KR20050073497A - Method for controlling transmit power of uplink retransmit packet in radio mobile communication system - Google Patents

Abstract

The present invention relates to a method for configuring transmission power of an uplink retransmission packet (E-DCH packet) in consideration of a base station scheduling and HARQ in a 3GPP WCDMA system, and in particular, a dedicated physical data channel (DPDCH) and a dedicated physical control channel (DPCCH). In a wireless mobile communication system for transmitting an uplink E-DCH packet to a base station using Rx), when the uplink E-DCH packet of a terminal is retransmitted, a relative transmission power ratio for the DPCCH of the DPDCH is initially transmitted. We propose a scheme that can be properly scheduled within a range not greater than the transmit power ratio of.

Description

How to set up transmit power of uplink retransmission packet in wireless mobile communication system {METHOD FOR CONTROLLING TRANSMIT POWER OF UPLINK RETRANSMIT PACKET IN RADIO MOBILE COMMUNICATION SYSTEM}

The present invention relates to uplink E-DCH packet transmission in a 3GPP WCDMA system, and more particularly, to a transmission power setting method capable of effectively setting a transmission power of an uplink retransmission packet in consideration of base station scheduling and HARQ.

In the cellular wireless mobile communication system in accordance with the demand of the high speed of the uplink, there is an active discussion about the transmission of data from the terminal to the base station, that is, the high-speed packet communication method in the uplink, which is discussed in 3GPP wireless mobile communication. An enhanced uplink dedicated channel (E-DCH) is a representative example.

In the E-DCH technology, uplink packet scheduling by a base station (Node B) and a hybrid ARQ (HARQ) in the physical layer are introduced into an existing 3GPP WCDMA uplink dedicated channel (DCH) to improve uplink efficiency. I'm trying. However, the transmission power determination method applied to uplink DCH transmission in the existing 3GPP WCDMA system may be inefficient to apply to the E-DCH in which the new technologies are introduced. Therefore, the present invention proposes a transmission power determination method applicable to 3GPP WCDMA E-DCH.

TFC and β-factors for Uplink DCH Transmission

The existing 3GPP WCDMA uplink DCH data is transmitted through a dedicated physical data channel (DPDCH) through channel coding and multiplexing in the physical layer. In the DPDCH frame, data requested to be transmitted on a plurality of DCHs may be multiplexed and transmitted. The multiplexed format of the DCH data in the DPDCH is called a transport format combination (TFC).

In general, in the physical layer, a DPDCH frame is transmitted by I / Q multiplexing with a dedicated physical control channel (DPCCH). The DPCCH includes TFC information of the DPDCH transmitted together, a pilot signal for uplink power control and data demodulation, and other control signals.

The transmit power of the uplink DPDCH is determined as a value relative to the uplink DPCCH transmit power transmitted together. In more detail, in the 3GPP WCDMA standard, the transmission power ratio of DPCCH and DPDCH is defined as β-factor. β-factor is the nominal value for the amplitude of the DPDCH Is a nominal value for the transmission size of Divided into Therefore, the ratio of DPDCH transmit power to DPCCH transmit power is Is determined.

Β-factor in the current standard Can be determined in two ways.

In the first method, the β-factor values are determined for each TFC in the upper layer. In the second method, the β-factor value is determined for the reference TFC in the upper layer. For other TFCs, the corresponding β- factor is determined in the physical layer. The remaining β-factor value is determined by combining and calculating the factor value and other information. In both of these schemes, the β-factor value is determined semi-statically according to each TFC. Therefore, the transmission power of the DPDCH for the DPCCH is fixed according to the TFC.

TFCS Management for Uplink DCH Transmission

The TFC allowed for transmission on the uplink DCH is basically determined by the upper layer. When the set of TFCs is called TFCS (TFCS), if the TFCS defined by the upper layer is called TFCS _RNC , the physical layer of the UE is the β-factor value corresponding to each TFC belonging to the TFCS _RNC and the maximum transmit power of the UE. In consideration of this, the TFC is continuously updated to determine whether the TFC is actually transmittable. In this way, if the set of TFCs determined to be transmitted is called a TFCS _UE , the UE can perform uplink DCH transmission only to the TFC belonging to both the TFCS _RNC and the TFCS _UE .

