KR20080036506A - Method for setting data channel transmission power in frequency division multiple access system and terminal device for same - Google Patents

Abstract

The present invention relates to a method and apparatus for setting transmission power when transmitting data in a packet data mobile communication system using a frequency division multiple access scheme. According to the present invention, when the base station intends to transmit at a lower transmission rate than the transmission rate assigned by the base station, the power is set so that the power can be lowered accordingly, and the terminal adjusts the transmission power by using the scheduled transmission rate and the actual transmission rate information. . Therefore, in the present invention, when the terminal transmits using a lower transmission rate than the allocated transmission rate, the transmission quality is maintained as it is, but the transmission is performed using low transmission power, thereby reducing interference on neighboring cells.

Description

A method for setting data channel transmission power in a frequency division multiple access system and a terminal device for the same {A method for power setting of shared data channel in frequency division multiple access system}

1 shows the structure of an IFDMA transmitter

2 shows the structure of an LFDMA transmitter

3 shows an example of scheduling on a time axis;

4 is an operation procedure diagram of a terminal for implementing a power setting method according to a first embodiment of the present invention;

5 is a configuration diagram of a terminal for implementing a power setting method according to a first embodiment of the present invention;

6 is an operation procedure diagram of a terminal for implementing a power setting method according to a second embodiment of the present invention;

The present invention relates to a frequency division multiple access system, and more particularly, to a method and apparatus for setting data channel transmission power in a frequency division multiple access system.

Recently, a reverse multiple access scheme used in a mobile communication system is largely divided into a non-orthogonal multiple access scheme and an orthogonal multiple access scheme. The non-orthogonal multiple access scheme refers to a multiple access scheme in which reverse signals transmitted from a plurality of terminals are not orthogonal to each other. An example of the non-orthogonal multiple access scheme is code division multiple access (CDMA). There is a way. The orthogonal multiple access scheme refers to a multiple access scheme in which reverse transmissions from multiple terminals are orthogonal to each other. Examples of the orthogonal multiple access scheme include a frequency division multiple access (FDMA) scheme and a time division multiple access scheme. (Time Division Multiple Access, hereinafter referred to as TDMA).

In a typical packet data mobile communication system, a mixture of the frequency division multiple access scheme and the time division multiple access scheme is used as an orthogonal multiple access scheme. That is, the transmission signals of different users are distinguished in frequency and time. Hereinafter, in the present invention, a frequency division multiple access scheme is collectively referred to as a mixed form of the frequency division multiple access scheme and the time division multiple access scheme.

Representative examples of conventional frequency division multiple access schemes include orthogonal frequency division multiple access (OFDMA) and single carrier frequency division multiple access (SC-FDMA). The FDMA schemes refer to a multiple access scheme in which a plurality of terminals transmit signals through different subcarriers so that signal separation between terminals is possible.

Hereinafter, a transmitter of an interleaved frequency division multiple access (IFDMA) (or DFDMA) method, which is one of the SC-FDMA schemes, will be described in detail with reference to FIG. 1.

1 illustrates an example of an IFDMA transmitter structure. In addition to the method using the fast Fourier transform (hereinafter referred to as FFT) and the inverse fast Fourier transform (hereinafter referred to as IFFT) as shown in FIG. 1, another transmitter implementation method is possible. The implementation using FFT and IFFT as shown in FIG. 1 has the advantage of facilitating change of IFDMA system parameters with low hardware complexity.

In terms of transmitter structure, the difference between OFDM and IFDMA is that in the IFDMA transmitter, in addition to the IFFT 106 used for multi-carrier transmission in the OFDM transmitter, an FFT 104 is further present in front of the IFFT 106. Thus, in FIG. 1, the transmission symbol 100 is input to the FFT 104 in block units. The signal output from the FFT 104 is input to the IFFT 106 at equal intervals so that the IFDMA transmission signal components are transmitted through equally spaced subcarriers in the frequency domain. Generally, the size N of the input / output signal of the IFFT 106 has a larger value than the size M of the input / output signal of the FFT 108.

In OFDM, the transmit symbol 100 is directly input to the IFFT without passing through the FFT 104 and transmitted through various subcarriers, thereby generating a large value of Peak to Average Power Ratio (PAPR). On the other hand, IFDM transmits the transmission symbol 100 to the FFT 104 beforehand even though the transmission symbol 100 is finally processed by the IFFT 106 and transmitted on a multicarrier. Due to the mutual offsetting effect of the FFT and the IFFT, an effect similar to that of the output signal of the IFFT 106 is transmitted on a single carrier, thus achieving low PAPR.

