KR0170196B1 - Overload control method of digital mobile communication network service control point - Google Patents

Abstract

The present invention relates to an overload control method for a digital mobile communication network service control point. The present invention relates to an overload control method for a digital mobile communication network service control point, comprising: a first process of obtaining a call processing request message from a network interface and an input message number per unit time; If it is determined that the process is positive in the second process and the second process, the call processing request message is sent to a call processing application program, and if it is determined that the process is not positive in the second process, the call processing request message is discarded. Including the third process, by using a small amount of control data, the call processing request message, which is the input of the system, is kept below the limit per unit time and the excess message is blocked to protect the system from an overload situation to ensure the stability of the system. Can be out of service during traffic congestion It is suitable for services such as PCS, UPT, etc., where one damage will be catastrophic or a large number of subscribers.

Description

High Load Control Method of Digital Mobile Network Service Control Point

1 is a schematic diagram of the overload control function proposed in the present invention.

2 is a flow chart of the shared control data access method of the NIO (5) during network input and output.

3 is a flowchart of a shared control data access method of a timer.

4 is a flow chart of a method for generating unit time within a tolerance range.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for overload control of a digital mobile communication network service control point. In particular, the present invention relates to a service control point such as a location register of a digital mobile communication system to protect a system from traffic congestion with only a small amount of shared data. An overload control method of a digital mobile communication network service control point for counting an input call processing request message to perform the call processing request message only when the number of input messages per unit time is positive.

In general, a service control point (hereinafter referred to as SCP), such as a home location register (HLR) in a digital mobile communication system, is referred to as a mobile switching center (MSC). It provides information necessary for call processing through information exchange with other objects in the digital mobile communication network.

However, if network traffic congestion occurs due to congestion, large call interruptions may occur due to the exhaustion of SCP call processing resources associated with multiple MSCs.

In order to prevent this situation, SCP needs overload control function. In particular, overload control in overload condition should perform the desired function with minimum resources so as not to worsen the system overload condition.

An object of the present invention for solving the above problems is to provide an overload control method of a digital mobile communication network service control point that protects the system from overload by using only a small amount of system resources in an overload condition without affecting the processing capability of the SCP. .

In order to achieve the above object, an aspect of the present invention provides an overload control method of a digital mobile communication network service control point, comprising: a first process of obtaining a call processing request message from a network interface; and a second process of determining whether the number of input messages per unit time is positive; When the determination result of the second process, the number of input messages is positive. And a fourth step of discarding the call processing request message when the number of input messages is negative as a result of the determination of the third process and the second process of sending the call processing request message to the call processing application program.

Another object of the present invention for achieving the above object is to set the number of input messages per unit time as the allowable message value per unit time in the method for accessing the shared control data of the timer of the digital mobile communication network service control point. .

According to still another aspect of the present invention, there is provided a method for generating a unit time within an allowable error range in a digital mobile communication network service control point, wherein the unit time t is divided into n sections to form n sync points. And a second step of determining a time delay value for reaching the next sync point by calculating a difference from the actual time after attempting a time delay by t / n each time.

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

FIG. 1 is a configuration diagram of an overload control function proposed by the present invention. Referring to FIG. 1, a configuration of a service control point 1 that communicates with the network medium 7 includes the network medium 7 and a service control point ( A network input / output (hereinafter referred to as NIO) 5 for performing the interface of 1), a call processing application 6 for transmitting and receiving call processing information through the NIO 5, and shared control. Timer that resets the allowable messages per unit time (3) and the input messages per unit time (4), and the input messages per unit time (4) to the allowable messages per unit time (3) periodically per unit time. It consists of (2).

At this time, the NIO 5 counts the number of call processing request messages input from the network medium 7 to the service control point 1 for a unit time, and sends the call processing request message to the call processing application program. Each delivery reduces the number of input messages (5) per unit time.

At this time, if the number of input messages per unit time 4 is negative, the call processing request message is discarded without being delivered to the call processing application.

On the other hand, the number of allowed messages per unit time (3) is a value that is dynamically determined according to the load state of the system measured during the unit time, and refers to the number of call processing request messages that can be processed by the call processing application. The number of input messages per unit time 4 refers to the number of call processing request messages transmitted to the call processing application by the NIO 5 in a unit time interval.

In order to implement the method for controlling the overload by such a configuration, a timer configuration capable of generating a unit time within a tolerance range and a shared control data access algorithm of the NIO 5 and the timer 2 is required. This is illustrated in FIGS. First, FIG. 2 is a flowchart of a method of accessing shared control data by the NIO 5 during network input / output. Referring to FIG. 2, the method of accessing shared control data by the NIO 5 during network input / output is as follows.

