KR100241341B1 - New cell delineation method in atm network based on sdh - Google Patents

Abstract

The present invention relates to a cell boundary identification method for identifying a cell boundary in an SDH based ATM network. In the prior art, the cell boundary identification method of the present invention for solving the problem of identifying an edge of a cell header by checking an error of only a cell header part may check an error over an entire area of an ATM cell. Therefore, it provides a means of evaluating the performance of a transmission line by counting ATM cells containing errors. That is, the transmission line may evaluate the performance as the number of cells including errors is large and small.

Description

Cell boundary identification method in synchronous digital layer based ATM network

The present invention relates to a cell boundary identification method for identifying a cell boundary by checking an error over an entire area of an ATM cell in a synchronous digital layer (SDH) based ATM network.

SDH-based ATM networks use STM-N type frames to deliver ATM cells.

1 shows a data structure in which an ATM cell is delivered using a STM-N (Synchronous Transport Mode-N) frame.

The STM-N frame is composed of Section OverHead (SOH), Administrative Unit Pointer (AUP), and STM-N payload. SOH is used to provide maintenance information such as the transmission status of an STM-N frame between two devices generating or terminating an STM-N frame. The Virtual Container (VC) -4-Xc frame is delivered to the STM-N payload. AUP marks the starting position of a VC-4-Xc frame within the STM-N payload. The VC-4-Xc frame consists of C-4-Xc and Path Overhead (POH). C-4-Xc is used to deliver ATM cells. The POH consists of 9 bytes and is used to convey data transfer status and maintenance information between two devices that generate and terminate the VC-4-Xc frame.

2 shows the configuration of an ATM cell.

The ATM cell consists of a header portion of 5 bytes and a payload portion of 48 bytes. The first four bytes of the header contain information identifying the cell destination and the cell type, and the fifth byte is a header error control (HEC) octet. The HEC octet is used to check whether an error has occurred in the header portion of an ATM cell. The payload portion is a message delivered to the destination by the ATM cell.

In the prior art, a cell boundary identification method in an SDH-based ATM network is provided by an International Telecommunication Union-Telecommunication Standardization Sector (ITU-T) Recommendation to identify a start position of an ATM cell. The transmitting side that delivers the ATM cell generates an ATM cell, inserts the ATM cell into the STM-N payload, and delivers it to the receiving side. The receiver recovers the STM-N frame and extracts the ATM cell.

In order to identify the start position of the ATM cell, the following functions are required at the transmitting side and the receiving side. The sender displays the contents of the first byte to the fourth byte in a binary polynomial such that the first bit of the header is the most significant term. 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 octet and transmitted to the receiver. On the receiving side, the header part (5 octets) of the received cell is expressed as a polynomial so that the first bit is the highest term. The receiver polynomial is divided by the generated polynomial (X ⁸ + X ² + X + 1). If the cell does not generate an error and a value other than this, it is determined that the cell contains an error in the cell header portion.

3 shows a cell boundary identification state transition diagram that transitions to a tracking state 301, a quasi-synchronization state 302, and a synchronization state 303 according to a cell's reception state at the receiving side.

In the tracking state 301, header error control (HEC) is calculated using a generation polynomial (X ⁸ + X ² + X + 1) for five octets assumed to be headers moving in bytes. If the calculated value is zero, it is considered to find the starting position of the cell and transitions to quasi-synchronous state 302. In quasi-synchronous state 302, HEC values are calculated for a cell header that is 5 octets by shifting 53 bytes corresponding to the cell length. If the correct HEC in delta (DELTA) times is confirmed in succession, the state of synchronization 303 is reached. However, if the wrong HEC comes out even once in the middle, it goes back to the tracking state (301). In the synchronous state 303, the HEC is calculated as in the quasi-synchronous state 302. If the correct HEC is confirmed, it is kept in sync. However, if a wrong HEC is detected consecutively (ALPHA) times, it is assumed to be out of sync and goes back to the tracking state (301).

The existing cell boundary identification method checks an error occurrence of only a cell header part, identifies a cell boundary, and determines discarding of a cell. Therefore, an error cannot be checked for an error generated in an ATM cell payload. The proposed cell boundary identification method checks an error over the entire area of an ATM cell and identifies a cell boundary, so that an ATM cell including an error can be counted. Therefore, it is possible to evaluate the performance of the transmission line by counting the cell where the error occurred.

When an error occurs in an ATM cell delivered in an SDH based ATM network, the present invention provides a method of monitoring an existing cell boundary identification method while maintaining compatibility. That is, when the device using the existing cell boundary identification method and the device using the proposed cell boundary identification method are connected, the proposed cell boundary identification method is generated in the header part of the ATM cell in the same manner as the existing cell boundary identification method. Check for errors to identify cell boundaries. In addition, when the devices using the proposed cell boundary identification method are connected between both ends, the proposed cell boundary identification method evaluates the performance of the line by checking the errors generated over the entire area of the ATM cell.

