KR100359809B1 - Method for call setup in mobile communication system - Google Patents

Abstract

TECHNICAL FIELD The present invention relates to mobile communications, and in particular, to a call setup method of a mobile communication system, which is adapted to efficiently perform call setup by allocating optimized power for a forward traffic channel. Such a call setup method of a mobile communication system according to the present invention comprises the steps of a base station receiving a channel transmission delay value and a call related parameter from an mobile station through an access channel, and the base station using the traffic channel gain determination table to transmit Allocating the traffic channel power according to the channel transmission delay value of each mobile station can increase the null traffic acquisition rate and call connection rate of the mobile station regardless of the mobile station's location and propagation environment.

Description

Method for call setup in mobile communication system

TECHNICAL FIELD The present invention relates to mobile communications, and in particular, to a call setup method of a mobile communication system, which is adapted to efficiently perform call setup by allocating optimized power for a forward traffic channel.

1 is a block diagram illustrating a conventional code division multiple access (CDMA) mobile communication system.

Referring to FIG. 1, a conventional mobile communication system includes a mobile station 100 that makes an origination request and an incoming response and performs a call setup procedure in association with a base station, and a base station that allocates a channel required for call setup by wirelessly connecting to the mobile station. 101, a control station 102 that controls the base station 101, and an exchange station 103 that performs location registration / retrieval, paging message generation, and call setup / release control for the mobile station.

2 is a flowchart illustrating a call setup procedure of the mobile communication system shown in FIG.

Referring to FIG. 2, the mobile station transmits an origination request and an incoming response to the base station through an access channel (S200, S201). Then, the base station transmits a reception response for the access channel of the mobile station through the paging channel (S202, S203), and transmits a call request and an incoming response of the mobile station to the control station (S204). The control station transmits the outgoing request and incoming response received to the switching center (S205), and the switching station transmits the connection request to the controlling station (S206). The base station and the control station then make a connection request and response to each other (S207).

At this time, the processor of the base station determines a traffic channel element that can be used after allocating channel resources such as Walsh code, frame offset, and vocoder. Subsequently, the processor of the base station determines parameters for initializing the traffic channel such as Walsh code, frame offset, long code, electric serial number (ESN), and initial traffic channel gain (Nominal TX gain). In step S208, the traffic channel assignment message is transmitted.

The traffic channel element then initializes the TX modulator using the parameters of the received traffic channel assignment message, allocates power of the forward traffic channel according to the received initial traffic channel gain, and then null traffic to the mobile station. Is transmitted (S209). This null traffic is meaningless data with a value of zero and the mobile station senses that the base station is waiting for a reverse traffic channel acquisition by receiving null traffic from the forward traffic channel.

At this time, the initial transmission power of the traffic channel is determined by the initial traffic channel gain (Nominal TX gain) received from the base station, and this value is fixed to a specific value (ie, 100). This initial traffic channel gain is a parameter for determining the power size of null traffic transmitted on the forward traffic channel, which may have a value from 0 to 127, but is assigned a fixed specific value in the conventional mobile communication system.

The forward null traffic channel power determined by this initial traffic channel gain is related to the base station forward capacity and the mobile station's forward null traffic acquisition rate. That is, the higher the forward null traffic power, the greater the mutual interference, so that the forward capacity of the base station is decreased and the null traffic acquisition rate of the mobile station is increased, while the lower the forward null traffic power, the lower the mutual interference, the lower the forward capacity of the base station. And the null traffic acquisition rate of the mobile station decreases.

Meanwhile, the base station transmits a traffic channel assignment message to the traffic channel element and then transmits a channel assignment message, which is traffic channel assignment information, to the mobile station through a paging channel so that the mobile station can set up forward and reverse traffic channels (S210, S211).

Then, the mobile station receives the channel assignment message, initializes the traffic mode, acquires the forward null traffic, and transmits a reverse preamble to the base station through the reverse traffic channel (S212).

After the base station acquires the reverse preamble through the assigned traffic channel, it determines the completion of setting up the forward and reverse traffic channels (S213). Subsequently, time synchronization is established between the traffic channel of the base station and the vocoder of the control station, and the wireless section between the base station and the control station is completed (S214).

