KR100893037B1 - Open loop power control apparatus and method for the same - Google Patents

Abstract

The present invention relates to an open power control apparatus and method that can control the up-step and down-step in accordance with the target error rate to reduce the transmission error rate to increase the efficiency of power control. According to the present invention, in the open power control method between the terminal and the base station, the sum of the number of transmission error messages and transmission success messages reported in the n-1th frame, the maximum value of the power calibration value, the target error rate, and the marginal power error rate Given a linear equation, the terminal consists of a linear equation whose variables include an upward step value, a target error rate, and a downward step value, and a linear equation with the maximum value of the upward step value, the marginal power error rate, the downward step value, and the power calibration value as variables. Erecting; Calculating an upward step value and a downward step value in the binary linear equation; When the terminal receives a transmission error message from the base station, raising the power correction value by an upward step value; And lowering the power correction value by a downward step value when the terminal receives the transmission success message from the base station. Therefore, the terminal may control the upward step value and the downward step value by adapting to the target error rate. Compared to the power control method, the transmission error rate is reduced to increase the power control efficiency.

Mobile communication, open power control

Description

OPEN LOOP POWER CONTROL APPARATUS AND METHOD FOR THE SAME

1 illustrates an exemplary open power control method in a WiBro system.

2 is an exemplary view of an open power control device according to an embodiment of the present invention.

3 is an operation flowchart of an open power control method according to an embodiment of the present invention;

<Description of the symbols for the main parts of the drawings>

100: open power control device 110: memory

120: step value calculation unit 130: power calibration unit

The present invention relates to an open power control device and method, and more particularly, to an open power control device and method for reducing the transmission error rate by adjusting the up step value and the down step value by adapting to a target error rate to increase the efficiency of power control. It is about.

In the conventional open power control method, the transmission power of the terminal is determined based on information obtained through internal resources of the terminal without feedback information for power control from the base station. The open power control method can save resources that have been allocated for power control because it does not get feedback for power control from the base station. However, since the current channel state of the base station is not obtained, power that is not suitable for the target error rate may be allocated to the terminal.

1 is an exemplary diagram of a general open power control method in a WiBro system. The following equations represent power estimation through open power control in a WiBro system.

Where P is the transmission power (dBm) determined through open power control, L is the signal attenuation (dB) according to the distance between the base station and the terminal, and C / N is the signal-to-noise ratio (dB) normalized by WiBro system rules. Where NI is the average power of the noise interference (dBm) expected to be received by the base station, R is the number of repetitions of the modulation / FEC ratio, Offset_SS _perSS is the number to calibrate the terminal power controlled by the terminal, and Offset_RAS _perSS is A value for calibrating the terminal power controlled by the base station.

The method of determining the power calibration value controlled by the terminal is as follows.

The power calibration value (Offset_SS _perSS ) determination method controlled by the terminal proposed by the WiBro system initializes the power calibration value so that it is not affected by the calibration value of the previous frame (n-1 frame) every frame (n-th frame). . The power correction value of the n th frame is determined based on the probability of success for the data transmission attempted in the n-1 th frame.

The initialization of the power calibration value attempted every frame is as follows.

The terminal sets the power calibration value to 0 dB every frame. In addition, the terminal fixes the up / down step value to 2 dB.

When the terminal receives a transmission error message (NAck) from the base station, the power of the terminal is corrected as follows.

Here, UP_STEP is an upward step value of the terminal power.

When the terminal transmits data to the base station and receives a transmission error message from the base station, the terminal sets the power correction value up by an upward step value.

When the terminal receives an Ack message from the base station, the power of the terminal is calibrated as follows.

Here, DOWN_STEP is a downward step value of the terminal power.

When the terminal transmits data to the base station and receives a transmission success message from the base station, the terminal sets the power correction value by a downward step value.

Limit the range of power calibration value (Offset_SS _perSS ) controlled by the terminal. It depends on the up / down step value of power control, but limits the minimum value (Offset_SS _perSS Bound _lower ) and maximum value (Offset_SS _perSS Bound _upper ) of the power calibration value to accommodate this within a certain range. Therefore, the range of power calibration values is as follows.

In the conventional open power control method, the transmission power value is determined according to the accumulated value of the up / down step values. This is equivalent to determining the transmit power in the next frame depending on how high the transmission success rate is obtained in the current wireless environment. However, the up / down step value determined irrespective of the target error rate may determine the transmission power that does not satisfy the target error rate.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and provides an open power control apparatus and method in which a transmission success rate approaches a target error rate with a target error rate in mind when determining an up / down step value. .

In the open power control method according to the present invention for achieving the above object, in the open power control method between the terminal and the base station, the total number of times the transmission error message and transmission success message is reported in the n-1th frame, Given the maximum value, target error rate, and marginal power error rate of the power calibration values, the terminal has a linear equation, the upward step value, target error rate, and downward step value as variables, and the upward step value, marginal power error rate, downward step value, and power calibration value. Establishing a binary linear equation composed of linear equations having a maximum value of as a variable; Calculating an upward step value and a downward step value in the binary linear equation; When the terminal receives a transmission error message from the base station, raising the power correction value by an upward step value; And lowering, by the terminal, the power correction value by a downward step value when receiving a transmission success message from the base station.

