KR20110068123A - Method and apparatus for providing uplink services in mobile communications system - Google Patents

Abstract

PURPOSE: A method and device for providing an uplink service in a mobile communication system are provided to multiplex a plurality of transmission flows in consideration of transmission offset. CONSTITUTION: At least two first data flows with the same offset are allocated to a first carrier. The other data flows are allocated to a second carrier. Data of the allocated data flows are multiplexed by a carrier. The multiplexed data are transmitted to a base station through the first and second carriers. The entire transmission power of the first data flows is not larger than maximum transmission power.

Description

Method and apparatus for providing uplink service in mobile communication system {METHOD AND APPARATUS FOR PROVIDING UPLINK SERVICES IN MOBILE COMMUNICATIONS SYSTEM}

The present invention relates to a mobile communication system, and more particularly, to a method and apparatus for providing an uplink service.

Third generation mobile communication based on the European mobile system Global System for Mobile Communications (GSM) and General Packet Radio Services (GPRS) and using Wideband Code Division Multiple Access (WCDMA) The system, the 3rd Generation Partnership Project (3GPP) system, provides a consistent service that enables mobile phone or computer users to transmit packet-based text, digitized voice or video and multimedia data at high speeds from anywhere in the world.

In the 3GPP system, an enhanced uplink dedicated channel (Enhanced) is further improved to further improve the performance of packet transmission in uplink (UL) communication from a user equipment (UE) to a base station (Node B). Fast uplink packet access using Enhanced Dedicated Physical Data Channel (E-DPDCH) and Enhanced Dedicated Physical Control Channel (E-DPCCH) mapped to uplink Dedicated (EDCH) (High Speed Uplink Packet Access: HSUPA) is supported. HSUPA supports Adaptive Modulation and Coding (AMC), Hybrid Automatic Retransmission Request (HARQ), Base Station Control Scheduling, and Short TTI (Shorter Transmission Time) to support more stable high-speed data transmission. Interval) size and other technologies are supported.

The format of transport blocks transmitted through physical channels of HSUPA is defined as a transport format combination (TFC). In HSUPA communication, a base station Node B and a UE select a TFC according to a predetermined rule, and exchange uplink data using the selected TFC. The predetermined rule is called a TFC selection algorithm. Each TFC defines the size of transport blocks and thus represents different data rates.

The power required for stably delivering data through the E-DPDCH is determined by the power ratio of the E-DPDCH to the Dedicated Physical Control Channel (hereinafter referred to as DPCCH) used as a reference channel. Since the power ratio is differentially adjusted according to the additionally set power offset, the power level applied to the corresponding E-DPDCH varies according to the power offset even for the same data size, and accordingly, the quality of service (QoS) is differential. Apply.

In the conventional mobile communication system operating as described above, in case of multiplexing a plurality of transmission flows into one transmission channel, unnecessary power waste occurs in the terminal by multiplexing a plurality of transmission flows having different power characteristics. There is a problem that causes performance degradation.

The present invention provides a method and apparatus for multiplexing a plurality of transmission flows for an uplink service in a mobile communication system.

The present invention provides a method and apparatus for multiplexing a plurality of transmission flows in consideration of a transmission offset in a mobile communication system.

Method according to a preferred embodiment of the present invention; In the method of providing the uplink service in a wireless communication system using at least two carriers for the uplink service, at least two first data flows having the same power offset among all data flows to be transmitted are assigned to the first carrier. Allocating the remaining data flows among the entire data flows to a second carrier, multiplexing the data of the allocated data flows for each carrier and transmitting the multiplexed data to the base station through the first carrier and the second carrier It includes the process of doing. The first data flows allocated to the first carrier are selected such that the total transmit power of the first data flows does not exceed the maximum transmit power allowed for the terminal.

Apparatus according to a preferred embodiment of the present invention; In the apparatus for providing uplink services in a wireless communication system using at least two carriers for uplink service, at least two first data flows having the same power offset among all data flows to be transmitted are assigned to the first carrier. A controller for allocating and assigning the remaining data flows of the entire data flows to a second carrier, and a transmitter for multiplexing the data of the allocated data flows for each carrier and transmitting the multiplexed data to a base station through the first carrier and the second carrier It includes. The first data flows allocated to the first carrier are selected such that the total transmit power of the first data flows does not exceed the maximum transmit power allowed for the terminal.