Node B Scheduling in Uplink E-DCH

In the current 3GPP WCDMA system standard, the uplink E-DCH is similar to the existing uplink DCH, but additional techniques for improving uplink packet transmission efficiency are discussed. Node B (base station) scheduling for uplink transmission is one of the core technologies under consideration for E-DCH. In the currently discussed Node B scheduling technique, Node B continuously controls TFCS that can be transmitted on the uplink E-DCH for each UE so that the amount of uplink interference is maintained at an appropriate level. For example, Node B currently allows transmission of TFCs that require large transmission power when the amount of uplink interference is relatively small and transmission of TFCs that require large transmission power when the amount of uplink interference is relatively large. By banning, the amount of uplink interference can be maintained at an appropriate level.

In addition, Node B allows the transmission of TFCs that require large transmission power to certain UEs at certain time points and prohibits the transmission of TFCs that require large transmission power to other UEs. Reduce the increasing situation. In a similar manner, Node B may directly control the allowable transmit power of each UE instead of controlling the transmittable TFCS of each UE. In this case, the UE may derive TFCS that can be transmitted using the β-factor within the transmission power allowed by the Node B at each uplink E-DCH transmission time.

Therefore, as described above, the TFCS _RNC allowing the transmission of the upper layer for the E-DCH, the transmittable TFCS _UE managed by the UE physical layer, and the transmission allowed TFCS _{Node B} controlled by the _{Node B} exist. According to the current general assumption, the UE may perform E-DCH transmission only in a TFC format included in all three TFCSs at any time.

HARQ on Uplink E-DCH

Hybrid ARQ (HARQ) in the physical layer is one of the core technologies that are being applied to the E-DCH. In HARQ technology, the physical layer of the Node B informs the UE of ACK / NACK feedback whether or not decoding (reception) of a packet transmitted on the uplink E-DCH is successful. When applying the general ARQ technique, Node B discards a packet that failed to decode previously and performs new decoding on the retransmitted packet. However, when the HARQ technique is applied, Node B stores a packet that has previously failed to decode in a reception buffer, and when receiving a retransmission packet, combines the retransmission packet with a previously decoded packet that has been previously stored and then decodes the packet. By performing this, it is possible to improve the packet decoding performance at the time of retransmission.

However, the transmission power of the existing uplink DPDCH is fixed semi-statically to a value relative to the DPCCH according to the TFC. Even when retransmitting an E-DCH packet, the TFC of the corresponding DPDCH is not changed, and thus, the β-factor value for retransmission is not changed. Therefore, when this method is applied to E-DCH transmission as it is, the transmission power ratio of (E) DPDCH to (E) DPCCH to which retransmission packets are transmitted is fixed to the same value as the first transmission packet.

However, in the uplink E-DCH packet transmission to which HARQ is applied, Node B combines and decodes the retransmitted E-DCH packet and the packet that has not been previously decoded because decoding fails, and thus a desired packet may be transmitted with a smaller transmission power than the previous transmission power. Decoding performance can be obtained. Therefore, transmitting a retransmission packet at a transmission power ratio equal to the previous transmission power ratio has a problem that it may be inefficient in terms of uplink interference management.

In addition, when considering Node B scheduling, Node B should always allocate the same power ratio to retransmitted E-DCH packets, which may cause a lack of scheduling freedom to adjust the amount of uplink interference.

An object of the present invention is to provide a transmission power setting method that can effectively set the transmission power of the uplink retransmission packet in consideration of the base station scheduling and HARQ.

Another object of the present invention is to provide a transmission power setting method that can be applied to uplink E-DCH packet transmission.

Another object of the present invention is to provide a transmission power setting method for a retransmission packet when transmitting an uplink E-DCH packet.

