing is done, the switch element converts this bit address value to zero so that there is no longer routing on the switch element in the same row.

In addition, the reference number MGN (15: 0) is a signal that transmits the path setting state of the switch element to the right switch element as a modified address output, and changes the output address value according to its path setting state and transmits it to the right side. If routing is done, the switch element converts this bit address value to zero so that there is no longer routing on the switch element in the same row.

In addition, the reference number GIN is a signal that transmits timing information to indicate the last state after the routing operation of all switch elements in the 16 × 16 switching block is completed. Referring to FIG. 4 attached to a preferred example of a crosspoint element structure for an ATM switch according to the present invention configured as described above, input connection information RGN (15: 0) and an already assigned address. If the information AGN (15: 0) is compared and matched using the address comparator 1, if the upper status information input through SIN is received and the upper status information is '0', it is not the upper status of the upper element. By using logical multiplication device (2) and flip-flop (3), (SIN = 0) and STATUS (address corrector (4)) = 1 are maintained, and the three-state buffer (5) is connected to GIN Pulsed mouth Simultaneously with the output, the input data DI (7: 0) is connected to the output QO (7: 0).

Then, using the address corrector 4, the matching bit address among the bits inputted from the RGN (15: 0) is modified to 0, and then output to the MGN (15: 0), and the matching result SOUT = 1 is output. If the bit address of RGN (15: 0) and AGN (15: 0) is identical, but the upper status information SIN = 1, the result is already matched at the upper level, so STATUS = 0 is maintained and SOUT through the logic element 5 Export as = 1 and output as MGN (15: 0) = RGN (15: 0).

On the other hand, the truth table of the input and output signals of Table 1 is shown in Table 2 below, xxxx means dont care bit. And yyyy can have 0 or 1 but it means that it is transmitted transparently without modification. AGN (15: 0) must be 1 bit among 16 bits.

AGN (15: 0) RGN (15: 0) SIN DI (7: 0) QI (7: 0) GIN AI (15: 0) SOUT QO (7: 0) MGN (15: 0) DO (7: 0) GO xxxx ... x 0000 ... 0 0 D (n + 1) Q (n + 1) 0 AGN (15: 0) 0 Q (n) RGN (15: 0) D (n + 1) 0 xxxx ... x 0000 ... 0 0 D (n + 1) Q (n + 1) One AGN (15: 0) 0 Q (n + 1) RGN (15: 0) D (n + 1) One xxxx ... x 0000 ... 0 One D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) RGN (15: 0) D (n + 1) 0 xxxx ... x 0000 ... 0 One D (n + 1) Q (n + 1) One AGN (15: 0) One Q (n + 1) RGN (15: 0) D (n + 1) One 0000 ... 0 xxxx ... x 0 D (n + 1) Q (n + 1) 0 AGN (15: 0) 0 Q (n) RGN (15: 0) D (n + 1) 0 0000 ... 0 xxxx ... x 0 D (n + 1) Q (n + 1) One AGN (15: 0) 0 Q (n + 1) RGN (15: 0) D (n + 1) One 0000 ... 0 xxxx ... x One D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) RGN (15: 0) D (n + 1) 0 0000 ... 0 xxxx ... x One D (n + 1) Q (n + 1) One AGN (15: 0) One Q (n + 1) RGN (15: 0) D (n + 1) One 1000 ... 0 0xxx ... x 0 D (n + 1) Q (n + 1) 0 AGN (15: 0) 0 Q (n) RGN (15: 0) D (n + 1) 0 1000 ... 0 0xxx ... x 0 D (n + 1) Q (n + 1) One AGN (15: 0) 0 Q (n + 1) RGN (15: 0) D (n + 1) One 1000 ... 0 0xxx ... x One D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) RGN (15: 0) D (n + 1) 0 1000 ... 0 0xxx ... x One D (n + 1) Q (n + 1) One AGN (15: 0) One Q (n + 1) RGN (15: 0) D (n + 1) One 1000 ... 0 1yyy ... y 0 D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) 0yyy ... y D (n + 1) 0 1000 ... 0 1yyy ... y 0 D (n + 1) Q (n + 1) One AGN (15: 0) One D (n + 1) 0yyy ... y D (n + 1) One 1000 ... 0 1xxx ... x One D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) RGN (15: 0) D (n + 1) 0 1000 ... 0 1xxx ... x One D (n + 1) Q (n + 1) One AGN (15: 0) One Q (n + 1) RGN (15: 0) D (n + 1) One 0100 ... 0 x0xx ... x 0 D (n + 1) Q (n + 1) 0 AGN (15: 0) 0 Q (n) RGN (15: 0) D (n + 1) 0 0100 ... 0 x0xx ... x 0 D (n + 1) Q (n + 1) One AGN (15: 0) 0 Q (n + 1) RGN (15: 0) D (n + 1) One 0100 ... 0 x0xx ... x One D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) RGN (15: 0) D (n + 1) 0 0100 ... 0 x0xx ... x One D (n + 1) Q (n + 1) One AGN (15: 0) One Q (n + 1) RGN (15: 0) D (n + 1) One 0100 ... 0 y1yy ... y 0 D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) y0yy ... y D (n + 1) 0 0100 ... 0 y1yy ... y 0 D (n + 1) Q (n + 1) One AGN (15: 0) One D (n + 1) y0yy ... y D (n + 1) One 0100 ... 0 x1xx ... x One D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) RGN (15: 0) D (n + 1) 0 0100 ... 0 x1xx ... x One D (n + 1) Q (n + 1) One AGN (15: 0) One Q (n + 1) RGN (15: 0) D (n + 1) One

