KR100698259B1 - Apparatus and method for estimating integral frequency offset - Google Patents

Abstract

An integer frequency offset estimation apparatus and a method therefor are provided to consume low power and estimate an integer frequency offset at high speed. The first to the Nth storing units(10,12,14) divide demodulated PRSs(Phase Reference Symbols) by N, and store the N-divided PRSs. An address generating unit(16) generates addresses for writing the PRSs in the first to the Nth storing units(10,12,14) and reading the PRSs from the first to the Nth storing units(10,12,14). A PRS generating unit(20) generates the PRSs, and outputs the generated PRSs as reference PRSs. A correlation calculating unit(22) calculates sample correlation values between the N PRSs read from the first to the Nth storing units(10,12,14) and the N reference PRSs. A frequency offset output unit(24) adds the sample correlation values, generates the last correction values, and outputs the maximum value among the last correction values as an integer frequency offset value.

Description

Apparatus and method for estimating integral frequency offset}

1 is a block diagram of an embodiment of an integer frequency offset estimation apparatus according to the present invention.

2 is a flowchart for explaining an embodiment of the integer frequency offset estimation method according to the present invention.

3 are tables illustrating a relationship between an indicator and a parameter of a phase reference symbol.

4 is a graph illustrating a phase reference symbol.

5 is a graph illustrating a phase reference symbol with an integer frequency offset.

6 is a diagram for describing an example of an operation of the correlation calculator illustrated in FIG. 1.

The present invention relates to a receiver such as a terrestrial digital multimedia broadcasting (DMB) receiver and the like, and more particularly, to an apparatus and method for estimating an integral frequency offset in a receiver.

The terrestrial DMB adopted in Korea is based on Eureka-147 Digital Audio Broadcasting (DAB), adopted as the European terrestrial radio standard. In order to improve multimedia broadcasting performance, for example, a Reed-Solomon (RS) error correction encoder and a convolutional interleaver are added.

In general, according to the DAB standard, null symbols, phase reference symbols (PRS), and messages are multiplexed and transmitted for synchronization. In addition, the DAB transmission frame is composed of a synchronization channel (Synchronization channel), a fast information channel (Fast Information channel) and the main service channel (Main Service Channel). Eureka-147 uses Orthogonal Frequency Divisional Multiplexing (OFDM) transmission.

In general, since the DMB uses the OFDM transmission scheme, the DMB has better characteristics for signal distortion due to multipath and adjacent symbol interference than the single carrier scheme. However, the transmitted frequency and the received frequency have an error. At this time, the frequency error generated in the DMB receiver is represented by the sum of the integer frequency offset and the fractional frequency offset. At this time, in order to accurately measure the integer frequency offset, the DMB transmitter transmits phase reference symbols (PRSs) having good autocorrelation relation characteristics in advance at the beginning of every frame.

In a conventional DMB receiver, PRSs transmitted from a transmitter are demodulated and stored in a memory, a correlation between PRSs stored in a memory and PRSs generated by itself is estimated, and an integer frequency offset is estimated from the correlation result.

When estimating the integer frequency offset by the conventional method described above, the following two problems occur.

In terrestrial DMB receivers, the range of integer frequency offsets is equal to the guard band of the FFT, thus becoming '512'. In this case, all of the '1536' memory address areas must be read to calculate a correlation value, and all of the '512' correlation values must be calculated for the estimation. Therefore, in the conventional case, 1536 x 512 = 786432 times of memory access is required. Therefore, when the integer frequency offset is estimated by the conventional terrestrial DMB receiver, there are problems in that the estimation time is long and power consumption is increased.

It is an object of the present invention to provide an integer frequency offset estimating apparatus and method capable of estimating an integer frequency offset at high speed while consuming little power.

In order to achieve the above object, the integer frequency offset estimation apparatus according to the present invention comprises first to Nth storage units for dividing the demodulated phase reference symbols (PRS) into N (where N is a positive integer of 2 or more). And an address generator for generating addresses for writing the PRSs to the first to Nth storage units and reading the PRSs from the first to Nth storage units, and generating the PRSs by itself. A PRS generator for outputting as PRSs, a correlation calculator for calculating sample correlations between the N PRSs and the N reference PRSs read from the first to Nth storage units, and the sample correlations And an integer frequency offset output unit for generating correlation values and outputting a maximum value as an integer frequency offset among the generated final correlation values. Is recommended.

