KR100576723B1 - Method for decision of phase error of QPSK signal due to down-converter and apparatus thereof - Google Patents

Abstract

The present invention discloses a method and apparatus for determining a phase error due to a down converter of a QPSK signal.

According to the present invention, the I and Q channels of the down-converted QPSK signal are sampled at predetermined periods, and the average of the I and Q channel signals is calculated for each channel, so that the sampling values of the I channel, the average of the I channel signals, A predetermined statistic is calculated using the sampling values of the Q channel and the average of the Q channel signal, and the presence or absence of a phase error is determined by performing a statistical test according to a reference according to the T-distribution having degrees of freedom. It is possible to evaluate downconverting, which is a key component of the device receiver, so that it is easy to provide the presence or absence of phase error when applied to a measuring device that receives a QPSK signal, and program a statistical hypothesis test method to a signal receiving measuring device. In this case, it is possible to automatically provide phase error determination of the QPSK signal.

Description

Method and apparatus for determining phase error due to down converter of Kewpiesuke signal {Method for decision of phase error of QPSK signal due to down-converter and apparatus}

Figure 1 shows the structure of a receiver of a conventional wireless device of the QPSK system.

Figure 2 shows the flow of a method for determining the phase error due to the down converter of the QPSK signal in accordance with the present invention.

3 is a block diagram illustrating a configuration of an apparatus for determining a phase error due to a down converter of a QPSK signal according to the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to wireless communications, and to a method and apparatus for determining a phase error due to a down converter of a QPSK signal.

Quadrature phase shift keying (QPSK) is a digital frequency modulation technique that is mainly used when transmitting data over a coaxial cable network or when transmitting data in a CDMA wireless communication.

Figure 1 shows the structure of a receiver of a conventional wireless device of the QPSK system. The received signal is separated into an I channel and a Q channel through the channel separator 100. The separated I and Q channels are frequency-converted to the base band by the down-converting (110, 120). The phase shifter 130 rotates the reference sine wave of the oscillator by 90 degrees and inputs it to the Q channel down converting 120 for frequency conversion of the down converting. The reference sine wave 140 of the oscillator is input directly to the down-converting 110 of the I channel. The down-converting outputs of the I and Q channels are input to the baseband demodulator 150 and demodulated.

As described above, the signal receiver of the QPSK wireless device generally uses down converting for demodulation, and the I and Q channels of the signal passing through the down converting lose orthogonality, that is, a phase error occurs. I always have

In order to solve such a problem, many conventional measuring devices provide a function of measuring the phase error of the wireless device as described above, which uses a complex circuit to obtain a phase and obtain the measured value. However, this requires the use of complex and space-consuming components, and does not provide a separate method for verifying phase error due to the orthogonality between the I and Q channels.

In order to solve the above problems, the present invention provides a down converter of a QPSK signal through signals of down-converted I and Q channels for the orthogonality test of the I and Q channels of the QPSK demodulation signal. The present invention provides a method and apparatus for determining a phase error caused by the same.

According to an aspect of the present invention, a method for determining a phase error due to a down converter of a QPSK signal includes: (a) sampling an I channel and a Q channel of a down-converted QPSK signal at predetermined periods; (b) calculating an average of the I channel signal and the Q channel signal for each channel; (c) calculating a predetermined statistic using the sampling values of the I channel, the average of the I channel signals, the sampling values of the Q channel, and the average of the Q channel signals obtained in steps (a) and (b); And (d) performing a statistical test on the predetermined statistics according to a predetermined criterion to determine the presence or absence of a phase error.

According to another aspect of the present invention, there is provided an apparatus for determining a phase error due to a down converter of a QPSK signal, including: a sampling unit sampling I and Q channels of a down-converted QPSK signal at predetermined periods; A signal average calculator configured to calculate an average of the I and Q channel signals for each channel; A statistic calculator for calculating a predetermined statistic using the sampling value of the I channel, the average of the I channel signals, the sampling value of the Q channel, and the average of the Q channel signals obtained by the sampling unit and the signal average calculating unit; And a phase error judging unit which performs a statistical test on the predetermined statistics calculated by the statistics calculating unit according to a predetermined criterion to determine the presence or absence of a phase error.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 shows the flow of a method for determining the phase error due to the down converter of the QPSK signal in accordance with the present invention.

