KR100480293B1 - Cell transfer controlling method and device in atm - Google Patents

Abstract

The present invention relates to an asynchronous transfer mode, and more particularly, to an apparatus and a method for preventing the loss of an ATM cell that may be caused by a mismatch of Start of Cell (SOC) between an ATM switch element and a routing table element. will be.

The apparatus for controlling a queue according to the present invention includes a proportional bandwidth queue, a reverse flow signal control element, and a reverse flow signal acquisition element. A reverse flow signal is transmitted from an ATM switch element to an input of the reverse flow signal acquisition element. An output of the backflow signal acquisition device is connected to an input of the backflow signal control device. The backflow signal control element is a logic gate, and if the backflow signal for any one priority queue is '1', it does not transmit cells in all non-wideband queues. And the output of the backflow signal control element is connected to the input of each of the non-wideband queues. The non-wide queue stores the cell for multiplexing for circuit sharing in cell transmission. And the output of the non wide bandwidth queue is connected to the input of the FIFO buffer.

The present invention configured as described above has an advantage of enabling stable information transmission by preventing cell loss due to SOC mismatch in an ATM system.

Description

Method and apparatus for controlling cell transmission in asynchronous transmission mode {CELL TRANSFER CONTROLLING METHOD AND DEVICE IN ATM}

The present invention relates to an asynchronous transfer mode (hereinafter, referred to as 'ATM'), and particularly to the loss of an ATM cell that may be caused by a mismatch of a start of cell (SOC) between an ATM switch element and a routing table element. An apparatus and a method for preventing the present invention.

In general, ATM is a dedicated connection switching technology that divides digital data into 53 bytes of cells or packets and transmits them through a medium using digital signal technology. One cell is individually processed asynchronously with respect to the other cells and placed in a queue for multiplexing for circuit sharing.

Because ATM is designed to be easier to implement in hardware than software, it is possible to speed up processing. Such ATM is a core technology of the broadband integrated telecommunication network (BISDN).

1 is a connection diagram illustrating a conventional ATM routing table element and an ATM switch element.

Referring to FIG. 1, an ATM cell (Data) is input to an input port of an ATM switch element 130. The ATM switch element 130 then determines the output port of the ATM switch element 130 with reference to the routing table provided by the operator.

The routing table elements 110, 111, 112,..., 113 in the board 10 including the routing table are located in front of the input port of the ATM switch element 130 and attach a routing tag.

In the general ATM system as described above, the ATM switch element 130 and the routing table elements 110, 111, 112,..., 113 are configured on separate boards 10 and 20, respectively. Each of the boards 10 and 20 uses the same operation clock, but each board receives a clock from different clock sources 100 and 140 to generate the operation clock. At this time, the operation clock cycles generated by the clock sources 10 and 20 of the two boards are the same. However, since time deviation occurs according to the physical characteristics of each board 10 and 20, the period of the start of cell (SOC) is different. For example, clock source 140 in board 20 including an ATM switch element generates a clock of S Hz. However, due to the physical characteristics of the board 20 including the ATM switch element, a time deviation (Multiply with M) occurs in the clock. Therefore, the time difference is reflected in the ATM switch element 130, and a clock of C Hz is input. Similarly, the clock of S 'Hz generated from the clock source 100 inside the board 10 including the routing table is reflected in the timetable (Multiply with M') so that the routing table elements 110, 111, 112, ... 113, a clock of C 'Hz is input.

Therefore, the first input first output (FIFO) buffers 120, 121, 122,. Are provided between the ATM switch element 130 and the routing table elements 110, 111, 112,. .., 123).

The data transmission procedure in the ATM system is as follows.

The ATM switch element 130 and the routing table elements 110, 111, 112,..., 113 respectively give priority to ATM cells to transmit cells of high priority first.