Accordingly, an object of the present invention is to provide a measurement of the performance of a transmission line in an ATM network by counting an error occurring in an ATM cell.

1 is an ATM cell delivery structure based on SDH;

2 is an ATM cell structure,

3 is a cell boundary identification state transition diagram,

4 is an operation conceptual diagram of an ATM apparatus using a cell boundary identification method according to the present invention;

5 is a flowchart illustrating an operation of a transmitter of a cell boundary identification method according to the present invention;

6 is a sequence and position of a header error control octet according to a cell boundary identification method of the present invention;

7 is a flowchart illustrating an operation of a receiver of a cell boundary identification method according to the present invention;

8 is a cell boundary identification state transition diagram in accordance with the present invention.

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

When the proposed cell boundary identification method is used in the SDH based ATM network, the ATM cell is delivered through the payload of the STM-N frame in the same manner as the conventional cell boundary identification method.

4 illustrates a connection between an ATM device using a new cell boundary identification method and an ATM device using an existing or new cell boundary identification method.

The cell boundary identification method 402 of the present invention includes a receiver 403 and a transmitter 404. In order to maintain compatibility with the existing cell boundary identification method, the following functions are required.

The transmitter 404 of the cell boundary identification method generates an STM-N frame and an ATM cell according to the flowchart of FIG. 5.

That is, in the initial state 501, the initial condition is determined so that the HEC octet of the next delivered ATM cell is generated by the new HEC generation method. In the STM-N frame generation 502, the HEC of the ATM cell is generated in the POH (Path OverHead) byte of the VC-4-Xc frame according to the cell boundary identification method generated by the other ATM device. Display the creation method. The POH byte is used to convey data type and maintenance information between devices that are transferred between ATM devices terminating the ATM cell. The use of this POH bit is recommended by the ITU-T. Therefore, an ATM device using the new cell boundary identification method allocates and displays a specific bit of the POH part to distinguish it from the existing device. The ATM cell generation 503 generates an ATM cell by indicating a VPI / VCI value in the header portion of the ATM cell and inserting data to be delivered in the payload portion. The ATM cell thus generated must include a HEC to identify the starting position of the ATM cell. Transition to new HEC generation and ATM cell forwarding 506 or existing HEC generation and ATM cell forwarding 505 depending on the type of counterpart ATM device 504. The existing HEC generation and ATM cell delivery 505 generates an ATM cell and delivers it to the counterpart ATM device in the same manner as the HEC generation method currently in use. New HEC generation and ATM cell forwarding 506 marks the N-th forwarding ATM cell in a binary polynomial such that the first bit of the header is the most significant term. This polynomial is multiplied by X ⁸ and the result divided by the generated polynomial (X ⁸ + X ² + X + 1) is the new HEC octet. The HEC octet generated in this way is inserted into the header error control (HEC _N ) octet of the cell N + 1 to be transmitted next, and delivered to the receiver. That is, as shown in FIG. 6, the HEC value calculated for the N-th cell is inserted and transferred into the HEC _N octet, which is the HEC region of the N + 1 th cell.

New STM-N frame generation 507 determines whether to generate a new STM-N frame to deliver the next generated ATM cell. If the ATM cell is delivered to the existing STM-N frame without generating a new STM-N frame, the process transitions to the ATM cell generation 503. However, if a new STM-N frame is needed for cell delivery, it transitions to the counterpart ATM device type identification 508. The counterpart ATM device type identification 508 identifies a cell boundary identification method used by the counterpart ATM device from the received STM-N frame. Transition to STM-N frame generation 502 after counterpart ATM device type identification 508.

Next, the receiver 403 of the cell boundary identification method operates according to the operation flowchart of FIG.

The STM-N frame processing 701 processes the received STM-N frame and determines what kind of cell boundary identification method the counterpart ATM device uses. Since the transmitter of the counterpart ATM apparatus displays and transmits the HEC octet generation method to a specific bit of the POH part, the receiver can identify the receiver. The ATM cell delivered to the payload of the STM-N frame is identified by the new cell boundary identification state transition diagram 702 at the start of the cell. New STM-N frame reception 703 transitions to STM-N frame processing 701 if a new STM-N frame is received after the ATM cell has been processed, or otherwise transitions to a new cell boundary identification state if an ATM cell is received. 702 identifies the cell boundary.

8 shows a cell boundary identification state transition diagram operated according to the counterpart ATM device.

The cell boundary identification state transition diagram consists of an existing cell boundary identification state transition diagram 805 and an added cell boundary identification state transition diagram 801. In the initial state, it is located in tracking state 1 (802) of the added cell boundary identification state transition diagram. In the tracking state 1 (802), if the counterpart ATM device uses the existing cell boundary identification method, it transitions to the tracking state 806 of the existing cell boundary identification state transition diagram. In the tracking state 806, quasi-synchronization state 807, and synchronization state 808 in the existing cell boundary identification state transition diagram, the cell boundary identification method detects an error generated in the header portion of an ATM cell in the same manner as the conventional method. Examine to identify cell boundaries.