The I and Q channels of the down-converted QPSK signal are sampled at predetermined intervals (step 200), and the average of the I and Q channel signals is calculated for each channel (step 210). Using the sampling values, the average of the I channel signal, the sampling values of the Q channel, and the average of the Q channel signal, a predetermined statistics are calculated (step 220), and the predetermined statistics are statistically tested according to a predetermined criterion to obtain a phase error. Determine the presence or absence (step 230).

3 is a block diagram illustrating a configuration of an apparatus for determining a phase error due to a down converter of a QPSK signal according to the present invention.

The apparatus includes a sampling unit 300 for sampling the I and Q channels of the down-converted QPSK signal at predetermined periods, a signal average calculating unit 310 for obtaining the average of the I and Q channel signals for each channel, and a sampling unit ( 300) and a statistic calculator 320 that calculates a predetermined statistic using the I channel sampling values, the I channel signal averages, the Q channel sampling values, and the Q channel signal averages obtained by the signal average calculator 310. And a phase error determination unit 330 for performing a statistical test on the predetermined statistics calculated by the statistical calculator 320 according to a predetermined criterion to determine the presence or absence of a phase error.

In FIG. 3, the I-channel and Q-channel signals input to the sampling unit 300 and the signal average calculating unit 310 are divided into I-channel and Q-channel in FIG. 1, respectively, and then down-converted at 110 and 120. admit. The sampling unit 300 samples the signals at predetermined periods to obtain sampled values for each channel (step 200). If you sample for a period of time, you can get a certain number of times, for example n sampling values.

The signal average calculator 310 calculates an average of the I and Q channel signals for each channel (step 210). In step 200, the sampling unit 300 temporarily stores the n sampling values for each channel obtained for a predetermined time or unit time in a storage means such as a memory device, and then averages the values to calculate the average value of the signal for each channel. have.

The statistical calculator 320 may determine a predetermined value by using the sampling value of the I channel, the average of the I channel signals, the sampling value of the Q channel, and the average of the Q channel signals obtained by the sampling unit 300 and the signal average calculating unit 310. Compute the statistics (step 220).

는 I 채널 신호의 평균,

는 I 채널 신호의 평균,

는 I 채널의 샘플링 값,

는 Q 채널의 샘플링 값이며, n은 샘플링부(300)에서 샘플링하는 샘플링 크기일 때에, 통계량계산부(320)가 계산하는 소정의 통계값 R은,At this time,

Is the average of the I-channel signals,

Is the average of the I-channel signals,

Is the sampling value of the I channel,

Is a sampling value of the Q channel, and n is a sampling size sampled by the sampling unit 300, the predetermined statistical value R calculated by the statistical calculation unit 320 is

It is preferable to determine that.

In addition, the phase error determining unit 330 performs a statistical test on the R, which is the statistics calculated by the statistical calculation unit 320, according to a predetermined criterion to determine whether there is a phase error (step 230).

In this case, the phase error determination unit 330

It is preferable to perform a hypothesis test with a significance level of 5% to determine the presence or absence of a phase error.

Where T is a function of R and follows the T-distribution with n-2 degrees of freedom.

Statistically, we use variance, in particular population variance, to represent the distribution of data values. In practice, however, the variance is often unknown. In this case, statistically follow the T-distribution when the variance is not known. The T-distribution is suitable for the difference test for whether the mean and the population variance of two independent normal populations differ significantly. That is, a distribution suitable for use, such as comparison of two independent samples and comparison of the population mean of paired samples.

The T-distribution is characterized by a mean distribution of zero and a symmetrical distribution around zero, and a distribution similar to the standard normal distribution, but spreads farther to the left and right than the standard normal distribution, resulting in low peaks and thick tails. Also, the smaller the degree of freedom, the farther the form, and the greater the degree of freedom, the closer to the standard normal distribution. Since the T-distribution is well known and widely used in statistics, it is obvious to those skilled in the art to which the present invention pertains, and thus, further description of the T-distribution is omitted.

