KR100545254B1 - Management method of transmission rate for packet channel in CDMA System - Google Patents

Abstract

The present invention relates to a data channel transmission rate operating method of a mobile communication system.

According to the present invention, when providing various types of wireless services to a plurality of mobile stations in a CDMA mobile communication system, power control is performed in consideration of system resources and a wireless channel environment, FCH (Dedicated Control CHannel), DCCH, Efficiently adjust the forward link data channel transmission speed of the physical layer by the power of the traffic channel including SCH (Supplemental CHannel), the remaining sector power and the amount of packet data,

Accordingly, the RLP throughput of the base station sector is improved by reducing the frame error rate of the forward link, and the packet data amount is reported at every upper period, and the transmission rate of the physical layer is determined to fill the fill frame. There is an advantage that can prevent the degradation.

CDMA, mobile communication system, mobile station, data channel, traffic channel, channel transmission rate

Description

Operation method of data channel transmission rate in mobile communication system {Management method of transmission rate for packet channel in CDMA System}             

1 is a block diagram illustrating an access network of a mobile communication system;

2 is a flowchart illustrating a data channel transmission rate operating method of a mobile communication system according to the present invention;

3 is a graph comparing a radio frame error rate for a mobile communication system and an existing system to which the present invention is applied;

4 is a graph comparing radio resource waste and RLP throughput in a mobile communication system and an existing system to which the present invention is applied.

<Explanation of symbols for main parts of the drawings>

10: PDSN interface unit 11: PCF

12: SDU 13: Channel Card

14: IF processor 15: RF converter

16: power amplifier 17: MSC switch

18: Vocoder 19: Base Station Main Processor

20: call control processor 21: call control / movement manager

The present invention relates to a mobile communication system, and more particularly, to a data channel transmission rate operating method of a mobile communication system for efficiently adjusting the forward link data channel transmission speed of a physical layer in a CDMA mobile communication system.

In the conventional CDMA mobile communication system, the data channel transmission rate of the forward link is determined only by the amount of packet data without considering the system resources and the radio channel environment. Recently, RF scheduling is performed by considering only the system resource and the radio channel environment. The technology for determining the data channel transmission rate is being developed.

However, as described above, the method of determining the data channel transmission rate of the forward link based on the packet data amount does not perform RF scheduling in consideration of system resources and radio channel environment, resulting in a high frame error rate in the radio period, thereby increasing the RLP of the base station sector. Radio Link Protocol) When throughput is lowered and there are a plurality of users in the system, call blocking occurs frequently.

In addition, as described above, the method of determining the data channel transmission rate of the forward link by considering only the system resources and the wireless channel environment has an advantage of lowering the frame error rate in the radio section due to RF scheduling, but does not consider the amount of packet data. Since there is a disadvantage in that the random data is filled in the physical layer frame and transmitted, the radio resources are inefficiently used, and thus, the RLP throughput is still lowered.

Accordingly, an object of the present invention is to overcome the above-described problems, and an object of the present invention is to provide power control in consideration of system resources and a wireless channel environment when various types of wireless services are provided to a plurality of mobile stations in a CDMA mobile communication system. The forward link data channel transmission rate of the physical layer is determined by the power of the traffic channel including the Fundamental Traffic Channel (FCH), Dedicated Control CHannel (DCCH), and Supplemental CHannel (SCH), and the remaining sector power and the amount of packet data. To provide a method for operating a data channel transmission rate of a mobile communication system to efficiently adjust the speed.

