KR100206307B1 - Method for executing x.25 protocol in ess - Google Patents

Abstract

end. The technical field to which the invention described in the claims belongs

The present invention relates to the application of the X.25 protocol of the electronic exchange, and more particularly to a method for increasing the efficiency of internal communication interworking (hereinafter referred to as interworking) in the exchange.

I. The technical problem that the invention is trying to solve

The conventional system has a protocol functional layer between several processors in each layer, so when the actual data is to be transmitted, all the processors must pass through each step, and the data transmission efficiency is lowered. Solve the problem.

All. Summary of Solution of the Invention

In applying the X.25 protocol function at the exchange, it provides transport and session layer module that can perform data link status management, routing information management for the connection target system, and virtual circuit establishment and release. .

la. Important uses of the invention

Efficient X.25 Protocol Implementation in Electronic Switching System.

Description

Efficient X.25 Protocol Implementation in Electronic Switching System

The present invention relates to the application of the X.25 protocol of the electronic exchange, and more particularly to a method for increasing the efficiency of internal communication interworking (hereinafter referred to as interworking) in the exchange.

In general, an electronic exchange performs data communication through a packet network by applying the X.25 protocol function. Therefore, the X.25 protocol satisfies the normal packet network connection standard recommended by the International Telecommunication Union Telecommunications (ITU-T), and its upper layer is the state of the related X.25 protocol device required by the system called the electronic exchange. And a method of interworking transport layer, session layer, function, etc. with application layer with routing information management function.

1, the X.25 hierarchy and its flow in a conventional general electron exchanger will be described. First, the X.25 layer module 150 includes a packet layer 120 for exchanging and relaying information, a data link layer 130 for transmitting information between adjacent devices, and a physical layer for transmitting electrical signals to a transmission medium. And each layer is controlled by one processor Z including a physical line connection device. The transport and motion layer module 110 corresponds to the upper layer of the X.25 layer module 150, and is connected to a separate processor Y that is closely related to the input / output processing for state management or routing information control of the X.25 physical line. It works by The application layer module 100 corresponds to an upper layer of the transport and motion layer module 110, and processes the transmission / reception data so as to facilitate data processing for the corresponding purpose when the exchange operates as a data terminal equipment (DTE). It is operated by processor X.

In this case, the process of transmitting packet data using each layer will be described. First, when there is a request for establishing a virtual circuit from the processor X controlling the application layer module 100, a transport and session layer module ( 110) and the X.25 layer module 150 to connect to the other side's DTE (① → ②). Then, the response to the connection request from the counterpart DTE is also transmitted to the application layer module 100 through the X.25 layer module 150 and the transport and session layer module 110 (③ → ④). . Then, after establishing the virtual line, the final data transmitted from the application layer module 100 is transmitted to the counterpart DTE through the session layer module 110 and the X.25 layer module 150 (① → ②). .

Therefore, such a system has a protocol functional layer between several processors in each layer. Therefore, when the actual data is to be transmitted, all the processors must pass through each step. There was a problem taking.

Accordingly, an object of the present invention is to provide an X.25 protocol function at an exchange, to manage link state management of data, to manage routing information for a system to be connected, and to establish and release a virtual circuit. And to provide a layer layer module.

In the present invention for achieving the above object, in the electronic switch having an application layer module, transport and session layer module, X.25 layer module in the data transmission method by the mutual communication between each module,

Transmitting the virtual line establishment request signal generated from the application layer module to the packet network through the transport and session layer module and the X.25 layer module;

Receiving the virtual line establishment request signal from the called party system through the packet network and transmitting a virtual line establishment notification to the calling party X.25 layer module through the packet network;

The X.25 layer module receiving the virtual line establishment notification and notifying the application layer module directly;

The application layer module notified of the establishment of the virtual line transmits data to be directly transmitted to the X.25 layer module;

The X.25 layer module receiving the transmission data is characterized by performing a process of converting the transmission data into packet data and transmitting the packetized data to the destination system through the packet network.

1 is a X.25 hierarchical structure diagram of a conventional general electron exchanger.

2 is an X.25 hierarchical structure diagram of an electron exchanger according to the present invention.

3 is a virtual line establishment control protocol by data transmission of an electronic exchange according to the present invention.

4 is a data transmission control protocol of an electronic exchange according to the present invention.

5 is a virtual circuit establishment control protocol by the data transmission of the electronic exchange according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals have the same reference numerals as much as possible even if displayed on 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.

