KR20040014796A - Outer loop power control method in reverse link - Google Patents

Abstract

PURPOSE: A method for controlling outer loop power in a reverse link is provided to control a primary power control threshold value used for controlling substantial inner loop power by using a virtual power control threshold value for many traffic channels, thereby preventing performance of a specific traffic channel from deteriorating. CONSTITUTION: A base station controller calculates outer loops for an FCH(Fundamental Channel) and an SCH(Supplement Channel) according to a target FER(Frame Error Rate), and monitors differences between the FCH and the SCH(S11). The base station controller calculates virtual power control threshold values of a master channel and a slave channel according to a result of monitoring differences between a power control threshold value of the master channel and the virtual power control threshold value of the slave channel(S12). The base station controller compares a difference between the virtual power control threshold values with a set reference value(S13). If the difference exceeds the reference value, the base station controller transmits a message for commanding a terminal to correct a relative power ratio of a traffic channel for the slave channel(S15).

Description

Outer loop power control method in reverse link}

The present invention relates to a method for controlling outer loop power in a reverse link, and more particularly, in a reverse link capable of preventing performance degradation of a specific traffic channel through efficient outer loop power control for multiple traffic channels when the terminal supports multiple channels. To an outer loop power control method.

The existing international standard, IS-95A, supported only low-speed services such as voice-oriented 8Kbps or 13Kbps. Because of this, it was common to use only one traffic channel.

However, CDMA2000, the standardization standard for mobile communication system, is not only using one traffic channel like IS-95A, but also provides various multimedia services such as voice, video, and data at 64Kbps or more. Multiple traffic channels are used.

1 shows a transmission apparatus of a multi-channel structure for transmitting information using these various traffic channels.

In the transmitting apparatus of FIG. 1, a supplemental channel and a fundamental channel are used as traffic channels. In addition, a pilot channel and a dedicated channel transmitting only a bit value of '1' are used. A dedicated control channel is used for control.

Each of these channels is mapped to the symbols of the I channel feeder and the Q channel feeder and then complex spreaded by each successive PN code (PN _I or PN _Q ). That is, each channel is spread at a constant chip rate by a specific complex scrambling code. In this case, a long scramble code (long code) or a short scramble code (short code) is used. It can be used, and spread on each carrier after spreading at a chip rate according to the scramble code used.

In order to allow the base station to perform coherent demodulation on the traffic channel, the terminal also transmits a pilot channel along with several traffic channels as shown in FIG. 1.

In this case, the traffic-to-power ratio (TP ratio) of the traffic channel to the pilot channel transmitted is the coding rate for each traffic channel and the required signal-to-interference ratio (SIR). It is determined differently according to the ratio and transmission rate, and is defined in Table 2.1.2.3.3.2-1 of C.S0002 (physical layer) specification.

In FIG. 1, the transmission power of the pilot channel and the traffic channels is adjusted according to the gain value G _P by reverse closed loop power control after complex spreading and filtering described above. do.

Closed loop power control is generally divided into inner loop power control and outer loop power control.

Inner loop power control measures the signal-to-interference ratio (SIR) for a received signal by observing the pilot channel on the reverse link at the base station and then predicts the power corresponding to this measured signal-to-interference ratio. Thereafter, the predicted power value is compared with a previously specified power control threshold value, and a command bit for controlling power is transmitted to the forward link.

Outer loop power control is a power control used for inner loop power control based on the frame error rate of a decoded received signal to maintain a target FER for the radio channel. Periodically adjust the threshold.

The outer loop power control is independently performed by a selector provided in a base station controller (BSC) that controls the base station. An operation procedure thereof will be described below.

First, the base station receives a signal from the terminal and performs a cyclic redundancy check (hereinafter, abbreviated as CRC) on the received frame.

The base station then reports the CRC result to the selector, which selects the frame error rate according to the history of the CRC result for the previously received frame, that is, the frame error rate according to the previous CRC result and the received frame reported by the current base station. Based on the CRC result, the power control threshold used for inner loop power control is periodically adjusted to maintain the desired frame error rate.

At this time, the power control threshold is raised or lowered at a constant step size ratio, and the rising or falling step size ratio K of the power control threshold is determined according to the desired frame error rate F.

For example, the size ratio is determined to be "K = (1 / F)-1" in order to maintain the desired frame error rate (F) in the selector, so that "K = (1 / 0.01) -1 = 99 ".

Therefore, if the falling step size is Δ, the rising step size is 99 * Δ. Conversely, if the rising step size is Δ, the falling step size is Δ / 99.

The conventional outer loop power control described so far has no problem when transmitting signals using only one traffic channel of a terminal.

However, in a multi-channel structure using multiple traffic channels, the quality of service (QoS) of each traffic channel is different, and accordingly, the target frame error rate of each traffic channel is different. Although the rising step size to raise the power control threshold for the same, the falling step size is different depending on the target frame error rate.