In order to achieve the object of the present invention, a data channel transmission rate operating method of a mobile communication system includes a SCH allocation period in which a base station main processor interfacing with an SDU, a channel card, and a call control processor included in an access network of the mobile communication system. In SCH_DURATION, the power of the basic traffic channel (FCH) in which power control is performed in units of the reference time (Ts) from the channel card and the SCH transmission power are inputted, and the specific time (T1) is divided by the reference time (Ts) for each sector. Accumulating for a corresponding number of times (T1 / Ts) and obtaining an average value for this constant cumulative number of times (T1 / Ts) for each channel; Calculating, by the base station main processor, SCH assignable sector power using average power for each channel in use, which is received for each sector at a specific time T1; Determining, by the base station main processor, that a traffic channel has been transmitted during a previous SCH allocation period (SCH_DURATION); Determining, by the base station main processor, if a traffic channel has been transmitted, whether a SCH, which is a data transmission channel, has not been transmitted during a previous SCH allocation period (SCH_DURATION) (DTX; Dis-continuous Transmission); Allocating, by the base station main processor, a specific initial SCH transmission rate preset if the traffic channel has not been transmitted; Calculating, by the base station main processor, the SCH power at the basic transmission rate by using the 1x FCH power if the SCH was not transmitted before the SCH allocation time (DTX); Calculating the SCH power of the basic transmission rate using the previously transmitted SCH power if the SCH was transmitted before the SCH allocation time; After calculating the SCH power of the basic transmission rate, determining, by the base station main processor, a wireless SCH transmission rate using a power ratio obtained by dividing the available sector power by the SCH power of the basic transmission rate; And comparing the data transmission rate by the wireless SCH transmission rate with the amount of packet data delivered in the SDU, or comparing the initial SCH transmission rate and the data transmission rate by the amount of packet data delivered in the SDU, and transmitting a small value to the final SCH. Characterized in that it consists of a step of determining the speed.

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

Referring to FIG. 1, a PCF (Packet Control Function) 11 of an access network of a mobile communication system to which a data channel transmission rate operating method of the mobile communication system is applied is a PDSN interface unit 10 serving as a packet network access interface 10. It is a switch function that connects packet data to packet network through.

The SDU (Selection & Distribution Unit) 12 functions to generate voice traffic and packet traffic, and to select a base station having better reception performance when the reverse traffic channel is in a soft handoff situation. If applicable, serves to generate the SCH packet according to the SCH transmission rate information generated by the following base station main processor (BMP) 19 and informs the base station main processor 19 of the packet rate.

The channel card 13 is a baseband processor and is responsible for baseband modulation and demodulation by an embedded modem, and is responsible for channel coding, modulation and demodulation, spreading and despreading, and power control of a traffic channel.

The IF processor 14 converts the digital baseband signal into an analog signal of intermediate frequency IF.

The RF converter 15 adjusts the frequency up to the carrier frequency assigned to the wireless carrier.

The power amplifier 16 amplifies the RF signal.

The MSC switch 17 connects the voice traffic passing through the lower Vocoder 18 to another MSC or PSTN.

The vocoder 18 compresses and converts an analog audio waveform into a digital signal in the forward direction, and converts the digital signal into an analog signal in the reverse direction.

The base station main processor 19 manages the resources of the channel card 13 and is responsible for receiving and processing call allocation and call processing messages from the call control processor 20 below, and in particular, the mobile communication system of the present invention. It manages data channel transmission rate operation method.

The call control processor 20 interfaces with the SDU 12 and the base station main processor 19 in connection with call processing and generates a call processing related signaling message.

The call control / mobile manager 21 processes the information according to the movement of the mobile station and the call processing related information in the MSC.

In the access network of the mobile communication system configured as described above, data is transmitted from the PDSN interface unit 10, the PCF 11, the SDU 12, the channel card 13, the IF processor 14, and the RF converter in the packet network. 15), the power amplifier 16, the antenna (ANT) is transmitted to the mobile station, the voice signal is MSC switch 17, vocoder 18, SDU 12, channel card 13, IF processor of the mobile exchange. 14, the RF converter 15, the power amplifier 16, and the antenna ANT are transmitted to the mobile station.

At this time, the base station main processor 19 of the base station (BTS) is responsible for call processing, and adjusts the channel card 13, the call control processor 20 of the base station controller (BSC) is responsible for call processing and the SDU 12 Interface with the base station main processor 19 and interface with the call control / mobile manager 21 of the mobile switching center.