First, when an ATM cell is input to an input port of the ATM switch element 130, the ATM switch element 130 determines an output port of the ATM switch element 130 with reference to a routing table provided by an operator. At this time, when one ATM cell is using an output port to be routed to another input port, the ATM cell is stored in a shared buffer (not shown) in the ATM switch element 130. At this time, the shared buffer is allocated a space for storing the ATM cells to be provided to the output port through each input port for each priority, the ATM cells are stored in the shared buffer according to the priority. However, the shared buffer has a limit in its storage capacity. Therefore, if the shared buffer allocated for a particular priority exceeds the limit of storage capacity, the ATM switch element 130 sends a back pressure signal to the routing table elements 110, 111, 112, ..., 113. To block the transmission of cells of a particular priority. However, cells of other priorities may be transmitted. The reverse flow signal has a function of not transmitting a cell of a specific priority and is composed of 1 bit.

2 is a configuration diagram of a cell transmission control apparatus in a conventional asynchronous transmission mode.

Referring to FIG. 2, each routing table element 110, 111, 112,..., 113 includes a cell transmission control apparatus 200 as shown in FIG. 2. The cell transmission control apparatus 200 includes a high priority queue 220 for storing the cell for multiplexing for circuit sharing with respect to a cell to be transmitted and a proportional bandwidth A: 'PB A'. 221, Proportional Bandwidth B ('PB B') 222, Proportional Bandwidth C ('PB C') 223 and the High Priority Cue A BP0 acquisition element 210 for acquiring BP0 as a backflow signal for 220, a BP1 acquisition element 211 for acquiring BP1 as a backflow signal for the non-wide A cue (PB A) 221, the BP2 acquisition device 212 for acquiring BP2, which is a backflow signal for non-wideband B cues (PB B) 222, BP3 for acquiring BP3, which is a backflow signal for non-wideband C cues (PB C) 223 Acquisition element 213 and a non-wide priority table 230 for specifying the priority of the non-wide queue to which the cell is to be transmitted.

The cell transmission control apparatus 200 operates as follows.

The backflow signals BP0, BP1, BP2, and BP3 from the ATM switch element 130 are serially transmitted to the cell transmission control apparatus 200. In FIG. 2, it is assumed that the reverse flow signals are transmitted in the order of BP0, BP1, BP2, and BP3. Then, the BP0 acquiring device 210 acquires a backflow signal BPO, and transmits a cell in the high priority queue 220 when the backflow signal BP0 is '0', and does not transmit when '1'. .

Each of the BP1 acquiring device 211, the BP2 acquiring device 212, and the BP3 acquiring device 213 is configured to obtain the respective width-A cues PB A when the acquired backflow signals BP1, BP2, and BP3 are '0'. ) 221, the non-wide B queue (PB B) 222, the cell in the non-wide C queue (PB C) 223 is transmitted, if not '1'.

However, as described above, since the ATM switch element 130 and the routing table elements 110, 111, 112,..., 113 are configured on different boards, a difference in SOC (Start of Cell) occurs. In addition, due to the difference in SOC, the routing table elements 110, 111, 112,..., 113 are described as the cell transmission control apparatus 200 in the routing table elements 110, 111, 112,..., 113. ) May have already transmitted a cell of a particular priority corresponding to the countercurrent signal prior to receiving the countercurrent signal. At this time, cells transmitted from the priority queues 220, 221, 222, and 223 are accumulated in the FIFO buffers 120, 121, 122,..., 123. However, the ATM switch element 130 does not retrieve the cells stored in the FIFO buffers 120, 121, 122, ..., 123 unless specific priority cells in the internal shared buffer are sent to the output port. Do not. Even in this case, the routing table elements 110, 111, 112, ..., 113 may transmit cells of different priorities to the FIFO buffers 120, 121, 122, ..., 123. At this time, when the storage capacity of the FIFO buffers 120, 121, 122, ..., 123 is reached, all cells previously stored in the FIFO buffers 120, 121, 122, ..., 123 are stored. There is a problem of being lost.

