KR100386697B1 - Measurement method of load call control processor using call simulator - Google Patents

Abstract

The present invention relates to a call processing of a mobile communication system, and in particular, a call simulator capable of measuring a load of a call control processor through a simulator in order to accurately measure a call control processor load according to an amount of a call. A method for measuring a call control processor load using a method comprising: inputting system parameters for a control station environment currently operating in a call simulator, and in the simulator according to an originating call, an incoming call, an incoming call, and a handoff call. Determining a call type to be simulated, inputting a number of calls corresponding to the determined call type and an internal call interval, informing the call control processor of the start of the simulation by the call control processor, During call processing according to the call type between the simulators After performing a migration and, wherein the call handling simulation operation has ended a step of outputting a load result of the call control processors in accordance with the call processing operation.

Description

Load measurement method using call simulator {Measurement method of load call control processor using call simulator}

The present invention relates to a call processing of a mobile communication system, and in particular, to be suitable for measuring the load of a call control processor through a simulator in order to accurately measure the call control processor load according to the amount of calls. The present invention relates to a load measurement method of a call control processor using a call simulator.

In general, in mobile communication, a selector / vocoder card (hereinafter referred to as SVC) is provided in a base station controller (hereinafter referred to as BSC), which is used for call setup and call release. It is in charge of network coordination.

In addition, a plurality of DSPs are provided in a mobile communication system, and each of them executes its own data service program to process a generated call.

That is, the DSP processes pulse code modulation (hereinafter, referred to as PCM) packets for each channel.

Here, the communication method using the PCM is a method of converting an analog signal of 24 channels or 30 channels into a digital signal in one transmission path, and transmitting the same through a transmission path through sampling, quantization, and encoding.

In such a call control processor, the load that may occur on the call processing processor is measured in various ways.

Knowing the theoretical and actual load of the call control processor according to such measurements can improve the reliability of the mobile communication system.

However, until now, the method of measuring the load of the call control processor includes the tester measuring the load of the call control processor through the terminal by manual operation. Therefore, the test results for the load of the call control processor differ according to the tester's state. There was a problem that is difficult to detect.

An object of the present invention has been made in view of the above-mentioned problems of the prior art, the load of the call control processor through the call simulator (Simulator) for accurate measurement of the call control processor load according to the amount of calls An object of the present invention is to provide a method for measuring a call control processor load using a call simulator capable of measuring.

According to an aspect of the present invention for achieving the above object, the step of inputting the system parameters for the control station environment currently operating in the call simulator, and the call according to the originating call, incoming call, incoming and outgoing call and handoff Determining a call type to be simulated in the simulator, inputting a number of calls corresponding to the determined call type and an internal call interval, informing the call control processor of the start of the simulation by the call control processor; Performing a call processing task simulation according to the call type between a control processor and the simulator, and outputting a load result of the call control processor according to the call processing task when the call processing task simulation is completed.

Other objects, features and advantages of the present invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

1 is a flowchart illustrating a simulation process of a call control processor load according to the present invention.

Hereinafter, a configuration and an operation according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

In general, the call control processor of the base station controller needs to exchange call-related messages with the base station, the SVC, and the switching center in order to perform call processing.

In the present invention, the base station, the SVC, and the switching center for performing the call processing may be formed in a block form and placed as a counter part of the call control processor to perform call processing simulation of the call control processor regardless of whether the other sub system is driven. .

That is, the call control processor and the simulator correspond to 1: 1 to perform call processing. The simulator receives a user's request and generates a sub task for each call and a call according to the user's requirements. There are bcg_main0 and bcg_main1 for generating a shape, bcg_o and bcg_t blocks for generating an incoming call, and a transmission block for transmitting a corresponding message to the call control processor.

1 is a flowchart illustrating a simulation process of a call control processor load according to the present invention.

First, in order to drive a simulation for a test call in the call control processor simulator, first input a system parameter (S100). At this time, the system parameters are set according to the control station environment currently in operation. The parameter includes a control station address, a corresponding base station frame offset, and a usable frequency setting. For hand-off call testing, a neighbor base station list of a base station to be tested should be set. If the parameter is not set properly, an error occurs during call processing, and normal operation is impossible.

After the parameter input related to the simulation above, input the 'sim' command to inform the start of the simulation and select the desired arc type (S101).

Call types provided by the simulator include BCG simulation, timer BCG simulation, origination call, and termination call. The BCG simulation and the timer BCG simulation are basically the same as the arcs provided, but the BCG simulation ends when the user inputs a command, but the timer BCG simulation ends the simulation when the user arbitrarily set time elapses. The result is displayed.

The BCG simulation and the timer BCG simulation provide general calls, ie incoming or outgoing, incoming and outgoing and soft handoff or softer handoff calls.

The initiating call processes only messages that correspond to the calling party during the call processing procedure, and the ending call processes only messages that correspond to the called party.

After the simulation call type is selected, the simulated call number and the inter-call interval are input (S102). The inner call interval is the interval between the call and the next call, and the narrower the interval, the greater the number of calls that occur per unit time. The input ends and the simulation begins. The simulator transmits a SimMode_Req signal to the call control processor informing the start of the simulation.