In addition, the base station main processor 19 applies a data channel transmission rate operating method of a mobile communication system according to the present invention applied to a data dedicated channel (SCH) conforming to the IS-2000 standard, which is a wireless standard scheme of a TIA / EIA apparatus. In order to interface with the SDU 12, the channel card 13 and the call control processor 20.

When the channel card 13 delivers the power for each channel received from the internal modem to the base station main processor 19 at a reference time (Ts) period, the base station main processor 19 performs the call control processor at every reference time (Ts) period. And the SCH transmission message when the call control processor 20 transmits an SCH request message together with packet data amount information when there is a packet to be transmitted in a specific SCH transmission interval (SCH_DURATION). Send to processor 20.

In addition, the call control processor 20 transmits the SCH transmission rate information received from the base station main processor 19 to the SDU 12 of the base station controller (BSC) so that the SDU 12 satisfies the data rate of the SCH. Create a packet frame.

At this time, the SDU 12, which has created an SCH packet frame, transfers an ESCAM message having information on the SCH to be assigned to the channel card 13, so that the channel card 13 transmits the message to the mobile station, and the base station (BTS). ) Receives an ACK message for the ESCAM message from the mobile station, the SDU 12 of the base station controller (BSC) transmits a SCH service data unit to the channel card 13.

The access network of the mobile communication terminal system according to the present invention configured as described above operates as follows by the method shown in FIG.

Initially, the base station main processor 19 receives the power of the basic traffic channel (FCH) and the SCH transmission power for which power control is performed in units of a reference time Ts from the channel card 13 in the SCH allocation period (SCH_DURATION). The base station main processor 19 accumulates the power of the basic traffic channel (FCH) and the SCH transmission power for the number of times (T1 / Ts) corresponding to a value obtained by dividing a specific time T1 by the reference time Ts for each sector. For each channel, the average value is calculated for this constant cumulative number of times T1 / Ts (S10).

Subsequently, the base station main processor 19 calculates SCH-allocable sector power by using Equation 1 below using the average power for each channel received in units of a specific time T1 for each sector (S20).

In Equation 1, the definitions of the variables are as follows.

P _{sector_avail} : remaining power available

P _sector : The total possible power of the sector

P _overheadCH : _overhead channel power common to all mobile stations in a sector

P _FCH : Power of FCH

P _otherSCH : SCH power except allocated SCH

P _guard : Guard power provided so as not to exceed the capacity of power amplifier because transmit power is fluctuated by power control

In addition, according to Equation 1, the SCH assignable sector power (P _{sector_avail} ) is the sum of the _overhead power (P _overheadCH ) and the FCH power (P _FCH ) at the total possible power (P _sector ) of the _sector , and is transmitted. It is obtained by subtracting the sum of the SCH power P _otherSCH and the guard power P _guard excluding the desired SCH. In this case, the base station main processor 19 receives the input only once from the channel card 13 because the overhead power is kept constant, but the FCH power and the SCH power change every 1.25ms due to power control, so that the reference time Ts Each channel is input from the channel card 13.

Next, the base station main processor 19 determines whether traffic channels such as FCH, Dedicated Control CHannel (DCCH), SCH, etc. have been transmitted during the previous SCH allocation interval (SCH_DURATION) (S30). Therefore, it is determined whether the SCH, which is a data transmission channel, is not transmitted (DTX) during the previous SCH allocation interval (SCH_DURATION) (S40). On the contrary, if the traffic channel is transmitted, the base station main processor 19 allocates a predetermined initial initial SCH transmission rate (S50), and the data determined by the initial SCH transmission rate and the amount of packet data transmitted from the SDU 12. By comparing the transmission rates, a small value is determined as the final SCH transmission rate (S60).

On the other hand, if the SCH, which is a data transmission channel, is not transmitted during the previous SCH allocation interval (SCH_DURATION) (DTX), the base station main processor 19 uses the 1x FCH power calculated by Equation 2 below. The SCH power of the basic transmission rate is calculated by Equation 3, and if it is transmitted, the SCH power of the basic transmission rate is calculated by Equation 4 below using the previously transmitted SCH power (S40, S42, S44).

