KR20010009425A - Outer loop power control method in mobile with multi-channel structure - Google Patents

Abstract

PURPOSE: A method for controlling an outer loop power for a terminal having a multiple channel structure is provide to control an outer loop power proper for multiple communication channels having different service qualities each other. CONSTITUTION: A base station controller performs an outer loop power control according to a target frame error rate of each channel for every reception communication channel, and controls virtual power control threshold values. According to an operation mode of the outer loop power control, the base station controller uses the controlled virtual power control threshold values, and controls power control threshold values for controlling a real inner loop power. The base station controller monitors threshold value differences between virtual power control threshold values of master channels controlled by the outer loop power control of each channel and virtual power control threshold values of slave channels, and compares the threshold value differences with a predetermined reference value. If the threshold value differences exceed the reference value, the base station controller is operated in a fixed mode. If the threshold value differences do not exceed the reference value, the base station controller is operated in a normal mode.

Description

Outer loop power control method for a terminal having a multi-channel structure {Outer loop power control method in mobile with multi-channel structure}

TECHNICAL FIELD The present invention relates to next generation mobile communication, and more particularly, to outer loop power control for a mobile terminal having a multi-channel structure in a future CDMA cellular communication system.

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

However, IMT-2000 (IS-95C), the standardization standard for the next generation mobile communication system, does not use only one communication channel like IS-95A, but provides various multimedia services such as voice, video, and data at 64Kbps or more. In order to do so, multiple call channels are used simultaneously.

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

In the transmitting apparatus of FIG. 1, a supplemental channel and a fundamental channel are used as a call channel, and a pilot channel and a dedicated channel transmitting only a bit value of '1' are also used. Dedicated Control Channel (Dedicated Control Channel) is used for the 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 enable the base station to perform coherent demodulation on the talk channel, the mobile station also transmits a pilot channel along with several talk channels as shown in FIG. 1.

In this case, the relative transmission power ratio of the talk channel to the transmitted pilot channel is determined by a coding rate, a required signal-to-interference ratio (SIR), and a transmission rate for each talk channel. The transmission power of the pilot channel and the call channel in FIG. 1 is a gain value due to reverse closed loop power control after complex spreading and filtering described above. Adjusted according to (G _P ).

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 mobile 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 communication channel of a mobile terminal.

However, in a multi-channel structure in which signals are transmitted using multiple call channels, the quality of service (QoS) of each call channel is different, and accordingly, the target frame error rate of each call 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, let the rising step size be Δ. In this case, the falling step size is Δ / 99 for a call channel requiring a target frame error rate of 1%, and the falling step size is Δ / 19 (= Δ / [( 1 / 0.05)-1].

Eventually, the pilot channel of the reverse link is observed to measure the signal-to-interference ratio (SIR) for the received signal, and then the predicted power value corresponding to the measured signal-to-interference ratio and one previously specified power control threshold are obtained. In comparison, since the command bits for the required power control are transmitted to the forward link, the outer loop power control considering the target frame error rate according to the quality of service (QoS) of each call channel using the multi-channel structure cannot be performed. 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 call channels. This results in performance degradation for the entire call channel.

SUMMARY OF THE INVENTION The present invention has been made in view of the above, and an object thereof is to provide an appropriate outer loop power control method for multiple call channels having different service qualities, especially when a mobile terminal supports multiple channels.

A feature of an outer loop power control method of a mobile communication system according to the present invention for achieving the above object is that, in a mobile communication system using any master channel and one or more slave channels as a call channel, Adjusting a corresponding virtual power control threshold value according to each desired frame error rate of the slave channel, calculating a difference between the adjusted virtual power control threshold values, and comparing the result with a predetermined reference value; And performing outer loop power control in a corresponding operation mode determined according to the comparison result, and adjusting a power control threshold for inner loop power control according to the outer loop power control result.

Preferably, when the difference between the calculated virtual power control thresholds is compared with a reference value, when the difference between the virtual power control threshold is greater than the reference value, the power control threshold for the inner loop power control is determined. On the contrary, when the difference of the virtual power control threshold is relatively smaller than the reference value, the power control threshold for the inner loop power control is adjusted according to the master-slave mode or the combined mode.