For example, assuming that the rising step size is Δ, for a traffic channel requiring a target frame error rate of 1%, the falling step size is Δ / 99, and for a traffic channel requiring a target frame error rate of 5%, The falling step size becomes Δ / 19 (= Δ / [(1 / 0.05) -1).

Therefore, in a multi-channel structure in which the reverse power control bit supports only one reverse traffic channel, the base station compares the signal-to-interference ratio (SIR) value estimated by measuring the pilot channel with one power control threshold (generally R-FCH). Therefore, it is not possible to perform outer loop power control considering the desired frame error rate (FER) of a plurality of traffic channels and to perform outer loop power control only for one specific traffic channel, thereby degrading the performance of another traffic channel (R-SCH). Will be.

Also, the TP ratios defined in Table 2.1.2.3.3.2-1 of the C.S0002 (physical layer) spec are not always optimal for multichannels. In other words, the nominal TP ratio in the specification means 1% FER for R-FCH and 5% for R-SCH. However, in outer loop power control using only the FCH, the SCH may even have a FER of 50% depending on the data rate and the channel environment.

In other words, when using the existing outer loop power control procedure, it is impossible to properly adjust the power control thresholds for the various traffic channels. This results in performance degradation for the entire traffic channel.

The present invention has been made in view of the above, and in particular, when the terminal supports multiple channels, effective outer loop power control is performed for multiple traffic channels having different quality of service to prevent performance degradation of a specific traffic channel. An object of the present invention is to provide an outer loop power control method in a reverse link that can improve the performance of a reverse link.

The outer loop power control method in the reverse link of the present invention as described above calculates power control thresholds for each traffic channel according to a target frame error rate for each traffic channel received through the multi-traffic channel of the reverse link. And adjusting the transmission power ratios of the traffic channel and the pilot channel of the terminal by using the difference between the calculated power control thresholds.

Preferably, the multi traffic channel is divided into a master channel and a slave channel of the terminal.

The adjusting of the transmission power ratio uses a difference between a power control threshold of a master channel and a virtual power control threshold of a slave channel in the multi-traffic channel.

Preferably, monitoring the difference between the power control threshold of the master channel and the virtual power control threshold of the slave channel, and as a result of the monitoring, the difference between the power control threshold of the master channel and the virtual power control threshold of the slave channel And transmitting a message for adjusting a transmission power ratio of a traffic channel and a pilot channel of the terminal in proportion to the difference value of the set threshold.

Other objects, features and advantages of the present invention will become apparent from the detailed description of the embodiments with reference to the accompanying drawings.

1 is a view showing a transmission apparatus of a general multi-channel structure

2 is a flowchart illustrating a terminal and base station control period for explaining a reverse link outer loop power control method according to the present invention.

3 is a flowchart for explaining an outer loop power control method according to a first embodiment of the present invention.

4 is a flowchart for explaining an outer loop power control method according to a second embodiment of the present invention.

Hereinafter, a preferred embodiment of an outer loop power control method in a reverse link of a mobile communication system according to the present invention will be described with reference to the accompanying drawings.

2 is a flowchart illustrating a terminal and base station control period for explaining a reverse link outer loop power control method according to the present invention, and FIG. 3 is a flowchart for explaining the outer loop power control method according to the first embodiment of the present invention.

When the terminal has a multi-channel structure and the reverse power control bit supports only one traffic channel, the outer loop power control procedure is configured to operate in a master-slave mode.

Here, the master-slave mode is a mode in which the outer loop power control result for the master channel is used to adjust the power control threshold for the actual inner loop power control.

The master channel is a traffic channel that performs outer loop power control to match the required quality of service (QoS) of each traffic channel, and other traffic channels become slave channels. At this time, if the master channel is set to R-FCH, the slave channel becomes R-SCH.

The base station controller should perform outer loop power control for actual inner-loop power control of the base station, which is performed according to the frame error rate (FER) of the channel set as the master channel. In addition, the target value for outer-loop power control is calculated even if the slave channel, which is a channel that is not used as a target value of inner loop power control, is not used as the actual target value. do. In other words, the virtual power control threshold is calculated and possessed.

In other words, the master channel performs the outer loop power control by matching the quality of service (QoS) to the channel, calculates the target value, and uses the inner loop power control.

The slave channel also performs the outer loop power control to match the appropriate quality of service (QoS) for that channel to calculate the desired value, but not for the inner loop power control.

Since the base station controller calculates the target value in both channels, the value can be used.

The terminal shoots a fixed TP ratio of the various traffic channels according to the specification. Therefore, the power ratio of the channels received at the base station is received like the power ratio shot from the terminal. The target value of the outer loop power control calculated by the base station controller will initially be similar to the power ratio shot by the terminal. However, as pointed out above, the calculated objective value between the two channels will continue to vary as the channel environment and different QoS requirements are required and over time.

