KR100698172B1 - Method of estimating SIR in mobile terminal and mobile terminal thereof - Google Patents

Abstract

The present invention relates to a method for estimating a more accurate signal-to-interference ratio by measuring the power of a signal without bias in estimating a signal-to-interference ratio (SIR) in a mobile communication terminal and a mobile communication terminal will be. In the method for estimating the signal-to-interference ratio in a mobile communication terminal according to the present invention, a signal-to-interference ratio (SIR) is measured by measuring signal power and interference power from a combiner output signal of a rake receiver. A method of estimating an interference ratio, comprising: a first step of multiplying a conjugate value of a pilot symbol by a combiner output signal; A second step of averaging the output signal of the first step during a pilot bit field; a third step of obtaining a simple square of an average value that is a result of the second step; And a fourth step of taking a real part of the square value in the third step and outputting the real part with the signal power.

Mobile terminal, bias, signal to interference ratio, SIR

Description

Method of estimating SIR in a mobile communication terminal and a mobile communication terminal thereof

1 is a block diagram of an SIR estimation apparatus in a mobile communication terminal according to the prior art.

Figure 2 is a block diagram of a preferred embodiment of an SIR estimation apparatus in a mobile communication terminal according to the present invention.

Figure 3 shows the simulation results in the ideal path of 1, AWGN.

The present invention relates to a mobile communication terminal. More specifically, the present invention provides a method for estimating a more accurate signal-to-interference ratio by measuring the signal power without bias in estimating a signal-to-interference ratio (SIR) in a mobile communication terminal and its movement. It relates to a terminal for communication.

The mobile communication terminal receives a signal transmitted from the base station and estimates a signal-to-interference ratio (SIR). The SIR is a value that already determines the ratio of the received signal power and the interference power of the channel through which the signal is transmitted, and is measured as one parameter for determining the state of the channel at the terminal. In particular, for downlink power control, the UE estimates the SIR, compares it with an SIR _target , which is a preset threshold, and transmits a TPC (Transmit Power Control) value to the base station according to the comparison result. Accurate estimation of the SIR is very important because it must be sent.

1 is a block diagram of an SIR estimating apparatus in a mobile communication terminal according to the prior art. In Fig. 1, the power of the received signal is measured using the output signal of the combiner 10 of the rake receiver. The signal received through the antenna of the terminal is despreading at the rake finger end to convert the signal of the chip unit into the signal of the symbol unit, the channel obtained by the channel estimator 11 of the rake combiner 10 The channel compensation is performed by conjugate and multiplying the estimated value. If the signal transmitted from the base station is received by the terminal through L multipaths, the number of fingers becomes L, and the LAKE combiner 10 L-signal channel-compensated in each L fingers. Is combined by MRC (Maximal-Ratio-Combining) method.

The output signal of the rake combiner 10 is branched and input to the signal power measuring module 20 and the interference power measuring module 30. The signal power measuring module 20 measures the power of the input signal, and the interference power measuring module 30 measures the interference power of the input signal. The interference power measurement module 30 may have various methods for measuring interference power. However, since the interference power measurement module 30 is not considered, the measurement process of the signal power will be described below.

The power of the signal is generally obtained coherently using a pilot signal of a dedicated physical control channel (DPCCH). Coherent means that the pilot bit corresponding to the training signal known in advance is used. That is, after extracting a pilot bit field of the DPCCH from the output signal of the lake combiner 10, the signal power is measured using the pilot bit field.

As shown in Fig. 1, in the conventional signal power measurement method as described above, the pilot bit or pilot symbol of the DPCCH is extracted from the DPCH, coherently averaged during the pilot bit field, the absolute value is taken, and then the squared. Obtain the signal power by

As described above, when measuring the power of the signal according to the conventional method, the power of the noise added from the channel acts as a bias to the measured power of the signal.

은 다음의 수학식1과 같이 표현할 수 있다.For convenience of analysis, the channel is assumed to be AWGN, which is path 1. First, the n-th DPCH symbol, which is a complex value of the rake combiner output terminal

Can be expressed as Equation 1 below.