The present invention can reduce the transmission power consumption of the terminal due to the power offset while differentially applying the quality of service (QoS) for each service. The reduced transmission power of the terminal not only reduces the interference of the network, but also reduces the overall power consumption of the terminal, thereby increasing the data rate that the terminal can transmit during one TTI, resulting in an increase in the efficiency of the terminal.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, only parts necessary for understanding the operation of the present invention will be described, and other background art will be omitted so as not to distract from the gist of the present invention.

In this specification, reference will be made to a communication standard based on 3GPP in describing operations in a cellular communication system. However, the operation according to the present invention is not limited to a specific communication protocol or system configuration, and various modifications can be made without departing from the gist of the present invention, which are obvious to those skilled in the art. Im sure.

1 is a diagram illustrating transmission of uplink data through an E-DCH in a mobile communication system according to a preferred embodiment of the present invention. Here, reference numeral 110 denotes a base station supporting a E-DCH, that is, a Node B, and reference numerals 101, 102, 103, and 104 denote terminals that use the E-DCH. As shown, the terminals 101 to 104 transmit data to the base station 110 through the E-DCHs 111, 112, 113, and 114, respectively.

The base station 110 notifies whether the E-DCH data can be transmitted for each terminal using a buffer occupancy, a request data rate, and a channel state provided from the terminals 101 to 104 using the E-DCH. Or transmit scheduling information indicating the allowed transmission power for the E-DCH. This is called scheduling of uplink data transmission. Since the amount of resources that the base station can use for the HSUPA is limited, when a specific terminal occupies a large amount of resources (that is, power), less power may be allocated to the remaining terminals. Therefore, scheduling should be properly performed to increase the performance of the whole system.

As an example, low data rates (ie, low power) are allocated to terminals far away from the base station (eg, 103 and 104), and high data rates (ie, high power) to nearby terminals (eg, 101 and 102). ) Is assigned. Each terminal 101 to 104 determines the maximum allowable data rate of the E-DCH data according to the scheduling information, and transmits the E-DCH data within the determined data rate.

For E-DPDCH and E-DPCCH, which are physical channels for EDCH service, one or more carriers may be used. In particular, HSUPA using dual carriers may be selected as a dual-cell or dual-carrier (DC-HSUPA). HSUPA). In DC-HSUPA, an E-TFC (EDCH TFC) selection algorithm for determining the size of data to be transmitted by the UE through each E-DPDCH, which is an HSUPA uplink data channel, needs to be determined. The E-TFC selection algorithm includes not only data size but also determination of various transmission parameters for EDCH service, such as flow type, power offset, carrier mapping, and the like.

In one embodiment, the parallel E-TFC selection method determines the data size of the two carriers in consideration of the total power available to the two carriers and the buffer status of the terminal. In another embodiment, the sequential E-TFC selection method first determines the data size to be loaded on the carrier in consideration of the power and the buffer state available in one carrier, and then uses the remaining power and the buffer state to determine the data size. Determine the data size to be loaded on the carrier.

Hereinafter, the E-TFC selection method of the terminal according to the power offset based on the parallel E-TFC selection method in the DC-HSUPA will be described.

The main parameters to be considered when selecting an E-TFC include a Serving Grant (SG) value, which indicates the level of transmission power that the base station permits to the terminal for data transmission, interference, and configuration. Taking into account the maximum power (max power) which means the maximum power level that the terminal can transmit at present, and the buffer status which means the amount of data awaiting transmission remaining in the current transmission buffer of the terminal. There is. The E-TFC selection algorithm reflects several different factors based on the above parameters to determine what kind of data is to be transmitted and how much size through each E-DPDCH. Here, each type of data is classified into a medium access control-data (MAC-d) flow.

MAC-d flow is a concept introduced to provide QoS in the AS (Access Stratum), and means a set of logical channels having similar characteristics. Each MAC-d flow has a power offset and a maximum number of re-transmissions as QoS parameters. For example, since a real time service is sensitive to delay, it requires fewer retransmissions.

The power offset increases the transmission power of the E-DPDCH, thereby increasing the probability that the base station can receive data without error. As an example, the required reception error probability of the EDCH may be 20%. Therefore, the probability of reception error of a specific MAC-d flow is lowered by the power offset, and different QoS may be provided for each MAC-d flow by adjusting the power offset.

