KR100953632B1 - Method for controlling transmission power of physical channel - Google Patents

Abstract

The present invention relates to a transmission power control method, and more particularly, to a transmission power control method of a physical channel that enables efficient transmission and reception of a physical channel when an imbalance exists between connected links in order to exchange data through a physical channel. As described above, when a forward link and a reverse link are established between a plurality of sectors and a terminal, the terminal includes a first power control bit transmitted from a sector having the forward link and the reverse link. The transmit power of the transmit power control channel for the plurality of sectors is determined from the second power control bits transmitted from the formed sectors.

Transmission power control

Description

Method for controlling transmission power of physical channel

1 is a diagram illustrating a link imbalance state of a general physical channel.

2 is a view for explaining the change in transmit power magnitude of the reverse pilot channel when the transmission control bit rise of the physical channel according to the prior art;

3 is a view for explaining a change in transmit power magnitude of a reverse pilot channel when the transmission control bit of a physical channel is down according to the prior art;

4 is a diagram illustrating a change in transmit power of a reverse pilot channel according to the present invention.

5 is a view for explaining a transmission power control method according to a first embodiment of the present invention.

6 is a view for explaining a transmission power control method according to a second embodiment of the present invention.

7 to 14 are diagrams for explaining the transmission power change rule according to the first embodiment of the present invention.

15 to 23 are diagrams for explaining the transmission power change rule according to the first embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *                 

100, 110, 120, 130: sector 140: terminal

The present invention relates to a transmission power control method, and more particularly, to a transmission power control method of a physical channel that enables efficient transmission and reception of a physical channel when an imbalance exists between connected links in order to exchange data through a physical channel.

There may be an imbalance between the connected links to exchange data over the physical channel. This imbalance between links is called link imbalance.

There are largely reverse link and forward link in the link.

The reverse link refers to a virtual channel transferring data from the terminal to the base station, and the forward link refers to a virtual channel transferring data from the base station to the terminal.

In addition, a physical channel for transmitting data or the like through the reverse link is called a reverse channel, and a physical channel for transmitting data or the like through the forward link is called a forward channel.

Hereinafter, link imbalance in a physical channel according to the prior art will be described with reference to the accompanying drawings.

1 is a diagram illustrating a link imbalance state of a general physical channel.                         

FIG. 1 is an exemplary diagram for explaining link imbalance, in which one terminal 14 and several sectors (first sector, second sector, ... Nth sector) 10, 11, 12, 13 are shown. In each case, a reverse link is formed, and only a specific forward link is formed between the first sector 10 and the terminal 14. In this case, it is assumed that sectors belonging to the same base station are represented by one sector. In addition, there may be other types of forward links in addition to the specific forward link, but the presence or absence of other types of forward links is not related to the present invention.

In general, in the case where a link is formed as shown in FIG. 1, among the possible forward links between each of the sectors 10, 11, 12, and 13 and the terminal 14, the first sector 10 and the terminal 14 are connected. Occurs when the forward link has the best transmission environment.

However, if the reverse link between the first sector 10 and the terminal 14 among the reverse links does not have the best transmission environment, the terminal 14 and any one of the other sectors 11, 12, 13 are not. If the reverse link between them has the best transmission environment, it is said that link imbalance has occurred.

In such a case, there is a problem in that a sector may not properly receive reverse channels being transmitted on the reverse link due to link imbalance.

As an example of such a case, the channels shown in the standard (3GPP2 C.S0002-C Version 1.0) of the mobile communication system established by 3GPP2 will be described as an example.

It is assumed that the forward channel of FIG. 1 is a forward packet data channel (F-PDCH). This F-PDCH is a physical channel for transmitting packet data in the forward direction and uses only the best forward link.

