KR100246609B1 - Method of discriminating the boundary of cell of atm net - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a cell boundary identification method in an asynchronous delivery mode network.

2. The technical problem to be solved by the invention

An object of the present invention is to provide a cell boundary identification method in an asynchronous delivery mode network that can identify an edge of a cell by checking an error over an entire area of an ATM cell.

3. Summary of Solution to Invention

According to an aspect of the present invention, there is provided a cell boundary identification method in an asynchronous transmission mode network, comprising: a first step of calculating a header error control (HEC) octet for all cells and transmitting the same to a receiver; A second step of checking a syndrome calculated by dividing a result of subtracting a predetermined hexa value from a header error control (HEC) octet of all cells received from a transmitter by a generation polynomial; And a third step of determining whether an error is based on the syndrome calculation value.

4. Important uses of the invention

The present invention is used to measure the performance of a transmission line.

Description

Cell Border Identification Method in Asynchronous Transfer Mode Network

The present invention relates to a cell boundary identification method capable of identifying a cell boundary by checking an error over an entire area of an ATM cell when an error occurs in an ATM cell in an Asynchronous Trasfer Mode (ATM) network. .

In the related art, an error generated only in a cell header part is examined to identify a cell boundary, and then discarding of a cell is determined, and a method of correcting only a single bit error is used.

Therefore, since most errors are bursts, the conventional method of correcting only a single bit error could not correct all the errors, and the errors in the ATM cell's payload could not be checked. There is a problem in that the bandwidth is wasted because the ATM cell containing.

Disclosure of Invention The present invention devised to solve the above problems is to provide a cell boundary identification method in an asynchronous delivery mode network capable of identifying cell boundaries by checking errors over the entire area of an ATM cell. have.

1 is a structural diagram of an asynchronous transfer mode (ATM) cell to which the present invention is applied.

2 is a boundary identification state transition diagram of a cell to which the present invention is applied.

3 is an embodiment structural diagram of a cell used in the present invention.

4 is a flowchart illustrating a cell boundary identification method in a transmitter according to the present invention.

5 is a flowchart illustrating a cell boundary identification method in a receiver according to the present invention.

* Explanation of symbols for the main parts of the drawings

12: tracking status

13: quasi-synchronous state

14: Sync state

According to an aspect of the present invention, there is provided a method for identifying a cell boundary in an asynchronous delivery mode network, comprising: a first step of calculating a header error control (HEC) octet for all cells and transmitting the same to a receiver; A second step of checking a syndrome calculated by dividing a result of subtracting a predetermined hexa value from a header error control (HEC) octet of all cells received from a transmitter by a generation polynomial; And a third step of determining whether an error is based on the syndrome calculation value.

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

1 is a structural diagram of an asynchronous transfer mode (ATM) cell to which the present invention is applied.

An ATM cell consists of a 5-byte ATM header and a 48-byte ATM payload.

ATM headers include Virtual Path Identifier (VPI), Virtual Channel Identifier (VCI), Payload Type Identifier (PTI), Cell Loss Priority (CLP), and It consists of Header Error Control (HEC) bytes.

The remaining four bytes of the ATM header excluding the HEC byte contain information identifying the cell destination and the cell type, and the fifth HEC octet is used to check whether an error has occurred in the header of the ATM cell.

The 48 byte ATM payload is a message sent to the destination by the ATM cell.

The cell boundary identification method follows the recommendations of the Telecommunication Part of International Telecommunication Union (ITU-T) to identify the starting position of an ATM cell. That is, to identify the start position of the ATM cell, it is classified into a transmitter and a receiver.

First, the transmitter displays the contents of the first byte to the fourth byte in a binary polynomial such that the first bit of the header becomes the most significant term. Then, the polynomial is multiplied by X ⁸ and the result divided by the generated polynomial (X ⁸ + X ² + X + 1) is inserted into the header error control (HEC) octet and transmitted to the receiver.

On the other hand, the receiver displays the header (5 octets) of the received ATM cell so that the first bit is the most significant term by the polynomial, and divides it by the generated polynomial (X8 + X2 + X + 1). In this case, if the value obtained by dividing the header of the ATM cell represented by the polynomial by the generated polynomial is 0, no error has occurred in the header of the ATM cell. If the value is otherwise, the header of the ATM cell is regarded as a cell including the error.

2 is a boundary identification state transition diagram of an ATM cell to which the present invention is applied, and illustrates a cell boundary identification state transition that transitions to a tracking state, a quasi-synchronous state, and a synchronous state according to a reception state of an ATM cell in a receiver.

In trace state 21, HEC bytes are computed using the generation polynomial (X ⁸ + X ² + X + 1) for the five octets assumed to be ATM headers, moving bit by bit or byte by byte. At this time, if the calculated value is 0, it is regarded as finding the starting position of the ATM cell and transitions to quasi-synchronous state 22.