Accordingly, an object of the present invention is to provide a cell transmission control method and apparatus for preventing cell loss due to SOC mismatch in an ATM system.

In order to achieve the above object, the present invention provides a routing table element having queues for storing asynchronous transmission mode (ATM) cells for each priority and outputting ATM cells stored in the queues, and ATM cells from the routing table element. At least one input port and an output port for receiving, buffers for storing ATM cells to be provided to the output port through the input port for each priority, and the ATM cells stored in the buffers are preset An ATM switch element which generates a backflow signal to request the corresponding queue of the routing table element to suspend transmission of ATM cells stored in the corresponding one of the queues when the capacity is exceeded, the routing table element and the ATM switch Routing table to correct mismatch in cell start (SOC) period between devices A method for controlling cell transfer from the routing table element to the ATM switch element in an ATM system having a first-in first-out (FIFO) buffer that temporarily stores and outputs ATM cells from the queues of the element to the ATM switch element. To

Determining whether an ATM cell stored in at least one of the buffers of the ATM switch element exceeds a storage capacity; and storing an ATM cell stored in at least one buffer of the buffers of the ATM switch element. And stopping the output of the ATM cells stored in the queues to the FIFO buffer when it is determined to exceed.

The present invention also provides a routing table element having queues for storing asynchronous transmission mode (ATM) cells for each priority and outputting ATM cells stored in the queues, and ATM cells from the routing table element. At least one input port and an output port for receiving the data, and buffers for storing ATM cells to be provided to the output port through the input port in priority order, wherein the ATM cells stored in the buffers are pre-set. An ATM switch element for generating a backflow signal to request the corresponding queue of the routing table element to stop transmission of ATM cells stored in the corresponding one of the queues when the set capacity is exceeded, the routing table element and the ATM; Routing to correct mismatch in cell start (SOC) period between switch elements In an ATM system having a first-in first-out (FIFO) buffer that temporarily stores ATM cells from the queues of a table element and outputs them to the ATM switch element, controlling cell transfer from the routing table element to the ATM switch element. In the apparatus,

Distinguishing and obtaining respective backflow signals generated to stop transmission of a priority cell corresponding to each buffer when an ATM cell stored in at least one of the buffers of the ATM switch element exceeds a storage capacity Stopping the output of the ATM cells stored in all the queues when the at least one reverse flow signal acquisition device and the at least one of the reverse signal are signals for stopping output of the ATM cells stored in the queues to the FIFO buffer. The apparatus comprises a countercurrent control element and at least one queue storing the ATM cells.

DETAILED DESCRIPTION A detailed description of preferred embodiments of the present invention will now be described with reference to the accompanying drawings. It should be noted that reference numerals and like elements among the drawings are denoted by the same reference numerals and symbols as much as possible even though they are shown in different drawings. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

3 is a block diagram of an apparatus for controlling cell transmission in an asynchronous transmission mode according to an embodiment of the present invention.

Referring to FIG. 3, the cell transmission control device 300 includes a proportional bandwidth queue 320, 321, 322, and 323, a backflow signal control device 330, and a backflow signal acquisition device 310, 311, or the like. 312 and 313 and non-wide priority table 340.

The reverse flow signal is transmitted from the ATM switch element 130 to the inputs of the reverse flow signal acquisition elements 310, 311, 312, and 313.

At this time, the BP0 acquiring element 310 is a device for acquiring the backflow signal BP0 for the highest priority queue High 320, and the BP1 acquiring element 311 is connected to the non-width A cue (PB A) 321. Is a device for acquiring the reverse flow signal BP1, and the BP2 acquiring element 312 is a device for acquiring the countercurrent signal BP2 for the B-width cue (PB B) 322, and the BP3 acquiring element 313 is non-width. A device for acquiring the backflow signal BP3 for the C cue (PB C) 323. The backflow signal acquisition elements 310, 311, 312, and 313 may be easily implemented using a programmable logic device (PLD), and an output thereof is connected to an input of the backflow signal control element 330. At this time, in the exemplary embodiment of the present invention, the non-width cue 320, 321, 322, and 323 and the reverse flow signal acquisition elements 310, 311, 312, and 313 are each composed of four.