The apparatus according to the present invention as shown in FIG. 3 may be included as a component of the demodulator 150 of FIG. 1, and the I channel down-converted to the demodulator after determining the presence or absence of a phase error through the apparatus according to the present invention before demodulation. And Q channel signals.

Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. Examples included in the above description are introduced for the understanding of the present invention, and these examples do not limit the spirit and scope of the present invention. It will be apparent to those skilled in the art that various embodiments in accordance with the present invention in addition to the above examples are possible. The scope of the present invention is shown not in the above description but in the claims, and all differences within the scope will be construed as being included in the present invention.

In addition, it can be easily understood by those skilled in the art that each of the above steps according to the present invention can be variously implemented in software or hardware using a general programming technique.

And some steps of the invention may also be embodied as computer readable code on a computer readable recording medium. The computer-readable recording medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of computer-readable recording media include ROM, RAM, CD-ROM, CD-RW, magnetic tape, floppy disks, HDDs, optical disks, magneto-optical storage devices, and carrier waves (e.g. It also includes the implementation in the form of). The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion.

According to the present invention, the I and Q channels of the down-converted QPSK signal are sampled at predetermined periods, and the average of the I and Q channel signals is calculated for each channel, so that the sampling values of the I channel, the average of the I channel signals, A predetermined statistic is calculated using the sampling values of the Q channel and the average of the Q channel signal, and the presence or absence of a phase error is determined by performing a statistical test according to a reference according to the T-distribution having degrees of freedom. It is possible to evaluate down-converting, which is a key component of the device receiver, to easily provide the presence or absence of phase error when applied to a measuring device that receives a QPSK signal, and to program a statistical hypothesis test method to a signal receiving measuring device. In this case, it is possible to automatically provide phase error determination of the QPSK signal.

Claims (7)

(a) sampling the I and Q channels of the down-converted QPSK signal at predetermined intervals; (b) calculating an average of the I channel signal and the Q channel signal for each channel; (c) calculating a predetermined statistic using the sampling values of the I channel, the average of the I channel signals, the sampling values of the Q channel, and the average of the Q channel signals obtained in steps (a) and (b); And (d) performing a statistical test on the predetermined statistics according to a predetermined criterion to determine the presence or absence of a phase error; and determining the phase error due to the down converter of the QPSK signal. The method of claim 1,

Is the average of the I-channel signals,

Is the average of the I-channel signals,

Is the sampling value of the I channel,

Is the sampling value of the Q channel, and n is the sampling size of step (a), The predetermined statistical value R of step (c) is

The phase error due to the down converter of the QPSK signal, characterized in that determined by. The method according to claim 1 or 2, When the predetermined statistic of step (c) is R and n is the sampling size of step (a), the statistical test of step (d)

And determining the presence or absence of a phase error, wherein the phase error due to the down converter of the QPSK signal is determined. The method of claim 3, Wherein the statistical verification is performed with a hypothesis test with a significance level of 5%. A sampling unit sampling the I-channel and Q-channel of the down-converted QPSK signal at a predetermined period; A signal average calculator configured to calculate an average of the I and Q channel signals for each channel; A statistic calculator for calculating a predetermined statistic using the sampling value of the I channel, the average of the I channel signals, the sampling value of the Q channel, and the average of the Q channel signals obtained by the sampling unit and the signal average calculating unit; And A phase error determination unit for determining the presence or absence of a phase error by performing a statistical test on the predetermined statistics calculated by the statistics calculation unit according to a predetermined reference to determine the phase error due to the down converter of the QPSK signal Device. The method of claim 5,

Is the average of the I-channel signals,

Is the average of the I-channel signals,

Is the sampling value of the I channel,

Is the sampling value of the Q channel, and n is the sampling size sampled by the sampling unit. The predetermined statistical value R calculated by the statistical calculation unit is

The apparatus for determining the phase error due to the down converter of the QPSK signal, characterized in that determined by. The method of claim 5 or 6, The phase error judging portion is a predetermined statistic calculated by the statistic calculating portion is R and n is a sampling size sampled by the sampling portion.

And a phase error due to a down converter of a QPSK signal, characterized in that a hypothesis test with a significance level of 5% is used to determine the presence or absence of a phase error.

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