KR20010038967A - Resorce Load preventing method in base station controller of CDMA digital cellular system - Google Patents

Abstract

PURPOSE: A method for preventing a resource overload at a base station controller of a CDMA digital cellular system is provided to select an overload object on the basis of a control processor utilization rate and a call resource seizure rate for an overload control of a base station and a base station controller by suppressing the usage of an object generating an overload at the base station controller. CONSTITUTION: A driving part drives an overload monitoring processor after executing an initialization stage that sets up an overload determination threshold as a predefined value in a database embedded in a processor memory of a base station or a base station controller(S1-S3). An overload object selection part calculates a control processor utilization rate and a call resource seizure rate, compares the values with the overload threshold stored in the database and deducts the overload grades of a control processor and a call resource(S4,S5). The overload object selection part compares the overload grades and selects a candidate overload object having a higher overload grade as an overload object(S6).

Description

Resource overload prevention method in a base station controller of a CDA digital cellular system {Resorce Load preventing method in base station controller of CDMA digital cellular system}

The present invention relates to a CDMA digital cellular system. In particular, the present invention relates to an overload based on the utilization rate of a control processor and the occupancy rate of a call resource when controlling an overload of a control station and a base station by suppressing the use of an overloaded object in a control station of a CDMA digital cellular system. The present invention relates to a method for preventing resource overload in a base station controller of a CDMA digital cellular system for selecting a target.

In general, in the CDMA digital mobile communication system, when controlling the overload of a base station or a control station, the control processor or call resource is used as a criterion for overload determination and the occupancy rate of the call processor. The control station manager (BSM) is notified to allow the operator to know that a system overload has occurred.

In the conventional CDMA digital mobile communication system, when selecting an overload target when an overload occurs and entering control, it is determined by giving priority to any one of a control processor and a call resource.

That is, when priority is given to call resources, when overload occurs in both the control processor and the call resources, the priority is placed on the call resources. Therefore, even if the call resource occupancy is lower than the control processor utilization, the call resources are selected as an overload target. Overload control.

At this time, due to the overload of the control processor having a high utilization rate, the system may perform abnormal operation such as congestion, and as a result, call service may be interrupted, resulting in a lot of inconvenience and damage to service subscribers.

SUMMARY OF THE INVENTION The present invention has been made to solve such a conventional problem, and an object of the present invention is to solve a problem occurring in a conventional overload countermeasure system which prioritizes one of a control processor or a call resource. During the continuous overload monitoring process, the control processor utilization and the call resource occupancy were calculated, and the overload thresholds stored in the database were compared with the utilization and occupancy ratios. By comparing the overload level of the call resources and selecting the one with the highest level as the overload target, if it is determined to be overload, limit the call according to the overload class and notify the BSM of the overload grade and the overload target information so that the operator can know the data. Stored in the base It is possible to change the overload threshold to a desired value at any time, and to provide a method for allowing the value to be reflected in real time when selecting an overload target as soon as the operator changes the value.

1 is a block diagram for preventing resource overload of the present invention

2 is an operational flowchart of the present invention.

<Explanation of symbols for main parts of drawing>

1: drive unit 2: overload target selection unit

3: database section 4: overload processing section

5: Operator Requirements

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

1 is an overload control block diagram of the present invention, which is embedded in a base station or a control station processor and drives a process for initializing an overload-related database and periodically monitoring an overload condition when initially driven, and every cycle. After calculating the control processor utilization of the system and the occupancy rate of the call resources, calculate the overload rating based on the overload threshold stored in the database, and then select the overload target selection unit (2) to select the overload target, and store the latest overload threshold. A database unit 3, an overload processor 4 for determining whether the overload object selected by the overload object selector 2 and the overload class is overloaded, and performing an appropriate overload control operation; and the database unit ( 3) when the operator requests to change the overload threshold to the desired value at any time Performing operator comprises a requesting unit (5).

Referring to Figure 2 illustrates the operation of the present invention configured as described above.

