KR100551172B1 - Method for collecting statistic data in mobile communication system - Google Patents

Abstract

The present invention provides a method for collecting statistical data of a mobile communication system. The present invention provides a first processor that requires data on an operating system of a system and a second processor that provides data to the first processor, respectively. Checking the time provided by the system periodically while performing predetermined operations of the device to determine whether the predetermined time has come; The first processor waits for a time for the second processor to update data in a database when a predetermined time arrives, and the second processor unconditionally counts data in a predetermined region of the database when the predetermined time arrives. Updating the database with a database; The first processor selects, collects, and processes updated data in the database, thereby independently writing a program of the processors, lowering the possibility of error, and disappearing signals from one processor to many processors. The traffic load on the communication can be reduced.

Description

Method for collecting statistic data in mobile communication system

1 is a schematic configuration diagram of a general mobile communication system,

2 is a flowchart illustrating a method of collecting statistical data of a conventional mobile communication system.

3 is a flowchart illustrating a method of collecting statistical data in a mobile communication system according to the present invention.

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

1 terminal 2 base station

3: control station 4: switching station

5: home location register 11: the first processor

12: second processor 13: database

The present invention relates to a method for collecting statistical data in a mobile communication system, and in particular, a conventional synchronization method by exchanging a signal between a processor for updating a database in statistics and a processor for collecting and utilizing the data in a manner not using a signal signal. Instead, it relates to a method for facilitating independent project execution and debugging of each block and reducing communication load.

In general, a mobile communication system is a communication system for a mobile device such as a person, a car, a ship, a train, an aircraft, and includes a mobile phone (mobile phone, a vehicle phone), a port phone, an aircraft phone, a mobile public phone (train, Cruise ships, express buses, etc.), radio calling, radiotelephony, satellite mobile communication, amateur radio, fishing service.

These mobile communications include the Advanced Mobile Phone Service (AMPS) system using analog methods, CDMA and TDMA (Time Division Multiple Access) systems using digital methods, and Frequency Division Multiple Access (FDMA) systems. System, etc.

1 is a block diagram of a general mobile communication system.

As shown therein, a terminal (1), which is a terminal device that enables a subscriber to communicate through a mobile communication network by selectively or simultaneously supporting a service of an AMPS system and a service of a CDMA system; A base station 2 for communicating with the terminal 1 using a protocol defined in IS-95 in a wireless section; A control station (3) which controls the radio link and the wire link and performs a handoff function for maintaining the continuity of the call even when the subscriber is moving; An exchange station (4) which constitutes a subscriber's communication path and performs connection with another communication network; Subscriber information is entered and consists of a home location register (5) or the like that communicates with the switching center (4). Through the base station 2, the control station 3, and the switching station 4, the call of the terminal 1 is realized.

As with such a mobile communication system, the present invention is applicable to a communication system for transferring and collecting data without using a signal signal between processors accessing a database when exchanging data between multiple processors.

2 is a flowchart illustrating a method of collecting statistical data of a conventional mobile communication system.

Thus, when the first processor 11, which needs data on the system operating system, sends signals to the various second processors 12 in a signal manner used on the Unix operating system to obtain data from the processors providing the data ( ST1 to ST4), and the plurality of second processors 12 update their own values in their respective database 13 areas (ST11 to ST13). Then, the first processor 11 collects and processes data from the database 13 (ST5).

However, some of these updating second processors 12 do not need a signal and must signal it separately. If you send a signal to a processor you don't need, the processor will die. In addition, if the name or number of the second processor changes, there is also the inconvenience that the program of the first processor must also be changed.

Meanwhile, when a program for the first processor 11 collecting data is prepared, accurate update data of the second processor 12 is required in order to determine the accuracy of data collected and processed by the program.

Therefore, if the operation of the portion of the second processor 12 is incomplete, there is a problem that it is difficult to check the program accuracy of the first processor (11).

Accordingly, the present invention has been proposed to solve the above-mentioned conventional problems, and an object of the present invention is to provide a conventional synchronization method by exchanging signals between a processor for updating a database in statistics and a processor for collecting and utilizing the data. Signal The present invention provides a method of collecting statistical data of a mobile communication system that can be replaced by a method that does not use a signal, thereby facilitating independent project execution and debugging of each block and reducing communication load.

Statistical data collection method of the mobile communication system according to the present invention to achieve the above object,

The first processor that requires data on the operating system of the system and the second processor that provides data to the first processor periodically check the time provided by the system while performing their specified operations to determine whether the time has been reached. Making a step; The first processor waits for a time for the second processor to update data in a database when a predetermined time arrives, and the second processor unconditionally counts data in a predetermined region of the database when the predetermined time arrives. Updating the database with a database; The technical characteristics of the first processor may include selecting, collecting, and processing data updated in the database.