In this case, in the master-slave mode, the virtual power control threshold of the master channel is used as the power control threshold for the inner loop power control, and the rising or falling of the power control threshold for the inner loop power control. The step size ratio is determined according to the desired frame error rate of the master channel.

Further, in the combined mode, a power control threshold for the inner loop power control is adjusted by using the virtual power control thresholds of the master channel and the slave channel, wherein each virtual power of the master channel and the slave channel is adjusted. When the control threshold rises or falls equally, the power control threshold for the inner loop power control is raised or lowered according to the rising / falling step size ratio of the master channel, and each of the master channel and the slave channel is increased. When the rise / fall of the virtual power control threshold is opposite to each other, the power control threshold for the inner loop power control is adjusted according to the situation of each call channel.

1 is a diagram illustrating a general multi-channel transmission apparatus.

2 is a flow chart illustrating a reverse link outer loop power control method in accordance with the present invention.

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

In the present invention, first, a channel having the highest transmission rate among a plurality of communication channels is called a master channel, and the remaining channels are defined as slave channels.

In addition, the outer loop power control procedure of the present invention operates in a master-slave mode and a combined mode to adjust the power control threshold PRI_THRESH for inner loop power control.

In each mode, external loop power control is first performed for each channel, thereby adjusting the virtual power control threshold for each channel, and using the adjusted virtual power control threshold, the actual internal power is controlled. Adjust the power control threshold PRI_THRESH for loop power control.

The rising / falling step size ratio K of the power control threshold PRI_THRESH adjusted at this time is determined according to the target frame error rate of the master channel, and for power control according to the determined rising / falling step size ratio K. Generates command bits and sends them to the forward link.

2 is a flowchart illustrating an external power control procedure according to the present invention.

In the master-slave mode shown in FIG. 2, the outer loop power control result for the master channel is used to adjust the power control threshold (PRI_THRESH) for the actual inner loop power control, and in the combined mode, the outer loop power of the master channel and the slave channel. The control results are used together to adjust the power control threshold (PRI_THRESH) for the actual inner loop power control.

The outer loop power control procedure will be described in more detail with reference to FIG. 2.

First, the base station controller adjusts the virtual power control thresholds by performing outer loop power control according to the target frame error rate (target FER) of each channel for all received call channels (master channel and slave channel) (S10).

Then, the power control threshold PRI_THRESH for the actual inner loop power control is adjusted using the corresponding virtual power control threshold adjusted according to the operation mode of the outer loop power control (FIG. 2B).

At this time, the master-slave mode and the coupled mode are also divided into two operating modes, a fixed mode using a fixed power control threshold (PRI_THRESH) for inner loop power control, and a normal mode described later. The operation mode is determined according to a difference between the virtual power control threshold VIRTUAL_MASTER_THRESH of the master channel and the virtual power control threshold VIRTUAL_SLAVE_THRESH of the slave channel adjusted by the outer loop power control of each channel.

To do this, the base station controller monitors the difference between the virtual power control threshold value (VIRTUAL_MASTER_THRESH) of the master channel and the virtual power control threshold value (VIRTUAL_SLAVE_THRESH) of the slave channel adjusted by the outer loop power control of each channel. Comparison is made (S11). If the difference between the virtual power control threshold (VIRTUAL_MASTER_THRESH) of the master channel and the virtual power control threshold (VIRTUAL_SLAVE_THRESH) of the slave channel exceeds δ, it operates in fixed mode (S12). Operation in the normal mode (S13) to be described later (S13).

In master-slave mode of normal mode, the virtual power control threshold (VIRTUAL_MASTER_THESH) of the master channel is used as the power control threshold (PRI_THRESH) for the inner loop power control, and the rising / falling step size ratio (K) is the Determined according to the target frame error rate.

Referring to FIG. 2B, in the combined mode of the normal mode, the power control threshold for inner loop power control using the virtual power control threshold VIRTUAL_MASTER_THRESH of the master channel and the virtual power control threshold VIRTUAL_SLAVE_THRESH of the slave channel is used together. PRI_THRESH).