At this time, data is transmitted from the terminal to the base station through the master channel and the slave channels (FCH, SCH), and the base station reports the channel quality of the master channel and slave channels (FCH, SCH) to the base station controller is received from the base station controller According to the target frame error rate (target FER) of each traffic channel (master channel and slave channel (FCH, SCH)), the outer loop is calculated for the multi-receive traffic channel, that is, the FCH and SCH, and the difference value between the two is monitored ( S11).

The channel selected as the master channel is sent to the base station for inner loop power control, whereby the base station performs inner loop power control.

The base station controller monitors the difference between the power control threshold value of the master channel and the virtual power control threshold value of the slave channel according to the monitoring result of the virtual power control threshold value of the master channel and the slave channel. Calculate X. In this case, the difference between the power control threshold value of the master channel and the virtual power control threshold value of the slave channel is defined as X (that is, X = power control threshold value of the master channel-virtual power control of the slave channel. Threshold value) (S12).

Next, the difference between the power control threshold value of the master channel and the virtual power control threshold value X of the slave channel is compared with the set reference value δ1 (S13).

As a result of the comparison (S13), when the value of X becomes large (when the difference between the master power control threshold value and the slave power channel virtual power control threshold value is greater than δ1), the energy of the slave channel currently received is low and thus the frame error is reduced. Much is the situation. If the FCH is a master channel and the SCH is a slave channel, the FCH maintains quality because of the outer loop power control operation for 1% FER, but the SCH cannot meet the required quality. Therefore, when the value of X is greater than or equal to the reference value δ1, the base station controller does not instruct the terminal to modify the traffic pilot ratio of the traffic channel to the slave channel. Since the desired quality of service is not obtained, the base station controller transmits a message instructing the terminal to modify the relative power ratio of the traffic channel to the slave channel (S15). The message includes a control command for adjusting the transmission power ratio of the traffic channel and the pilot channel of the terminal in proportion to the difference between the power control threshold of the master channel and the virtual power control threshold of the slave channel.

However, as a result of the comparison (S13), when the value of X becomes small (the difference δ1 between the power control threshold of the master channel and the virtual power control threshold of the slave channel becomes smaller), the slave channel now received Because we are transmitting at higher power than is required for energy, we can cause interference on other channels and reduce system capacity. If the FCH is a master channel and the SCH is a slave channel, the FCH maintains quality because it operates the outer loop power control for 1% frame error rate (FER), but the SCH receives better than the required quality. It is a situation. Therefore, it is determined whether the value of X is equal to or less than the reference value δ2 (S14).

If the result of the determination (S14) X is equal to or less than the reference value δ2, the base station controller does not instruct the terminal to modify the relative pilot ratio of the traffic channel to the slave channel. (QoS) or higher, resulting in reduced system capacity. Therefore, the base station controller transmits a message instructing the terminal to modify the relative power ratio of the traffic channel to the slave channel (S15).

That is, it is determined that the traffic to pilot ratio of the traffic channel to the pilot channel of the terminal is set incorrectly according to the result of X and δ1 or δ2, and thus the relative power ratio of the traffic channel to the pilot channel to the terminal. send a modify command message to change the pilot ratio).

At this time, in the step of transmitting a modification of the relative power ratio (T / P Ratio) of the traffic channel to the pilot channel to the terminal (S15), the generation of the message is the target frame error rate (FER) for the current FCH and the target for the SCH Use the frame error rate (FER) as it is, or generate a correction command message using the average value of the previously accumulated target frame error rate (FER). Therefore, it is possible to specify the correct value by using several experiments or field tests.

However, if the determination result (S14) X is not equal to or less than the reference value δ2 to calculate the outer loop for the next frame (S11).

FIG. 4 is a flowchart for explaining an outer loop power control method according to a second embodiment of the present invention, and shows that the comparison order of δ1, δ2 and X is changed in the first embodiment of the present invention of FIG.

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.

The outer loop power control method of the present invention as described above has a multi-channel structure in which the terminal has a plurality of received traffic channels even when the reverse power control bit supports only one traffic channel. By using the virtual power control threshold for the control of the primary power control threshold used for the actual inner-loop power control to reduce the performance of a specific traffic channel There is an effect to improve the performance of the reverse link.

Claims (4)

Calculating power control thresholds for each traffic channel according to a target frame error rate for each traffic channel received on the multiple traffic channels of the reverse link; And adjusting the transmission power ratios of the traffic channel and the pilot channel of the terminal by using the calculated difference of the power control thresholds. The method of claim 1, wherein the multi-traffic channel is divided into a master channel and a slave channel of a terminal. The method of claim 2, wherein adjusting the transmission power ratio comprises: And using the difference between the power control threshold of the master channel and the virtual power control threshold of the slave channel in the multi-traffic channel. 4. The method of claim 3, further comprising: monitoring a difference between a power control threshold of the master channel and a virtual power control threshold of a slave channel; As a result of the monitoring, a message for adjusting the transmission power ratio of the traffic channel and the pilot channel of the terminal to the terminal is proportional to the difference between the threshold value of the power control threshold of the master channel and the virtual power control threshold of the slave channel. And transmitting the outer loop power of the reverse link.