As an example, the power offset applied to the MAC-d flow may be defined within a range of 0 to 6. A gain factor (GF) representing the power of the entire E-DPDCH to be transmitted may be determined according to Equation 1 according to the power offset.

는 주어진 기준 E-TFC의 기준 이득 인자를 의미하며, L_e,ref는 기준 E-TFC에 사용되는 E-DPDCH들의 개수이며, L_e,i는 해당 i번째 E-TFC에 사용되는 E-DPDCH들의 개수이며, K_e,ref는 기준 E-TFC의 전송 블록 크기이며, K_e,i는 i번째 E-TFC의 전송 블록 크기를 의미한다. 또한

는 해당 MAC-d 플로우에 적용되는 전력 옵셋을 의미한다.here

Is the reference gain factor of the given reference E-TFC, where L _{e, ref} is the number of E-DPDCHs used for the reference E-TFC, and L _{e, i} is the E-DPDCH used for the i-th E-TFC. K _{e, ref} is the transport block size of the reference E-TFC, and K _{e, i} means the transport block size of the i-th E-TFC. Also

Denotes a power offset applied to the corresponding MAC-d flow.

As such, even for the same data size, the power level applied to each E-DPDCH varies according to the power offset, and accordingly, QoS is differentially applied. As an example, if a MAC-d flow mapped to a real-time service is assigned a higher power offset than other MAC-d flows, the transmission power level of the corresponding E-DPDCH is increased, and thus the probability of the base station receiving the data is increased. This reduces the number of retransmissions, which in turn reduces the delay. In this way, different power offsets can be assigned to each MAC-d flow to provide QoS for each service.

Meanwhile, one or more MAC-d flows may be multiplexed in one EDCH channel, and the MAC-d flow multiplex list (MAC) may be used to inform the UE whether multiple MAC-d flows may be multiplexed in one EDCH channel and transmitted simultaneously. flow multiplexing list) is defined. The MAC-d flow multiplex list allows simultaneous transmission of MAC-d flows with similar QoS, but because it limits the type of MAC-d flows being multiplexed, the priority (priority) not included in the multiplex list is Problems may occur where low MAC-d flows may not be transmitted. Also, since only data of the MAC-d flows included in the multiplex list may be transmitted in one transmission time interval (TTI), if the amount of data of the MAC-d flows included in the multiplex list is small, one TTI Since the amount of data that can be transmitted is reduced, the performance of the terminal is reduced.

To solve this problem, the network sets the multiplex list to all MAC-d flows to enable multiplexing of all MAC-d flows. Therefore, the performance degradation and low priority MAC-d flow of the terminal is prevented from being transmitted.

In this way, if the multiplex list is set to all MAC-d flows, the MAC-d flows having different power offsets may be multiplexed into one transport channel unless limiting the type of MAC-d flows that can be transmitted to the current TTI. Can be. If MAC-d flows having different power offsets in one transport channel are multiplexed, in one embodiment, the power offset of the corresponding transport channel follows the power offset of the highest priority MAC-d flow. At this time, the power offset of the corresponding MAC-d flow is applied to the entire E-DPDCH.

2 illustrates transmission power levels for respective carriers when multiplexing two MAC-d flows having different power offsets according to priorities according to an embodiment of the present invention. Configuration information of the MAC-d flows is shown in Table 1 below.

MAC-d flow ID Power offset Priority Data size MAC-d flow 1 0 2 900 bits MAC-d flow 2 N One 100 bits

Referring to FIG. 2, MAC-d flow 1 has a data size of power offset 0 and 900 bits, and MAC-d flow 2 has a data size of power offset N and 100 bits. When MAC-d flow 1 and MAC-d flow 2 are multiplexed and transmitted, the E-DPDCH transmit power level is changed as follows according to the power offset change of MAC-d flow 2.

When the power offset of the MAC-d flow 2 is 0, there is no extra power (extra power) according to the power offset. The E-DPDCH power at this time is called P _origin .

When the power offset of the MAC-d flow 2 is 1, since the power offset of the high priority MAC-d flow 2 is applied to the E-DPDCH, additional power is generated according to the power offset. E-DPDCH power at this time is 1.12 XP _origin by Equation 1 mentioned above.