Finally, the output of the IFFT 106 is converted into a serial stream in a parallel-to-serial converter (PSC) 102, and a CP adder cyclic prefix (CP) is added as in an OFDM system through the CP adder 102. Post-transmission may prevent interference between multipath channel signal components.

FIG. 2 illustrates an example of a structure of a transmitter of a Localized Frequency Division Multiple Access (LFDMA) technique that is similar to IFDMA and guarantees orthogonality among multiple access users and achieves low PAPR compared to OFDM based on a single carrier transmission. It is.

As can be seen in Figures 1 and 2, the difference between the LFDMA technique and the IFDMA technique in terms of the transmitter structure is that the output of the FFT 204 is applied to the input of the IFFT 206 of the continuous index. Thus, looking at the LFDMA transmission signal in the frequency domain, it occupies a band of adjacent subcarriers used when the output of the FFT 204 is mapped to the input of the IFFT 206. In other words, in the frequency domain, an IFDMA transmission signal occupies subcarrier subbands scattered at equal intervals, and an LFDMA signal occupies a subcarrier band composed of adjacent subcarriers.

Meanwhile, in a conventional reverse mobile communication system, a base station can support higher system capacity with limited radio resources through channel selective scheduling. The reverse direction refers to transmission from the terminal to the base station, and channel selective scheduling improves system capacity by allocating time intervals or frequency intervals having a better channel environment for channels changing on the time axis or frequency axis. Point to the technique of getting.

3 shows an example of scheduling on a time axis.

Referring to FIG. 3, in step 303, the terminal 302 transmits a pilot signal to receive a scheduling for data transmission. Since the base station 301 can determine the channel state of the terminal 302 through the pilot signal transmitted from the terminal 302, it is possible to determine whether to schedule and, when scheduling, appropriate demodulation scheme and coding rate. In step 304, the terminal 302 reports the status. At this time, the state refers to the state of the buffer or the power of the terminal to be transmitted. The information indicating the state of the buffer can report the amount of packet data, the service priority of the packet data, and the like, and the maximum transmission power can be reported as the information indicating the state of power. The base station 301 performs the scheduling procedure in step 305 based on the information obtained through the information and the pilot signal. If the corresponding UE is scheduled after the scheduling, the base station 301 transmits grant information in step 306. When the terminal 302 receives the grant information, the terminal 302 transmits data accordingly as in step 307.

In the general scheduling scheme, the power information may be transmitted or omitted by the terminal to the base station according to an algorithm for setting the transmission power. In other words, in the case of a system using a closed loop power control method, it is necessary to transmit power headroom information to the base station so that the base station knows the maximum data rate that the base station can allow. In the case of the loop power control method, even if the terminal does not provide power information, the base station can know the maximum transmission rate that is acceptable to the terminal only by the SIR (Signal Interference Ratio) of the pilot received from the terminal.

Next, a method of setting power when a terminal transmits data in a shared data channel (hereinafter referred to as SDCH) will be described. In a conventional wideband code division multiple access (WCDMA) system, data transmission power uses different beta values according to a transport format to be sent. The transmission format is a value that varies depending on the size of the data to be transmitted or the service type of the data. In the above, the beta value indicates how much to use in proportion to the transmission power of the pilot channel controlled by the closed loop power control. The beta value may be signaled or set by calculation.

In WCDMA, an uplink transmission power is efficiently set in a system that freely determines a transmission format according to the amount and type of data that a UE wants to send. However, in the current FDMA system, a different transmission power setting method is discussed. The reason is that since the WCDMA system and the FDMA system use orthogonal frequency resources differently, there is no interference between terminals in a cell, and the scheduling method currently discussed is based on the amount of frequency resources corresponding to a transmission format that the terminal intends to transmit freely. This is because the base station does not select the modulation and coding scheme (MCS) level and transmits as set by the base station. However, even in an orthogonal frequency system, since the interference to neighboring cells is still present, the transmission power needs to be set in consideration of only this interference level.

The channel transmission power setting method of the data will be described in detail as follows. First, the terminal transmits a reference channel for closed loop power control and receives a power control command from the base station to adjust the transmit power of the channel. At this time, the transmit power of the reference channel is called P_ref, and the transmit power of the data channel is called P_data. P_data can be set through Equation 1 below.