First, the NIO 5 obtains a call processing request message from the network medium 7 (s11), determines whether the number of input messages 4 per unit time of the shared control data is positive (s12), and determines the above (s12). As a result, if the number of input messages 4 per unit time is positive, the input call processing request message is transmitted to the call processing application 6 of FIG. 1 (s13), and as a result of the determination (s12), the input message per unit time If the number 4 is zero or negative, the input call processing request message is discarded (s14). If the call processing request message is delivered to the call processing application program as described above (s13) or discarded (s14), the number of input messages 4 per unit time is reduced by one.

At this time, since the timer 2 resets the number of input messages 4 per unit time periodically to the number of allowable messages 3 per unit time, the call processing request of the number of allowable messages 3 per unit time per unit time interval is requested. Only the message is passed to the call processing application 6 and the excess call processing request message is discarded. When the number of input messages 4 per unit time is negative at the last minute of the unit time interval, the number of messages discarded in the unit time interval becomes an absolute value of the number of input messages 4 per unit time.

FIG. 3 is a flowchart of a method of accessing a shared control data of a timer. Referring to FIG. 3, a method of accessing a shared control data of a timer is described. Referring to FIG. 3, the timer 2 uses the number of input messages 4 per unit time once per unit time. To set the number of allowed messages per hour (3), first, a time delay (s21) is performed for a unit time (s21), and the number of input messages (4) per unit time is reset to the number of allowed messages (3) per unit time. Repeat the process (s22).

At this time, the NIO 5 can deliver the call processing request message to the call processing application only when the number of input messages per unit time (4) is reset to the number of allowed messages per unit time (3) by the timer. In order for the request message to be input in the unit time interval, the precision of the unit time generated by the timer 2 must be maintained within the tolerance range. A flowchart of the unit time generation method within the tolerance range is shown in FIG. have.

Referring to FIG. 4, the method of generating the unit time within the tolerance range is as follows.

First, the unit time t is divided into n intervals to form n sync points, and after each time t / n time delay is attempted, an appropriate time for reaching the next sync point by calculating a difference from the actual time is calculated. Determine the delay value.

Repeating the above process n times yields a unit time having an error range of t / n.

That is, in order to generate the unit time in the tolerance range as described above, s (i) is initialized (s31) as shown in equation (I) by using the value obtained by dividing the unit time t by the number of synchronization n.

That is, n sync points are formed by dividing the unit time t into n sections.

Then, the current time is assigned to an arbitrary variable X and 0 is assigned to i (s32).

Then, a time delay (s33) is performed by (t / n), the time at that time is substituted into the variable Y (s34), and the time delay value z for reaching the next sync point is obtained. In order to substitute the above X and Y into (Equation 2) (s35).

((X + s (i + 1))-Y)

When the Z value is obtained as described above, a time delay (s) (s36) is delayed by (t / n) + Z, i is increased by 1 (s37), and it is determined whether the i value is larger than (n-1) ( s38).

As a result of the determination (s38), if i is greater than (n-1), the process proceeds to S32. If i is not greater than (n-1), the process proceeds to S34 until i is greater than (n-1). .

In this way, the unit time within the tolerance range is generated.

Therefore, the present invention as described above, by using a small amount of control data to keep the call processing request message, which is the input of the system below the limit per second and to block the excess messages to protect the system in the overload situation to ensure the stability of the system This makes it suitable for communication systems such as PCS and UPT, which will accommodate a large number of subscribers or a communication system where the damage caused by service failure during traffic congestion is fatal.

Claims (3)

A network input / output (NIO) that interfaces with a network medium, a call processing application program that transmits and receives call processing information through the network input / output (NIO), the number of allowed messages per unit time and the number of input messages per unit time, which are shared control data. And a timer for resetting the number of input messages per unit time periodically to a value of the number of allowable messages per unit time in a unit time, wherein the call is transmitted from a network medium. A first step of obtaining a processing request message; A second step of determining whether the number of input messages per unit time of the call processing request message inputted to the network input / output is positive in the first step; If it is determined that the number of input messages per unit time is positive in the second process, the network input / output sends the call processing request message to a call processing application program, and if it is determined that the number of input messages per unit time is not positive in the second process, And an input / output step of discarding the call processing request message. The method of claim 1, further comprising a fifth process of reducing the number of input messages per unit time by one after performing the third process and proceeding to the first process. . A network input / output (NIO) that interfaces with a network medium, a call processing application program that transmits and receives call processing information through the network input / output (NIO), the number of allowable messages per unit time and the number of input messages per unit time as shared control data. And a timer for resetting the number of input messages per unit time periodically to an allowable number of messages per unit time period, wherein the unit time t is generated within a tolerance range at a control point of a digital mobile communication network. a first step of forming n sync points by dividing into n sections; And a second step of determining a time delay value for reaching a next synchronization point by calculating a difference with the actual time after attempting a time delay by t / n each time, and performing the first process after performing the second process. And proceeding with the process, and repeating the first process and the second process by a predetermined number of times in order to generate unit time within a predetermined error range.