KR100867105B1 - Apparatus for compensation of frequency offset based on nonuniform power allocation and method thereof - Google Patents

Abstract

An apparatus and a method for compensating for a frequency offset based on non-uniformity power allocation are provided to improve estimation performance for a frequency offset error of a transmission and reception period by controlling a power ratio of a long training symbol and a small training symbol among a packet training symbol according to an SNR of a channel. An SNR(Signal to Noise Ratio) measurer is included in a receiving side and measures the SNR of the received signal. An LSPR power controller is included in a transmission side and determines the LSPR(Long training symbol to Short training symbol Power Ratio) control parameter by comparing the measured SNR with a standard SNR. A LSPR power controller(100) controls the power rate of a short training symbol and a long training symbol. The power rate of the short training symbol and the long training symbol is controlled according to the measured SNR for supporting the frequency offset estimation and compensation.

Description

Apparatus for Compensation of Frequency Offset Based on Nonuniform Power Allocation and Method

The present invention relates to a non-uniform power allocation-based frequency offset compensation apparatus and method, and particularly, a long training symbol among packet training symbols in a dedicated short range communications (DSRC), wireless LAN, and orthogonal frequency-division, multiplexing-based packet communication system The present invention relates to a non-uniform power allocation-based frequency offset compensation apparatus and technique that can improve communication reliability by adjusting the power ratio of the training symbol and the short training symbol according to the SNR of the channel.

Dedicated Short Range Communications (DSRC), WLAN, and OFDM-based communication systems transmit and receive signals on a packet-by-packet basis, which includes a preamble for detecting the beginning of the packet, time and frequency synchronization, and channel prediction.

1 is a structural diagram showing a preamble compliant with the IEEE802.11a and IEEE802.11p standards. As shown in FIG. 1, a preamble according to the IEEE802.11a and IEEE802.11p standards is inserted between a short training symbol (t1 to t10), a short training symbol, and a long training symbol. Cyclic Prefix (G12) and Long Training Symbol (T1, T2).

The short training symbols t1 to t10 are the same symbols each having 16 sample lengths used for coarse frequency offset estimation timing synchronization.

CP (G12) is a guard interval inserted between the short training symbol and the long training symbol.

The long training symbols T1 and T2 are the same symbol having 64 sample lengths used for Channel and Fine Freq.Offset Estimation.

In such a wireless communication scheme, the frequency offset prediction of the receiver is predicted as the amount of phase change per hour according to the calculation of the phase change value for the samples of the same value transmitted over a certain time interval among the training symbols of the preamble.

This is a two-step process of predicting the approximate frequency offset by the short training symbols t1 to t10 and then predicting the fine frequency offset by the long training symbols T1 and T2.

The SNR (Signal to Noise Ratio) of the received signal varies according to the degree of channel noise according to the situation of the channel. Accordingly, the training symbols to be important in frequency offset prediction are different.

Specifically, when the SNR is low, predicting a coarse frequency offset by short training symbols in terms of Mean Square Error (MSE) of overall frequency offset prediction performance is better than predicting fine frequency offsets by long training symbols. On the contrary, when the SNR is high, accurate frequency offset prediction by long training symbols is more important to the overall MSE performance.

However, in the preamble according to the related art, the power ratios of the long training symbols and the short training symbols are set to be the same, so that two types of training symbols have the same importance in frequency offset prediction regardless of the SNR of the channel.

The present invention is to predict the frequency offset error of the transmission and reception period by adjusting the power ratio of the long training symbol and the short training symbol of the packet training symbols according to the channel SNR in Dedicated Short Range Communications (DSRC), WLAN and OFDM-based packet communication systems The purpose of the present invention is to provide a non-uniform power allocation-based frequency offset compensation device and technique with high communication reliability.

