KR20040009118A - Method for Routing in No.7 Signaling - Google Patents

Abstract

The present invention receives and stores registration information input by a user, determines and activates a signal link adjacent to a local station from the stored registration information, and then generates an RST message to determine a state of another station to generate an adjacent signal. A signal common line No. 7 automatic route is transmitted to a point, receiving a transmission acceptance signal according to whether the other station is activated from the adjacent signal point, and setting a route using the value of the received transmission acceptance signal. The setup function allows the software to automatically find the signal route without registering the user's signal loop and more easily register the No. 7 MTP layer 3 information to users without a network concept.

Description

Route setting method in the signaling method {Method for Routing in No.7 Signaling}

The present invention relates to a route setting method in a No. 7 signaling method for software control of signal route setting at No. 7 MTP level 3.

The common line signaling method is used when a computer is used as a control device, such as an electronic exchange, because a lot of signal information processing is possible by the centralized processing of signal information, and connection time is reduced. No.7 signaling is also a common-line signaling method, and is adopted as a standard signaling system for ISDN, IN (Intelligent Network), and the like.

The No.7 signal system is capable of high-speed data processing of 64 kbit / sec, and the communication and signal are separated, so that the inconvenience of sending together can be transmitted even during a call, and the signal capacity is also large, which enables high-speed transmission. Therefore, various kinds of signals can be prepared to realize various services.

The ISDN service can provide several additional services, such as displaying the calling party's phone number on the called telephone, or intercepting calls such as interception and prank calls or indecent calls that can be accessed automatically and immediately after a call. It plays an important role in providing various services. Such a service is possible because it uses No.7 signaling.

The No.7 signaling layer is composed of a message transmission unit, a signal connection control unit, and a user unit. The message transfer part (MTP: Level 1 to 3. OSI reference model layer 1 to layer 3) in the layer of the common line signaling method is a functional block and signal data for transmitting and receiving a level 4 user part between signal stations. It consists of link level (level 1), signal link level (level 2), and signal network level (level 3).

Hereinafter, a method of setting a route at level 3 of the message transmitter will be described.

1 is a diagram illustrating a network configuration, and FIG. 2 is a diagram illustrating registration information input by a user for setting a conventional route.

The user must input his own signal point, other station signal point, adjacent signal point, signal link, and signal route directly from the monitor task to set the route.

In more detail with reference to FIGS. 1 and 2, a user inputs a local station signal point A 210, a foreign station signal point B, C, D, E 220, a neighbor signal point B, C in a monitor task. Enter 230.

In addition, the user inputs a signal link and a signal link code 240 to be connected to the adjacent signal point in the monitor task in order to input the signal link (240). That is, the signal link is input in the form of adjacent signal point = B, SLC = 0, sign signal point = C, SLC = 0, and the like.

In addition, the user enters a signal route in the monitor task (250). In other words, the user inputs routes a and b to go to signal point B in the monitor task, inputs root b and a to go to signal point C, inputs root a and b to go to signal point D as signal point E. Enter the roots a and b to go.

The registration information input as described above is stored in the data management unit of the message transmitter layer 3. A configuration of the message transmitter layer 3 will be described with reference to FIG. 3.

3 is a block diagram schematically illustrating a configuration of a message transmitter layer 3. Referring to FIG.

Referring to FIG. 3, the message transmitter layer 3 300 may generate a signal link activation command for activating a signal link adjacent to a local signal point, and a data manager 310 storing registration information input by a user. A signal activated by the signal link manager 330 and the signal link manager 330 for activating a signal link adjacent to a signal point of a local station in response to an internal manager 320, a signal link activation command of the internal manager 320. Signal link set management unit 340 for storing link activation information, a signal generating a route set test (RST) message to determine whether signal route activation of signal stations of other stations with the signal route information stored in the data management unit 310 Root management unit 350 is included.

Hereinafter, an operation of the message transmitter layer 3 300 configured as described above will be described.

When operating the system, the internal manager 320 takes the information registered in the data manager 310 and transmits a signal link activation command to the signal link manager 330 to activate an adjacent signal link. The signal link manager 330 activates a signal link adjacent to the own point in response to the signal link activation command.