When the forward and reverse traffic channels are established between the mobile station and the base station as described above, the vocoder and the mobile station of the control station exchange bs_ack / ms_ack messages and perform service option negotiation procedures to perform call setup procedures between the mobile station, the base station, the control station, and the switching station. Complete (S215, S216).

However, considering the call setup procedure of the conventional mobile communication system, the base station uses the traffic channel element as a traffic channel assignment message with parameters necessary for initialization of the traffic channel such as Walsh code, frame offset, long code, ESN and initial traffic channel gain. The same initial traffic channel gain is assigned to all mobile stations during the transmission.

As described above, since the initial traffic channel gain is related to the forward capacity of the base station and the null traffic acquisition rate of the mobile station, the forward capacity of the base station can be reduced when all mobile stations determine a value that is easy to obtain null traffic, whereas Considering that the reception rate of null traffic varies depending on the location and propagation environment in the base station, the mobile station may not be able to smoothly allocate the traffic channel by degrading the forward null traffic acquisition rate to the mobile station that needs an initial traffic channel gain above a fixed specific value. There is a problem.

Accordingly, an object of the present invention is to provide a call setup method of a mobile communication system that allocates traffic channel power optimized for the location and propagation environment of a mobile station, in view of the above-mentioned problems of the prior art.

According to an aspect of the present invention for achieving the above object, the base station receives a channel transmission delay value and a call-related parameter from the mobile station through an access channel, and the base station using the traffic channel gain determination table Allocating traffic channel power according to the channel transmission delay value of each mobile station transmitted.

Advantageously, the generation of the traffic channel gain determination table comprises the steps of: the base station setting the traffic channel gain to any particular value; collecting the call setup failure rate of the mobile station at the set particular value; Determining a channel transmission delay value before the call setup failure rate increases as a channel transmission delay value suitable for the set specific value, and constructing a traffic channel gain determination table using the determined channel transmission delay value and the set specific value It is made, including.

1 is a block diagram illustrating a conventional code division multiple access (CDMA) mobile communication system.

2 is a flowchart showing a call setup procedure of the mobile communication system shown in FIG.

3 is a flowchart illustrating a call setup method of a mobile communication system according to the present invention;

4 is a flowchart illustrating a procedure of generating an initial traffic channel gain determination table in accordance with 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.

The present invention proposes a call setup method of a mobile communication system for allocating an optimized traffic channel power according to a location and a propagation environment of a mobile station.

To this end, in the present invention, when the base station allocates forward null traffic power, the initial traffic channel gain is variably determined by using a round trip delay (RTD) of the mobile station.

In particular, the present invention generates an initial traffic channel gain determination table for each RTD at the time of initialization of the base station and makes a database to allocate different initial traffic channel gains for each RTD during call setup.

3 is a flowchart illustrating a call setup method of a mobile communication system according to the present invention.

Referring to FIG. 3, the mobile station transmits an origination request and an incoming response to the base station through an access channel. At this time, the access channel reports a round trip delay (RTD), which is a transmission delay value between the base station and the mobile station, to the base station (S300 and S301).

Then, the base station receives the mobile station's origination request and incoming response through the access channel, and then transmits a reception response for the access channel through the paging channel (S302, S303), and sends the mobile station's origination request and the control station to the control station. The incoming response is transmitted (S304). The control station transmits the received outgoing request and incoming response to the switching center (S305), and the switching center transmits the connection request to the controlling station (S306). The base station and the control station then make a connection request and response to each other (S307).

At this time, the processor of the base station determines a traffic channel element that can be used after allocating channel resources such as frame offset, traffic channel, and Walsh code. At this time, the base station stores the RTD reported by the mobile station in step S301 in an internal database of the call. The base station determines an initial traffic channel gain to be allocated to the RTD from the already generated initial traffic gain determination table for each RTD.

Subsequently, the processor of the base station determines parameters for initializing the traffic channel such as Walsh code, frame offset, long code, electric serial number (ESN), and initial traffic channel gain (Nominal TX gain). The traffic channel assignment message is transmitted (S308).

The traffic channel element then initializes a TX modulator using the parameters of the traffic channel assignment message, allocates power of the forward traffic channel according to the determined initial traffic channel gain, and then transmits null traffic to the mobile station. (S309).