를 결정하고, 그에 따라 긴 훈련심볼과 짧은 훈련심볼의 전력비(LSPR)를 조절하는 LSPR 전력 제어기를 포함하고, 상기 측정 SNR에 따라 긴 훈련심볼과 짧은 훈련심볼의 전력비를 주파수 오프셋 추정 및 보상에 유리하도록 조절하는 점에 그 특징이 있다. In order to achieve the above object, a non-uniform power allocation-based frequency offset compensation apparatus according to the present invention includes an SNR measuring instrument included in a receiving side and measuring an SNR of a received signal, and included in the transmitting side to compare the measured SNR with a reference SNR. LSPR control parameters

And an LSPR power controller that adjusts the power ratio (LSPR) of the long training symbol and the short training symbol accordingly, wherein the power ratio of the long training symbol and the short training symbol is advantageous for frequency offset estimation and compensation according to the measured SNR. The feature is that it is adjusted to.

Here, it is preferable that the SNR measuring device measures the SNR of the received signal according to the request of the transmitting side transmitted at a predetermined time period.

를 결정하는 기준 SNR 비교부와, 상기

에 따라 상기 긴 훈련심볼과 짧은 훈련심볼의 전력비를 조절하여 상기 송신 프리앰블의 전력을 정규화하는 전력 정규화부로 구성된다. The LSPR power controller compares the magnitude of the measured SNR with the reference SNR.

A reference SNR comparison unit for determining

The power normalization unit is configured to normalize the power of the transmission preamble by adjusting the power ratio of the long training symbol and the short training symbol.

를 증산하며, 그 반대는 상기

를 감산하며, 최초의

값인 1 또는 이전에 결정된

를 저장하는 버퍼를 더 포함하고, 상기 저장된

를 기준으로 증산 또는 감산하는 것이 바람직하다. In this case, the reference SNR comparison unit is performed when the measured SNR is greater than the reference SNR.

Vice versa, and vice versa

To subtract the first

The value 1 or previously determined

Further comprising a buffer for storing, the stored

It is preferable to increase or subtract on the basis of.

Here, the LSPR power controller is the following equation

에 의해 산출되는 전력 정규화된 송신 프리앰블을 출력하며, 상기 송신 프리앰블의 평균 전력

는 다음 수학식

에 의해 산출된다.

Output a power normalized transmission preamble calculated by the method, and average power of the transmission preamble

Is the following equation

Calculated by

은 짧은 훈련심볼, 상기

은 긴 훈련심볼 및 CP의 이산신호 표현이며, 송신 프리앰블은 DSRC, 무선랜 및 OFDM을 포함하는 통신방식에 기반한다.At this time, the

Short training symbols, reminding

Is a discrete signal representation of a long training symbol and CP, and the transmission preamble is based on a communication scheme including DSRC, WLAN and OFDM.

를 증감하는 단계와, 상기

를 적용하 여 송신 프리앰블의 긴 훈련심볼과 짧은 훈련심볼의 전력비를 제어하는 단계를 포함하고, 상기 측정 SNR에 따라 긴 훈련심볼과 짧은 훈련심볼의 전력비를 주파수 오프셋에 강하도록 제어하는 점에 그 특징이 있는 비균일 전력 할당기반 주파수 오프셋 보상 기법이 제공된다.Comparing the measured SNR and the reference SNR according to another feature of the invention, and according to the comparison result LSPR control parameters

Increasing and decreasing the above,

Controlling the power ratio of the long training symbol and the short training symbol of the transmission preamble by applying a value, and controlling the power ratio of the long training symbol and the short training symbol to the frequency offset according to the measured SNR. A non-uniform power allocation based frequency offset compensation technique is provided.

At this time, in the comparing step, the measured SNR is determined by transmitting a transmission signal from the transmitting side and requesting a receiving SNR at a predetermined time period, and measuring and transmitting the receiving SNR at the receiving side to the transmitting side. It is preferable.

일 때 수신 프리앰블 주파수 오프셋 예측 성능의 MSE값에 기준하여 결정된다. The method may further include determining a reference SNR before the comparing, wherein the reference SNR is

When is determined based on the MSE value of the received preamble frequency offset prediction performance.

를 출력하는 단계, (d-2) 상기 측정 SNR ＞ 기준 SNR이면 상기

를 증산하는 단계, (d-3) 상기 측정 SNR ＜ 기준 SNR이면 상기

를 감산하는 단계 중 어느 하나의 단계이다. Increasing or decreasing the LSPR control parameter may include (d-1) if the measurement SNR = reference SNR.