When the signal link adjacent to the own point is activated, the signal link manager 330 transmits the activation information of the activated signal link to the signal link set manager 340 to recognize that the other station signal point is adjacent to be activated. The activation information of the signal link is transmitted to the signal route manager 350.

The signal route manager 350 transmits an RST message to a corresponding signal point in order to confirm whether signal routes of other station signal points are activated with the signal route information registered in the data manager 310. Here, the RST message is sent to signal points B and C to go to signal point B, to signal points C and B to go to signal point C, and to B and C to go to signal point D. To go to point E, it is sent to signal points B and C.

The signal point B transmits a transmission permission signal including the information of the signal points C, D, and E to the signal route manager 350 when the signal link of the adjacent signal points C, D, and E managed by the signal point is activated. If the signal link is not activated, the transmission prohibition signal including the information of the signal points C, D, and E is transmitted to the signal route manager 350.

In addition, when the signal link of the adjacent signal points B, D, and E managed by the signal point C is activated, the signal point C transmits a transmission permission signal including the information of the signal points B, D, and E to the signal route manager 350. If the signal link is not activated, a transmission prohibition signal including information of signal points B, D, and E is transmitted to the signal route manager 350.

Then, the signal route manager 350 sets a route using signal route information registered in advance in response to the transmitted transmission permission signal or transmission inhibition signal.

However, in the conventional art as described above, the local station, the other station, and the signal link are generally visible to the network, so that the user does not have a big problem in registering. However, the signal route is effective depending on which other point is passed in the middle. However, since there is a difference in signal route management, input of an incorrect signal route has a problem in that a large problem occurs in network management.

In addition, when matching the network to No. 7, there was an inconvenience that the user had to register the load sharing and bypass route one by one by setting the route.

Accordingly, an object of the present invention is that a user must input a route to a destination other station as a load sharing purpose according to a change in network configuration, but a user who is unfamiliar with such a change of network or a user input for the purpose of effective load sharing. It is to provide the route setting method in No.7 signaling method that the software automatically loads the load by inputting signal point, other station signal point, adjacent signal point and signal link value.

1 is a diagram showing a network configuration.

2 is a diagram showing registration information input by a user for setting a conventional route.

3 is a block diagram schematically illustrating a configuration of a message transmitter layer 3. FIG.

4 is a diagram illustrating registration information input by a user for setting a route according to an exemplary embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

300: message transmission unit layer 3 310: data management unit

320: internal management unit 330: signal link management unit

340: signal link set management unit 350: signal route management unit

360: message distribution management unit

According to an aspect of the present invention to achieve the above objects, receiving and storing the registration information input by the user, determine and activate the signal link adjacent to the local point from the stored registration information, and the state of the other station In order to grasp, the RST message is generated and transmitted to an adjacent signal point to receive a transmission acceptance signal according to whether another station is activated from the adjacent signal point, and then a route is set using the value of the received transmission acceptance signal. A route setting method is provided in the No. 7 signal system characterized by the above-mentioned.

The registration information includes at least one of a local signal point, another station signal point, an adjacent signal point, and a signal link, and is directly input by a user in a monitor task.

In order to determine the state of the other station, the RST message is generated and transmitted to the adjacent signal point because the stored registration information has no information for load sharing or destination signal point. With the information, grasp the state of the other country.

If the signal link of the other station is activated in the step of receiving a transmission acceptance signal according to whether the other station is activated from the adjacent signal point, the transmission acceptance signal including the information of the other station is received, and the other station If the signal link of the point is not activated, the transmission prohibition signal including the information of the other station is received.

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

A network configuration shown in FIG. 1 and a message transmitter layer 3 shown in FIG. 3 will be described.

4 is a diagram illustrating registration information input by a user for setting a route according to an exemplary embodiment of the present invention.

The user must enter his own signal points, other station signal points, adjacent signal points, and signal links directly from the monitor task for routing purposes.

Referring to FIG. 4, in the network configuration of FIG. 1, a user inputs a local station signal point A in a monitor task 410, registers another station signal point, and an adjacent signal point 420. After inputting B, C, D, and E (S422), it is determined whether the other station signal point and the adjacent signal point are the same (S424). If it is determined in step 424 that the other station signal point is the same as the adjacent signal point, it is registered as an adjacent signal point (S426). If it is different from the adjacent signal point, it is input as the other station signal point (S428).