In quasi-synchronous state 22, HEC bytes are calculated for an ATM cell header that is 5 octets, shifting by 53 bytes corresponding to the length of the ATM cell. At this time, if the correct HEC byte is detected successively δ times, the state transitions to the synchronous state, and if the wrong HEC byte is detected even once in the middle, it returns to the tracking state 21 again.

In the synchronous state 23, the HEC byte is calculated as in the quasi-synchronous state 22. At this time, if the correct HEC byte is detected, the synchronization state 23 is maintained. However, if a wrong HEC byte is consecutively detected, the synchronization is regarded as lost and transitioned to the tracking state 21.

3 is a structural diagram of an embodiment of a cell used in the present invention.

The cell boundary identification method according to the present invention may count an ATM cell including an error by using a correlation between the HEC byte value calculated for the entire ATM cell area and the HEC byte value of the cell to be transmitted next.

Therefore, the N + 1 th ATM cell to be delivered must first include the header error control (HEC) octet calculated for the N th cell delivered to the cell header (HEC _{N + 1} ).

The new cell boundary identification method is divided into a transmitter and a receiver to identify the start position of an ATM cell.

4 is a flowchart illustrating a cell boundary identification method in a transmitter according to the present invention.

First, the N value indicating the order of cells to be transmitted is initialized to 1, and the first HEC ₁ octet delivered is set to 55h as a hexa (Hexa) value (401).

Thereafter, the calculated header error control octet (HEC _N ) is inserted into the N th ATM cell to be delivered (402).

Next, the HEC byte value is calculated for the Nth delivered ATM cell (HEC _{N + 1} ) (403). In this case, the HEC byte value is expressed as a binary polynomial such that the first bit of the N-th transmitted ATM cell header becomes the most significant term, multiplied by this polynomial X ⁸ , and divided by the generation polynomial (X ⁸ + X ² + X + 1). Add 55h to the result.

Finally, the next cell to be delivered is queued (404).

5 is a flowchart illustrating an embodiment of a cell boundary identification method in a receiver according to the present invention.

First, E, which indicates the number of cells including an error, is initialized to 0, and N value, which indicates the order of cells to be delivered, is set to 2 (501). In this case, the reason why the N value is set to 2 is that at least two cells must be received to check the error state of the received cell.

Subsequently, the N-th cell is received to simply distinguish the order of the received cells (502).

Next, all regions of the N-th cell and only the HEC _{N + 1} octet of the N + 1-th received cell are represented by the binary polynomial such that the first bit of the N-th received cell becomes the most significant term (503). That is, the result of subtracting 55h from all header error control (HEC) octets is divided by the generated polynomial (X ⁸ + X ² + X + 1). This is called a SYNDROME calculation.

At this time, it is determined whether the calculated syndrome SYNNDROME is 0 (504).

If the SYNNDROME value is 0, it is assumed that no error occurs in the received ATM cell, and the next cell is waited (506).

On the other hand, if the SYNDROME calculation value is other than 0, an error is generated in the received cell, and the number of cells including the error is increased by one (505), and the next cell is waited (506).

In the cell boundary identification method according to the present invention, the cell boundary is identified by checking an error over the entire area of the ATM cell, so that an ATM cell including an error can be counted.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the spirit of the present invention for those skilled in the art to which the present invention pertains, and the above-described embodiments and accompanying It is not limited to the drawing.

According to the present invention as described above, since the error can be inspected over the entire area of the cell, it is possible to reduce the waste of the band by the cell including the error, and to count the ATM cell including the error, so that the transmission line in the ATM network can be There is an easy effect on the performance measurement.

Claims (5)

A cell boundary identification method in an asynchronous delivery mode network, A first step of calculating and transmitting a header error control (HEC) octet for all cells to a receiver; A second step of checking a syndrome calculated by dividing a result of subtracting a predetermined hexa value from a header error control (HEC) octet of all cells received from a transmitter by a generation polynomial; And A third step of determining whether an error is based on the syndrome calculation value; Cell boundary identification method in an asynchronous delivery mode network comprising a. The method of claim 1, The second step, Dividing an order of cells received from the transmitter; A fifth step of determining whether the calculated syndrome calculation value is a predetermined value indicating whether an error occurs; A sixth step of determining that there is no error and waiting for the next cell when the predetermined value is satisfied as a result of the determination in the fifth step; And As a result of the determination of the fifth step, if the predetermined value is not satisfied, the received cell is regarded as having an error, and the number of cells including the error is increased and the seventh step of waiting for the next cell. Cell boundary identification method in an asynchronous delivery mode network comprising a. The method according to claim 1 or 2, The predetermined value of the second step is A cell boundary identification method in an asynchronous delivery mode network, characterized in that the value of 55H (Hexa). The method of claim 2, The predetermined values of the fifth to seventh steps are respectively, A cell boundary identification method in an asynchronous delivery mode network, characterized in that zero. The method of claim 1, The calculated syndrome (SYNDROM) is, A cell boundary identification method in an asynchronous delivery mode network, characterized in that the result of subtracting 55 h from all header error control (HEC) octets is divided by the generated polynomial (X ⁸ + X ² + X + 1).

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