In Equations 2 to 4, the definitions of the variables are as follows.

P ^nth _{FCH_full} : FCH transmit power at 1x of ^nth user

α _i : Gain required when converting the variable transmission rate of FCH to 1x speed

P ^nth _{FCH_variable (i)} : FCH power of the variable transmission rate currently being transmitted by the ^nth user

P ^nth _{SCH_basic} : SCH power of basic transmission rate having the same transmission rate as FCH of 1x of ^nth user

G _SCH : ratio of transmission power between FCH and SCH having the same transmission rate

G _softHO : Soft handoff gain in soft handoff area

β _i : Gain for compensating for performance differences according to transmission speed

At this time, the base station main processor 19 is the speed of the FCH during the fast power control is changed to 1/8 times, 1/4 times, 1/2 times, 1 times, so as to compensate a certain gain for each transmission rate of the FCH Calculate the FCH power at 1x speed.

In addition, since the frame structure of the FCH and the SCH is different from the target frame error rate, and the power required between the two channels is different according to different operations in the handoff region, the base station main processor 19 differs in gain between the two channels. Compute the power required by the SCH of the basic transmission rate by compensating the 1x FCH power.

When the SCH is not transmitted (DTX) before the SCH allocation time (S40, S42), according to Equation 2, the FCH transmission power (P ^nth _{FCH_full} ) at 1x speed of the ^nth user before the SCH allocation time is SCH. The variable transmission rate FCH power P ^nth _{FCH_variable (i) of the} ^nth user before the allocation time point is multiplied with a conversion value α _i for compensating for the performance difference according to the transmission rate. The SCH power (P ^nth _{SCH_basic} ) of the basic transmission rate is a soft handoff gain for compensating the performance difference with the SCH performing hard handoff when the FCH transmit power (P ^nth _{FCH_full} ) of 1x speed is in the handoff region. The value obtained by dividing (G _softHO ) is obtained by multiplying the ratio of the transmission power (G _SCH ) between the FCH and the SCH indicating the difference in the reception gain caused by the difference between the channel structure and the modulation / demodulation scheme of the FCH and the SCH.

On the other hand, if the SCH is transmitted before the SCH allocation time, according to Equation 4, the SCH power (P ^nth _{SCH_basic} ) of the basic transmission rate is the performance according to the transmission rate at the previously transmitted SCH transmission power (P ^nth _SCH ) Divide the gain β _i to compensate for the difference.

After calculating the SCH power of the basic transmission rate as described above, the base station main processor 19 uses the power ratio obtained by dividing the available sector power by the SCH power of the basic transmission rate according to Equation 5 and Equation 6 below. After the SCH transmission rate is determined (S46), the wireless SCH transmission rate is compared with the data transmission rate based on the amount of packet data transmitted from the SDU 12 by using Equation 7 below. Determine (S60).

In Equations 5 to 7, the definitions of the variables are as follows.

R ^nth _{SCH_avail} : SCH transmission rate obtained by calculating wireless environment and remaining power of ^nth user

G _turbo : The gain of a turbo encoder over a convolutional encoder.

R _(i) : The ratio range of the power of each double speed to the SCH power of the basic transmission rate

RATE ^nth _radio : Possible SCH transmission rate considering sector residual power and wireless environment

RATE ^nth _packet : Packet transmission rate determined by the amount of packet data to be transmitted by the nth user transmitted from the SDU.

RATE ^nth _PSA : SCH transmission rate obtained by selecting a small value by comparing the transmission rate obtained by using the ^nth user's wireless environment and available sector power with the packet data amount.

According to Equation 5, the SCH transmission rate (R ^nth _{SCH_avail} ) obtained by calculating the radio environment and the remaining power of the ^nth _user is a ratio of the SCH power of the available sector power (P _{sector_avail} ) and the basic transmission rate (P ^nth _{SCH_basic} ). It is obtained by multiplying with the gain G _turbo of the turbo encoder to multiply when the SCH channel uses the turbo channel codec.