The reverse channels of FIG. 1 are assumed to be a reverse pilot channel (R-PICH), a reverse channel quality indictor channel (R-CQICH), a reverse acknowledgment channel (R-ACKCH), and a reverse packet data channel (R-PDCH). Here, the R-PDCH is a name for a reverse fundamental channel (R-FCH), a reverse supplemental channel (R-SCH), or a reverse packet dedicated channel to be developed in a later standard. That is, the R-PDCH means a channel for transmitting traffic or voice over the reverse link (hereinafter, the description will be given by taking only R-PDCH, R-CQICH, and R-ACKCH as an example. The majority of the linked sectors collectively refer to the reverse channel defined to receive, and the R-CQICH and R-ACKCH collectively refer to the reverse channel defined so that only a small number of sectors in the reverse linked sector receive. .

According to the standard, the first sector 10 transmitting the F-PDCH must receive the R-ACKCH and the R-CQICH from the terminal 14 through the reverse link. On the other hand, the R-PDCH is received by all sectors from the first sector 10 to the Nth sector 13.

The R-PICH is an auxiliary channel that helps each sector to properly receive reverse channels. There is a predetermined ratio between the transmit power of the R-PICH and the transmit power of the remaining reverse channels.

For convenience of explanation, assuming that T_cqich, T_ackch, T_pdch, and P are transmission powers of R-CQICH, R-ACKCH, R-PDCH, and R-PICH, respectively, the ratio between them is assumed to be as follows.

T_cqich / P = TP_cqich

T_ackch / P = TP_ackch

T_pdch / P = TP_pdch

Each sector receiving the reverse channels compares the received power of the received R-PICH with a specific value and transmits a power control command to the terminal through the specific forward channels.

Hereinafter, it is assumed that the power control command transmitted by sector_k is a power control bit (PCB) k. Further, if the received power of the R-PICH received in sector_k is smaller than the specified value, sector_k delivers PCB (k) = Up, and the received power of the R-PICH received in sector_k. If it is greater than or equal to this particular value, it is assumed that sector_k carries PCB (k) = Down.

It is assumed that the result of reading and receiving the PCB k from the terminal 14 is PCB k '. If no error occurred during transmission, PCB (k) = PCB (k ') would hold.

Meanwhile, the terminal 14 calculates a transmission power command to be performed by the terminal 14 using the values of the received power control commands. In this case, when the transmission power command calculated by the terminal 14 is called a PCB, the PCB value is determined by the following rule.

That is, if all power control commands received by the terminal 14, namely, PCB (1), PCB (2), and PCB (N), are all Up, PCB = Up, otherwise, PCB = Down. At this time, if PCB = Up, the terminal increases the transmit power of the R-PICH, and if PCB = Down, decreases the transmit power of the R-PICH. That is, the power control bit (PCB) Up only if all of the Up, even one Down Power control bit (PCB) Down.

Meanwhile, the increase and decrease of the transmission power depends on a predetermined value, hereinafter, it is assumed to increase or decrease by z dB. If the transmit power of the R-PICH is increased, the transmit power of the R-CQICH, R-ACKCH, and R-PDCH is also increased to comply with the ratio (for example, 1: 2: 5) defined in Equations 1 to 3; If the transmit power of the R-PICH decreases, the transmit power of the R-CQICH, R-ACKCH, and R-PDCH is similarly reduced.

2 and 3 are exemplary diagrams showing the transmit power of the R-PICH at time t + 1 when the transmit power command is performed when the transmit power of the R-PICH is r dB at time t.

In this case, Figure 2 is a PCB Up, Figure 3 is a PCB Down.

However, such a prior art had the following problems.

The forward link is best for the forward link between the first sector and the terminal, and the reverse link between the kth sector (k is an integer greater than 1 and equal to or less than N) and the terminal is better than the reverse link between the first sector and the terminal. If it is assumed that the transmission environment, the reverse link between the sector_k and the terminal has a good transmission environment, so the value of the PCB (k) is often Down. On the other hand, since the reverse link between the first sector and the terminal has a relatively bad transmission environment, the value of the PCB 1 is often Up. As a result, the PCB value is often Down. That is, the transmission power of the R-PICH is reduced and the transmission power of the R-CQICH, R-ACKCH, and R-PDCH is also reduced by Equations 1 to 3. In this case, the R-PDCH is not affected by the reception performance due to the soft handoff gain, but the R-CQICH and R-ACKCH, which are intended to receive only the first sector, are reduced through the relatively poor reverse link transmission environment. Since the first sector is transmitted at the transmission power, the first sector cannot properly receive the R-CQICH and the R-ACKCH.

