KR20070006400A - Method for controlling transmission power of channel controlling data retransmission in mobile communication systems - Google Patents

Abstract

A method for controlling transmission power of a channel to control data re-transmission of a mobile communication system is provided to prevent a terminal located in an adjacent region from unnecessarily consuming power while maintaining a reception detection rate of an ACK channel in a cell boundary region. It is checked whether a mobile terminal is in a cell boundary region. Namely, it is checked whether the mobile terminal performs cell switching from a serving base station to a target base station. Pre-set transmission power of the first channel which is applied during a pre-set interval is obtained according to the checking result. A signal is transmitted through the first channel with the obtained transmission power. The first channel is an ACK channel for transmitting ACK/NACK information for controlling data re-transmission of a base station.

Description

Method for controlling transmission power of channel controlling data retransmission in mobile communication systems

1 is a diagram illustrating an operation of HARQ on a packet data channel in a cdma2000 1xEV-DO system.

2 is a diagram illustrating a transmission structure of an ACK channel included in a reverse control channel.

3 is a diagram illustrating a cell boundary region for determining transmission power of an ACK channel according to the present invention.

4 is a diagram illustrating a method of controlling transmit power of an ACK channel according to a preferred embodiment of the present invention.

The present invention relates to a transmission power determination method of a mobile communication system, and more particularly, a transmission power determination method of a channel for controlling data retransmission of a base station that can prevent power waste while maintaining a high reception detection rate in a mobile communication system. It is about.

Hereinafter, a method of determining a transmission power of a system of a system of a mobile communication according to the prior art will be described. As an example of various communication systems, a method of determining a transmission power of a communication system according to cdma2000 1xEV-DO (1x Evolution-Data Only) Take a look.

In a current mobile communication system, broadcast or unicast (Broadcast / Unicast) is sent through Packet Data Channels of a physical layer. The Packet Data Channels are designed to reliably and reliably send Internet or Near Real-time or Non-real-time video in a mobile communication environment where fading exists. Hybrid Automatic Repeat Request (hereinafter referred to as 'HARQ') Technology). HARQ is a technology in which Forward Error Correction (hereinafter referred to as 'FEC') and Automatic Repeat reQuest (hereinafter referred to as 'ARQ') are combined, and the raw data (hereinafter referred to as 'Raw Data') is an error in a fading environment. Encoding is performed by using a channel code having an error correction function, and then it is divided into several sub-packets and sequentially sent. The receiver decodes the sub-packets and sends an acknowledgment signal (hereinafter referred to as 'ACK') when the sub-packets are successfully received without error. If not, the receiver receives a non-acknowledgement (hereinafter referred to as 'NACK'). Send it. The transmitting end no longer retransmits a packet that has received an ACK from the receiving end, and then transmits the next new packet. If the NACK is received from the receiving end, the transmitting end transmits the next subpacket for the packet receiving the NACK.

1 illustrates an operation of HARQ for a packet data channel in a cdma2000 1xEV-DO system. As shown in FIG. 1, the packet data channel has a structure in which it is transmitted through four interlaces. One encoder packet is transmitted using one of the four interlaces, and when the interlace used for the transmission is determined, the encoder packet transmitted by the determined interlace is transmitted. Continue to use the interlace until it succeeds. FIG. 1 illustrates an example of transmitting an encoder packet using interlace 0. The first subpacket for the encoder packet is P00 and the second subpacket is shown in FIG. (Sub-packet) as P01, the third sub-packet (P02) and the fourth sub-packet as P03. In addition, when defining the first sub-packet (P-packet) for the new encoder packet (Encoder Packet) next to the encoder packet as P10, the transmitting end interlaces the first sub-packet (P10) ) Wait for ACK / NACK after transmitting to slot corresponding to 0. The interval to the slot corresponding to the next Interlace 0 uses a synchronous structure fixed to 4 slots because the total interlace consists of four. After receiving the NACK, the receiving end that fails to decode P00 receives P01, combines it with P00 previously received and stored in the buffer, and then decodes again. If the decoding is successful, the ACK is transmitted. If the decoding is not successful, the NACK is transmitted. The subpackets assigned to each interlace are independent of each other in ACK / NACK operation. For example, the reception of an ACK / NACK signal for subpackets assigned to interlace 0 and a subsequent retransmission operation may include the reception of an ACK / NACK signal for subpackets assigned to other interlaces such as interlace 1 and the like. Independent of retransmission behavior.

The ACK / NACK information is transmitted to a base station using an ACK channel included in a reverse link control channel. The transmission power of the ACK channel included in the reverse control channel is determined by the ACK channel gain. The ACK channel gain information is transmitted through a traffic channel assignment message as shown in Table 1 below. Table 1 below shows part of a traffic channel assignment message transmitted from a base station.