According to Equation 6, the possible SCH transmission rate (RATE ^nth _radio ) in consideration of the sector residual power and the radio environment is obtained using the range R _(i) obtained as a ratio of the available sector power to the SCH power of the basic transmission rate. . In this case, if i = 0, RATE ^nth _radio is 1x speed, if i = 1, RATE ^nth _radio is 2x speed, if i = 2, RATE ^nth _radio is 4x speed and i = 3 If RATE ^nth _radio is 8x, i = 4, RATE ^nth _radio is 16x, and if i = 5, RATE ^nth _radio is 32x. If the SCH is allocated at less than 1x speed, it is determined that the radio channel environment is very bad and is processed in the discontinuous transmission mode (DTX) and is not transmitted during the SCH allocation period (SCH_DURATION).
That is, if the basic transmission rate is assigned to less than 1x speed using the range R _(i) obtained as the ratio of the available sector power to the SCH power of the basic transmission rate, the transmission rate is not transmitted during the SCH allocation interval (DTX). Is assigned at 32x speed, the possible SCH transmission rate (RATE ^nth _radio ) is obtained in consideration of the sector residual power and the radio environment.

According to Equation 7, the final SCH transmission rate (RATE ^nth _PSA ) is a SCH transmission rate (RATE ^nth _radio) obtained by using a data transmission rate (RATE ^nth _packet ) according to the amount of packet data to be transmitted and a wireless environment and available sector power. ) Is determined by a small value.

As described above, the final SCH transmission rate RATE ^nth _PSA is determined by the base station main processor 19, so that the channel card 13, the IF processor 14, the RF converter 15, and the power amplifier of the base station BTS are determined. (16), and when the SCH is transmitted via the antenna ANT, the radio interval frame error rate for the mobile communication system to which the present invention is applied and the existing system are shown as shown in FIG.

3 (a) shows that the base station determines the possible SCH speed (Link Quality) of the forward link in consideration of the radio channel environment in the mobile communication system and the existing system to which the present invention is applied, Figure 3 (b) In FIG. 2, SCH available power of the power amplifier 16 required according to the SCH speed is shown in the mobile communication system and the existing system to which the present invention is applied.

3 (c) shows that in a conventional system in which the SCH speed is determined only by the amount of packet data, a large portion of packets are considered as bad packets when the wireless environment changes and the available power of the power amplifier 16 changes. It is lost.

FIG. 3D illustrates scheduling of a base station main processor 19 in a system to which the present invention is applied by controlling the SCH rate in consideration of a transmission power of a traffic channel undergoing fast power control and a radio channel environment. After the SCH rate is determined by (1) the base station main processor 19 transmits the SCH rate information to the mobile station through the ESCAM message, and then receives the ACK message of the mobile station to transmit the SCH at the determined channel rate (2). ) SCH latency occurs from the time when the transmission rate of the SCH channel is determined to the point at which the base station transmits (3). In particular, the channel environment worsens and the remaining power of the power amplifier 16 is insufficient to change the SCH rate. When it is necessary, due to the SCH delay, a certain portion of the packet error is relatively small compared with the existing system.

Meanwhile, as described above, the final SCH transmission rate RATE ^nth _PSA is determined by the base station main processor 19, so that the channel card 13 of the base station BTS, the IF processor 14, the RF converter 15, When the SCH is transmitted via the power amplifier 16 and the antenna ANT, the radio resource waste and the RLP throughput are compared to the mobile communication system to which the present invention is applied and the existing system, as shown in FIG. 4.

4 (a) shows that the packet data amount fluctuates due to the provision of services such as web browsing when determining the physical layer SCH rate in the mobile communication system and the existing system to which the present invention is applied.

4 (b) shows the SCH transmission rate obtained in consideration of the remaining sector power and the radio channel environment in the mobile communication system and the existing system to which the present invention is applied.

The present invention considers the amount of packet data and compares methods that do not consider the amount of packet data in the past.

