KR100230973B1 - Atm switching system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a split copy type copy network in an asynchronous transfer mode (ATM) switching system, and more particularly, to a branch copy network in an ATM switching system for facilitating switch expansion.

An object of the present invention is to provide a copy network that allows a copy larger than N to be performed in the unit switch when the unit copy network is N × N, and ensures the order of the output cells as well as allows the output memory table to be vertically partitioned. To reduce memory complexity and hardware complexity.

Accordingly, more than N copies can be made in the N × N copy network, the order of the output cells can be guaranteed, and memory reliability and hardware complexity are reduced, thereby maximizing reliability.

Description

Branch copy network in ATM switching system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a split copy type copy network in an asynchronous transfer mode (ATM) switching system, and more particularly, to a branch copy network in an ATM switching system for facilitating switch expansion.

In the ATM switching system, a general branch copy type copy network is configured as shown in FIG. 1.

The A / U concentrator 1 is a cell concentrator that focuses an input cell separately into an active cell and an idle cell. Therefore, the order of the output cells is a recycling active cell from a higher order, a newly input active cell, and an idle cell.

The trap summation unit 2 passes through these cells to a cell in which the sum of the number of copy branches does not exceed N, and the remaining cells fail mark.

The P / R concentrator 3 inputs cells from the trap summ to align on the basis of pass marking and fail marking. The sorting order of the cells at the output terminal is the pass-active cell and the idle cell from the upper side and the fail-active cell and the idle cell from the lower side.

Therefore, since the total number of branches of the outputs of the P / R concentrator 3 does not exceed N, non-blocking does not occur in the N × N copy network 4. Then, the lower M output cells are recycled to the A / U concentrator 1 and concentrated again.

At this time, the N × N copy network 4 is a Banyan copy network and is a non-block switch in which N × N switches are connected in multiple stages.

As described above, the cell passing through the N × N copy network 4 passes through a trunk number translation table (TNT) which converts the output address into an output address, and then passes through the routing network to reach a desired destination address.

However, the branched copy network as described above is not guaranteed to handle a fanout greater than N when the copy network is extended.

In other words, copying larger than N cannot be performed. Therefore, separate hardware is required to expand a copy network.

Therefore, in order to solve the problems described above, the present invention enables a copy larger than N to be performed in a unit switch when the unit copy network is N × N, and ensures the order of output cells as well as vertically partitions the output memory table. It aims to save memory and reduce hardware complexity by providing a copy network that can be used.

In the ATM switching system of the present invention for achieving the above object, the branched copy network A / B outputs the active cells and the idle cells by focusing them separately, and outputs the recycled active cells, the newly inputted active cells, and the idle cells from the top. U concentrator; A trap sum unit for pass-marking the output cells of the A / U concentrator from the upper side to a cell which does not exceed N, and fails-marks the remaining cells; A P / R concentrator for inputting cells from the trap sum unit and sorting based on a pass marking and a fail marking and sending a cell to the A / U concentrator through a recirculation path for cells having a copy number exceeding N; An N × N copy network for outputting a cell to be branch-copyed to the lowest port when branch copying occurs while switching to a cell in which the copy branch number does not exceed N in the P / R concentrator; The total number of cells to be copied in the trap island portion is equal to or less than the total number of copies of the cells delivered to the N × N copy network and the value of the sum of the cells of the lowest port of the N × N copy network is greater than N. In this case, after converting the header of the master cell, the branch field is increased, and passed to the A / U concentrator, otherwise it is characterized by including a splitter to pass the idle path to the recycle path.

1 is a configuration diagram of a branch copy network in a typical ATM switching system;

2 is a block diagram of a branch copy network in the ATM switching system of the present invention.

<Explanation of symbols for main parts of drawing>

10: A / U Integrator 20: Trap Island Part

30: P / R concentrator 40: N × N copy network

50: Splitter

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

2 is a schematic diagram of a branch copy network in the ATM switching system of the present invention, the configuration of which is an A / U concentrator 10, a trap summ unit 20, a P / R concentrator 30, and N × N. The radiation network 40 and the splitter 50 are included.