Field Length (bits) MessageID 8 MessageSequence 8 ChannelIncluded One Channel 0 or 24 FrameOffset 4 DRCLength 2 DRCChannelGain 66 ACKChannelGain 6 NumPilots  4

NumPilots occurrences of the following record:

PilotPN 9 Softerhandoff One MACIndexLSBs 6 DRCCover 3 RABLength 2 RABOffset 3

[...]

2 is a diagram illustrating a transmission structure of an ACK channel included in a reverse control channel. As shown in FIG. 2, the ACK channel is time-divisionally transmitted with a DSC (Data Source Control) channel. That is, the reverse control channel has a structure in which ARQ information and DSC information are time-divided and transmitted in one slot. The DSC channel transmits information for distinguishing each cell and informs the base station of information of a target cell when the terminal switches to another cell. Packet data It serves to smooth cell switching of transmissions. The terminal may receive a signal from the base station of the cell, and inform the base station of the information about the switching of the cell to the base station through the DSC channel according to the received power of the signal. It can inform the base station through the DSC channel. As shown in FIG. 3, the UE updates and transmits DSC information for each DSCLength slot, and when switching from cell A to cell B, cell switching by indicating the cell B with DSC information. smooth switching. The cell switching is to switch a cell to which the terminal belongs, and after switching, the terminal communicates with a base station of the target cell, that is, the target base station.

When the base station properly detects an ACK / NACK signal transmitted by the terminal through an ACK channel, the terminal can receive a new packet for the ACK and receive the next subpacket for the NACK. If the base station detects the NACK incorrectly when the terminal transmits the ACK to the base station through the ACK channel, the base station sends the next sub packet and the terminal incorrectly recognizes the sub packet sent by the base station as a new packet. Is generated.

As described above, the reliability of the ACK channel is very important in the mobile communication system. However, the ACK channel gain does not consider a cell boundary region of the cell and a region other than the cell boundary region of the cell. For this reason, the prior art causes the following problems. If the UE determines the ACK channel gain in order to maintain appropriate reliability of the ACK channel based on the cell boundary region of the cell, the UE is not in the cell boundary region of the cell. The ACK channel transmission power of the unsuccessful terminal is greater than the power required for ensuring reliability, thereby increasing interference with respect to the terminal belonging to the cell. This increase in interference also causes a problem of reducing the backward capacity of the system. In addition, if the base station determines the ACK channel gain (ACKChannelGain) in order to maintain the reception reliability of the ACK channel based on the terminal located in the area other than the cell boundary area of the cell, the base station of the terminal in the cell boundary (Cell boundary) of the cell There is a problem that the reception detection rate of the ACK channel is lowered.

The present invention has been proposed to solve the above problems, and an object of the present invention is to provide a transmission power determination method of an ACK channel that can prevent power waste while maintaining a high reception detection rate.

The present invention can be applied to various wireless communication systems having an ACK channel for transmitting ACK / NACK information for controlling retransmission of a base station.

In a method of controlling a transmission power of a channel for data retransmission control of a mobile communication system according to the present invention, the method of controlling a transmission power of a first channel for controlling data retransmission of a base station by the mobile terminal, wherein the mobile terminal is the boundary of a cell Determining whether it is located in an area; Acquiring a predetermined transmission power of the first channel applied during a predetermined period according to the determination result; And transmitting a signal through the first channel at the obtained transmit power.

A detailed feature of the present invention is that the first channel is an ACK channel for transmitting ACK / NACK information for controlling data retransmission of a base station, and determining whether it is located in a boundary region of a cell includes: A step of determining whether to perform cell switching from a serving base station to a target base station, and the step of determining whether to perform cell switching, included in the reverse control channel for providing control information for cell switching to the base station It is a step of determining whether the DCS channel includes information about a target cell to be switched.

Acquiring a predetermined transmission power of the first channel according to the determination result, when the mobile terminal is located in the boundary region of the cell, the base channel gain value (ACKChannelGainBase) for the mobile terminal located in the adjacent region of the cell Acquiring an additional channel gain value (ACKChannelGainBoosted) for a mobile station located in the boundary region of the cell; And adding the obtained base channel gain value and the additional channel gain value (ACKChannelGainBase + ACKChannelGainBoosted).

In addition, in the present invention, the predetermined interval (ACKBoostLenth slot) preferably represents the length of the interval in which the transmission power of the first channel is increased.

The construction, operation and other features of the present invention will become apparent from the preferred embodiments of the present invention described with reference to the accompanying drawings.

The present invention overcomes the shortcomings of the conventional principles described above, and when the transmission power value of the ACK channel is determined, switching from a serving cell to which a mobile terminal is currently communicating with a target cell. The UE proposes to determine the transmit power of the ACK channel in consideration of both a cell boundary region, which is a point in time, and a region adjacent to the serving cell, that is, a region other than the cell boundary region.