In the above equation, Nc_ref and Nc_data are the number of frequency subcarriers used for the reference channel and the data channel, respectively, and Offset_data is a power offset value as a ratio of power per frequency tone of the reference channel and the data channel. It is called. As described above, Offset_data is a value set by the base station or controlled by the terminal in consideration of factors such as neighboring cell interference regardless of the data rate to be transmitted.

Next, an operation when the terminal intends to transmit a lower rate than the scheduled rate will be described. In the FDMA system, because the base station knows exactly how much data the terminal wants to send through the buffer status / power status report, basically the terminal transmits data as scheduled by the base station, but the status report is delayed or the amount of information. If the status report is not accurate due to the limitation and if the resources are allocated to occupy a certain time during Voice over Internet Protocol (VoIP) scheduling, it is difficult to say that the base station knows the buffer status of the terminal correctly. If the UE needs a higher transmission rate than the base station assigns, it may increase through a scheduling request. However, if the UE requires a high transmission rate allocated to the UE, zero-padding is performed at a higher level if the UE does not have authority to select a transmission rate. Through padding), we have no choice but to match the rate format that allocated the total amount of data. This method is simple but can cause unwanted interference. In other words, lower transmission power can be used for lower transmission rates, where zero-padding data is transmitted, resulting in higher transmission power, causing interference. Therefore, as a method to compensate for this, when a base station schedules a specific frequency resource and the MCS level, a method of transmitting data by selecting a transmission rate among several limited transmission rates based on this has been discussed.

Alternatively, when the base station allocates a frequency resource for data transmission and the control information that the terminal needs to transmit on the uplink is generated and transmits the data and the control information at the same time, some of the frequency resources allocated for the data occur. . In this case, some bits of the data are punctured. However, the puncturing causes the data to be transmitted using a small amount of physical layer bits, and thus has a higher coding rate than the expected coding rate, thereby degrading data transmission quality. In the case where data and control information are transmitted at the same time, the control information may be transmitted by increasing the power by a predetermined amount. However, when the amount of control information is variable, for example, when transmitting ACK / NACK, when transmitting CQI, or both. In the case of transmission, it is not preferable to simply add the amount of resources to be punctured.

There is no discussion on how to set the transmission power in transmitting data at a low data rate as described above. However, since Offset_data obtained by Equation 1 is not defined as a value according to the transmission rate, if the UE uses Offset_data obtained by Equation 1 as it is, there is no advantage of sending data at a low transmission rate.

Accordingly, in order to solve the problems described in the prior art, the present invention proposes a transmission power setting method required for transmitting data at a lower transmission rate than that scheduled by a base station in a frequency division multiple access based wireless communication system.

In addition, the present invention proposes a method for setting the transmission power of the terminal by the ratio of the scheduled transmission rate and the transmission rate selected by the terminal in the frequency division multiple access based wireless communication system.

In addition, the present invention proposes a method and a transmission apparatus for setting the transmission power when the terminal transmits reverse data.

According to an embodiment of the present invention, in a method for setting a transmission power of a data channel by a terminal in a frequency division multiple access system, a process of scheduling from a base station, a transmission rate of data to be transmitted and a transmission rate of the scheduled data And comparing the transmission power of the data to be transmitted according to the transmission rate of the data and the scheduled data when the transmission rate of the data to be transmitted is smaller than the transmission rate of the scheduled data. And setting power of data to be transmitted to the base station by using the adjusted power offset value and transmitting data by using the set power value.

In addition, according to an embodiment of the present invention, in a method for setting a transmission power of a data channel by a terminal in a frequency division multiple access system, a process of receiving scheduling from a base station, a transmission rate of data to be transmitted and a transmission rate of the scheduled data Comparing the transmission rate and the transmission rate of the data to be transmitted with the power offset value used when the terminal reports the status to the base station when the transmission rate of the data to be transmitted is smaller than the transmission rate of the scheduled data. Adjusting the transmission rate according to the received data rate, comparing the adjusted power offset value with a currently set power offset value, and if the adjusted power offset value is less than or equal to the currently set power offset value. , The adjusted power offset value It characterized in that it comprises the step of transmitting data to the base station by using.