When the power offset N value of the MAC-d flow 2 is 6, the power offset of the high priority MAC-d flow is applied to the E-DPDCH, so that additional power is generated according to the power offset. E-DPDCH power at this time is 2 XP _origin by Equation 1 mentioned above.

As described above, in the case of multiplexing the MAC-d flows according to the priority, the power offset of 100 bits (MAC-d flow 2) does not increase only the power of 100 bits (MAC-d flow 2) but the total 1000 bits. Power is increased. The increased power acts as an interference in the entire network to reduce the network capacity, and increases the total power consumption of the terminal, thereby reducing the size of data that the terminal can transmit at one time, resulting in performance degradation of the terminal.

If two MAC-d flows are not multiplexed to avoid power increase due to power offset, 1000 bits of data are divided into 100 bits (MAC-d flow 2) and 900 bits (MAC-d flow 1), respectively. Since it must be transmitted in the TTI, another performance degradation occurs.

That is, when multiplexing the MAC-d flows according to priority, unnecessary waste of power may occur, which may adversely affect the performance of other terminals. Moreover, the differential of QoS due to power offset cannot be utilized.

As wireless data communication networks such as DC-HSUPA can support higher data rates, various services can be provided, and necessity thereof is emerging. For example, different types of services are required, such as File Transfer Protocol (FTP), Voice over Internet Protocol (VoIP), and Real-Time Video on Demand (VOD). You need to apply

Another embodiment of the present invention to be described below provides an E-TFC selection method of a terminal according to a power offset in a wireless mobile communication system such as DC-HSUPA.

Specifically, the E-TFC selection method according to the power offset preferentially allocates MAC-d flows having power offsets of the same or similar size to each carrier, so that each carrier can provide different services. . In this case, the similar size means a case in which a difference between two power offsets is the same size within a predetermined range. As an example, if a range of +/- 1 is specified, the power offsets of 4, 5, 6 are considered similar.

FIG. 3 illustrates a transmission power level for each carrier when multiplexing MAC-d flows having different power offsets according to power offsets according to another embodiment of the present invention. Configuration information of the MAC-d flows is shown in Table 1 below.

MAC-d flow ID Power offset Priority Data size MAC-d flow 1 0 2 500 bits MAC-d flow 2 6 One 500 bits MAC-d flow 3 6 One 1000 bits

In FIG. 3, for convenience of description, the transmission power levels of the multiplexed according to the data rate 302 and the transmission power levels of the multiplexed according to the power offset 304 are shown. As shown, MAC-d flow 1 has a power offset of 0 and a data size of priority 2 and 500 bits, and MAC-d flow 2 has a power offset of 6 and a data size of priority 1 and 500 bits. flow 3 has power offset 6 and data size of priority 1 and 1000 bits.

In the first case 302, 500 bits of MAC-d flow 1 and 500 bits of MAC-d flow 2 are assigned to the f ₁ carrier in order to assign similar data rates to the two carriers f ₁ , f ₂ . And 1000 bits of MAC-d flow 3 is allocated to the f ₂ carrier. In the f ₁ carrier in which MAC-d flows 1 and 2 are multiplexed, the power offset follows 6, which is the power offset of MAC-d flow 2 because MAC-d flow 2 has a higher priority. The power offset 6 results in double E-DPDCH power increase by Equation 1 mentioned above. As a result, the E-DPDCH power of the f ₁ carrier becomes 2 XP _A. Here, P _A refers to the E-DPDCH power used to transmit 1000 bits when the power offset is zero. The E-DPDCH power of the f ₂ carrier on which only the MAC-d flow 3 is loaded is 2 XP _A by the power offset 6 of the MAC-d flow 3. As a result, the total E-DPDCH power applied to the two carriers in the first case is as follows.

E-DPDCHs Total Power = P ₁ (= 2XP _A ) + P ₂ (= 2XP _A ) = 4 XP _A

In the second case 304, in order to assign MAC-d flows with similar power offsets to the two carriers f ₁ , f ₂ , 500 bits of MAC-d flow 2 and 1000 bits of MAC-d flow 3 are assigned to f _1. Assigned to the carrier. 500 bits of the MAC-d flow 1 are allocated to the f ₂ carrier. In this case, the power offset of the f ₁ carrier becomes 6, the power offset of the f ₂ carrier becomes 0, and the total E-DPDCH power applied to the two carriers is as follows.