However, if the other ATM device uses a new cell boundary identification method, the polynomial is the HEC _N octet of the received cell (Nth) and the next received (N + 1th) cell, with the first bit of the cell header being the highest term. If the result is 0, the cell does not generate an error, and if it is a value other than the generated polynomial (X ⁸ + X ² + X + 1), the cell contains an error. 8 illustrates a process of transitioning to tracking state 1 802, quasi-synchronous state 1 803, and synchronization state 1 804 according to the cell boundary identification state of the received cell.

First, in trace state 1 (802), the first state of the cell is shifted bit by bit (or byte) at the point predicted to be the start position of the cell, and the HEC octet of the N + 1 th received cell Calculate the HEC value using the polynomial generated over (X ⁸ + X ² + X + 1). If the correct HEC value is found as a result of the calculation, it is determined that the ATM cell has been received, and transition to quasi-synchronous state 1 (803). In quasi-synchronous state 1 (803), a polynomial (X ⁸ + X ^{2) is} generated over the entire area of the Nth received ATM cell and the HEC octet of the N + 1th received cell, shifting by 53 bytes corresponding to the cell length. Calculate the HEC value using + X + 1). Finding the correct HEC value DELTA times in a row proceeds to sync state 1 (804). However, if an incorrect HEC value is calculated even once in the middle, it returns to tracking state 1 (802). In synchronization state 1 (804), the HEC value is calculated in units of cells as in quasi-synchronization state 1 (803). If a correct HEC is found, it remains in sync state 1 (804), but if successive ALPHA wrong HECs are detected, it is assumed to be out of sync and returns to tracking state 1 (802).

As described above, when the new cell boundary identification method is used in the SDH-based ATM network, the ATM cell including the error may be selectively discarded, thereby preventing the waste of the band by the cell including the error. In addition, since the counting of ATM cells including errors is possible, it provides a performance measurement method of transmission line in ATM network.

Claims (5)

A method of identifying a cell boundary by checking an error generated in a header portion of an ATM cell delivered to a counterpart ATM device in a synchronous digital layer (SDH) based ATM network, A first step of setting an initial condition for newly generating a header error control (HEC) octet of an ATM cell to be transferred next; Generating a STM-N frame and displaying a HEC generation method of an ATM cell on a path overhead (POH) byte of a VC-4-Xc frame according to a cell boundary identification method used by a counterpart ATM; Displaying a virtual path identifier / virtual channel identifier value in a header portion of the ATM cell and inserting data to be transmitted in the payload portion to generate an ATM cell; A fourth step of performing new HEC generation and ATM cell transfer or existing HEC generation and ATM cell transfer according to the type of the counterpart ATM device to determine whether to use the existing cell boundary identification method; If it is necessary to generate a new STM-N frame in order to deliver the next generated ATM cell, the STM-N frame is generated again after identifying the cell boundary identification method used by the other ATM device from the received STM-N frame. A fifth step; And And after the fourth step, if the ATM cell is delivered to the existing STM-N frame without generating a new STM-N frame, a sixth step of generating the ATM cell again. The method of claim 1, The conventional HEC generation and ATM cell transfer are cell boundary identification methods, which generate ATM cells and transmit them to the counterpart ATM device in the same manner as the HEC generation method currently in use. The method of claim 1, In the new HEC generation and ATM cell forwarding, the Nth forwarding ATM cell is represented by a binary polynomial such that the first bit of the header is the most significant term, and the polynomial is multiplied by X ⁸ to generate the polynomial (X ⁸ + X ² + X + A cell boundary identification method comprising generating the result divided by 1) into a new HEC octet and inserting the generated HEC octet into the HEC octet of the cell N + 1 to be delivered next. . A method for identifying a cell boundary by checking an error generated in a header portion of an ATM cell transmitted from a counterpart ATM device in a synchronous digital layer (SDH) based ATM network, A first step of processing the received STM-N frame; A second step of identifying a boundary of an ATM cell carried in the payload of the processed STM-N frame; And Performing a STM-N frame process when a new STM-N frame is received after the ATM cell is processed; otherwise, if the ATM cell is received, a third step of identifying a boundary of the new cell is performed. Cell boundary identification method. The method of claim 4, wherein The cell boundary identification of the second step is If the other ATM device uses the existing cell boundary identification method, it checks the error generated in the header part of the ATM cell and identifies the cell boundary.If the other ATM device uses the new cell boundary identification method, the first bit of the cell header is the highest. If the result of dividing the HEC octet of the received Nth cell and the next received N + 1th cell by the polynomial and dividing by the generated polynomial is 0, the cell does not generate an error. A cell boundary identification method, characterized in that the cell is determined to contain an error.

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