That is, when the virtual power control threshold (VIRTUAL_MASTER_THRESH) of the master channel and the virtual power control threshold (VIRTUAL_SLAVE_THRESH) of the slave channel rise or fall in the same manner, the power depends on the rising / falling step size ratio (K _m ) of the master channel. The control threshold PRI_THRESH is raised or lowered (S21).

However, when the virtual power control threshold (VIRTUAL_MASTER_THRESH) of the master channel rises, or when the virtual power control threshold (VIRTUAL_SLAVE_THRESH) of the slave channel falls, or when the virtual power control threshold (VIRTUAL_MASTER_THRESH) of the master channel falls. When the virtual power control threshold VIRTUAL_SLAVE_THRESH of R rises, the power control threshold PRI_THRESH is adjusted according to the situation of the call channel (S22). This may vary depending on how the system is implemented. If the rise / fall of the virtual power control threshold (VIRTUAL_MASTER_THRESH) of the master channel and the virtual power control threshold (VIRTUAL_SLAVE_THRESH) of the slave channel are opposite to each other, interference in the wireless channel To reduce power consumption, the power control threshold PRI_THRESH can be lowered according to the rising / falling step size ratio K _m of the master channel, and in some cases, the power according to the rising / falling step size ratio K _s of the slave channel. It is also possible to lower the control threshold PRI_THRESH.

In equation 1 Is the target frame error rate of the master channel, Is the target frame error rate of the slave channel.

As described above, according to the present invention, the outer loop power control method of the present invention performs an outer loop power control for each talk channel in a multi-channel structure in which a signal is transmitted using several talk channels, thereby virtualizing the corresponding channel. By adjusting the power control thresholds first, these virtual power control thresholds adjust the power control thresholds for the inner loop power control, which satisfies the target frame error rate of each call channel according to different quality of service (QoS). External loop power control is possible.

In addition, the outer loop power control method of the present invention adjusts the power control threshold for the actual inner loop power control by using each virtual power control threshold value for the multiple call channels, thereby preventing performance degradation of a specific call channel. Can be.

As a result, there is a performance improvement for the reverse link call channel.

Claims (7)

In a mobile communication system using multiple call channels, Adjusting a corresponding virtual power control threshold according to a desired frame error rate of each call channel, respectively; And adjusting a power control threshold value for generating a power control command of a corresponding channel by using the adjusted virtual power control threshold values. In a mobile communication system using any master channel and one or more slave channels as call channels, Adjusting corresponding virtual power control thresholds according to respective desired frame error rates of the master channel and the slave channel; Calculating a difference between the adjusted virtual power control thresholds and comparing the result with a predetermined reference value; Performing outer loop power control in a corresponding operation mode determined according to the comparison result; And adjusting a power control threshold for inner loop power control according to a result of the outer loop power control. The power control threshold for controlling the inner loop power according to claim 2, wherein when the difference between the calculated virtual power control thresholds is compared with a reference value, the difference between the virtual power control threshold is greater than the reference value. A method for controlling the outer loop power of a reverse link, using a fixed value. The power control threshold for controlling the inner loop power according to claim 2, wherein when the difference between the calculated virtual power control thresholds is compared with a reference value, the difference between the virtual power control thresholds is smaller than the reference value. Adjusting the value according to the master-slave mode or the coupled mode. 5. The method of claim 4, wherein in the master-slave mode, a virtual power control threshold of the master channel is used as a power control threshold for the inner loop power control, and in the combined mode, each of the master channel and the slave channel is determined. Adjusting a power control threshold for the inner loop power control using a virtual power control threshold. 6. The method of claim 5, wherein the rising or falling step size ratio of the power control threshold for the inner loop power control is determined according to a desired frame error rate of the master channel. The power control method of claim 5, wherein when the virtual power control thresholds of the master channel and the slave channel rise or fall in the same manner, power control for the inner loop power control is performed according to a rising / falling step size ratio of the master channel. When the threshold value is raised or lowered and the rising / falling values of the virtual power control thresholds of the master channel and the slave channel are opposite to each other, power control for the inner loop power control according to the situation of each call channel. A method for controlling outer loop power of a reverse link characterized by adjusting a threshold.