(D-2) if the measured SNR> reference SNR,

(D-3) if the measured SNR <reference SNR;

Subtracting any one of the steps.

값인 1 또는 이전에 결정된

에 기준한다. Here, the increase or decrease is the first

The value 1 or previously determined

Based on.

On the other hand, in the step of controlling the power ratio of the long training symbol and the short training symbol, the transmission preamble is

에 의해 산출되며, 상기

는 다음 수학식

에 의해 산출되는 평균 전력이고, 상기

은 짧은 훈련심볼, 상기

은 긴 훈련심볼 및 CP의 이산신호 표현이다.

Calculated by

Is the following equation

Is the average power calculated by

Short training symbols, reminding

Is a discrete signal representation of the long training symbol and CP.

은 상기 긴 훈련심볼과 상기 짧은 훈련심볼의 전력비가 동일한 경우이다. And,

Is a case where the power ratio of the long training symbol and the short training symbol is the same.

Non-uniform power allocation-based frequency offset compensation apparatus and technique according to the present invention is the SNR of the channel to the power ratio of the long training symbol and the short training symbol of the packet training symbols in the DSRC (Dedicated Short Range Communications), WLAN and OFDM-based packet communication system By adjusting according to the present invention, it is possible to increase the prediction performance and the communication reliability of the frequency offset error in the transmission and reception period.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following embodiments are provided to those skilled in the art to fully understand the present invention, it can be modified in various forms, the scope of the present invention is limited to the embodiments described below It is not.

를 결정하고, 그에 따라 긴 훈련심볼과 짧은 훈련심볼의 전력비를 조절하는 LSPR 전력 제어기(100)로 구성된다. 2 is a block diagram illustrating a non-uniform power allocation-based frequency offset compensation apparatus according to an embodiment of the present invention. As shown in FIG. 2, the non-uniform power allocation-based frequency offset compensator includes an SNR measuring device 200 included in a receiving side and measuring an SNR of a received signal, and included in the transmitting side to compare the measured SNR with a reference SNR. LSPR control parameters

LSPR power controller 100 to determine the power control ratio of the long training symbol and the short training symbol accordingly.

The SNR meter 200 measures the SNR of the received signal according to the situation of the channel.

At this time, it is preferable that the SNR measuring unit 200 measures the SNR according to the request of the transmitting side transmitted at a predetermined time (for example, 0.1 ms) and transmits the value to the transmitting side.

를 결정하고, 그에 따라 긴 훈련심볼과 짧은 훈련심볼의 전력비를 조절한다. The LSPR power controller 100 is composed of a reference SNR comparator 110 and a power normalizer 120 to compare the measured SNR and the reference SNR transmitted by the SNR meter 200 to the LSPR control parameter.

And adjust the power ratio of the long and short training symbols accordingly.

를 결정한다. The reference SNR comparison unit 110 compares the measured SNR and the size of the reference SNR to control the long training symbol to short training symbol power ratio (LSPR) control parameter.

Determine.

일 때 긴 훈련심볼과 짧은 훈련심볼의 전력은 동일하며,

일 때 긴 훈련심볼보다 짧은 훈련심볼의 전력이 작고,

일 때 긴 훈련 심볼보다 짧은 훈련심볼의 전력이 크다. Where LSPR control parameters

The power of the long and short training symbols is the same when

When the power of the short training symbol is smaller than the long training symbol,

Is shorter than the long training symbol.

값인 1 또는 이전에 결정된

를 저장하는 버퍼(미도시)를 더 포함하여 측정 SNR이 기준 SNR보다 크면 버퍼(미도시)에 저장된 값을 기준으로

를 증산하고, 그 반대의 경우는

를 감산한다. On the other hand, the reference SNR comparison unit 110 is the first

The value 1 or previously determined

And a buffer (not shown) for storing the measured SNR greater than the reference SNR, based on a value stored in the buffer (not shown).