In order to achieve the above object, in a wireless mobile communication system for transmitting an uplink E-DCH packet to a base station using a dedicated physical data channel (DPDCH) and a dedicated physical control channel (DPCCH), retransmission according to the present invention The transmission power setting method of a packet is characterized in that, when retransmission of an uplink E-DCH packet, the relative transmission power ratio for the DPCCH of the DPDCH is set differently from the transmission power ratio for the first transmission of the E-DCH packet.

Preferably, the transmission power ratio relative to the DPCCH of the DPDCH at the time of retransmission is set smaller than the transmission power ratio at the first transmission of the E-DCH packet.

Preferably, when the base station controls to select the transmission format combination (TFC) of the E-DCH packet only in the transmission format combination set (TFCS _{Node B} ) allowed by the base station, even if the TFC of the retransmission packet is not included in the TFCS _{Node B} And transmitting a retransmission packet.

Preferably, the TFC of the retransmission packet is the same as the TFC of the first transmitted packet.

Preferably, when the base station controls to select the TFC of the E-DCH packet only within the TFCS _{Node B} allowed by the base station, the terminal dynamically selects the β-factor value to be used for determining the transmission power of the E-DCH retransmission packet. In this case, the β-factor value is a β-factor value for DPDCH. Value and the β-factor value for DPCCH It means the value.

Preferably, the terminal is a TFC of the TFCS _NodeB And Out of the values Is the maximum value , When ≤ Proper to satisfy And It is characterized by selecting a value. In particular, in this case, the UE corresponds to the TFC of the first transmitted packet. And Each value And When you say ≤ To satisfy And Only the value is used to determine the transmit power of the retransmission packet.

Preferably, when the base station controls the transmission power of the E-DCH packet, the terminal is a β-factor value (β _{d (E-DCH)} and β _{c (E-DCH)} not to exceed the transmission power allowed by the base station Value) to determine the retransmission power of the E-DCH packet. In particular, in this case, the UE measures β _{d (E-DCH)} and β _{c (E-DCH)} values corresponding to the TFC of the first packet. And When you say ≤ The transmission power of the retransmission packet is determined using only the values of beta _{d (E-DCH)} and beta _{c (E-DCH)} satisfying.

Preferably, when the base station controls the transmission power of the E-DCH packet, the terminal does not exceed the maximum transmission power of the terminal when the E-DCH packet retransmission And It is characterized by selecting one of the values.

Hereinafter, preferred embodiments of the present invention will be described in detail.

The present invention is implemented in a mobile communication system such as a universal mobile telecommunications system (UMTS) developed by 3GPP, and is particularly applied to DCH transmission of 3GPP WCDMA uplink. However, the present invention can also be applied to communication systems operating according to other standards.

The present invention proposes a transmission power determination method that can be applied to 3GPP WCDMA E-DCH. Particularly, the present invention provides a method for more efficiently applying Node B scheduling and HARQ techniques to uplink E-DCH by freely setting transmission power for retransmission packets when transmitting uplink E-DCH packets in a 3GPP WCDMA system. Suggest. To this end, in the present invention, when retransmitting an uplink E-DCH packet in a 3GPP WCDMA system, a transmission power ratio of (E) DPDCH to (E) DPCCH is different from that of the first transmission packet. Preferably, the transmission power ratio for the (E) DPDCH of the (E) DPDCH of the retransmission packet is limited to less than the transmission power ratio at the time of initial transmission.

Hereinafter, a transmission power setting method for an uplink E-DCH retransmission packet will be described. First, in the case of Node B scheduling TFCS for E-DCH transmission, Node B scheduling (E) DPDCH transmission power for E-DCH transmission. And no Node B scheduling is applied to the E-DCH retransmission packet.

When Node B schedules TFCS for E-DCH transmission

1 is a view showing a transmission power setting method of an uplink transmission packet according to the present invention.

When Node B schedules TFCS for E-DCH transmission, UE uplink E-DCH packet transmission is performed considering the TFCS _NodeB controlled by the Node B scheduling command.