FIG. 2 is a X.25 hierarchical structure and a flowchart thereof in the electronic exchange according to the present invention. Since the main hierarchical structure is the same as FIG. 1, detailed description thereof will be omitted. However, the transport and session layer module 210 is designed to perform a link state management function of data, routing information management for a connection target system, and establishing and releasing a virtual line. Therefore, the operation will be described in detail as the protocol of Figs. 3, 4 and 5.

3 is a control protocol for establishing a virtual line by data transmission according to the present invention. First, in step 300, the processor X of the application layer module 200 is a destination connection target in X.25 routing information previously configured with an operator command. The system ID is read and transmitted to the transport and session layer module 210 to make a virtual line connection request. Then, the transport and session layer module 210 receiving the virtual line connection request reads the relevant state information, that is, local data using the access system ID transmitted from the application layer module 200, and then the called party's DTE state. Figure out. Thereafter, the transport and session layer module 210 transmits the request result to the application layer module in step 310 according to the called party's DTE state. At this time, when the called party's DTE state is abnormal state, the transport and session layer module 210 transmits the request result to the application layer module 200 in an unacceptable state, but the connection request of the application layer module is terminated. When the DTE state of the called party is in a normal state, the request result is allowed to be transmitted to the application layer module 200 as allowable. After the establishment, the application layer module 200 and the X.25 layer module 250 transmit data including the processor ID of the application layer module to which the direct connection can be directly, and the calling and destination numbers distinguished from the packet network. Then, in step 330 the X.25 layer module 250 is a call request (call request) to fit the standard packet format of the general information about the virtual line connection transmitted from the transport and session layer module 210 Create a packet protocol date unit (PPDU) and send it to the packet network (DCE). Then, in step 340, the DTE of the terminating system receives the PPDU transmitted from the X.25 layer module 250, checks the eligibility of the packet call, and checks the result of the X.25 layer module 250 of the calling exchange. Call confirm (or a confirmation signal). At this time, when the packet call is normal, the called party DTE informs the information that the virtual line is normally established, but when the packet call is not normal, the establishment of the virtual line is abnormally terminated. Then, in step 350, the X.25 layer module 250 receives the confirmation signal transmitted from the DTE of the terminating system, converts the logical channel number of the established virtual line into a device ID managed internally, and applies the application layer. The module 200 is notified of the availability of the direct line. Therefore, when transmitting / receiving packet data with the destination DTE later, the transmitted device ID is used as a medium. In addition, the X.25 layer module 250 transmits the result status to the transport and session layer module 210 to manage the associated X.25 data link state in step 360.

As a result, when the called party's DTE and the virtual line are established as described above, data is transmitted by the control protocol as shown in FIG. 4 and the circuit is restored. Therefore, in step 400, the application layer module 200 transmits data directly to the X.25 layer module 250. Thereafter, in step 410, the X.25 layer module 250 receives data transmitted from the application layer module 200, processes the packet data to a size dedicated to the packet data to be transmitted to the destination DTE, and then returns the destination DTE. To send. At the time of reception, data is transmitted in the reverse direction of the transmitted path in steps 420 to 430. After the transmission and reception of the data is terminated, there are two types of recovery of the circuit: forward recovery for recovering the virtual line at the calling party and reverse recovery for recovering the virtual line at the called party. In operation 440, the application layer module 200 transmits a disconnection request signal to the X.25 layer module 250. Then, in step 450, the X.25 layer module 250 receives a circuit disconnect request signal from the application layer module 200 and transmits a clear request signal, which is a circuit disconnect request signal, to the DTE of the terminating system. send. Then, in step 460 to 470, the DTE of the terminating system receives the clear request signal transmitted from the X.25 layer module 250, and then returns to the X.25 layer module 250 of the calling party. The application layer module 200 transmits a signal for notifying the cancellation result, that is, a clear confirm signal.

In step 480, the DTE of the terminating system transmits a disconnection request signal, that is, a clear request signal, to the calling X.25 layer module 250. Then, in step 490 to 500, the X.25 layer module 250 receives the clear request signal from the DTE of the called system and transmits a clear confirm signal to the DTE of the called system again to establish a virtual line. It releases and transmits a virtual circuit result to the application layer module 200. In this case, when the recovery is completed during the forward recovery and the reverse recovery, in step 510, the X.25 layer module 250 returns the assigned device ID to the application layer module 200, and the result message Notify transport and lotion layer module 210.