AGN (15: 0) RGN (15: 0) SIN DI (7: 0) QI (7: 0) GIN AI (15: 0) SOUT QO (7: 0) MGN (15: 0) DO (7: 0) GO 0010 ... 0 xx0x ... x 0 D (n + 1) Q (n + 1) 0 AGN (15: 0) 0 Q (n) RGN (15: 0) D (n + 1) 0 0010 ... 0 xx0x ... x 0 D (n + 1) Q (n + 1) One AGN (15: 0) 0 Q (n + 1) RGN (15: 0) D (n + 1) One 0010 ... 0 xx0x ... x One D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) RGN (15: 0) D (n + 1) 0 0010 ... 0 xx0x ... x One D (n + 1) Q (n + 1) One AGN (15: 0) One Q (n + 1) RGN (15: 0) D (n + 1) One 0010 ... 0 yy1y ... y 0 D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) yy0y ... y D (n + 1) 0 0010 ... 0 yy1y ... y 0 D (n + 1) Q (n + 1) One AGN (15: 0) One D (n + 1) yy0y ... y D (n + 1) One 0010 ... 0 xx1x ... x One D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) RGN (15: 0) D (n + 1) 0 0010 ... 0 xx1x ... x One D (n + 1) Q (n + 1) One AGN (15: 0) One Q (n + 1) RGN (15: 0) D (n + 1) One 0001 ... 0 xxx0 ... x 0 D (n + 1) Q (n + 1) 0 AGN (15: 0) 0 Q (n) RGN (15: 0) D (n + 1) 0 0001 ... 0 xxx0 ... x 0 D (n + 1) Q (n + 1) One AGN (15: 0) 0 Q (n + 1) RGN (15: 0) D (n + 1) One 0001 ... 0 xxx0 ... x One D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) RGN (15: 0) D (n + 1) 0 0001 ... 0 xxx0 ... x One D (n + 1) Q (n + 1) One AGN (15: 0) One Q (n + 1) RGN (15: 0) D (n + 1) One 0001 ... 0 yyy1 ... y 0 D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) yyy0 ... y D (n + 1) 0 0001 ... 0 yyy1 ... y 0 D (n + 1) Q (n + 1) One AGN (15: 0) One D (n + 1) yyy0 ... y D (n + 1) One 0001 ... 0 xxx1 ... x One D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) RGN (15: 0) D (n + 1) 0 0001 ... 0 xxx1 ... x One D (n + 1) Q (n + 1) One AGN (15: 0) One Q (n + 1) RGN (15: 0) D (n + 1) One Omit from bit11 to bit1 because it is repeated as above. 0000 ... 1 xxxx ... 0 0 D (n + 1) Q (n + 1) 0 AGN (15: 0) 0 Q (n) RGN (15: 0) D (n + 1) 0 0000 ... 1 xxxx ... 0 0 D (n + 1) Q (n + 1) One AGN (15: 0) 0 Q (n + 1) RGN (15: 0) D (n + 1) One 0000 ... 1 xxxx ... 0 One D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) RGN (15: 0) D (n + 1) 0 0000 ... 1 xxxx ... 0 One D (n + 1) Q (n + 1) One AGN (15: 0) One Q (n + 1) RGN (15: 0) D (n + 1) One 0000 ... 1 yyyy ... 1 0 D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) yyyy ... 0 D (n + 1) 0 0000 ... 1 yyyy ... 1 0 D (n + 1) Q (n + 1) One AGN (15: 0) One D (n + 1) yyyy ... 0 D (n + 1) One 0000 ... 1 xxxx ... 1 One D (n + 1) Q (n + 1) 0 AGN (15: 0) One Q (n) RGN (15: 0) D (n + 1) 0 0000 ... 1 xxxx ... 1 One D (n + 1) Q (n + 1) One AGN (15: 0) One Q (n + 1) RGN (15: 0) D (n + 1) One