3 is a conceptual diagram illustrating a terminal located in a cell boundary region and a terminal located in an area other than the cell boundary region according to the present invention. As shown, the present invention is to determine the transmission power of the ACK channel adjacent area adjacent to the base station (100, 200), and if the terminal is located in the area that is not the cell boundary (cell boundary area), that is, the adjacent area The case is as follows. When the second terminal 102 located in the cell neighboring region determines the transmission power of the ACK channel at the same power as the first terminal 101 located in the cell boundary region, detection of ACK / NACK information of the ACK channel is detected. The use of more power than the power required for the reliability) occurs. Accordingly, the second terminal 102 determines the transmission power value of the ACK channel according to the ACK channel gain value required for the reliability of detection of the ACK / NACK information of the ACK channel without reducing the backward capacity. It is desirable to. The present invention proposes that the second terminal 102 located in the adjacent region uses an ACKChannelGainBase value, which is a transmission power value that satisfies the reliability of detection of ACK / NACK information of the ACK channel and does not reduce the reverse capacity. . The first terminal 101 is located in a cell boundary region. When the transmission power is determined using the ACKChannelGainBase value, the first terminal 101 receives ACK / NACK information from the receiving side (that is, the serving base station 100). The problem of not correctly detecting the NACK information may occur. Accordingly, the present invention proposes that the first terminal 101 located in the cell boundary region transmits an ACK channel by adding ACKChannelGainBooested power to the ACKChannelGainBase power.

4 is a diagram illustrating an example in which transmission power of an ACK channel is controlled during cell switching according to the method according to the present invention. As shown, when the terminal is located in the cell A and is not switched to the cell B, the transmission power of the ACK channel is determined as ACKChannelGainBase, and ACK / NACK information is transmitted through the ACK channel. The determined ACKChannelGainBase is delivered in a TrafficChannelAssignment message from the base station. The ACKChannelGainBase is preferably determined in consideration of the ACK / NACK information detection rate at the receiving side of the ACK channel and the backward capacity for a specific cell. According to the present invention, the transmission power of the ACK channel is controlled differently according to whether the cell is located in the cell boundary region. Hereinafter, as an embodiment of the present invention, the terminal at the time of cell switching is identified as a terminal located in the cell boundary region. Let's look at an example.

According to a preferred embodiment of the present invention, when the terminal is transmitting the information on the target cell in the DSC channel in order to switch from the A cell (Cell) serving cell to the target cell (Cell), the terminal is A cell ( It is preferred to be considered to be in the boundary region of Cell) and B (Cell). In this case, the detection rate of the ACK / NACK information of the ACK channel should be maintained higher than that of each terminal located in an adjacent region of each cell. As a method of maintaining a high detection rate of the base station, the terminal may boost the transmission power of the ACK channel by ACKChannelGainBoosted. As a result, the transmission power of the ACK channel is preferably the sum of the ACKChannelGainBase and the ACKChannelGainBoosted. As shown in Figure 4, the transmission power control method according to an embodiment of the present invention increases the ACK channel transmission power of the terminal located in a particular section. The transmit power of the ACK channel is preferably boosted from the moment of cell switching, and more preferably, for a specific period. The interval in which the transmission power is increased is preferably a predetermined ACKBoostLength slot interval from the first slot of the DSC channel including the information that the cell is switched (that is, information on the target cell transmitted to the base station through the DSC channel). In addition, the transmission power of the ACK channel during the interval is more preferably the sum of ACKChannelGainBase and ACKChannelGainBoosted. If the ACKBoostLength slot is out of the length, it is preferable to transmit the transmission power of the ACK channel to the ACKChannelGainBase. The ACKBoostLength and ACKChannelGainBoosted are values included in a configuration attribute, and default values are determined in a performance negotiation process between the terminal and the base station and are known as the terminal.

Field Length (bits) MessageID 8 MessageSequence 8 ChannelIncluded One Channel 0 or 24 FrameOffset 4 DRCLength 2 DRCChannelGain 6 ACKChannelGainBase 6 NumPilots 4 NumPilots occurrences of the following record: PilotPN 9 Softerhandoff One MACIndexLSBs 6 DRCCover 3 RABLength 2 RABOffset 3

Table 2 shows part of the TrafficChannelAssignment message structure indicating the ACKChannelGainBase proposed in the present invention.