And vice versa

Subtract

에 따라 긴 훈련심볼과 짧은 훈련심볼의 전력비를 조절하여 송신 프리앰블의 전력을 정규화한다. Power normalization unit 120 is determined

According to the power ratio of the long training symbol and the short training symbol is adjusted to normalize the power of the transmission preamble.

은 짧은 훈련심볼의 이산신호 표현,

는 긴 훈련심볼 및 CP

의 이산신호 표현이다. The preamble signal including the short training symbol and the long training symbol is calculated by Equation 1 below,

Is a discrete signal representation of a short training symbol,

Long training symbol and CP

Is a discrete signal representation of.

는 다음 수학식 2 에 의해 산출된다. And, average power of transmission preamble when LSPR is applied

Is calculated by the following equation (2).

The discrete signal representation of the transmission preamble power normalized by the LSPR power controller 100 is expressed by Equation 3 below.

Thereafter, the signal represented by Equation 3 is transmitted to a channel that is a transmission / reception path through a DA converter (not shown), an RF transmitter (not shown), etc. of the transmitter.

Subsequently, the receiver performs signal detection, ACG, symbol and frequency synchronization acquisition, and symbol demodulation through an RF receiver (not shown), an AD converter (not shown), and the like.

Received by AWGN (Additive White Gaussian Noise) due to multipath fading, the received signal considering the frequency offset through the AGC (Auto Gain Control) and the signal detection process is represented by the following equation (4).

는 각각 다중경로 채널의 임펄스 응답,

는 채널 길이,

는 AWGN,

은 IFFT/FFT 포인트 수,

는 부반송파 주파수 간격에 정규화된 주파수 오프셋 에러이다. here,

Are the impulse responses of each of the multipath channels,

Is the channel length,

AWGN,

Is the number of IFFT / FFT points,

Is the frequency offset error normalized to the subcarrier frequency interval.

 Based on the preamble structure shown in Fig. 1, signal detection and AGC are completed before the start point of the eighth short training symbol (t1 to t7), so that the last three short training symbols (t8, t9, t10) and two long drills are completed. Assume that the symbols T1 and T2 can be used for carrier frequency offset prediction.

As described above, the preamble predicts the frequency offset through a two-step process and performs correction for it.

Equation 5 below is a result of one-step rough frequency offset prediction using short training symbols t8, t9, and t10.

Equation 6 is a result of two-step fine frequency offset prediction using long training symbols T1 and T2.

과 같이, 짧은 훈련심볼과 긴 훈련심볼의 합으로 산출된다.Therefore, the overall frequency offset estimate is

As a result, the sum of short training symbols and long training symbols is calculated.

구간으로 제한되어 있으므로, 주파수 오프셋 예측 범위는 다음 수학식 7와 같이 제한된다. The arc tangent calculation to calculate the amount of rotation by frequency offset

Since it is limited to a section, the frequency offset prediction range is limited as shown in Equation 7 below.

는 짧은 훈련심볼에 의한 주파수 오프셋에 대해서는 16이고, 긴 훈련 심볼에 의한 주파수 오프셋에 대해서는 64이다. here,

Is 16 for the frequency offset by the short training symbol and 64 for the frequency offset by the long training symbol.

와

이다. The frequency offset prediction ranges corresponding to Equations 5 and 6 calculated in the range of Equation 7 are respectively.

Wow

to be.

That is, the frequency offset range of the predictable received signal is within ± 2, the frequency offset is normalized within ± 0.5 by the short training symbol, and then the frequency offset prediction by the long training symbol is performed.

인 경우를, 도 4는

인 경우를 도시하였다. 3 and 4 are graphs showing simulation results of frequency offset prediction at the receiver for a preamble to which a non-uniform power allocation based frequency offset compensation scheme is applied according to an embodiment of the present invention. 3 is

4 is

The case is shown.

In this case, when the LSPR is 0dB, the power ratio of the long training symbol and the short training symbol is the same as in the prior art, and when the LSPR is 0dB or more, the long training symbol is higher in power than the short training symbol, and the LSPR is 0dB or less. The case is that a long training symbol has a lower power than a short training symbol.