In addition, according to an embodiment of the present invention, in the terminal device for setting the transmission power of the data channel in the frequency division multiple access system, a transmission data determiner for determining the data rate to transmit data by using the scheduling information received from the base station And a transmission power controller for adjusting a power offset value required for data transmission by using the data rate to be transmitted, the data rate scheduled from the base station, and a power offset value currently set, and the adjusted power offset value. It characterized in that it comprises a data channel transmitter for transmitting data to the base station using.

Hereinafter, with reference to the accompanying drawings will be described in detail the operating principle of the preferred embodiment of the present invention. In the following description of the present invention, detailed descriptions of well-known functions or configurations will be omitted if it is determined that the detailed description of the present invention may unnecessarily obscure the subject matter of the present invention. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the specification.

An important aspect of the present invention is that, when the terminal transmits data in the case of FDAM-based reverse data transmission, the data is transmitted by using the data rate lower than that specified by the base station in the system in which the transmission power level of the data is not defined as a specific value according to the data rate. In this case, the transmission power is set. The transmission rate is a value determined according to which amount of frequency resource and MCS level is used, and means the amount of information data and the transmission format or the number of bits of the physical layer that can be transmitted by the terminal.

The biggest feature of the present invention is to set the power to minimize the interference to the neighboring cell using the transmission rate information, the scheduled transmission rate information, and the power level information controlled by the terminal in determining the transmission power To set the power level. The scheduled rate information refers to the maximum data rate that the terminal can transmit data. In addition, in the related art, the terminal uses transmission rate information and transmission power information corresponding thereto or only power offset information controlled by the terminal. However, in the present invention, both the transmission rate information and the scheduled transmission rate information used by the terminal are used. There is a characteristic to it.

First, the reason why the terminal uses the scheduled transmission rate information in setting the transmission power will be described. When performing base station-based scheduling in uplink, the base station determines the transmission rate required for the terminal based on the buffer state information and the power state information of the terminal. As the power state information, when the terminal performs power control, it reports the allowable power amount or reports power offset information indicating a power ratio per frequency tone of the data channel to the reference control channel. In particular, when the UE determines the data transmission power using a value such as the interference degree of the neighboring cell or the path loss of the scheduling cell irrespective of the transmission rate, the base station needs to know the power offset information to efficiently schedule.

Knowing the power offset information, the base station can determine the transmittable rate based on the power offset information. In this case, even in the same power offset, a different transmission rate may be determined according to the quality of service of data to be transmitted by the terminal. When the base station scheduling operates normally, the relationship between the power offset information of the terminal and the scheduled transmission rate may be regarded as a power level that satisfies the transmission quality. Therefore, when the terminal transmits using a lower transmission rate than the scheduled transmission rate, if the power offset value is adjusted using the ratio of the scheduled transmission rate and the actual transmission rate, an appropriate transmission power level may be set.

Hereinafter, the transmission power setting method will be described in detail with reference to specific embodiments of the present invention.

<< first embodiment >>

According to the first embodiment of the present invention, the power offset value set in the terminal is adjusted by the ratio of the scheduled transmission rate and the transmission rate to be transmitted. To this end, the following Equation 2 for setting the power offset value is proposed.

In Equation 2, Offset_data_k is a power offset value required for k-th data transmission, and Offset_data_ori is a power offset value currently set in the terminal. DataRate_scheduling is a value corresponding to a transmission rate scheduled by the base station, and DataRate_k is a transmission rate that the terminal intends to transmit at the kth time. In the above embodiment, DataRate_scheudling and DataRate_k may mean a transport block size (TBS) or a size of a physical layer bit.

According to Equation 2, the power offset value currently set in the terminal is adjusted by a value determined by a function of a transmission rate and a scheduled transmission rate. The function of Equation 2 may be defined as in Equation 3 so as to be adjusted by the ratio of the scheduled transmission rate and the transmission rate of data to be transmitted.

(Delta_diff)는 추가적으로 조절이 필요한 경우에 사용하기 위한 파라미터이다. 즉, 이 값은 두 전송률에 의해서 전송하고자 할 때 부호화율(code rate)이 크게 달라지거나 복조 방식이 바뀔 경우에 필요한 전력 레벨이 조금 달라질 수 있기 때문에 이를 보정하기 위한 파라미터이다. According to Equation 3, the scheduling Offset_data_ori is adjusted by the rate of the transmission rate. In other words, if the scheduled transmission rate is 1000 bits and the data transmission rate is 500 bits, the power offset value reduced by 1/2, that is, 3 dB, is used.