는 DPCH신호의 송신단에서의 파워이고,

는 CPICH의 송신단에서의 파워이다. 채널 추정은 AWGN이므로 '1'로 본다. 즉, 이상적인 채널 추정을 가정한다. x_D,I,x_D,Q는 송신단에서 전송한 DPCCH의 파일럿 비트로서 1 혹은 -1의 값을 갖는다. z_D,I,z_D,Q는 채널에서의 잡음이 역확산되면서 발생되는 가산 잡음으로 파워가 확산계수(spreading factor)만큼 줄어든다. 상기 레이크 컴바이너(10)의 출력 신호는 수학식1에서 보는 바와 같이 복소값이다. 이때 I와 Q에서의 신호의 통계는 동일하므로 신호의 파워 또한 동일하다고 볼 수 있다. 따라서, 본 발명에서는 I에서의 신호파워만 보기로 한다. I 에서의 신호 파워는 다음의 수학식2와 같다.here

Is the power at the transmitting end of the DPCH signal,

Is the power at the transmitting end of the CPICH. Since channel estimation is AWGN, it is regarded as '1'. That is, assume ideal channel estimation. x _{D, I} , x _{D, Q} are pilot bits of the DPCCH transmitted from the transmitter and have a value of 1 or -1. z _{D, I} , z _{D, Q} are additive noises generated by despreading noise in a channel, and the power is reduced by a spreading factor. The output signal of the rake combiner 10 is a complex value as shown in equation (1). At this time, since the statistics of the signals in I and Q are the same, the power of the signal can be regarded as the same. Therefore, in the present invention, only the signal power at I will be considered. The signal power at I is as shown in Equation 2 below.

The bias of the signal obtained as described above is obtained from Equation 3 below.

As shown in Equation 3, the average power of the obtained signal can be seen that the bias term due to noise is added to the power of the desired signal. When the interference and noise power are properly measured, the total SIR is measured higher than the actual value and reflected in the uplink TPC, which adversely affects the performance of the receiver.

 The present invention has been made to solve the problems of the prior art as described above, an object of the present invention is to estimate the power of the signal in estimating the Signal to Interference Ratio (SIR) in the mobile communication terminal By measuring the absence of bias, a more accurate method of estimating the signal-to-interference ratio is provided.

Another object of the present invention is to provide a mobile communication terminal capable of estimating a more accurate signal-to-interference ratio by measuring a signal power without bias.

As an aspect of the present invention, the method for estimating the signal-to-interference ratio in the mobile communication terminal according to the present invention, by measuring the signal power (interference power) and the signal power (interference power) from the combiner output signal of the rake receiver In the method for estimating a signal to interference ratio (SIR), the measuring signal power may include: a first multiplying a conjugate value of a pilot symbol by the combiner output signal; And a second step of averaging the output signal of the first step during a pilot bit field, a third step of obtaining a simple square of an average value that is a result of the second step, and the third step And a fourth step of taking a real part of a square value of E and outputting the real power.

As another aspect of the present invention, a mobile communication terminal according to the present invention includes a signal power measurement module for measuring the signal power from the combiner output signal of the rake receiver and an interference power measurement module for measuring the interference power ( In the mobile communication terminal comprising a device for estimating a signal to interference ratio (SIR), the signal power measurement module, the signal power multiplier multiplied by the conjugate value (conjugate) of the pilot symbol (pilot symbol) to the combiner output signal; 1 means; Second means for averaging the output signal of the first step during a pilot bit field; Third means for obtaining a simple square of an average value which is an output value of the second means; And fourth means for taking a real part of the square value obtained by the third means and outputting the real power with the signal power.

The configuration, operation, and other features of the present invention will be clearly understood by one preferred embodiment of the present invention described below with reference to the accompanying drawings. Figure 2 is a block diagram of a preferred embodiment of a signal-to-interference ratio estimation apparatus according to the present invention.