If any one of the input signals is '1', the output signal control element 330 becomes '1'. Therefore, if the backflow signal for any one non-wide queue is '1', cells in all non-wide queues 320, 321, 322, and 323 are not transmitted. As the backflow signal control element 330, an OR gate, which is a logic gate, is used in the exemplary embodiment of the present invention. The output of the backflow signal control element 330 is connected to inputs of the respective Proportional Bandwidth Queues 320, 321, 322, and 323.

The non-wide queues 320, 321, 322, and 323 store the cells for multiplexing for circuit sharing during cell transmission. The outputs of the High Priority (High Priority) 320, the Narrow A-Queue (PB A) 321, the Narrow B-Queue (PB B) 322, and the Narrow C-Queue (PB C) 323 are shown in FIG. It is connected to the input of FIFO buffers 120, 121, 122, ..., 123 of one.

In addition, the non-wide bandwidth ranking table 340 designates the priority of the non-wide bandwidth to which the cell is to be transmitted by a method previously set by an ATM system operator.

4 is a diagram illustrating a cell transmission control method in an asynchronous transmission mode according to an embodiment of the present invention.

Referring to FIG. 4, in step 402, the routing table device increases the serial number index whenever the cell time of the start of cell (SOC) increases.

In step 404, the backflow signal control element 330 determines the value of the backflow signal input to the backflow signal control element 330. At this time, if any one of the input reverse flow signal is '1', the reverse flow signal control element 330 becomes '1'. Therefore, when the output of the countercurrent control element 330 is '1', the cells in all non-wide queues 320, 321, 322, and 323 are transmitted to the FIFO buffers 120, 121, 122, ..., 123. If not, the operation 402 is performed again. However, if all of the reverse flow signals inputted to the reverse flow signal control element 330 are '0', the flow proceeds to step 406. That is, the backflow signal control element 330 waits until all the backflow signals BP0, BP1, BP2, and BP3 become '0'. When all of the backflow signals BP0, BP1, BP2, and BP3 become '0', the backflow signal control element 330 simultaneously supplies backflow signals to the non-width cues 320, 321, 322, and 323, respectively. Will output the value '0'.

In step 406, it is determined whether there is a cell in the high priority queue 320.

As a result of the determination in step 406, if there is a cell in the high priority queue 320, step 408 is performed. In step 408, since the backflow signal BP0 is '0', the cells in the high priority queue 320 are transmitted to the FIFO buffers 120, 121, 122, ..., 123, and the process returns to step 402.

As a result of the determination of step 406, if there is no cell in the high priority queue 320, step 410 is performed.

In the following steps 410 and 412, the remaining non-wide cue (PB A) 321, the non-wide B cue (PB B) 322 and the non-wide C cue (PB C) 323 Determine each cell transmission priority. Methods for determining cell transmission priority include a random method, a method based on bandwidth requirements, a method based on a condition of a virtual channel, a method based on a traffic type, and the like. This can be applied. In an embodiment of the present invention, a method using a proportional bandwidth order table is applied.

In step 410, round_robin is obtained. In an embodiment of the present invention, the round_robin is a three-bit counter, which is set as a remainder of the index divided by eight.

In step 412, the transmission priority of the non-width queue to which the cell is to be transmitted is determined by finding an offset that matches the round_robin in the non-width order table. At this time, PB_OrderN (N = 0, 1, 2) of the non-wide leader list specifies the priority of the non- wide queue to which the cell is to be transmitted. That is, it is determined whether the cell for the non-wide bandwidth corresponding to PB_Order0 is transmitted first. In addition, it is determined whether cells for the non-wideband corresponding to PB_Order1 and PB_Order2 are transmitted second and third, respectively. The non-wide leader board is configured such that the non-wide A queue 321, the non-wide B queue 322, and the non-wide C queue 323 can be designated at least once while a certain number of indexes are increased.

