KR100241339B1 - Method of message type change for compatibility of sccp in atm switch - Google Patents

Abstract

The present invention can support each node in order to maintain compatibility when interworking with the existing network is a signal connection control unit (SCCP) that delivers user information and information necessary for network operation implemented in an asynchronous transmission mode (ATM) switching system The present invention relates to a method of identifying a message type and converting the message type into an appropriate message type. A node of an existing network has a problem that a long unit data (LUDT) message or an extended unit data (XUDT) message is not supported. Therefore, the present invention routes the XUDT or LUDT message received by the signaling connection controller by inputting a message type that the operator can support in each node into the database, and then tests whether the destination node supports the LUDT message and the XUDT message. Performing the conversion reduces the discarding or returning of the message by inappropriate message transmission.

Description

Message Type Conversion Method for Compatibility of Signal Connection Control in Asynchronous Transfer Mode Switch

The present invention is a message type conversion method for the compatibility of the signal connection control unit in the asynchronous transfer mode switch, and in detail, the user information implemented in the asynchronous transfer mode (Asynchronous Transfer Mode, ATM) switching system and the information required for network operation Signaling control part (SCCP) is to identify the message type that each node can support in order to maintain compatibility when interworking with the signal connection control of the existing network and to convert to the appropriate message type will be.

The connectionless message provided by the signal connection controller of the broadband ISDN includes unit data (UDT), extended unit data (UDT), and long unit data (LUDT) messages. LUDT messages are provided to accommodate up to 3952 bytes of message size without segmentation according to the capabilities of MTP-3b, and XUDT messages are used to segment data according to selection parameter values in connectionless mode. The signal connection control unit of the existing TDX exchange cannot support LUDT according to MTP-3 capability, and XUDT is also not supported because segmentation / reassembly function is not implemented. Therefore, message type conversion is not implemented because message type conversion is not required for compatibility. However, the Asynchronous Exchange Mode (ATM) exchange needs to know which message types other nodes support as the B-ISDN network interworks with the existing network. There is a need. In addition, in the B-ISDN network, it is necessary to implement a message conversion function of an ATM exchange user connection controller in consideration of acceptance of an asynchronous transfer mode (ATM) exchange that supports LUDT messages but does not implement a split / combine function.

In the present invention, when the B-ISDN network is interworked with the existing network, the ATM exchanger receives a message from the database structure and the signal connection control unit inputted by the operator to identify the message type that the ATM node cannot support before transmitting the message to the destination node. It is an object of the present invention to provide a message type conversion method of a signal connection control unit in an asynchronous transfer mode exchanger that converts to an appropriate message type.

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

Figure 2 is a database structure diagram for knowing the message types supported by the destination node.

3 is a message type conversion table according to message type parameter values supported by a destination node.

4 is a message conversion flowchart for ensuring the compatibility of the user connection control unit when receiving a long unit data (LUDT) according to the present invention.

5 is a message conversion flow diagram for ensuring the compatibility of the user connection control unit upon receipt of Extended Unit Data (XUDT) according to the present invention.

* Explanation of symbols for main parts of the drawings

11 subscriber registration device 12 relay line matching device

13: ATM unit switch 14: call control module

In the message type conversion method according to the present invention for achieving the above object, a signal point code of a destination node is performed by first determining a destination node when a long unit data (LUDT) message is received by dividing a received message type. A first step of obtaining a Signaling Point Code (SPC); a second step of determining a support parameter (Support_LX) value corresponding to a signal point of a destination node in a database after performing the first step; and, as a result of the determination, Support_LX A third step of determining whether the length of the LUDT message is larger than 256 bytes if the value is '00', and a fourth step of performing a return function if the length of the LUDT message is larger than 256 bytes; A fifth step of converting the message type into unit data (UDT) and delivering the message to the called node if the length of the LUDT message is 256 bytes or less; If the Support_LX value is '01', the sixth step of converting the LUDT message to the XUDT message and delivering the message to the destination node when the Support_LX value is '01', and the Support_LX value is '10' If '11' or '11', a seventh step of delivering the message to the destination node without message type conversion is performed.