As shown in the graphs of FIG. 3 and FIG. 4, it can be seen that the LSPR value of which the MSE is small differs according to the degree of SNR, thereby controlling the LSPR to improve the frequency offset.

That is, LSPR is 0dB in the SNR range of 0.4dB to 3.1dB in FIG. 3 and -0.4dB to 1.8dB in FIG. 4, and LSPR is 0dB or less in the section below it, and LSPR in the above range. Controlling more than 0dB can generally improve the frequency offset.

In summary, when the SNR is high, the power allocated to the long training symbol is higher than the short training symbol, and the MSE performance is improved. On the contrary, when the SNR is low, the power allocated to the short training symbol is higher than the long training symbol. MSE performance is improved.

5 is a flowchart illustrating an operation procedure of a non-uniform power allocation-based frequency offset compensation apparatus according to an embodiment of the present invention. A description with reference to FIG. 5 is as follows.

First, a signal for requesting SNR of a received signal is transmitted from a transmitter to a receiver (S510).

Then, the receiver measures the SNR and transmits the value to the transmitter (S520).

Subsequently, the transmitter compares the measured SNR transmitted from the receiver to the reference SNR (S530).

일 때 수신 프리앰블 주파수 오프셋 예측 성능의 MSE에 기준하여 기준 SNR을 이미 결정해두어야 한다. At this time, the reference SNR before the execution of the step (S530) is

In this case, the reference SNR should be determined based on the MSE of the received preamble frequency offset prediction performance.

를 증감한다(S540~S570). And, according to the comparison result LSPR control parameter

Increase or decrease (S540 ~ S570).

값인 1 또는 이전에 결정된

에 기준한다. At this time, the increase or decrease of the LSPR control parameter is first performed.

The value 1 or previously determined

Based on.

로 결정하고(S570), 측정 SNR ＞ 기준 SNR이면(S530), 이전에 결정된

에 기준하여

를 증산하고(S550), 측정 SNR ＜ 기준 SNR이면(S530, S540), 이전에 결정된

에 기준하여

를 감산한다(S560). Specifically, if measurement SNR = reference SNR (S540),

(S570), if the measured SNR> reference SNR (S530), previously determined

Based on

Is increased (S550), and if the measured SNR <reference SNR (S530, S540),

Based on

To subtract (S560).

값을 적용하여 송신 프리앰블 긴 훈련심볼과 짧은 훈련심볼의 전력비를 제어한다(S580).And decided

The power ratio of the transmission preamble long training symbol and the short training symbol is controlled by applying a value (S580).

At this time, the LSPR-controlled transmission preamble is expressed as shown in Equation 3 above, and when the SNR is changed according to the channel condition, the LSPR is controlled again so that the preamble according to the present invention is strong in frequency offset.

That is, steps S510 and S520 may be repeatedly executed at predetermined time periods to update the measured SNR to suit the channel situation.

The configuration of the present invention has been described above through the preferred embodiments and the accompanying drawings. However, these are only examples and are not used to limit the scope of the present invention. Those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom, and the true scope of protection of the present invention should be determined by the technical spirit of the appended claims.

1 is a structural diagram showing a preamble compliant with IEEE802.11a and IEEE802.11p standards.

Figure 2 is a block diagram showing a non-uniform power allocation based frequency offset compensation apparatus according to the present invention.

3 and 4 are graphs showing simulation results of frequency offset prediction for a preamble to which a non-uniform power allocation-based frequency offset compensation technique is applied according to the present invention.

5 is a flowchart showing the operation procedure of the non-uniform power allocation-based frequency offset compensation apparatus according to the present invention.