4 (c) shows that when the SCH rate is determined without considering the amount of packet data in the existing system, radio resources are wasted by increasing the speed of the physical layer higher than the packet rate.

4 (d) shows a case in which the amount of packet data is considered in the system to which the present invention is applied and the SCH channel rate is determined based on the remaining sector power and the wireless channel environment. For example, due to the SCH delay, the packet rate to be transmitted is 76,8 kbps. However, since the physical layer speed is 153.6 kbps, the radio resources are reduced as much as the shaded portion compared to the existing system (1). In addition, the packet rate is increased, resulting in a packet rate of 76,8 kbps, but due to the SCH delay, the physical layer speed is set to 38.4 kbps, indicating a small loss in throughput compared to the existing system.

As described above, in the method of operating a data channel transmission rate of a mobile communication system according to the present invention, when various types of wireless services are provided to a plurality of mobile stations in a CDMA mobile communication system, power control is performed in consideration of system resources and wireless channel environments. Since the forward link data channel transmission rate of the physical layer is efficiently adjusted by the power of the traffic channel including the FCH, DCCH, and SCH, and the remaining sector power and the amount of packet data, the base station can be reduced by reducing the frame error rate of the forward link. It is possible to improve the RLP throughput of a sector and to prevent the reduction of the pure data throughput caused by filling the fill frame by determining the transmission speed of the physical layer by reporting the packet data amount at every upper period.

What has been described above is only one embodiment for implementing the data channel transmission rate operating method of the mobile communication system according to the present invention, the present invention is not limited to the above-described embodiment, which is claimed in the following claims Without departing from the gist of the present invention, anyone of ordinary skill in the art will have the technical spirit of the present invention to the extent that various modifications can be made.

Claims (8)

The SDU 12 and the base station main processor 19 interfacing with the channel card 13 and the call control processor 20 included in the access network of the mobile communication system are separated from the channel card 13 in the SCH allocation period (SCH_DURATION). Receives the power of the basic traffic channel (FCH) and the SCH transmission power in which power control is performed in units of reference time (Ts), and corresponds to the number of times corresponding to a value obtained by dividing a specific time (T1) by the reference time (Ts) for each sector (T1 / Accumulating for Ts) and calculating an average value for this constant cumulative number T1 / Ts for each channel (S10); Calculating, by the base station main processor (19), SCH assignable sector power using average power for each channel in use received at a specific time (T1) unit for each sector (S20); Determining, by the base station main processor 19, whether a traffic channel is transmitted during a previous SCH allocation period (SCH_DURATION) (S30); If the traffic channel has been transmitted, the base station main processor 19 continuously determining whether a SCH, which is a data transmission channel, has not been transmitted (DTX) during a previous SCH allocation interval (SCH_DURATION) (S40); If the traffic channel has not been transmitted, the base station main processor (19) assigning a predetermined initial SCH transmission rate (S50); If the SCH is not transmitted before the SCH allocation time (DTX), the base station main processor 19 calculates the SCH power of the basic transmission rate using the 1x FCH power (S40, S42, S44); Calculating SCH power of a basic transmission rate by using previously transmitted SCH power if SCH is transmitted before SCH assignment time (S40, S44); After calculating the SCH power of the basic transmission rate, the base station main processor 19 determining the wireless SCH transmission rate using a power ratio obtained by dividing the available sector power by the SCH power of the basic transmission rate (S46); And By comparing the data transmission rate by the wireless SCH transmission rate and the amount of packet data delivered from the SDU 12, or by comparing the data transmission rate by the initial SCH transmission rate and the amount of packet data delivered from the SDU 12 Determining the value as the final SCH transmission rate (S60) Data channel transmission rate operating method of the mobile communication system, characterized in that consisting of. The method of claim 1, wherein the calculating of the SCH assignable sector power by using the average power for each channel (S20)

The sum of the _overhead power P _overheadCH and the FCH power P _FCH in the total possible power P _{sector of the sector} , the sum of the SCH power P _otherSCH excluding the SCH to be transmitted, and the guard power ( A method of operating a data channel transmission rate in a mobile communication system, characterized by obtaining a SCH assignable sector power (P _{sector_avail} ) by subtracting P _guard ). The method of claim 1, wherein when the SCH is not transmitted before the SCH allocation time (DTX), the base station main processor 19 calculates the 1x FCH power (S40, S42).