5 is a control protocol for establishing a virtual line by data reception according to the present invention. First, in step 520, a counterpart system DTE requests a virtual line connection for a packet call to an X.25 layer module 250 of an originating exchange. It transmits a call request signal, which is a signal. Then, in step 530, the X.25 layer module 250 receives the call request transmitted from the counterpart DTE and allocates a device ID defined internally when using a logical channel on the X.25 data link. Then, it transmits to the transport and session layer module 210 according to the internal communication format together with the received call / call number. Thereafter, the transport and session layer module 210 receives the information transmitted from the X.25 layer module 250 and reads the relation and local data to check the state of the application layer module 200. At this time, it operates in two states, normal and abnormal, depending on the state of the application layer module 200. Therefore, when the state of the application layer module 200 is abnormal by performing steps 540 to 560, the transport and session layer module 210 transmits the result to the counterpart system DTE through the X.25 layer module 250. A notification is made to release the circuit connection immediately, and then the device ID assigned to the X.25 layer module 250 is returned and the result is transmitted to the transport and session layer module 210. However, when the state of the application layer module 200 is normal, the transport and session layer module 210 includes the information from the X.25 layer module 250 and receives the virtual line connection request in step 570. Notify and request connection. Then, in step 580, the application layer module 200 switches the state of the processor to the packet data processing mode, and notifies the X.25 layer module 250 of the result. Then, in step 590, the X.25 layer module 250 is notified of the connection result transmitted from the application layer module 200, the signal indicating that the virtual line is normally connected, that is, the call system (CALL CONFIRM) to the counterpart system Is sent to the DTE. Thereafter, the X.25 layer module 250 confirming the call connection finally notifies the transport and session layer module 210 of the completion of the virtual line connection to the application layer module 200 to terminate the virtual line connection procedure. .

Since the transmission of data after the establishment of the virtual line by the incoming call and the circuit recovery process after the transmission of data are the same at the above-mentioned transmission, a detailed description thereof will be omitted.

According to the present invention as described above, in the application of the X.25 protocol function in the exchange, the transport state management function of the data, routing information management for the system to be connected, and transport capable of establishing and releasing the virtual line can be performed. And by providing the layer module, it can improve the internal communication interworking efficiency inside the exchange, reduce the buffering between layers, improve the availability of OS resources of the system, and control the state management of the protocol device with session function. By carrying out the module, there is an advantage to minimize the functional burden of the application module.

Claims (3)

In an electronic exchange having an application layer module, a transport and session layer module, and an X.25 layer module, a data transmission method by mutual communication between the respective modules, Transmitting the virtual line establishment request signal generated from the application layer module to the packet network through the transport and session layer module and the X.25 layer module; Receiving the virtual line establishment request signal from the called party system through the packet network and transmitting a virtual line establishment notification to the calling party X.25 layer module through the packet network; The X.25 layer module receiving the virtual line establishment notification and notifying the application layer module directly; The application layer module notified of the establishment of the virtual line transmits data to be directly transmitted to the X.25 layer module; The X.25 layer module receiving the transmission data performs a process of converting the transmission data into packet data and transmitting the packet data to the destination system through the packet network. According to claim 1, The virtual line establishment process, Transmitting the virtual line establishment request signal generated from the application layer module to the packet network through the transport and session layer module and the X.25 layer module; The transport and session layer module receives a virtual line establishment request signal and then establishes a line and then establishes a virtual line establishment request signal including application layer module processor identification information to which the application layer module and the X.25 layer module can be directly connected. Transmitting back to the X.25 layer module, The X.25 layer module receives the virtual line establishment request signal including the application layer module processor identification information, converts it into a standard packet format, and transmits it to the destination system through a packet network; Receiving the virtual line establishment request signal and transmitting the virtual line establishment notification to the X.25 layer module of the calling party through the packet network; The X.25 layer module receives the virtual line establishment notification and converts the logical channel number of the established virtual line into device identification information managed internally to notify the application layer module of the availability. Efficient X.25 protocol implementation method in an electronic exchange characterized in that the. In an electronic switch having an application layer module, a transport and session layer module, and an X.25 layer module, a method for receiving data by mutual communication between the modules, Transmitting a virtual line establishment request from the called system to the X.25 layer module of the calling system through a packet network; The X.25 layer module receiving the virtual line establishment request transmits the virtual line establishment request to an application layer module through the transport and session layer module; The application layer module receiving the request for establishing the virtual line directly notifies the X.25 layer module of the connection result and transmits it to the called party system; The called party system notified of the result of establishing the virtual line transmits the transmission data to the calling party X.25 layer module through the packet network; The source X.25 layer module receives the data transmitted through the packet network and transmits the data directly to the application layer module.