Attribute ID Attribute Values Meaning 0xff DRCGating 0x00 Continuous transmission 0x01 Discontinuous transmission 0xfe DRCLockLength 0x00 DRCLock bit is repeated 8 times. 0x01 DRCLock bit is repeated 16 times. 0x02 DRCLock bit is repeated 32 times. 0x03 DRCLock bit is repeated 64 times. All other values Reserved 0xfd MultiUserPacketsEnabled 0x00 Use of Multi-User Packets is disabled 0x01 Use of Multi-User Packets is enabled All other values Reserved 0xfc DSCLength 0x08 Length of a single DSC transmission is 64 slots. 0x01 to 0x20 Length of a single DSC transmission in units of 8 slots. All other values Reserved 0xfb DeltaACKChannelGainMUP 0x0c DeltaACKChannel GainMUP is 6 dB. 0x00 to 0x12 DeltaACK Channel Gain MUP in units of 0.5 dB. All other values Reserved 0xfa ShortPacketsEnabledThresh 0x01 ShortPacketsEnabledThresh is 2048 bits. 0x00 ShortPacketsEnabledThresh is 1024 bits. 0x02 ShortPacketsEnabledThresh is 3072 bits. 0x03 ShortPacketsEnabledThresh is 4096 bits. All other values Reserved

0xf9 SingleUserMultiplexPacketsEnabled 0x00 Use of Single User Multiplex Packets is disabled 0x01 Use of Single User Multiplex Packets is enabled All other values Reserved 0xf8 DRCSupervisionTimer 0x00 DRC Supervision Timer is 0 0x01-0xff Value of DRC Supervision Timer 0xf7 ACKChannelGainBoosted 0x03 Increase in ACK Channel Gain is 3dB relative to ACKChannelGainBase starting in slot where DSC is changed 0x00 0x02, 0x04-0x06 Increase in ACK Channel Gain in dB relative to ACKChannelGainBase starting in slot where DSC is changed All other values Reserved 0xf6 ACKBoostLength 0x10 Number of slots starting with the slot in which the DSC is changed for which the ACK Channel Gain is boosted is 128 slots 0x01 to 0x40 Number of slots, in units of 8 slots starting with the slot in which the DSC is changed for which the ACK Channel Gain All other values Reserved

Table 3 shows Configuration Attributes including ACKBoostLength and ACKChannelGainBoosted proposed in the present invention. In Table 3, ACKChannelGainBoosted is set to 3dB as a default value, and ACKBoostLength is set to 128 slots as a default value. Each of the values suggested in the above table is a value that can be changed later.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be determined by the claims.

Effects of the transmission power control method according to the present invention as described above are as follows. When determining the transmission power of the ACK channel, it is determined by dividing the cell boundary region and the adjacent region instead of the cell boundary region so that the required ACK channel in the cell boundary region is determined. It is possible to prevent the terminal in the adjacent area from wasting power while maintaining the reception detection rate.

Claims (10)

A method for controlling a transmission power of a first channel for controlling data retransmission of a base station by a mobile terminal, the method comprising: Determining whether the mobile terminal is located in a boundary region of a cell; Acquiring a predetermined transmission power of the first channel applied during a predetermined period according to the determination result; And Transmitting a signal through the first channel using the obtained transmit power; Transmission power control method of a communication channel for controlling data retransmission comprising. The method of claim 1 The first channel is a transmission power control method of a communication channel for controlling data retransmission, characterized in that the ACK channel for transmitting the ACK / NACK information for controlling data retransmission of the base station. The method of claim 1, wherein the determining of whether the cell is located at a boundary area of the cell comprises: And determining, by the mobile terminal, whether to switch cells from a serving base station to a target base station. The method of claim 3, wherein determining whether to perform cell switching comprises: And determining whether information on a target cell to be switched is included in a second channel included in the reverse control channel and providing control information for cell switching to a base station. Transmission power control method of communication channel. The method of claim 4, wherein And the second channel is a DSC channel for transmitting information for identifying each cell. The method of claim 1, wherein the obtaining of the predetermined transmission power of the first channel according to the determination result comprises: When the mobile terminal is located in a boundary region of a cell, obtaining a basic channel gain value for the mobile terminal located in an adjacent region of the cell and an additional channel gain value for the mobile terminal located in the boundary region of the cell; And And summing the obtained basic channel gain value and the additional channel gain value. The method of claim 6, The basic channel gain value is included in a traffic channel assignment message transmitted from the base station (TrafficChannelAssignment) message, characterized in that the transmission power control method of a communication channel for controlling data retransmission. The method of claim 6, The additional channel gain value is determined by performance negotiation between a mobile station and a base station. The method of claim 1, The preset period is a transmission power control method of a communication channel for controlling data retransmission, characterized in that the length of the interval in which the transmission power of the first channel increases. The method of claim 9, The preset period is a transmission power control method of a communication channel for controlling data retransmission, characterized in that determined by the performance negotiation between the mobile terminal and the base station.

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