(Delta_diff) is a parameter used when additional adjustment is needed. That is, this value is a parameter for correcting this because the power level required when the code rate is greatly changed or the demodulation method is changed when the two data rates are to be transmitted.

Next, an operation procedure of a terminal for implementing the power setting method according to the first embodiment of the present invention will be described with reference to FIG. 4.

4 is a flowchart illustrating an operation procedure of a terminal for power setting according to the first embodiment of the present invention.

Referring to FIG. 4, first, if there is data to be transmitted, the UE receives scheduling from the base station in step 401 and starts data transmission. In step 402, the terminal compares the data rate Data_rate_k of the data to be transmitted with the data rate Data_rate_sch of the scheduled data. If the transmission rate of the data to be transmitted is not smaller than the scheduled transmission rate, the terminal proceeds to step 403 to set the offset_data_ori currently controlled by the terminal to data_offset_k and proceeds to step 404 to transmit data according to the transmission rate set in step 403. . On the other hand, if the data rate to be transmitted is smaller than the scheduled data rate, the terminal proceeds to step 405 and newly calculates offset_data_k using Equation 2. In step 404, data is transmitted according to the newly calculated data rate.

Next, a device of a terminal for implementing a power setting method according to a first embodiment of the present invention will be described with reference to FIG. 5.

5 illustrates a configuration of a terminal for implementing a power setting method according to a first embodiment of the present invention.

Referring to FIG. 5, the scheduling information controller 501 receives scheduling information from the base station and transmits the scheduling information to the transmission data determiner 502. The transmission data determiner 502 determines Data_rate_k using the information received from the scheduling information controller 501. The data channel transmitter 504 transmits the data generated by the data generator 503 according to Data_rate_k determined by the transmission data determiner 502. In this case, in order for the data channel transmitter 504 to transmit data, transmission power must be set. For this purpose, the reverse transmission power controller 505 determines the power offset of the reference channel through which power control is performed. That is, the reverse transmission power controller 505 receives Data_rate_sch from the scheduling information controller 501, receives Data_rate_k from the transmission data determiner 502, and calculates Offset_data_k using Equation 2 to the data channel transmitter 504. To pass.

<< 2nd Example >>

The power setting method according to the second embodiment of the present invention is almost similar to the first embodiment of the present invention. However, while the first embodiment of the present invention adjusts the power offset value currently set in the terminal, the second embodiment of the present invention differs in that it adjusts the power offset value previously reported by the terminal.

The reason for adjusting the power offset as described above is that the power offset value that satisfies the reception quality expected at the time of scheduling by the base station is a value reported from the terminal. This is because the base station cannot satisfy the desired reception quality if data is transmitted using the changed power offset when the power offset is changed by. In other words, when the terminal transmits data using the transmission rate scheduled by the base station, the terminal should use the currently set power offset value, but when the terminal transmits data at a lower transmission rate than the transmission rate scheduled by the base station, The transmit power should be set according to the power offset value reported from the terminal, which is a more accurate value.

To this end, the second embodiment of the present invention proposes the following Equation 4 for setting the power offset value.

In Equation 4, Offset_data_rep is a power offset value when a UE reports a power state to a base station. Offset_data_cal is a value obtained by adjusting Offset_data_rep according to the relationship between the scheduled transmission rate and the current transmission rate.

As the simplest function, the power offset value may be adjusted by the ratio of two data rates as shown in Equation 3 according to the first embodiment of the present invention. After calculating the power offset value suitable for the data rate to be actually transmitted, Offset_data_cal is compared with Offset_data_ori, which is the power offset value currently set in the terminal. If Offset_data_cal is larger than Offset_data_ori as a result of the comparison, Offset_data_k is set to Offset_data_ori, otherwise Offset_data_k is set to Offset_data_cal.

The reason why Offset_data_cal is compared with Offset_data_ori as described above may be larger than Offset_data_ori maintained by the current UE after Offset_data_rep is adjusted at the time of reporting. Since Offset_data_ori is set in consideration of effects such as interference of neighbor cells, Using a value higher than the value as Offset_data_cal may adversely affect the performance of neighboring cells. Therefore, Offset_data_cal, which is offset value of Offset_data_rep, is restricted from exceeding Offset_data_ori.

Next, an operation procedure of a terminal for implementing the power setting method according to the second embodiment of the present invention will be described with reference to FIG. 6.

6 illustrates an operation procedure of a terminal for implementing a power setting method according to a second embodiment of the present invention.