By _multiplying the variable transmission rate FCH power P ^nth _{FCH_variable (i) of the} ^nth user before the SCH allocation point by a transform value α _i to compensate for the performance difference according to the transmission rate, and before the SCH assignment point. A method of operating a data channel transmission rate of a mobile communication system, characterized by obtaining the FCH transmission power (P ^nth _{FCH_full} ) of 1x of the ^nth _user . The method of claim 1 or 3, wherein the base station main processor 19 calculates the SCH power of the basic transmission rate using the 1x FCH power (S40, S42, S44).

The FCH transmit power (P ^nth _{FCH_full} ) of _1x is divided by the soft handoff gain (G _softHO ) to compensate for the performance difference with the SCH performing hard handoff when the FCH is in the handoff region. To calculate the SCH power (P ^nth _{SCH_basic} ) of the basic transmission rate by multiplying the ratio of the transmission power (G _SCH ) between the FCH and the SCH, which represents the difference in the reception gain due to the difference between the channel structure and the modulation / demodulation scheme of the SCH. A data channel transmission rate operating method of a mobile communication system. The method of claim 1, wherein when the SCH is transmitted before the SCH allocation time, the base station main processor 19 calculates the SCH power of the basic transmission rate using the previously transmitted SCH power (S40, S44). Equation of

The SCH power P ^nth _{SCH_basic} of the basic transmission rate is obtained by dividing a gain β _i for compensating for the performance difference according to the transmission rate from the previously transmitted SCH transmission power P ^nth _SCH . Data channel transmission rate operating method of a mobile communication system. 2. The method according to claim 1, wherein after calculating the SCH power of the basic transmission rate, the base station main processor 19 determines the wireless SCH transmission rate using the power ratio divided by the available sector power by the SCH power of the basic transmission rate. In (S46), the following equation

By _multiplying the ratio of the available sector power (P _{sector_avail} ) and the SCH power of the basic transmission rate (P ^nth _{SCH_basic} ) by the gain (G _turbo ) of the turbo encoder that is multiplied when the SCH channel uses the turbo channel codec, A method of operating a data channel transmission rate of a mobile communication system, comprising calculating a SCH transmission rate (R ^nth _{SCH_avail} ) obtained by calculating a user's wireless environment and remaining power. 7. The method according to claim 6, wherein after calculating the SCH power of the basic transmission rate, the base station main processor 19 determines the wireless SCH transmission rate using the power ratio divided by the available sector power by the SCH power of the basic transmission rate. In (S46), the following equation

By using the range (R _(i) ) obtained by the ratio of the available sector power to the SCH power of the basic transmission rate, if the basic transmission rate is assigned to less than 1x, without transmitting during the SCH allocation interval (DTX), A method of operating a data channel transmission rate of a mobile communication system, wherein the SCH transmission rate (RATE ^nth _radio ) is obtained by considering the remaining sector power and the radio environment when the basic transmission rate is allocated to the 32x speed. 8. The method of claim 1, wherein the wireless SCH transmission rate is compared with the data transmission rate based on the amount of packet data transmitted from the SDU 12, or the initial SCH transmission rate and the packet data transferred from the SDU 12. Comparing the data transmission rate by the positive amount and determining a small value as the final SCH transmission rate (S60) in the following equation

By comparing the data rate (RATE ^nth _packet ) according to the amount of packet data to be transmitted and the SCH rate (RATE ^nth _radio ) obtained by using the wireless environment and available sector power, a small value is determined by the final SCH rate (RATE ^nth). _PSA ) and determine the data channel transmission rate operating method of a mobile communication system.

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