E-DPDCHs total power = P ' ₁ (= 3XP _A ) + P' ₂ (= 0.5XP _A ) = 3.5 XP _A

Comparing the above two cases (302, 304), it can be seen that the E-TFC selection method according to the power offset can reduce the power consumption by 0.5 XP _A compared to the method considering the data rate.

4 is a flowchart illustrating an operation according to the embodiment of FIG. 3. The illustrated operation may be performed by a processor in charge of E-TFC selection of a terminal as an example.

Referring to FIG. 4, in step 402, the UE compares a transmission buffer occupancy (BO) with 0 to determine whether there is data that can be transmitted in a current TTI. If BO is not 0, the process proceeds to step 404 to continue the E-TFC selection operation. If BO is 0, the process waits until the next TTI and returns to step 402 to resume the E-TFC selection operation.

In step 404, the UE checks whether there are two or more MAC-d flows to be transmitted. This may be performed by checking the number of MAC-d flows set between the terminal and the base station. If the number of MAC-d flows present in the terminal is two or more, the process proceeds to step 406 to continue the E-TFC selection operation. On the other hand, if there is only one MAC-d flow present in the terminal, in step 414, the UE determines the MAC-d flow in the range of the maximum power (MAX power) and the maximum UE transmission power allowed for each carrier. Allocates data to the appropriate carrier Here, the maximum terminal transmit power means the maximum transmit power allowed to the terminal in the network, and is calculated as the sum of the power of the first carrier and the power of the second carrier. In addition, the maximum power allowed for each carrier means the maximum transmit power allowed for each carrier in the network.

In step 406, the UE checks whether there are at least two MAC-d flows having the same power offset among the entire MAC-d flows. If there are at least two MAC-d flows with the same power offset, the flow proceeds to step 408; otherwise, the flow proceeds to step 410.

In step 408, the UE selects MAC-d flows having the same power offset among the entire MAC-d flows and assigns them to the first carrier within the maximum terminal transmit power. In this case, the first carrier is selected as a carrier capable of transmitting as much data as possible by comparing the power required for transmitting the selected MAC-d flows with the maximum power allowed for each carrier. That is, the MAC-d flows are selected such that the sum of total transmit powers of MAC-d flows having the same power offset is not greater than the maximum power allowed for the first carrier.

In step 410, the UE selects MAC-d flows having similar power offsets and assigns them to the first carrier within the maximum UE transmit power so as to minimize the total power of the UE. Similarly, the first carrier is selected to transmit as much data as possible. Here, similar power offsets mean a case where the difference between the corresponding power offsets is within a predetermined range. In a modified embodiment, even after MAC-d flows having the same power offset are allocated to the first carrier, if there is a margin in the maximum power allowed for the first carrier, MAC-d flows having a similar power offset may be additionally added. It may be assigned to one carrier.

In step 412, the UE allocates the remaining MAC-d flows not allocated to the first carrier to the second carrier. If the terminal can operate two or more carriers, the operations of steps 406 to 412 may be repeated for the subsequent carriers. When the carrier assignment for the MAC-d flow is completed as described above, the data of the MAC-d flows are multiplexed for each carrier and then transmitted to the base station through the corresponding carrier.

MAC-d data transmitted through each carrier includes an identifier of a MAC-d flow to which each data belongs, as a header. Accordingly, the base station can recognize the MAC-d flow belonging to the MAC-d data by receiving the MAC-d data through each carrier and checking the header of the MAC-d data.

5 is a block diagram of a terminal according to an embodiment of the present invention. Here, only the main components related to the implementation of the embodiments of the present invention are shown. As shown in the figure, the terminal is largely composed of a controller 514 and transmitters 502 to 512 that handle transmission of actual data under the control of the controller 514.

Referring to FIG. 5, the MAC layer processor 502 receives data to be transmitted by a terminal and outputs the data by distinguishing them into different MAC-d flows according to the type and service type of the logical channel through which the data is transmitted. do. Here, as an example, a case where data paths of N MAC-d flows are generated is illustrated. Data of each MAC-d flow is transferred to an encoding / rate-matching unit 504. The encoding / rate matching unit 504 is composed of a plurality of flow-specific processing elements corresponding to a plurality of MAC-d flows generated by the MAC layer processor 502, and each processing element is a corresponding MAC. -d The data of the flow is received from the MAC layer processor 502 and properly encoded and rate matched according to the transmission format of the MAC-d flow.