In addition, a first step of obtaining a signaling point code (SPC) of the called node by performing a routing process of determining a called node upon receiving the XUDT message, and after performing the first step, a signal point of the called node in the database. A second step of determining a Support_LX parameter value corresponding to the third step; and a third step of determining whether a remaining segment field in the split parameter is '0' if the Support_LX value is '00'; As a result, if the remaining segment field is '0', the fourth step of converting the XUDT message into a UDT message and delivering the message to the destination node; and if the remaining segment field is not '0', performing the return function. As a result of the determination of the fifth step and the second step, if the value of Support_LX is '10', the message combining process is performed to convert the XUDT message into an LUDT message and deliver the message to the called node. And the sixth step, and wherein performing a seventh step of transferring the two-stage determination result, Support_LX value is '01' or '11', a message without a message type conversion to the destination node.

In addition, in order to know the message types supported by the destination node, two-bit Support_LX parameter is provided for each signal point in the database to indicate whether LUDT and XUDT messages can be supported, and this value is input by the operator.

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

FIG. 1 is a block diagram of an asynchronous transmission mode (ATM) exchange to which the present invention is applied, and a subscriber matching device 11 connected to a subscriber, a relay line matching device 12 connected to a relay line, and the subscriber / relay line matching device. It consists of an asynchronous transmission mode (ATM) unit switch 13 is connected to the call control module 14 is connected to the asynchronous transmission mode (ATM) unit switch, the present invention is a call control module in which the signal connection control unit is located Is implemented in

FIG. 2 is a diagram of a database structure for knowing message types supported by a destination node, in which two bits of Support_LX (23) parameters of LUDT and XUDT messages are determined according to the signal point code (SPC) parameter 22 value of the switch node. Indicates whether or not support.

3 is a table of message types and message type conversions of the destination node according to the Support_LX parameter value. If the Support_LX value is '00' (31), the destination node can support only UDT messages. If the length is 256 bytes or less, it is converted into a UDT message and transmitted. When the LUDT is received, if the message length is 256 bytes or less, it is converted into a UDT message and transmitted. If the value of Support_LX is '01' (32), the destination node can support UDT and XUDT messages. Therefore, when receiving the LUDT, the destination node is divided into XUDT and transmitted. If the value of Support_LX is '10' (33), the destination node Since UDT and LUDT messages can be supported, when XUDT is received, the combined process is performed to convert to LUDT. If the Support_LX value is '11' (34), the destination node can support all UDT, XUDT, and LUDT messages. No type conversion is necessary.

The present invention is a method of identifying the LUDT, XUDT message support status of each node input by the operator in the user connection control unit before converting the message to the destination node and converts the message type to support it.

4 is a message conversion flow diagram for ensuring compatibility of a signal connection control unit when receiving an LUDT message according to the present invention, which is implemented in a call control module 14 in an asynchronous transfer mode (ATM) exchange.

In the message conversion method of the signal connection control unit in the call control module 14 according to the above, when receiving the LUDT message (401), the routing is performed to obtain the signal point code (SPC) of the destination node (402), the incoming call from the database Checking the value of the Support_LX parameter corresponding to the node's signal point code (403), if '01', the message division process is performed (404), the message is converted to XUDT format (405), and the XUDT message is transmitted to the destination node. (406).

If the value of the Support_LX parameter is '00', the message length is greater than 256 bytes (408). If the message length is larger (408), the message is returned (409). If the value is small (409), the message is converted into a UDT format (410). In step 411, the UDT message is transmitted.

If the Support_LX parameter value is '10' or '11', the LUDT message is transmitted to the called node without message conversion (407).

5 is a message conversion flowchart for ensuring compatibility of a signal connection control unit when receiving a XUDT according to the present invention, which is implemented in a call control module 14 in an asynchronous transfer mode (ATM) exchange.