In Fig. 2, the power of the received signal is measured using the output signal of the combiner 40 of the rake receiver. The signal received through the antenna of the terminal is despreading at the rake finger end to convert the signal of the chip unit into the signal of the symbol unit, the channel obtained by the channel estimator 41 of the rake combiner 40 The channel compensation is performed by conjugate and multiplying the estimated value. If the signal transmitted from the base station is received by the terminal through L multi-paths, the number of fingers becomes L and the LQ combiner 40 performs L channel-compensated L signals on each L fingers. Is combined by MRC (Maximal-Ratio-Combining) method.

The output signal of the rake combiner 40 is branched and input to the signal power measuring module 60 and the interference power measuring module 50. The signal power measuring module 60 measures the power of the input signal, and the interference power measuring module 40 measures the interference power of the input signal. A specific method of measuring the interference power in the interference power measurement module 40 may be implemented by various methods according to the prior art, and description thereof will be omitted.

The lake combiner (4) is obtained by multiplying a conjugate signal of a pilot signal of a dedicated physical control channel (DPCCH) by a signal output from the lake combiner 40 and input to the signal power measurement module 60. 40) Remove the signal component from the output signal and leave only the channel component. A value obtained by removing the channel component is averaged over the pilot bit field N _ps . The pilot bit field N _ps is a predetermined value and is a value previously known to the terminal. After simply squaring the average value, only the real part is taken from the value and output as a signal power.

A feature of the present invention is that simple squares are used instead of squares of absolute values used in conventional methods to remove biases that may occur when measuring signal power. After that, only the real term is taken from this squared value (complex value) and output as the signal power. When measuring the signal power in this way, the analysis of the bias is as follows.

First, the output signal of the despread rake combiner is the same as the conventional method. In other words,

Using the despread pilot bits, the signal power is calculated as in the proposed method.

Where Y _I and Y _Q are Gaussian random variables with the following distribution:

Therefore, it can be seen that the statistics of Y _I and Y _Q are equal to each other.

To verify that there is no bias, average the above equations as follows:

As shown in the above equation, it can be seen that the bias term generated by taking the square of the absolute value in the prior art is removed.

It is apparent to those skilled in the art that the present invention can be embodied in other specific forms without departing from the spirit and essential features of the present invention. Accordingly, the above detailed description should not be construed as limiting in all aspects and should be considered as illustrative. The scope of the invention should be determined by reasonable interpretation of the appended claims, and all changes within the equivalent scope of the invention are included in the scope of the invention.

According to the present invention, since the bias term due to noise can be eliminated when estimating signal power for measuring the signal-to-interference ratio (SIR) in the mobile communication terminal, it is possible to measure the signal-to-interference ratio more accurately.

Fig. 3 shows the simulation results in an ideal path of 1, which is AWGN, and it can be seen that the simple squared approach by the present invention approaches a more ideal situation than the square of the absolute value in the prior art. .

Claims (4)

In the method of estimating the signal to interference ratio (SIR) by measuring signal power and interference power from the combiner output signal of the rake receiver, Measuring the signal power, Multiplying a conjugate value of a pilot symbol by the combiner output signal; A second step of averaging the output signal of the first step during a pilot bit field; A third step of obtaining a simple square of an average value that is a result of the second step; And a fourth step of taking a real part of the square value in the third step and outputting the real part of the squared value at the signal power. The method of claim 1, The pilot symbol is a Dedicated Physical Control CHannel (DPCCH) pilot symbol. For mobile communication comprising a device for estimating a signal to interference ratio (SIR), including a signal power measurement module for measuring signal power from the combiner output signal of the rake receiver and an interference power measurement module for measuring interference power In the terminal, The signal power measurement module, First means for multiplying the combiner output signal by a conjugate of a pilot symbol; Second means for averaging the output signal of the first step during a pilot bit field; Third means for obtaining a simple square of an average value which is an output value of the second means; And And a fourth means for taking a real part of the square value obtained by the third means and outputting the real power with the signal power. The method of claim 3, And the pilot symbol is a dedicated pilot control channel (DPCCH) pilot symbol.

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