In the open power control apparatus according to the present invention, when the total number of transmission error messages and transmission success messages are reported in the n-1th frame, the maximum value of the power correction value, the target error rate, and the limit power error rate are given to the terminal. A memory for storing a binary linear equation consisting of a linear equation having a step value, a target error rate and a downward step value as variables, and a linear equation having a maximum value of an upward step value, a marginal power error rate, a downward step value, and a power correction value as variables; A step value calculator for calculating an upward step value and a downward step value in a binary linear equation stored in the memory by differently applying the sum of the number of reported transmission error messages and transmission success messages; And a power calibration unit for raising the power calibration value by an upward step value when the terminal receives the transmission error message from the base station and lowering the power calibration value by a downward step value when the terminal receives the transmission success message from the base station.

Hereinafter, preferred embodiments of the present invention will be described in detail according to the device configuration and method configuration.

In describing the embodiments, descriptions of technical contents which are well known in the technical field to which the present invention belongs and are not directly related to the present invention will be omitted. This is to more clearly communicate without obscure the subject matter of the present invention by omitting unnecessary description.

2 is an exemplary view of an open power control apparatus according to an embodiment of the present invention, and FIG. 3 is an operation flowchart of an open power control method according to an embodiment of the present invention. .

Referring to FIG. 2, an open power control apparatus according to an embodiment of the present invention will be described. In the memory 110, the total number of times a transmission error message and a transmission success message are reported and power calibration values in an n−1 th frame. Given the maximum value, target error rate, and marginal power error rate of the terminal, the terminal has an equation of linear equations with upward step value, target error rate and downward step value, and the maximum step value of the maximum step value, marginal power error rate, downward step value, and power calibration value. Store a binary linear equation made up of linear equations with.

The stair value calculator 120 calculates an upward step value and a downward step value in a binary linear equation stored in a memory by differently applying the sum of the number of reported transmission error messages and transmission success messages.

When the terminal receives a transmission error message from the base station, the power calibration unit 130 raises the power calibration value by an upward step value, and when the terminal receives the transmission success message from the base station, lowers the power calibration value by a downward step value.

The device configuration is also implemented by a computer capable of executing a program that performs a series of procedures over time. The computer executes a work procedure that programs the operation of a module composed of devices. The computer sequentially executes the programs stored in the program memory according to the scheduled work schedule, or branches to the program corresponding to the generated event. The computer performs the functions and operations of the device corresponding to the task currently executed among the programmed tasks. The program is recorded on a computer readable medium so that the computer functions by various means. Computers operate by different means depending on the task they are performing and perform methods according to the operation. The operation of this method will be described sequentially according to time flow and events.

The staircase determination method for power calibration is as follows.

The UP / STEP / DOWN_STEP setting suggests that two binary linear equations are determined when N and Offset_SS _perSS bound _upper , ε ₁ , and ε ₂ are given in the following equation.

Here, N is the total number of times NAck / Ack has been reported in the n-1th frame, and ε ₁ (0.0 to 1.0) is a constant representing a probability and represents a target error rate of the system. The target error rate is a system constant that determines the convergence target. ε ₂ (0.0 ~ 1.0) is a constant that indicates the probability of the marginal power error rate. If the data transmitted in the n-1th frame shows an error rate of ε ₂ or more, the maximum value is determined when the transmission power of the nth frame is determined (Offset_SS _perSS Bound _upper). To determine).

The proposed step determination method provides different up / down step values based on the target error rate even at the same transmission success rate, so it provides differentiated power calibration value (Offset_SS _perSS ). In the open power control method, it calculates the power suitable for the target error rate. do.

When the parameter affecting the up / down step value is determined as a constant, the step value is calculated using Equation 6 as the step value.

In the embodiment Offset_SS _perSS Bound _upper = 10dB, ε ₁ = 0.1, ε ₂ = 0.7, the up / down stairs are as follows.

N UP_STEP DOWN_STEP One 13.636 1.515 2 6.818 0.758 3 4.545 0.505 4 3.4.9 0.379 5 2.727 0.303 6 2.273 0.253 7 1.948 0.216 8 1.705 0.189 9 1.515 0.168

Unit: dB

In the embodiment Offset_SS _perSS Bound _upper = 10dB, ε ₁ = 0.01, ε ₂ = 0.7, the up / down stairs are as follows.

N UP_STEP DOWN_STEP One 14.224 0.144 2 7.112 0.072 3 4.711 0.048 4 3.556 0.036 5 2.845 0.029 6 2.371 0.024 7 2.032 0.021 8 1.778 0.018 9 1.580 0.016

Unit: dB

In the embodiment Offset_SS _perSS Bound _upper = 20dB, ε ₁ = 0.1, ε ₂ = 0.7, the up / down stairs are as follows.