The present invention has been made in view of the above-described problems of the prior art, and when there is an imbalance between linked links in order to exchange data through a physical channel, the transmission of a physical channel enabling efficient transmission and reception of a physical channel. It is to provide a power control method.

As described above, when a forward link and a reverse link are established between a plurality of sectors and a terminal, the terminal includes a first power control bit transmitted from a sector having the forward link and the reverse link. The transmit power of the transmit power control channel for the plurality of sectors is determined from the second power control bits transmitted from the formed sectors.

Preferably, sectors belonging to the same base station among the plurality of sectors are assumed to be one sector and receive the second power control bit.

The transmission power control channel uses a reverse pilot channel.

Preferably the transport channel from the sector on which the forward link is formed is a forward packet data channel.

Preferably, the channels transmitted on the reverse link are at least one of a reverse pilot channel, a reverse channel quality indication channel, a reverse acknowledgment channel and a reverse packet data channel.

Preferably, the sector in which the forward link is formed and the sector in which the reverse link is formed, respectively, are reverse pilots transmitted through a reception power of a reverse pilot channel transmitted through the transmission power control channel and a transmission power control channel other than the transmission power control channel. The first and second power control bits are transmitted according to the received power of the channel.

Preferably, when a forward link is formed in one of the terminal and one of the plurality of sectors, the sector in which the forward link is formed is smaller than the set specific value if the transmission power received through the transmission power control channel is smaller than a predetermined value. The transmission power is raised (Up) through a control bit, and if not small, the transmission power is down (Down), and if a forward link is formed in one of the sector and the plurality of sectors, the forward direction If the sector in which the link is formed has a sum of received power received through the transmit power control channel and the other transmit power control channel less than the set specific value, the sector increases the transmit power through the power control bit. If it is not small, the transmission power is lowered.

Preferably, when the reverse link between the terminal and the plurality of sectors other than the sector in which the forward link is formed among the terminal and the plurality of sectors is formed, the sectors in which the reverse links are formed have a transmission power received through the transmission power control channel. If it is smaller than the set specific value, the transmission power is increased (Up) through the power control bit, and if not smaller, the transmission power is lowered (Down), and the forward link of the terminal and the plurality of sectors When a reverse link is formed between a plurality of sectors except the formed sector and the terminal, the sectors in which the reverse link is formed have a sum of received powers received through the transmit power control channel and the other transmit power control channel than the set specific value. If it is small, when the transmission power up (Up) through the power control bit If it is not small, the transmission power is lowered.

Preferably, the first power control bit is PCB1, the second power control bit is PCB2, the transmission power according to the first power control bit is called PA, and the transmission power according to the second power control bit is called. PB, when the increase and decrease of the transmission power according to the determined transmission power is z dB, the determined transmission power PC,

PCB1 PCB2 PC PA PB Up Up z dB increase z dB increase PC-PA Up Down z dB increase z dB reduction PC-PA Down Up z dB reduction z dB increase PC-PA Down Down z dB reduction z dB reduction PC-PA

Will change accordingly.

Preferably, when the reverse link is established only between the terminal and the sectors other than the sector in which the forward link is established with the terminal among the terminal and the plurality of sectors, the first power control bit is referred to as PCB1 and the second power control. The bit is called PCB2, the transmit power according to the first power control bit is called PA, the transmit power according to the second power control bit is called PB, and the increase and decrease of the transmit power according to the determined transmit power is z dB. When the determined transmission power PC is,

PCB1 PCB2 PC PA PB Up Up z dB increase z dB increase PC-PA Up Down z dB increase z dB reduction PC-PA Down Up z dB reduction z dB increase PC-PA Down Down z dB reduction z dB reduction PC-PA

Will change accordingly.

And determining, in part, transmission power of the reverse link channel by power control commands transmitted from the sectors when a reverse link is formed between the terminal and the plurality of sectors and a forward link is formed with one of the sectors. Characterized in that comprises a.