Meanwhile, the base station transmits a traffic channel assignment message to the traffic channel element and then transmits a channel assignment message, which is traffic channel assignment information, to the mobile station through a paging channel so that the mobile station can set up forward and reverse traffic channels (S310, S311).

Then, the mobile station receives the channel assignment message, initializes the traffic mode, acquires the forward null traffic, and transmits a reverse preamble to the base station through the reverse traffic channel (S312).

After the base station acquires the reverse preamble through the assigned traffic channel, it determines the completion of setting up the forward and reverse traffic channels (S313). Subsequently, time synchronization is established between the traffic channel of the base station and the vocoder of the control station, and the wireless section connection between the base station and the control station is completed (S314).

When the forward and reverse traffic channels are established between the mobile station and the base station as described above, the vocoder and the mobile station of the control station exchange bs_ack / ms_ack messages and perform service option negotiation procedures to perform call setup procedures between the mobile station, the base station, the control station, and the switching station. Complete (S315, S316).

4 is a flowchart illustrating a procedure of generating an initial traffic channel gain determination table according to the present invention.

Referring to FIG. 4, the RTD is a value calculated in the access channel in the transmission request and the incoming response of the mobile station and represents a channel transmission delay between the base station and the mobile station.

The RTD value can be used to measure the distance between the mobile station and the base station. Also, the power received by the mobile station is inversely proportional to the N square of the distance (N: 3 to 5). The correlation between the forward null traffic acquisition rates can be estimated.

Therefore, the initial traffic channel gain determination according to the RTD is determined by collecting the statistics of the forward null traffic acquisition rate of the mobile station for each RTD while changing the initial traffic channel gain.

At this time, the base station analyzes the result of the statistics collection and databases the initial traffic channel gain decision table for each RTD. The initial traffic channel gain determination table is used to determine the initial traffic channel gain to be allocated in the mobile station's origination request and incoming response.

This initial traffic channel gain determination table is generated according to the following procedure.

First, the base station allocates the initial traffic channel gain to an arbitrary specific value (S400). Then, the base station collects the call setup failure rate due to the failure to acquire the forward null traffic for each RTD (S401).

Subsequently, when the initial traffic channel gain is a specific value set in step S400, the RTD immediately before the forward null traffic acquisition failure rate is increased is selected (S402).

In operation S403, an initial traffic channel gain determination table is generated using the selected RTD and the assigned specific value.

Subsequently, the base station increases the assigned specific value by a predetermined amount (S404), and repeats the steps (S401 to S403) to generate an initial traffic channel gain determination table. In this case, the gain increase value is an increase value for determining one initial traffic channel gain value optimized for RTDs having values of a predetermined interval. Therefore, the initial traffic channel gain decision table determines the optimized initial traffic channel gain value for a certain period of RTDs without determining the optimized initial traffic channel gain value for all the RTDs.

Table 1 below is an example of the initial traffic channel gain determination table.

RTD Optimal Initial Traffic Channel Gain RTD Optimal Initial Traffic Channel Gain 0-100 40 601-700 80 101-200 50 701-800 85 201 to 300 60 801 to 900 90 401-500 70 ..... .. 501-600 75 65535 100

As described above, the call setup method of the mobile communication system according to the present invention has the following effects by variably allocating the fixed traffic channel power according to the position of the mobile station when the null traffic is transmitted.

First, the null traffic acquisition rate of the mobile station increases regardless of the location and propagation environment of the mobile station.

Second, the call connection rate of the mobile station increases.

Third, base station forward capacity is increased by not assigning excess transmit power during null traffic transmission.

Claims (3)

Receiving, from the mobile station, a channel transmission delay value and a call related parameter through an access channel by the base station; And the base station allocating traffic power according to channel transmission delay values of the respective mobile stations using the traffic channel gain determination table. The method of claim 1, wherein the generation of the traffic channel gain determination table, Setting, by the base station, the traffic channel gain to any particular value; Collecting a call setup failure rate of the mobile station at the set specific value; Determining a channel transmission delay value before the collected call establishment failure rate increases as a channel transmission delay value suitable for the set specific value; And constructing a traffic channel gain determination table using the determined channel transmission delay value and the set specific value. The method of claim 2, wherein the base station determines a representative value of the traffic channel gains for channel transmission delay values having a predetermined interval by increasing the set specific value.