Referring to FIG. 1, when transmitting an E-DCH packet instead of retransmission, the UE selects an appropriate E-DCH TFC within the TFCS _NodeB range allowed by Node B as in the related art, and corresponds to the determined TFC. And The DPDCH transmission power is determined using the value, and then uplink transmission is performed (S10-S12). Where above And For (E) DPDCH and (E) DPCCH, respectively. -Means a factor. Also, the or Depending on the implementation of the or It may not be defined separately from.

In addition, when retransmitting an E-DCH packet, the TFC of the retransmission packet is the same as the TFC of the first transmitted packet, and the UE may retransmit even if the corresponding TFC is not included in the TFCS _NodeB at the time of retransmission. Used to determine transmission power of E-DCH retransmission packet of UE And The value is not determined according to the TFC, but can be determined in the following manner.

That is, the TFCs included in the TFCS _{Node B} And Out of the values Is the maximum value And When the terminal is called ≤ Proper to satisfy And A value is selected (S13).

Once appropriate And If a value is selected, the terminal And The retransmission power of the E-DCH packet is determined using the value, and then the E-DCH packet is retransmitted at the determined transmission power (S13-S15).

By using this method, it is possible to determine transmission power of E-DCH retransmission packet of UE. And To determine the value, The argument value is applied to the initial transfer. Can be different from the argument value. Additionally, the TFC of the first packet sent And Each value And In order to prevent the DPDCH transmission power of the retransmission packet from exceeding the transmission power at the initial transmission, ≤ To satisfy And You can restrict it to using only values.

When Node B schedules (E) DPDCH transmit power for E-DCH transmission

When Node B schedules (E) DPDCH transmission power for E-DCH transmission, uplink E-DCH packet transmission is performed within the transmission power allowed by the Node B scheduling command.

When transmitting E-DCH packets rather than retransmissions, the UE, as in the prior art, transmits the transmission power required for transmission of each available E-DCH TFC. And Obtained using the value. After selecting the appropriate TFC that can transmit within the range of transmit power allowed by Node B, And Determining the transmission power by using and performs uplink transmission.

Also, when retransmitting an E-DCH packet, the UE does not exceed the transmission power allowed by the Node B. And Select one of the values to determine the transmit power. Thus, applying to retransmission packets The argument value is applied at the first transmission. Can be different from the argument value. Additionally, the TFC of the first packet sent And Each value And When indicated as a value, in order to ensure that the DPDCH transmit power of the retransmission packet does not exceed the transmit power at the first transmission, the UE is capable of doing so. And Of the values ≤ It can be limited to use only values that satisfy.

When Node B scheduling is not applied to E-DCH retransmission packet

Finally, when Node B scheduling is not applied to the E-DCH retransmission packet, there is no limitation of the E-DCH transmission TFC or transmission power by Node B. At this time, when retransmitting the E-DCH packet, it corresponds to the TFC of the first transmitted packet. And Each value And In order to ensure that the DPDCH transmit power of the retransmission packet does not exceed the transmit power at the first transmission, And Of the values ≤ A value satisfying the following may be appropriately selected.

In addition, if the power at the initial transmission of the E-DCH packet is P, the power to be used for retransmission of the packet is defined as αP, and the retransmission power (αP) must satisfy the following equation.

≤ αP

Here, α is a real number that is signaled in the upper layer and satisfies α ≦ 1.

On the other hand, the TFCS _{UE, which} is a transmittable TFC set managed by the UE, is not considered in determining transmission power for the E-DCH retransmission packet. That is, even if the TFC of the packet to be retransmitted is not included in the TFCS _UE , the UE may transmit the packet. Instead, the UE determines the transmit power within a range in which the transmit power of the retransmission packet does not exceed the maximum transmit power of the UE.

As described above, in the present invention, when retransmitting an uplink E-DCH packet in a 3GPP WCDMA system, the transmission power ratio of (E) DPDCH for (E) DPCCH is less than the transmission power ratio of the first transmission packet so that the retransmission packet is unnecessary. By reducing the case of transmitting at a large power, there is an effect that can reduce the amount of uplink interference and improve the uplink capacity.