Advantageously, determining a first power control command by a power control command sent from a sector on which said forward link is formed, and second power control by power control commands sent from sectors where said forward link is not formed. The method may further include determining a command.

And when the reverse link is formed between the terminal and the plurality of sectors and the forward link is formed with one of the sectors, the transmission power of the reverse link channel is determined by the power control commands transmitted from the sectors. It is characterized by comprising.

Preferably, the reverse link channel is a reverse pilot channel.

Advantageously, determining a first power control command by a power control command sent from a sector on which said forward link is formed, and second power control by power control commands sent from sectors where said forward link is not formed. The method may further include determining a command.

Other objects, features and advantages of the present invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

Hereinafter, a method of controlling a transmit power of a physical channel according to the present invention will be described with reference to the accompanying drawings.

4 is a view for explaining the transmission power change of the reverse pilot channel according to the present invention.

In the present invention, the transmission power of the reverse pilot channel (R-PICH) is largely divided into two parts, A and B. In this case, when the transmit power size for the A portion PA and the transmit power size for the B portion PB, the transmit power of the entire R-PICH is as follows.

PC = PA + PB

First, as shown in FIG. 4, at the first time (T = 0) to start transmitting the R-PICH, the transmit power of the R-PICH has only the transmit power PA for the A portion. That is, the transmission power PB corresponding to the portion B is zero. Then, as time passes, according to the transmission power control method of the present invention described below, the transmission power for the portion B is generated as at the time point T = t, T = t + L, or T = t + M. . Of course, at some point, as in the case of T = t + N, the transmission power for the B part may be zero again. Hereinafter, description of the present invention is made under the above assumption. However, the contents of the present invention can also be applied to the case of adding a physical transport channel that plays the same role as the R-PICH.

If the newly added physical transport channel is named R-PICH ', the transmit power of the original R-PICH becomes PA in Equation 4, and the transmit power of R-PICH' becomes PB in Equation 4. do.

Therefore, in the following description, the description of the PA may be applied to the transmission power of the R-PICH as it is, and the description of the PB may be applied to the transmission power of the R-PICH 'as it is. Description may be applied to the sum of the total transmit powers of the R-PICH and the R-PICH '.

5 is a view for explaining a transmission power control method according to a first embodiment of the present invention, Figure 6 is a view for explaining a transmission power control method according to a second embodiment of the present invention.

Assumptions for explaining the transmission power control method according to the first and second embodiments of the present invention are as follows.

It is assumed that a reverse link is formed between one terminal 140 and several sectors 100, 110, 120, and 130, and a specific forward link is formed only between the first sector 100 and the terminal 140.

The first embodiment of the present invention is a case in which a reverse link exists between the first sector 100 and the terminal 140, which are sectors in which a specific forward link is formed.

5 shows a reverse link (reverse channel) between one terminal 140 and the first to Nth sectors 100, 110, 120, and 130, and a (specific) forward link between the first sector 100 and the terminal 140. (Reverse channel) is formed.

In the second embodiment of the present invention, there is no reverse link (reverse channel) between the terminal 100 and the sector 100 in which a specific forward link is formed.

6 illustrates a case in which a reverse link is formed between one terminal 140 and second to Nth sectors 110, 120, and 130, and a (specific) forward link is formed between the first sector 100 and the terminal 140. .

In the first and second embodiments of the present invention, the same assumptions as follows apply.

First, it is assumed that sectors belonging to the same base station are represented by one sector.

Second, it is assumed that the forward channel transmitted over a specific forward link is an F-PDCH.

Third, assume that the channels transmitted on the reverse links are R-PICH, R-CQICH, R-ACKCH, and R-PDCH.

Fourth, it is assumed that the power control command transmitted by the sector_k to the terminal is PCB (k), and the result of receiving and reading the PCB (k) at the terminal is PCB (k ').

The basic operating principles and parameters of the transmission power control method according to the first and second embodiments of the present invention are defined as follows.

First, the following equation holds between the transmit powers of R-PICH, R-CQICH, R-ACKCH, and R-PDCH.