<Description of main parts of drawing>

100: LSPR power controller 110: reference SNR comparison unit

120: power normalization unit 200: SNR meter

Claims (17)

An SNR measuring instrument included in the receiving side for measuring the SNR of the received signal; LSPR control parameter included in the transmitting side to compare the measured SNR and the reference SNR

And a LSPR power controller that adjusts and adjusts the power ratio (LSPR) of the long and short training symbols accordingly, And a non-uniform power allocation-based frequency offset compensation device for adjusting the power ratio of the long training symbol and the short training symbol to the frequency offset estimation and compensation according to the measured SNR. The method of claim 1, wherein the SNR meter, And a non-uniform power allocation-based frequency offset compensating apparatus for measuring the SNR of the received signal according to a request of a transmitter transmitted at a predetermined time period. The method of claim 1, wherein the LSPR power controller, By comparing the magnitude of the measured SNR and the reference SNR

A reference SNR comparison unit for determining remind

A power normalization unit for normalizing the power of the transmission preamble by adjusting the power ratio of the long training symbol and the short training symbol according to Non-uniform power allocation-based frequency offset compensation apparatus comprising a. The method of claim 3, wherein the reference SNR comparison unit, If the measured SNR is greater than the reference SNR

Vice versa, and vice versa

Non-uniform power allocation based frequency offset compensation apparatus, characterized in that for subtracting. The method of claim 4 wherein the first

The value 1 or previously determined

Further comprising a buffer for storing, the stored

Non-uniform power allocation based frequency offset compensation apparatus characterized in that the increment or subtraction on the basis of. The method of claim 1, wherein the LSPR power controller is the following equation

Output a power normalized transmission preamble calculated by Average power of the transmission preamble

Is the following equation

A non-uniform power allocation based frequency offset compensation device, characterized in that calculated by. The method of claim 6, wherein

Short training symbols, reminding

The non-uniform power allocation-based frequency offset compensation device, characterized in that the long training symbol and a discrete signal representation of the CP. The method of claim 1, wherein the transmission preamble, Dedicated Short Range Communications (DSRC), WLAN and OFDM Non-uniform power allocation based frequency offset compensation apparatus, characterized in that based on a communication scheme comprising a. The method according to any one of claims 1 to 6, wherein

Is 1, And a non-uniform power allocation-based frequency offset compensation device, characterized in that the power ratio of the long training symbol and the short training symbol is the same. Comparing the measured SNR with the reference SNR; LSPR control parameter according to the comparison result

Step of increasing and decreasing, remind

Controlling the power ratio of the long training symbol and the short training symbol of the transmission preamble by applying a; The non-uniform power allocation-based frequency offset compensation technique, characterized in that for controlling the power ratio of the long training symbol and the short training symbol to the frequency offset in accordance with the measured SNR. 11. The method of claim 10, wherein in the comparing step, the measured SNR is a predetermined time period, Requesting a reception SNR by transmitting a transmission signal at a transmitting side; Measuring the receiving SNR at the receiving side and transmitting to the transmitting side The non-uniform power allocation based frequency offset compensation technique, characterized in that determined by performing. The method of claim 10, wherein prior to the comparing step, Non-uniform power allocation based frequency offset compensation technique further comprising the step of determining a reference SNR. The method of claim 12, wherein the reference SNR is, remind

When the non-uniform power allocation based frequency offset compensation method characterized in that based on the MSE value of the received preamble frequency offset prediction performance. The method of claim 10, wherein increasing or decreasing the LSPR control parameter comprises: (d-1) If the measured SNR = reference SNR

Outputting, (d-2) If the measured SNR> reference SNR

Step of increasing the amount, (d-3) If the measurement SNR <reference SNR

Subtracting Non-uniform power allocation based frequency offset compensation technique, characterized in that any one of steps. The method of claim 14, wherein the step of increasing or decreasing, First

The value 1 or previously determined

A non-uniform power allocation based frequency offset compensation technique, characterized in that for reference. 11. The method of claim 10, wherein in the step of controlling the power ratio of the long training symbol and the short training symbol, the transmission preamble is

Calculated by

Is the following equation

Is the average power calculated by

Short training symbols, reminding

Is a discrete signal representation of a long training symbol and CP, non-uniform power allocation based frequency offset compensation technique. The method according to any one of claims 10, 12, 14 and 15, wherein

The non-uniform power allocation-based frequency offset compensation technique characterized in that the power ratio of the long training symbol and the short training symbol is the same.

Images