Referring to FIG. 6, first, in step 601, a UE receives a scheduling and starts transmission of data. In operation 602, the data rate (Data_rate_k) and the scheduled data rate (Data_rate_sch) of the data to be transmitted are compared. If the data rate to be transmitted is not small as a result of the comparison, the process proceeds to step 603 to set Offset_data_k to Offset_data_ori, which is a power offset value set in the terminal, and proceeds to step 604 to transmit data according to the set data rate. On the other hand, if the data rate to be transmitted is smaller than the scheduled data rate, the process proceeds to step 605 to obtain Offset_data_cal using Equation 4. In step 606, the calculated Offset_data_cal and Offset_data_ori are compared. If the offset_data_cal is larger than the offset_data_ori, the process proceeds to step 607, sets offset_data_k to offset_data_ori, and proceeds to step 604 to transmit the data. Otherwise, the process proceeds to step 608 to set Offset_data_k to Offset_data_cal. In operation 604, data is transmitted according to the set value.

Meanwhile, the terminal device for power setting according to the second embodiment of the present invention is the same as the terminal device according to the first embodiment of the present invention, except that Offset_data_rep information is additionally required as an input of the reverse power controller 505. .

<< third embodiment >>

In a power setting method according to a third embodiment of the present invention, a power offset value is determined by using a ratio of a transmission rate of previously transmitted data and a transmission rate to be transmitted, based on a power offset value set in a terminal. The base station may adjust the power offset value of the data in anticipation of the transmission of the control information when the data is transmitted together with the control information during the initial transmission of the data, but the base station does not consider the transmission of the control information when the data is retransmitted. Therefore, in the third embodiment, the power level is increased when control information is simultaneously transmitted when data is retransmitted, and when the control information is transmitted when initial data is transmitted but the control information is not present when retransmission, the power level is relatively lowered. This is because the amount of available radio resources is increased compared to the initial transmission when there is no control information in retransmission of data. In the above, the previous transmission may mean a transmission before a predetermined transmission time for the same data or may mean a previous transmission in the same HARQ process.

In order to set the power offset value for the preferred implementation of the third embodiment, the following Equation 5 is proposed.

In Equation 5, Offset_data_k is a power offset value required for the kth transmission of the same data, and Offset_data_k-1 is a power offset value used by the terminal during previous (k-1) th transmission of the same data. DataRate_ (k-1) represents a transmission rate at the previous transmission, and DataRate_k represents a transmission rate that the terminal intends to use at the kth time. In the third embodiment, DataRate_k and DataRate_ (k-1) may mean a transport block size (TBS) or a size of a physical layer bit.

는 추가적으로 전력 레벨의 조절이 필요한 경우에 사용하기 위한 파라미터이다. 즉 상기 파라미터는, 상기 언급된 두 전송률에 의해서 데이터를 전송하고자 할 때, 이전 전송에 비해 부호화율(code rate)이 크게 달라지거나 복조 방식이 바뀔 경우에 필요한 전력 레벨이 조금 달라질 수 있기 때문에 이러한 전력 레벨의 변화를 보정하기 위한 것으로서, 필요하지 않은 경우 '1'로 설정된다.According to Equation 5, offset_data_k is obtained by adjusting Offset_data_k-1 of the previous transmission by the ratio of the transmission rate of the previous transmission and the transmission rate of the current transmission. In other words, if the transmission rate of the previous transmission is 1000 bits but the data transmission rate is 500 bits, the power offset value is reduced by 1/2, that is, 3 dB less than the previous transmission.

Is a parameter for use when additional power level adjustment is required. In other words, when the data is to be transmitted according to the above-mentioned two transmission rates, the power level required when the code rate or the demodulation scheme is changed significantly compared to the previous transmission may be slightly different. It is set to '1' if it is not necessary to correct the change of level.

On the other hand, the operation and device of the terminal for power setting according to the third embodiment of the present invention is the same as the operation and device of the terminal according to the first embodiment of the present invention, except that DataRate_ (k-1) information instead of DataRate_scheduling , Offset_data_k-1 information is used instead of Offset_data_ori.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the appended claims, but also by the equivalents of the claims.

In the present invention operating as described in detail above, the effects obtained by the representative ones of the disclosed inventions will be briefly described as follows.

According to the present invention, when the terminal transmits data using a lower transmission rate than the allocated transmission rate, it is possible to maintain transmission quality but transmit using a lower transmission power, thereby reducing interference on neighboring cells.