T_cqich / (PA + PB) = TP_cqich '

T_ackch / (PA + PB) = TP_ackch '

T_pdch / PA = TP_pdch '

If the received power (ie, PA + PB) of the R-PICH received in the first sector 100 where the forward link is formed is smaller than the specified value, the first sector transmits PCB (1) = Up to the terminal 140. Otherwise, it passes PCB (1) = Down. If R-PICH 'is used, the total received power (ie, PA + PB) of the R-PICH and R-PICH' received in the sector in which the forward link is formed (first sector 100) is specified. If smaller, the first sector 100 delivers PCB 1 = Up to the terminal 140, otherwise it transfers PCB 1 = Down.

If the received power (ie, PA + PB) of the R-PICH received in the sectors 110, 120, and 130 where no forward link is formed is smaller than a specific value, the k-th sector PCB (k) = Up is transmitted to the terminal 140. Otherwise, pass PCB (k) = Down. If the R-PICH 'is used, if the received power (i.e., PA) of the R-PICH received in the sectors 110, 120, and 130 where the forward link is not formed is smaller than a specific value, the k-th sector is PCB (k). ) = Up to the terminal 140, otherwise PCB (k) = Down.

Here, the result of the terminal 140 decrypting the power control command (PCB) transmitted from the sector in which the forward link is formed (first sector 100) is called PCB1. That is, PCB 1 '= PCB1.

The new power control command generated by the terminal 140 by the power control commands transmitted to the terminal 140 by the sectors (second to Nth sectors 110, 120, and 130) other than the sector on which the forward link is formed is called PCB2. The value of PCB2 is determined as follows.

PCB2 Up is the case where PCB (2 ') = PCB (3') ... = PCB (N ') = Up.

PCB2 Down is a case where at least one of PCB (2 ') and PCB (3') is Down.

That is, PCB1 is the result of the terminal 140 deciphering the power control command (PCB) transmitted from the sector where the forward link is formed (the first sector 100), and PCB2 is the sector where only the reverse link is formed without the forward link. This is the result of decrypting the transmitted power control command.

The increase and decrease of the transmission power according to PCB1 and PCB2 is based on a predetermined value (assuming z dB) by a field test or the like.

Based on the above description, the rules for determining the PA and PB by the terminal according to the present invention using PCB1 and PCB2 are as shown in Table 1 and Table 2, respectively.

At this time, the value of PB is determined by Equation 4 using the changed values after changing the PA and PC according to the rules of the tables. However, if the calculated PB value is negative (ie, PB = PC-PA <0), PB = 0 is determined.

Table 1 shows the transmission power change rule in the first embodiment of the present invention.

PCB1 PCB2 PC PA PB Up Up z dB increase z dB increase PC-PA Up Down z dB increase z dB reduction PC-PA Down Up z dB reduction z dB increase PC-PA Down Down z dB reduction z dB reduction PC-PA

Table 2 shows the transmission power change rule in the second embodiment of the present invention.

PCB1 PCB2 PC PA PB Up Up z dB increase z dB increase PC-PA Up Down z dB increase z dB reduction PC-PA Down Up z dB reduction z dB increase PC-PA Down Down z dB reduction z dB reduction PC-PA

7 to 14 are views for explaining the transmission power change rule according to the first embodiment of the present invention in detail, Figures 15 to 23 are views for explaining the transmission power change rule according to the first embodiment of the present invention in detail to be.

That is, the figure shows how each transmit power size is determined at T = t + 1 according to the values of PCB 1 and PCB 2 determined at T = t.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

As described above, according to the present invention, power control is performed on all reverse channels with different criteria according to their characteristics. As a result, even if link imbalance occurs, it is possible to receive all reverse channels with the transmission quality desired by the corresponding base station.