In step 414, it is determined whether there is a cell in the non-width queue corresponding to PB_Order0. As a result of the determination of step 414, if there is a cell in the non-width queue corresponding to PB_Order0, step 416 is performed. However, if there is no cell in the non-width queue corresponding to PB_Order0, the process proceeds to step 418.

In step 416, the non-wide bandwidth corresponding to the PB_Order0 transfers the cells in the FIFO buffers 120, 121, 122, ..., 123 and returns to step 402.

In step 418, it is determined whether there is a cell in the non-width queue corresponding to PB_Order1. As a result of the determination in step 418, if there is a cell in the non-wide queue corresponding to PB_Order1, the process proceeds to step 420. However, if there is no cell in the non-width queue corresponding to PB_Order1, the process proceeds to step 422.

In step 420, the non-width queue corresponding to the PB_Order1 transfers the internal cells to the FIFO buffers 120, 121, 122, ..., 123 and returns to step 402.

In step 422, it is determined whether there is a cell in the non-width queue corresponding to PB_Order2. As a result of the determination in step 422, if there is a cell in the non-width queue corresponding to PB_Order2, the flow proceeds to step 424. However, if there is no cell in the non-width queue corresponding to PB_Order2, the process returns to step 402.

In step 424, the non-width queue corresponding to the PB_Order2 transfers the internal cells to the FIFO buffers 120, 121, 122, ..., 123 and returns to step 402.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, the present invention has an advantage of enabling stable information transmission by preventing cell loss due to SOC mismatch in an ATM system.

In addition, the present invention has the advantage of ensuring the quality of service and the quality of service when delivering information on the ATM system.

1 is a connection diagram illustrating a conventional ATM routing table element and an ATM switch element;

2 is a configuration diagram of a cell transmission control apparatus in a conventional asynchronous transmission mode,

3 is a block diagram of an apparatus for controlling cell transmission in an asynchronous transmission mode according to an embodiment of the present invention;

4 is a diagram illustrating a cell transmission control method in an asynchronous transmission mode according to an embodiment of the present invention.

Claims (4)

      A routing table element and an ATM switch element each having a buffer for storing ATM cells according to priority, and a first-in first-out (FIFO) buffer for temporarily storing and outputting ATM cells from the routing table element to the ATM switch element. A method for controlling cell transmission from the routing table element to the ATM switch element in an ATM system comprising: Determining whether an ATM cell stored in at least one of the buffers of the ATM switch element exceeds a storage capacity; Stopping the output of the ATM cell from the routing table element to the FIFO buffer when it is determined that an ATM cell stored in at least one of the buffers of the ATM switch element exceeds a storage capacity. Said method. The method of claim 1, Outputting ATM cells to the FIFO buffer according to the priority of the routing table buffers when it is determined that all of the ATM cells stored in the buffer of the ATM switch element do not exceed a storage capacity. Way. A routing table element and an ATM switch element each having a buffer for storing ATM cells according to priority, and a first-in first-out (FIFO) buffer for temporarily storing and outputting ATM cells from the routing table element to the ATM switch element. An apparatus for controlling cell transmission from the routing table element to the ATM switch element in an ATM system comprising: Distinguishing and obtaining respective backflow signals generated to stop transmission of a priority cell corresponding to each buffer when an ATM cell stored in at least one of the buffers of the ATM switch element exceeds a storage capacity At least one reverse flow signal acquisition device for A reverse flow signal for stopping output of ATM cells stored in all routing table element buffers when at least one of the backflow signals is a signal for stopping output of ATM cells stored in the routing table element buffers to the FIFO buffer; With a control element, And at least one buffer for storing the ATM cells. The method of claim 3, wherein And said backflow signal control element comprises a logic sum gate.