In the message conversion method of the signal connection control unit in the call control module 14 according to the above, when the XUDT message is received (501), routing is performed to obtain a signal point code (SPC) of the called node (502), and the call is received from the database. Checking the value of the Support_LX parameter corresponding to the node's signal point code (503), if '10', the message combining process is performed (504), the message is converted to LUDT form (505), and the LUDT message is transmitted to the called node. (506).

In addition, if the Support_LX parameter value is '00', it is checked whether the remaining segment field in the split parameter is '0' (508), and if it is '0', the message is converted into UDT form (509), and the UDT message is sent to the called node. In step 510, if it is not '0', a message is sent in step 511.

If the Support_LX parameter value is '01' or '11', the XUDT message is transmitted to the called node without message conversion (507).

According to the present invention, when a user connection control unit of an asynchronous transfer mode (ATM) exchange transmits a message received in the form of UDT, XUDT, or LUDT to the destination node, it grasps in advance the message type that the destination node can support and converts it into an appropriate message type. In this case, the message transmission and discarding caused by transmitting the message in a message type that the destination node cannot support is provided.

Claims (7)

In the message type conversion method implemented to send a message to the user connection control unit of the asynchronous transfer mode (ATM) switch to the message type that the destination node can support, A first step of obtaining a signaling point code (SPC) of a called node by performing a routing process of determining a called node when receiving a long unit data (LUDT) message; A second step of determining a value of a support parameter (Support_LX) corresponding to a signal point of a called node in a database after performing the first step; A third step of sending a UDT message or performing a message return according to the length of the message if the value of Support_LX is '00'; A fourth step of delivering an XUDT message to the called node if the value of Support_LX is '01'; If the Support_LX value is '10' or '11', the fifth step of transmitting the message to the destination node without changing the message type is performed. Message type conversion. The method of claim 1, wherein the third step, Determining whether the received LUDT message length is greater than 256 bytes; Performing a return process if the message length is greater than 256 bytes as a result of the determination; And converting the message type into unit data (UDT) if the message is 256 bytes or less and transmitting the message type to the destination node. The method of claim 1, wherein the fourth step, Performing a division process of the received LUDT message; And converting the LUDT message into an extended unit data (XUDT) message and delivering the message to the destination node. In the message type conversion method implemented to send a message to the user connection control unit of the asynchronous transfer mode (ATM) switch to the message type that the destination node can support, A first step of obtaining a signaling point code (SPC) of a called node by performing a routing process of determining a called node when receiving an extended unit data (XUDT) message; A second step of determining a value of a support parameter (Support_LX) corresponding to a signal point of a called node in a database after performing the first step; A third step of sending a unit data (UDT) message or carrying a message according to the number of divided XUDT messages if the value of Support_LX is '00'; A fourth step of transmitting an LUDT message to the called node if the value of Support_LX is '10' as a result of the second step determination; If the Support_LX value is '10' or '11', the fifth step of transmitting the message to the destination node without changing the message type is performed. Message type conversion. The method of claim 4, wherein the third step, Determining whether a remaining segment filter in the truncation parameter is '0' in the received XUDT message; If the remaining segment is '0', converting the message type into a UDT and delivering the message to the called node; And if the remaining segment is not '0', performing a step of carrying back a message. The method of claim 4, wherein the fourth step, Performing a combining process of the received XUDT message; And converting the XUDT message into an LUDT message and delivering the message to the called node after the execution. In the message type conversion method implemented to send a message to the user connection control unit of the asynchronous transfer mode (ATM) switch to the message type that the destination node can support, In order to know the message types supported by the destination node, a support parameter (Support_LX) with a 2-bit data type is provided for each signal point (SPC) in the database to support long unit data (LUDT) and extended unit data (XUDT) messages. The message type conversion method for compatibility of the signal connection control unit in the asynchronous transfer mode switch, characterized in that the input by the operator.

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