Hereinafter, with reference to the accompanying drawings an embodiment according to the technical idea of the method for collecting statistical data of the present invention as described above in detail.

In the conventional method, the first processor 11 which collects data continuously checks the time while continuously looping in an infinite loop, and when it is time to collect and process the data, the current method is located in a directory called 'proc' under the root of the system. Take a running processor ID and compare it with your list of processors.

At this time, if the current processor ID and its own list are the same, the first process sends a signal 'kill' to update the data value counted by the running second process to a predetermined area of the database 13. .

Then, the second processor 12 periodically checks whether the signal has arrived from the first processor 11, and when the signal arrives, the second processor 12 updates its own data value to the determined database 13.

When the update operation is completed, the first processor selects the data and performs its own task.

However, this signal transmission causes some problems.

One is that the first processor 11 sending the signal collects the processor IDs and compares these IDs with the list they have. In addition, when the name or number of the second processor 12 is changed, the first processor 11 may send a signal to a completely different place, and sometimes the signal is transmitted to a processor that does not need the signal. The processor will stop working.

The other is that if the program of the first processor 11 is written and debugging is performed to check the error, whether the signal arrives correctly at the second processor 12 and the data value sent by the second processor 12 Since the second processor 12 needs to be assisted to check the correctness of the first processor 11, it is difficult to perform a completely independent operation of the first processor 11.

Synchronous methods using these signals can be overcome by using the sleep function provided by Unix.

Therefore, in the operating method of the first processor 11 of FIG. 2, the above problem can be solved by using the sleep () function instead of collecting the processor ID, checking the processor list and transmitting the signal.

The sleep function is a function that temporarily waits for the operation of the processor for a given time. Instead of the first processor 11 sending a signal to each of the second processors 12, the second processor is based on a predetermined time of the system. (12) performs an update on each database 13 area unconditionally determined irrespective of the signal of the first processor 11. Since this update process takes about 10 seconds, the first processor 11 waits a sufficient time of about 15 seconds using the function sleep (20);

After 20 seconds, the first processor 11 performs a predetermined operation with the value updated by the second processor 12.

3 is a flowchart illustrating a method of collecting statistical data in a mobile communication system according to the present invention.

As shown therein, the first processor 11 requiring data on the operating system of the system and the second processor 12 providing data to the first processor 11 each perform their own predetermined operations. Checking the time provided by the system to determine whether a predetermined time is reached (ST21) (ST31) and ST32; When the first processor 11 reaches a predetermined time, the second processor 12 waits for a time to update data in the database 13, and when the second processor 12 reaches the predetermined time, the database unconditionally Updating the data counted by the second processor (12) in the database in the predetermined area (ST22) (ST33); The first processor 11 selects, collects, and processes updated data in the database 13 (ST23).

Referring to the operation of the present invention configured as described in detail as follows.

First, the first processor 11 and the second processor 12 periodically checks the time provided by the system while performing their own predetermined operations. The time check can extract the current time by using a function provided by Unix called time (); and at the first time when the minute unit is divided into 5 minutes, the first processor 11 and the second processor (12) starts the operation at a time.

For example, it can be set to 5, 10, 15, 20 minutes and the like. When the check time reaches a predetermined time, the first processor 11 includes a sleep 20; The function is used to pause its operation for 15 seconds. At this time, the second processors 12 unconditionally update the values they counted in a predetermined area of the database regardless of whether the signal from the first processor 11 is present.

When the update operation of the second processors 12 is completed, the first processor 11 wakes up from sleep after a while, selects data values updated by the second processors 12 in a predetermined order, processes the data, and selects other data values. It is passed to the processor.

This facilitates the independent project execution and debugging of each block and reduces the communication load.

Although the preferred embodiment of the present invention has been described above, the present invention may use various changes, modifications, and equivalents. It is clear that the present invention can be applied in the same manner by appropriately modifying the above embodiments. Accordingly, the above description does not limit the scope of the invention as defined by the limitations of the following claims.

As described above, the statistical data collection method of the mobile communication system according to the present invention is a sleep () instead of using a synchronization method using a signal between processors; Functions can be written independently by eliminating the behavior that affects each other's operation, and by reducing the possibility of error, by reducing the development time of the program. It can be effective.

In addition, the present invention also has the effect of reducing the traffic load on the communication by increasing the system speed by disappearing the signal sent from the first processor to a number of processors.

Claims (1)

In the statistical data collection method of the mobile communication system, The first processor that requires data on the operating system of the system and the second processor that provides data to the first processor periodically check the time provided by the system while performing their specified operations to determine whether the time has been reached. Making a step; The first processor waits for a time for the second processor to update data in a database when a predetermined time arrives, and the second processor unconditionally counts data in a predetermined region of the database when the predetermined time arrives. Updating the database with a database; And the first processor selects, collects, and processes the data updated in the database.

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