Claims (17)

When a forward link and a reverse link are established between a plurality of sectors and a terminal, The terminal transmits power of a transmission power control channel for the plurality of sectors in a first power control bit transmitted from a sector having a forward link and a second power control bit transmitted from sectors having a reverse link. The transmission power control method of the physical channel, characterized in that for determining. The method of claim 1, wherein the sectors belonging to the same base station among the plurality of sectors are assumed to be one sector and receive the second power control bit. The method of claim 1, wherein the transmission power control channel uses a reverse pilot channel.  2. The method of claim 1, wherein the transport channel from the sector on which the forward link is formed is a forward packet data channel. The method of claim 1, wherein the channels transmitted through the reverse link are at least one of a reverse pilot channel, a reverse channel quality indication channel, an reverse acknowledgment channel, and a reverse packet data channel. . The method of claim 1, wherein the forward link sector and the reverse link sector are respectively received through a transmit power control channel other than the receive power of the reverse pilot channel transmitted through the transmit power control channel and the transmit power control channel. And transmitting the first and second power control bits according to the received power of the reverse pilot channel. The method of claim 1, wherein when a forward link is formed in one of the sector and the plurality of sectors, If the sector in which the forward link is formed is smaller than a predetermined value, the sector causes the sector to increase the transmission power through the power control bit. A method of controlling the transmit power of a physical channel, characterized in that the power is lowered.  The method of claim 6, wherein when a forward link is formed in one of the terminal and one of the sectors, The sector on which the forward link is formed increases the transmit power through the power control bit if the sum of the received power received through the transmit power control channel and the other transmit power control channel is less than a predetermined value. (Up) and, if not small, to lower the transmission power (down).   The reverse link between the terminal and the plurality of sectors except for the sector in which the forward link is formed among the terminal and the plurality of sectors is formed. The sectors in which the reverse links are formed may raise the transmission power through the power control bit if the transmission power received through the transmission power control channel is smaller than a predetermined value, and if not, the sectors of the reverse links may be lowered. A method of controlling the transmit power of a physical channel, characterized in that the down. The reverse link between the terminal and the plurality of sectors other than the sector where the forward link is formed among the terminal and the plurality of sectors is formed. The sectors in which the reverse link is formed increase the transmission power through the power control bit if the sum of the received power received through the transmission power control channel and the other transmission power control channel is less than a predetermined value. And if it is not small, down the transmission power. The method of claim 1, wherein the first power control bit is called PCB1, the second power control bit is called PCB2, the transmission power according to the first power control bit is called PA, and the second power control bit When the transmission power according to the PB, and the increase and decrease of the transmission power according to the determined transmission power is z dB the determined transmission power PC, PCB1 PCB2 PC PA PB Up Up z dB increase z dB increase PC-PA Up Down z dB increase z dB reduction PC-PA Down Up z dB reduction z dB increase PC-PA Down Down z dB reduction z dB reduction PC-PA Transmitting power control method of the physical channel, characterized in that it changes according to. The method of claim 1, wherein a reverse link is established only between the terminal and the sectors except for a sector in which a forward link is established with the terminal among the terminal and the plurality of sectors, and the first power control bit is called PCB1. 2, the power control bit is PCB2, the transmit power according to the first power control bit is called PA, the transmit power according to the second power control bit is called PB, and the increase and decrease of the transmit power according to the determined transmit power When z dB is determined as the determined transmit power PC, PCB1 PCB2 PC PA PB Up Up z dB increase z dB increase PC-PA Up Down z dB increase z dB reduction PC-PA Down Up z dB reduction z dB increase PC-PA Down Down z dB reduction z dB reduction PC-PA Transmitting power control method of the physical channel, characterized in that it changes according to. When a reverse link is formed between the terminal and the plurality of sectors and a forward link is formed with one of the sectors And determining, in part, transmission power of a reverse link channel by power control commands transmitted from the sectors. The method of claim 13, Determining a first power control command by a power control command transmitted from a sector in which the forward link is formed; And determining a second power control command by power control commands transmitted from sectors in which the forward link is not formed. When a reverse link is formed between the terminal and the plurality of sectors and a forward link is formed with one of the sectors And determining the transmit power of the reverse link channel by the power control commands transmitted from the sectors, respectively. The method of claim 15, The reverse link channel is And a reverse pilot channel. The method of claim 15, Determining a first power control command by a power control command transmitted from a sector in which the forward link is formed; And determining a second power control command by power control commands transmitted from sectors in which the forward link is not formed.

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