After encoding and rate matching, the data of each MAC-d flow is transferred to the gain adjuster 506. The gain adjuster 506 is each provided to a plurality of MAC-d flows generated by the MAC layer processor 502. FIG. Comprising a plurality of multipliers, each multiplier receives the data of the MAC-d flow from the encoding / late matching unit 504 and multiplies the gain factor determined for the MAC-d flow. In this case, each of the gain factors to be multiplied has a value to which a power offset determined for the corresponding MAC-d flow is applied.

The multiplexer 508 receives data of MAC-d flows passed through the gain adjuster 506 and multiplexes the MAC-d flows for each carrier under the control of the controller 514. As an example, when the data of the MAC-d flows 1,2 and 3 shown in FIGS. 3 and 2 are input, the multiplexer 508 multiplexes the data of the MAC-d flows 1 and 3 to transmit a first carrier transmitter. And outputs data of the MAC-d flow 2 to the second carrier transmitter 512. The first and second carrier transmitters 510 and 512 carry data transmitted from the multiplexer 508 on the carrier and transmit the data to the base station through an antenna.

The controller 514 performs a TFC selection algorithm according to at least one of the embodiments of the present invention described above, to instruct the multiplexer 508 on which carrier the incoming MAC-d flows should be multiplexed. Additionally, the controller 514 may determine the data size, power offset, priority, coding scheme, etc. of each MAC-d flow according to the TFC selection algorithm.

By considering the power offset in performing the E-TFC selection in the DC-HSUPA as described above, the transmission power of the terminal can be reduced, thereby not only reducing network interference and improving efficiency of the terminal, but also improving QoS. Can be provided more clearly.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications may be made 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 determined not only by the scope of the following claims, but also by the equivalents of the claims.

1 is a diagram illustrating transmission of uplink data through an E-DCH in a mobile communication system according to a preferred embodiment of the present invention.

2 is a diagram showing transmission power levels for respective carriers according to an embodiment of the present invention.

3 is a diagram showing transmission power levels for respective carriers according to another embodiment of the present invention.

4 is a flow chart showing operation according to the embodiment of FIG.

5 is a block diagram of a terminal according to a preferred embodiment of the present invention.

Claims (8)

In the method of providing the uplink service in a wireless communication system using at least two carriers for the uplink service, Allocating at least two first data flows having the same power offset among all data flows to be transmitted to the first carrier, Allocating the remaining data flows of the entire data flows to a second carrier; Multiplexing data of the allocated data flows for each carrier and transmitting the data to the base station through the first carrier and the second carrier; And the first data flows allocated to the first carrier are selected such that the total transmit power of the first data flows does not exceed the maximum transmit power allowed by the terminal. The method of claim 1, further comprising: assigning the first carrier to at least two second data flows having power offsets within a predetermined range when there are no first data flows having the same power offset. , And the second data flows allocated to the first carrier are selected such that the total transmit power of the second data flows does not exceed the maximum transmit power allowed by the terminal. The method of claim 1, wherein each of the power offsets is applied to differentiate a quality of service (QoS) of a corresponding data flow. The method of claim 1, wherein each of the power offsets is used to calculate a gain factor for determining transmission power of a corresponding data flow. An apparatus for providing uplink service in a wireless communication system using at least two carriers for uplink service, A controller for allocating at least two first data flows having the same power offset among all the data flows to be transmitted to the first carrier and allocating the remaining data flows among the all data flows to the second carrier; A transmitter for multiplexing data of the allocated data flows for each carrier and transmitting the data to a base station through the first carrier and the second carrier, And the first data flows allocated to the first carrier are selected such that the total transmit power of the first data flows does not exceed the maximum transmit power allowed by the terminal. The method of claim 5, wherein the controller, If there are no first data flows having the same power offset, assign at least two second data flows having power offsets within a predetermined range to the first carrier, And the second data flows allocated to the first carrier are selected such that the total transmit power of the second data flows does not exceed the maximum transmit power allowed by the terminal. The apparatus of claim 5, wherein each of the power offsets is applied to differentiate a quality of service (QoS) of a corresponding data flow. The apparatus of claim 5, wherein each of the power offsets is used to calculate a gain factor for determining transmission power of a corresponding data flow.

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