RCEU consists of one latch (LD1Q) and most combinational logic circuits as shown in the structure of RCSU above. There are two bypassed 8-bit buses horizontally and vertically, and 16-bit buses are connected vertically. . Therefore, by designing the RCEU including these bypassed buses and arranging them adjacently regularly, Routing Crosspoint Switching Unit (RCSU) can be easily implemented.

As described above, when providing a crosspoint element structure for an ATM switch according to the present invention, switching by accepting the copy function of the cell to provide a multi-casting function and simultaneously processing the copy function and the routing function of the cell in one network In addition to reducing the type of network required to compose the device, the control required between the copy network and the routing network, like the existing switching device, has a characteristic of excluding a complex and large table configuration.

Claims (3)

In the 2x2 switch element structure for constituting the ATM switch of the MxM switch element structure, It is provided with output group address input terminal (AGN), input cell address input terminal (RGN), synchronous pulse input terminal (GIN), routing status input terminal (SIN), data input terminal (DI), and output transmission input terminal (QI). Output group includes output group address output stage (AI), routing status output stage (SOUT), synchronous pulse output stage (GO), data output stage (QO), bypass output stage (DO), address translation output stage (MGN), The address information of the preset output port inputted to the output group address input terminal AGN and the output port address information requiring routing included in the header of the cell inputted to the input cell address input terminal RGN are compared to determine whether they match. An address comparator 1; Logical multiplication means (2) for outputting the connection state information by ANDing the inverse value of the routing state information of the immediately above switch element in the same column input to the routing state input terminal (SIN) and the output of the address comparator 1 ; A flip-flop (3) for synchronizing the connection state information of the logical multiplication means with the synchronization signal pulse input to the synchronization pulse input terminal (GIN); The input cell address input terminal RGN and the output group address input terminal AGN are input, and the connection state information of the logical multiplication means 2 is received, and if it is a coupling condition, the input cell address input terminal RGN is inputted. An address corrector (4) for modifying output port address information and outputting the modified address to the address translation output terminal (MGN); A three-state buffer for bypassing data input through the data input terminal DI to the bypass output terminal DO or outputting the data output terminal QO according to the connection state information output from the flip-flop 3 ( 5); And Logic sum means (6) for ORing the routing state information of the immediately above switch element in the same column input to the routing state input terminal (SIN) and the output of the address comparator 1 to output to the routing state output terminal (SOUT). Crosspoint element structure for an ATM switch, comprising: a. delete The method of claim 1, The output of the routing state output terminal SOUT is input to the routing state input terminal of the next switch element structure. If the value is '0', it indicates that the routing of the previous switch element structure is not performed, and the value is '1'. 'Indicates that the previous switch element structure or the current switch element structure has already been routed, The address comparator 1 outputs a value of '1' if the two input address information matches, and outputs a value of '0' if it does not match. When the input value is '1', the tri-state buffer 5 outputs the data input to the data input terminal DI when the input value is '1', and outputs the data without setting the path when the input value is '0'. A crosspoint element structure for an ATM switch, characterized by bypassing data input to an input terminal DI to a bypass output terminal DO.