First, the driving unit 1 drives the process of periodically monitoring the overload after performing an initialization process of setting the overload determination threshold to a predefined value in the database unit 3 embedded in the processor memory of the base station or the control station. (Steps S1-S3).

At this time, the overload monitoring process driven by the main process is repeatedly executed at regular intervals.

Next, the control processor utilization and the call resource occupancy rate are calculated for the control processor and the call resources that may be the cause of the overload, and these values are compared with the overload threshold stored in the database to derive the overload class of the control processor and the call resources. (Step S4, S5).

In the database section 3, the overload threshold is not a single value but has various values such as a normal overload threshold, a minimum overload threshold, a maximum overload threshold, and a critical overload threshold, and these values are independent of each other for the control processor and the call resource. It is stored in the database section 3 to have a value.

As a result, the overload rating derived in step S5 becomes normal, minimum, maximum and significant.

At this time, it should be noted that the use rate or occupancy is higher than the other candidate overload targets, so that the overload rating is not high.

Since the overload grade is determined by the threshold, if the threshold is set lower than the threshold of other candidate overload targets, it may have a high overload grade even if the utilization rate or occupancy is relatively low.

In addition, by comparing the overload ratings of the two candidate overload targets derived in step S5 to select a candidate overload target having a high overload rating as the overload target (step S6).

The system operator may request to change the overload threshold value stored in the database unit 3 to a desired value through the BSM, and the requested base station or control station system may change the existing value stored in the database and the value requested to change. If the values are different from each other, the database is updated (steps S10 to S12).

The updated overload threshold is reflected in real time in step S5 in which the overload monitoring process derives the overload rating of the candidate overload target.

On the other hand, the overload rating selected in step S6 is also notified to the BSM when a change in the system overload rating due to overload, if the rating is minimum, maximum, or significant.

In addition, the BSM is also notified when a change in the system overload rating is detected, as well as information on the overload target, the overload rating for the entire cycle, and the overload rating for the current cycle to the BSM. Make sure you know.

When the overload occurs in both the control processor and the call resources, and the overload grade is changed independently during system operation, the candidate with the high overload grade is selected as the overload target in the process of going through the steps S6 and S7. Since the change notification is made, the operator can easily know the current overload class and the overload target of the current system in the overload class change notification message, and based on this information, the overload control suitable for the current system can be performed.

If it is determined that the overload has occurred in step S7 the appropriate call restriction occurs according to the overload class (step S9).

As described above, according to the present invention, the system may malfunction due to the overload because the overload control can be performed at the latest and highest overload level by always obtaining a new overload class every time and selecting an overload target for each periodic overload monitoring process. Can reduce the likelihood of this to a minimum.

In addition, since the overload threshold can be set to a desired value in units of a control station or a base station, the operator can control the overload according to the characteristics of the place where each system is located in the uniformity in operating the system.

In addition, by notifying the BSM of the overload message, the highest overload class and the overload object of the class are notified together, so that the operator can know at a glance the current overload state of the system.

Claims (1)

A first step of driving a process of periodically monitoring an overload after performing an initialization process of setting an overload determination threshold to a predetermined value in a database unit embedded in processor memory of a base station or a control station, After the control processor utilization and the call resource occupancy are calculated for the control processor and the call resources that may be the cause of the overload, these values are compared with the overload threshold stored in the database to derive the overload class of the control processor and the call resources. Step 2, The system operator requests the BSM to change the overload threshold stored in the database to the desired value, and the requested base station or control system compares the value requested to change with the existing value stored in the database. The third step of updating the database, A fourth step of selecting a candidate overload target having a high overload rating as an overload target by comparing the overload classes of the two candidate overload targets derived in the second step; When the overload target is the current overload rating, the BSM is notified, and if it is determined that an overload has occurred, the base station controller of the CDA digital cellular system is configured to perform appropriate call restriction according to the overload rating. Prevention method.