The call control processor that receives the signal determines whether the received signal is a simulation call (S103).

As a result of the determination (S103), if the received signal is not a simulation call, a general call processing operation is performed (S104).

However, if the received signal is a simulation call (S103), the processor sets the call processing mode to the simulation mode in the caller (S105).

Calls arriving after the configuration are transmitted to the simulator rather than to the corresponding subsystem.

The call control processor transmits a SimMode_Rep signal to the simulator, which generates a task of the simulation call type selected by the user (S106).

The task transmits the same MobOrg_B2C signal to the call control processor as a message transmitted by the base station to the call control processor during call processing.

In addition, the response signal receives the MobOrgAck signal.

In actual call processing, the call control processor transmits the MobOrg_B2C signal to the base station and then transmits a VsTcLink signal to the SVC.

However, the call control processor having the call processing mode set to SimMode transmits the VsTcLink signal to the simulator to perform the call processing (S107).

In response to the signal, the call control processor receives the TcLinkAct signal and transmits a setup signal to the simulator (S108).

The call setup related message is as follows.

That is, the simulator distinguishes whether the user simulation request call type is an outgoing call or an outgoing call and transmits a CallPro signal to the call control processor when the call is an outgoing call.

In the case of an incoming / outgoing call, a paging message is sent to the call control processor. That is, in the case of an outgoing call only, the call processing performed at the called party is not involved.

The call control processor receiving the paging message determines the simulator as a receiving base station, transmits a PageMobReq signal, and receives a PageMobRsp signal in response to the transmission.

The PageMobRspAck signal is transmitted to the simulator in response to the signal.

As in the processing on the calling side, the VsTcLink message is sent to the simulator, and Tc_LinkAct is received in response. Receiving this message, the call control processor sends a Page_Rep to the switching center (MSC) in response to paging and receives a PageConf. Receiving this message, the call control processor sends an Alert message to the called party simulator and receives MobConn in response.

In addition, an alert message is sent to the destination simulator, and at the same time, an alert message (ALERTING) to be transmitted to the MSC0 is transmitted to the simulator.

Upon receiving the alerting message, the simulator sends the alerting message to the calling call control processor and receives the alerting message in response.

The called party call control processor also sends a connect message to the simulator in response to MobConn. Upon receiving the connection message, the simulator sends a connection message to the calling party call control processor, and sends a ConnectAck message in response to the connection message.

Upon receiving the Connect message from the calling party, the call control processor sends a MobConn message corresponding to the SVC message to the simulator, and sends a ConnectAck message corresponding to the exchange message to the simulator in response to the connection message.

As the call setup operation is performed by transmitting and receiving a call setup related message between the simulator and the call control processor, a call is produced according to an internal call interval which is a user input parameter.

Subsequently, when transmission and reception of the call setup-related message is completed, it is determined whether the handoff call is received (S109).

If it is determined in step S109 that the call is a handoff call, the call control processor and the simulator transmit and receive a handoff call establishment related message (S110 and S111).

When all of these call setups are completed or in the case of a general call, simulation is performed until the user stops the simulation or the set timer is completed. In the case of a handoff call, soft handoff or soft handoff processing is performed according to the user setup. .

Then, it is determined whether the user command or the set timer is completed (S112).

If it is determined that the user command or the set timer is not completed, the call processing execution operation continues (S106).

However, when the determination result (S112) the user's command or the set timer is completed, the simulation is terminated and the results thus far performed are output on the screen (S113).

The load measurement method of the call control processor using the call simulator according to the present invention has the following effects.

First, since the interworking of the subsystems (base station controller, selector / vocoder card (SVC) and switching center) necessary for call processing is unnecessary, call processing simulation is easy.

Second, the simulation can be run according to the call type (incoming call, originating call, incoming and outgoing call, and handoff call) that occurs, so that the load of the call control processor for each call type can be measured.

Third, the number of calls that reach the limit value of the call control processor, which is difficult to implement in general tests, can be obtained, thus preventing the system downtime due to the reaching of the limit value of the call control processor that may occur during the actual mobile communication system operation. .

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the examples, but should be defined by the claims.

Claims (4)

Inputting system parameters for the control station environment currently in operation into the call simulator; Determining a call type to be simulated by the simulator among outgoing calls, incoming calls, incoming and outgoing calls and handoffs; Inputting a number of calls corresponding to the determined call type and an internal call interval; The simulator informing the call control processor of the start of the simulation; Performing a call processing task simulation according to the call type between the call control processor and the simulator; And outputting a load result of the call control processor according to the call processing task when the call processing task simulation is terminated. delete The method of claim 1, wherein the call processing operation simulation according to the call type between the call control processor and the simulator comprises the steps of exchanging a call setup related message between the simulator and the call control processor, and the call type is a handoff call authorization. And determining, if the handoff call is a handoff call, exchanging the handoff setting related message between the simulator and the call control processor. Way. The method of claim 1, wherein the load of the call control processor is a load on a maximum limit of the call control processor or a load on a busy call attempt (BHCA). .