The A / U concentrator 10 separates and concentrates an input cell into an active cell and an idle cell, respectively, and outputs a recycling active cell from an upper side, a newly input active cell, and an idle cell.

The trap sum unit 20 passes-marks the output cells of the A / U concentrator 10 from the upper side to a cell which does not exceed N and the remaining cells fail-mark. Alternatively, the recirculation condition is shown in Equation 1.

The P / R concentrator 30 inputs the cells from the trap sum unit 20 and sorts them based on the pass marking and the fail marking, so that the A / U is recycled to the cells having a copy number exceeding N through the recycling path. To the focusing machine (10).

The N × N copy network 40 outputs a cell to be branch-copyed to the lowest port when branch copying occurs while switching to a cell in which the copy branch number does not exceed N in the P / R concentrator 30. do.

The splitter 50 has a total number of cells to be copied in the trap island unit 20 equal to or less than the total number of copies of cells transferred to the N × N copy network 40, and the N × N copy network 40 corresponds to the value. If the number of copies of the cells of the lowest port of is greater than N, the header of the master cell is converted and the branch field is increased, and then passed to the A / U concentrator 10. Otherwise, the idle processing is performed to the recycle path. Pass it over.

Operation of the present invention having the configuration as described above is as follows.

The input cells are separately focused and concentrated in the A / U concentrator 10 into an active cell and an idle cell, and are output from a higher order to a recycle active cell, a newly input active cell, and an idle cell.

Such output cells are pass-marked or fail-marked by the radiation condition of Equation 1 in the trap sum unit 20.

In the cell marked as described above, i cells are transferred to the N × N copy network 40 at the output of the P / R concentrator 30 by the copying condition of Equation 1 above. Is always 63 or less and the copy number of the i-th cell can have any value.

At this time, when branch copying occurs, there is always a cell to be branch copyed in the lowest port of the N × N copy network 40.

On the other hand, in the N × N copy network 40, the cell to be branched to the copy is passed to the splitter 50, where the total number of copies of the cell to be copied in the trap island portion 20 is 63 or less, and its value If the number of copies is greater than N, the header of the master cell In this case, the branch field is increased, and then passed to the A / U concentrator 10, otherwise it is treated as an idle and passed to the recycle path.

In this case, the branch field may be used as a table memory index when extending the copy network.

As described above, in case of performing L (> N) copying in the unit switch fabric N × N, the number of copies that are less than or equal to N in the first time slot is copied and the cell recycled to the A / U concentrator 10 Because of the highest priority, the output cells are logically compact in consecutive time slots.

As described above, according to the present invention, more than N copies can be made in an N × N copy network, the order of output cells is guaranteed, memory savings, and hardware complexity are reduced, thereby maximizing reliability.

Claims (1)

In a branch copy network in an ATM switching system, An A / U concentrator for separating and focusing the input cell into an active cell and an idle cell, respectively, and outputting the recycled active cell from an upper side, a newly input active cell, and an idle cell; A trap sum unit for pass-marking the output cells of the A / U concentrator from the upper side to a cell which does not exceed N, and fails-marks the remaining cells; A P / R concentrator for inputting cells from the trap sum unit and sorting based on a pass marking and a fail marking and sending a cell to the A / U concentrator through a recirculation path for cells having a copy number exceeding N; An N × N copy network for outputting a cell to be branch-copyed to the lowest port when branch copying occurs while switching to a cell in which the copy branch number does not exceed N in the P / R concentrator; The total number of cells to be copied in the trap island portion is equal to or less than the total number of copies of the cells delivered to the N × N copy network and the value of the sum of the cells of the lowest port of the N × N copy network is greater than N. And a splitter for converting a header of a master cell, incrementing a branch field, and passing it to the A / U concentrator, otherwise splitting the idle cell and passing it to a recycling path.