In addition, the user inputs a signal link and a signal link code (SLC) to be connected to an adjacent signal point in the monitor task in order to register the signal link (430). Input the signal link in the form of adjacent signal point = B, SLC = 0, sign signal point = C, SLC = 0, and so on.

The registration information input as described above is stored in the data management unit of the message transmitter layer 3.

Hereinafter, a method of setting a route using the registration information input by the user will be described with reference to the configuration of the message transmitter layer 3 of FIG. 3.

When operating the system, the internal manager 320 takes the information registered in the data manager 310 and transmits a signal link activation command to the signal link manager 330 to activate an adjacent signal link. The signal link manager 330 activates a signal link adjacent to the own point in response to the signal link activation command.

When the signal link adjacent to the own point is activated, the signal link manager 330 transmits the activation information of the activated signal link to the signal link set manager 340 to recognize that the other station signal point is adjacent to be activated. The activation information of the signal link is transmitted to the signal route manager 350.

The signal route manager 350 checks the state of the other station with the information of the other station and the adjacent signal point input by the user because there is no information to go to the load sharing or destination signal point. That is, the signal route management unit 350 transmits an RST message to the adjacent signal points B and C to check the state of the other station signal points D and E as the adjacent signal points. The RST message is sent to signal points B and C to go to signal point B, to signal points C and B to go to signal point C, and to B and C to go to signal point D, and to signal point E. Since the signal is sent to the signal points B and C, the RST message is transmitted to the signal points B and C to check the status of the other station signal points D and E.

In order to determine the state of the signal point D, the RST message transmitted to the signal points B and C determines whether the signal point D is in an activated state or an inactive state. In addition, the RST message transmitted to the signal points B and C to determine the state of the signal point E determines whether the signal point E is in an activated state or an inactive state.

The signal point B transmits a transmission permission signal including the information of the signal points C, D, and E to the signal route manager 350 when the signal link of the adjacent signal points C, D, and E managed by the signal point is activated. If not activated, the transmission prohibition signal including the information of the signal points C, D, and E is transmitted to the signal route management unit 350.

In addition, when the signal link of the adjacent signal points B, D, and E managed by the signal point C is activated, the signal point C transmits a transmission permission signal including the information of the signal points B, D, and E to the signal route manager 350. If the signal is not activated, the transmission prohibition signal including the information of the signal points B, D, and E is transmitted to the signal route management unit 350.

Then, the signal route management unit sets the route by looking at the values of the received transmission permission signal and the transmission inhibition signal. That is, the route is set for the signal point to which the transmission permission signal is transmitted, and the route is not set to the signal point to which the transmission prohibition signal is transmitted.

The present invention is not limited to the above embodiments, and many variations are possible by those skilled in the art within the spirit of the present invention.

As described above, according to the present invention, the signal common line No. 7 automatic route setting function allows the software to automatically find the signal route without setting the user's signal loop, thereby making it easier to provide a user with no network concept. The route setting method can be provided by the No.7 signal system that enables registration.

Claims (5)

Receiving and storing registration information input by a user; Determining and activating a signal link adjacent to a local point from the stored registration information; Generating and transmitting an RST message to an adjacent signal point to determine a state of another station; Receiving a transmission acceptance signal according to whether the other station is activated from the adjacent signal point; Establishing a route using the value of the received transmission acceptance signal; Route setting method in the No.7 signaling method comprising a. The method of claim 1, And the registration information comprises at least one of a local signal point, another station signal point, an adjacent signal point, and a signal link. The method according to claim 1 and 2, And the registration information is directly input by a user in a monitor task. The method of claim 1, Generating an RST message to a neighboring signal point in order to grasp the state of the other station does not include load sharing or destination signal point information in the stored registration information. Route setting method in the No.7 signaling method characterized by grasping the state of the other station with. The method of claim 1, If the signal link of the other station is activated in the step of receiving a transmission acceptance signal according to whether the other station is activated from the adjacent signal point, the transmission acceptance signal including the information of the other station is received, and the other station And if the signal link of the point is not activated, a transmission prohibition signal including information of the corresponding foreign point is received.