In addition, although the present invention has been described with reference to the embodiments illustrated in the drawings, this is merely exemplary and will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. . Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

As described above, in the present invention, when retransmitting an uplink E-DCH packet in a 3GPP WCDMA system, the transmission power ratio of (E) DPDCH for (E) DPCCH is less than the transmission power ratio of the first transmission packet so that the retransmission packet is unnecessary. By reducing the case of transmitting at a large power, there is an effect that can reduce the amount of uplink interference and improve the uplink capacity.

In addition, although the present invention has been described with reference to the embodiments illustrated in the drawings, this is merely exemplary and will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. . Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1 is a flowchart illustrating an implementation process of a method of setting a transmission power of an uplink transmission packet according to the present invention.

Claims (13)

A wireless mobile communication system for transmitting an uplink E-DCH packet to a base station using a dedicated physical data channel (DPDCH) and a dedicated physical control channel (DPCCH), The terminal sets the transmission power ratio relative to the DPCCH of the DPDCH when the transmission of the uplink E-DCH packet different from the transmission power ratio of the first transmission of the E-DCH packet. The method of claim 1, wherein the relative transmission power ratio of the DPDCH to the DPCCH at the time of the retransmission is set smaller than the transmission power ratio at the first transmission of the E-DCH packet. The TFC _{node B} according to claim 1, wherein when the base station controls the TFC selection of the E-DCH packet to be selected only within the transmission format combination set (TFCS _{Node B} ) allowed by the base station, the TFC of the retransmission packet is transmitted to the TFCS _{Node B.} The transmission power setting method of the retransmission packet, characterized in that for transmitting a retransmission packet even if not included. 4. The transmission format combination (TFC) of claim 3, wherein A transmission power setting method of a retransmission packet, characterized in that the same as the TFC of the first packet transmitted. The method of claim 1, wherein, when the base station controls to select the TFC of the E-DCH packet only within the TFCS _{Node B} allowed by the base station, the terminal is used to determine the transmission power of the E-DCH retransmission packet. -Transmission power setting method of a retransmission packet, characterized in that the argument value is selected dynamically. The method of claim 5, wherein The argument value is For DPDCH Argument value For values and DPDCH Argument value The transmission power setting method of the retransmission packet, characterized in that the value. The method of claim 5, wherein the terminal TFCs included in the TFCS _NodeB And Out of the values Of Is the maximum value , When Of ≤ Of Proper to satisfy And A transmission power setting method of a retransmission packet, characterized by selecting a value. 8. The method of claim 7, wherein the first packet corresponds to the TFC of the transmitted packet. And Each value And Indicates that the transmit power of the retransmission packet meets the following conditions: And A transmission power setting method of a retransmission packet, characterized in that the determination using only a value. Of ≤ Of The method of claim 1, wherein when the scheduling of the base station is applied to the re-transmitted E-DCH packet, the terminal does not exceed the transmission power allowed by the base station Argument value ( And Transmitting power of the retransmission packet is selected by selecting one of the E-DCH packets. 10. The method of claim 9, wherein the TFC of the first transmitted packet And Each value And Indicates that the transmit power of the retransmission packet meets the following conditions: And A transmission power setting method of a retransmission packet, characterized in that the determination using only a value. ( , ) ≤ ( , ) The method of claim 1, wherein when the scheduling of the base station is not applied to the retransmitted E-DCH packet, the terminal does not exceed the transmission power of the first packet transmitted. Argument value ( And Transmitting power of the retransmission packet is selected by selecting one of the E-DCH packets. 12. The method of claim 11, wherein the TFC of the first transmitted packet And Each value And When the DPDCH transmission power of the retransmission packet is satisfied, And A transmission power setting method for a retransmission packet, characterized in that the value is appropriately selected and determined. ( , ) ≤ ( , ) 12. The method of claim 11, wherein when the power of the first packet is P, transmission power to be used for retransmission is determined as αP, and αP satisfies the following equation. Here,? ≤ αP