N UP_STEP DOWN_STEP One 27.273 3.030 2 13.636 1.515 3 9.091 1.010 4 6.818 0.758 5 5.455 0.606 6 4.545 0.505 7 3.896 0.433 8 3.409 0.379 9 3.030 0.337

Unit: dB

In the embodiment Offset_SS _perSS Bound _upper = 20dB, ε ₁ = 0.01, ε ₂ = 0.7, the up / down steps are as follows.

N UP_STEP DOWN_STEP One 28.448 0.287 2 14.224 0.144 3 9.483 0.096 4 7.112 0.072 5 5.690 0.057 6 4.741 0.048 7 4.064 0.041 8 3.556 0.036 9 3.161 0.032

Experimental results show that the proposed open power control method reduces the transmission error rate in the same wireless environment compared with the conventional open power control method.

The experimental results of the conventional open power control method and the proposed open power control method are as follows.

In the basic method, the up / down step values are fixed at 2dB, and the proposed method is shown in Table 1 above / down step values.

Attempts Way One 2 3 N = 3 Existing Method 37.6% 36.6% 36.4% Proposal method 20.3% 14.5% 15.5% N = 9 Existing Method 36.9% 37.2% 38.4% Proposal method 24.5% 25.0% 28.6%

The proposed method demonstrates a lower transmission error rate than the conventional method. The proposed method improves power control efficiency because transmission error rate is lower than existing method.

3 is an operation flowchart of an open power control method according to an embodiment of the present invention.

In the open power control method between the terminal and the base station,

Given the sum of the number of transmission error messages and transmission success messages reported in the n-1th frame, the maximum value of the power calibration value, the target error rate, and the marginal power error rate, the terminal refers to Equation 6 for the upward step value and the target. Construct a binary linear equation consisting of a linear equation with error rate and downward step value as variables, and a linear equation with the maximum value of upward step value, marginal power error rate, downward step value, and power correction.

The terminal calculates an upward step value and a downward step value in the binary linear equation by differently applying the sum of the number of reported transmission error messages and transmission success messages (S101).

The terminal transmits the data in the frame to the base station in consideration of the power calibration value.

When the terminal receives a transmission error message from the base station (S102), it raises the power correction value by an upward step value (S103). The terminal transmits the data in the next frame to the base station in consideration of the power correction value raised by the upward step value.

When the terminal receives the transmission success message from the base station (S104), the power correction value is lowered by a downward step value (S105). The terminal transmits data in the next frame to the base station in consideration of the power correction value lowered by the downward step value.

Although the present invention has been described in more detail with reference to examples, the present invention is not necessarily limited to these examples, and various modifications can be made without departing from the spirit of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

As described above, according to the present invention, by controlling the upward step value and the downward step value according to the target error rate, the transmission error rate is reduced compared to the conventional open power control method, thereby increasing the efficiency of power control.

Claims (4)

In the open power control method between the terminal and the base station, Given the sum of the number of transmission error messages and transmission success messages reported in the n-1th frame, the maximum value of the power calibration value, the target error rate, and the marginal power error rate, the terminal determines the upward step value, the target error rate, and the downward step value. Establishing a binary linear equation consisting of a linear equation having a variable and a linear equation having a maximum value of an upward step value, a marginal power error rate, a downward step value, and a power correction value; Calculating an upward step value and a downward step value in the binary linear equation by differently applying the sum of the number of reported transmission error messages and transmission success messages; When the terminal receives a transmission error message from the base station, raising the power correction value by an upward step value; And When the terminal receives the transmission success message from the base station is configured to include a step of lowering the power correction value by a downward step value, The binary linear equation is A linear equation of 0 being a product of an upward step value and a target error rate plus a product of a downward step value and (1-target error rate); The upward step value, the marginal power error rate, and the sum of the number of transmission error messages and transmission success messages reported within the n-1th frame, the downward step value, (1-limit power error rate), and within the n-1th frame. And a linear equation equal to the maximum value of the power calibration value, the product of the sum of the total number of transmission error messages and transmission success messages reported. delete Given the sum of the number of transmission error messages and transmission success messages reported in the n-1th frame, the maximum value of the power calibration value, the target error rate, and the marginal power error rate, the terminal determines the upward step value, the target error rate, and the downward step value. A memory for storing a binary linear equation consisting of a linear equation having a variable and a linear equation having a maximum value of an upward step value, a marginal power error rate, a downward step value, and a power correction value; A step value calculator for calculating an upward step value and a downward step value in a binary linear equation stored in the memory by differently applying the sum of the number of reported transmission error messages and transmission success messages; And And a power calibration unit for raising the power calibration value by an upward step value when the terminal receives a transmission error message from the base station, and lowering the power calibration value by a downward step value when the terminal receives the transmission success message from the base station. The binary linear equation is A linear equation of 0 being a product of an upward step value and a target error rate plus a product of a downward step value and (1-target error rate); The upward step value, the marginal power error rate, and the sum of the number of transmission error messages and transmission success messages reported within the n-1th frame, the downward step value, (1-limit power error rate), and within the n-1th frame. And a linear equation equal to the maximum value of the power calibration value, the product of the sum of the total number of transmission error messages and transmission success messages reported. delete

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