Claims (14)

In the frequency division multiple access system, the terminal sets the transmission power of the data channel, Receiving scheduling from the base station, Comparing the transmission rate of the data to be transmitted with the transmission rate of the scheduled data; When the data rate of the data to be transmitted is smaller than the data rate of the scheduled data, adjusting a currently set power offset value according to the data rate of the data to be transmitted and the data rate of the scheduled data; And setting the power of data to be transmitted to the base station using the adjusted power offset value and transmitting the data using the set power value.  The method of claim 1, Adjusting the power offset value, And adjusting the power offset value by a ratio of the transmission rate of the data to be transmitted to the transmission rate of the scheduled data.  The method of claim 1, When the transmission rate of the data to be transmitted is greater than or equal to the transmission rate of the scheduled data, the power of the data is set using the currently set power offset value, and the data is transmitted to the base station using the set power value. The transmission power setting method further comprising the step of transmitting.  In the frequency division multiple access system, the terminal sets the transmission power of the data channel, Receiving scheduling from the base station, Comparing the transmission rate of the data to be transmitted with the transmission rate of the scheduled data; When the transmission rate of the data to be transmitted is smaller than the transmission rate of the scheduled data, Adjusting, by the terminal, a power offset value used when reporting a status to the base station according to a transmission rate of the data to be transmitted and a transmission rate of the scheduled data; Comparing the adjusted power offset value with a currently set power offset value; And transmitting the data to the base station by using the adjusted power offset value when the adjusted power offset value is less than or equal to the currently set power offset value.  The method of claim 4, wherein If the adjusted power offset value is larger than the currently set power offset value, the power of the data to be transmitted to the base station is set using the currently set power offset value, and the data is transmitted using the set power value. The transmission power setting method further comprising the process.  The method of claim 4, wherein Adjusting the power offset value, And adjusting the power offset value used in the status report as a ratio of the transmission rate of the data to be transmitted to the transmission rate of the scheduled data.  The method of claim 4, wherein When the transmission rate of the data to be transmitted is greater than or equal to the transmission rate of the scheduled data, the power of data to be transmitted to the base station is set using the currently set power offset value and the data is set using the set power value. Transmission power setting method further comprising the step of transmitting.  A terminal apparatus for setting transmission power of a data channel in a frequency division multiple access system, A transmission data determiner for determining a data rate to transmit data using scheduling information received from a base station; A transmission power controller which adjusts a power offset value required for data transmission by using the data rate to be transmitted, a data rate scheduled from the base station, and a power offset value currently set; And a data channel transmitter for transmitting data to the base station using the adjusted power offset value.  The method of claim 8, The transmission power controller, The transmission rate of the data to be transmitted is compared to the transmission rate of the scheduled data when the transmission rate of the data to be transmitted is smaller than the transmission rate of the scheduled data by comparing the transmission rate of the data to be transmitted with the transmission rate of the scheduled data. And adjusting the power offset value by a ratio of.  The method of claim 9, The transmission power controller, The transmission rate of the data to be transmitted is compared with the transmission rate of the scheduled data, and when the transmission rate of the data to be transmitted is greater than or equal to the transmission rate of the scheduled data, the currently set power offset value is transmitted. And a power offset value required for the terminal device.  The method of claim 8, The transmission power controller, Comparing the transmission rate of the data to be transmitted with the transmission rate of the scheduled data, when the transmission rate of the data to be transmitted is smaller than the transmission rate of the scheduled data, the power offset value transmitted when the terminal reports the status to the base station Is adjusted according to the transmission rate of the data to be transmitted and the transmission rate of the scheduled data, The adjusted power offset value is compared with the currently set power offset value, and if the adjusted power offset value is less than or equal to the currently set power offset value, the adjusted power offset value is the power required for the data transmission. Terminal device characterized in that it is set to an offset value. The method of claim 11, The transmission power controller, And when the adjusted power offset value is larger than the currently set power offset value, setting the currently set power offset value to a power offset value required for the data transmission. The method of claim 11, The transmission power controller, And a power offset value transmitted during the status report by the ratio of the transmission rate of the data to be transmitted to the transmission rate of the scheduled data. The method of claim 11, wherein the transmit power controller, And when the transmission rate of the data to be transmitted is greater than or equal to the transmission rate of the scheduled data, setting the currently set power offset value to an offset value required for the data transmission.

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