In addition, in order to achieve the above object, the integer frequency offset estimation method according to the present invention comprises the steps of storing the demodulated phase reference symbols (PRS) divided into N (where N is a positive integer of 2 or more), and the PRS Generating the correlation coefficients, generating sample correlations between the stored N PRSs and the N generated PRSs, and adding the sample correlations to generate final correlation values, and generating the generated final correlation values. Among these, it is preferable that the maximum value is determined as an integer frequency offset.

Hereinafter, with reference to the accompanying drawings, the configuration and operation of the embodiment of the integer frequency offset estimation apparatus according to the present invention and the method will be described.

1 is a block diagram of an embodiment of an integer frequency offset estimation apparatus according to the present invention, wherein the first through Nth storage units 10, 12, ..., and 14, the address generator 16, and the buffers 18 are shown. , A PRS generator 20, a correlation calculator 22, and an integer frequency offset output 24.

FIG. 2 is a flowchart illustrating an embodiment of the integer frequency offset estimation method according to the present invention, in which the demodulated PRSs are divided and stored (steps 60 and 62), and various PRSs are generated using self-generated PRSs. Simultaneously obtaining the two sample correlations (steps 64 and 66) and determining the integer frequency offset (step 68).

The integer frequency offset estimation apparatus according to the present invention shown in FIG. 1 may be included in a DMB receiver. In order to facilitate understanding of the present invention, an integer frequency offset estimation apparatus according to the present invention is described as being included in the DMB receiver, but the present invention is not limited thereto.

First, the first to Nth storage units 10, 12,..., And 14 input demodulated phase reference symbols PRS in the DMB receiver through the input terminal IN, and divides the input phase reference symbols into N pieces. Each step is then stored (step 60). Where N is a positive integer of 2 or greater. For example, if a DMB transmitter modulates a signal using a 2048 (2 ^{X = 11} ) point Inverse Fast Fourier Transform (IFFT), the DMB receiver uses a 2048 point Fast Fourier Transform. Demodulate the signal. That is, the DMB receiver performs an FFT to convert the received time domain signal into a frequency domain signal. Accordingly, the demodulated phase reference symbols input through the input terminal IN refer to phase reference symbols included in a signal in a frequency domain that is a result of fast Fourier transform (FFT) at the DMB receiver. The phase reference symbol z _{1, k} may be expressed as Equation 1 below.

Φ in Equation 1 may be expressed as Equation 2 below.

3 are tables illustrating a relationship between an indicator and a parameter of a phase reference symbol.

In the above Equations 1 and 2, an example of the parameters of the k, k, i, n and the h parameter is shown in FIG.

4 is a graph showing a phase reference symbol, where the horizontal axis represents the index and the vertical axis represents the power, respectively.

The terrestrial DMB transmission system may have, for example, '1536' secondary transmission channels except for a direct current (DC) component. Therefore, the sub transmission frequency number (or indicator) may vary from '-768' to '768' as shown in FIG. Since the phase reference symbol determines the starting phase of every transmission frame, the power of all sub transmission channels is one of the phases of 0 °, 90 °, 180 ° and 270 ° instead of the same.

5 is a graph showing a phase reference symbol with an integer frequency offset, where the horizontal axis represents the indicator and the vertical axis represents the power, respectively.

When accurately positioning the frequency of the phase reference symbol in the DMB receiver, the phase reference symbol may have, for example, '-2' as an integer frequency offset as shown in FIG. 5. That is, the actual receiving sub transmission channel in a solid line has an integer frequency offset of '-2' and a small fractional frequency offset as compared to the exact virtual sub transmission channel shown in dashed line in FIG. 5.

The address generator 16 shown in FIG. 1 generates an address (hereinafter referred to as a 'write address') for writing PRSs into the first through Nth storage parts 10, 12, ..., and 14, and The first to Nth storage units 10, 12, ... and 14 serve to generate addresses for reading PRSs (hereinafter, referred to as read addresses). The first, second, ..., and Nth storage units 10, 12, ..., and 14 correspond to the write address inputted from the address generator 16 to the demodulated PRSs input through the input terminal IN. The PRSs are stored in the position of the stored PRSs, and the PRSs stored in the positions corresponding to the read addresses input from the address generator 16 are read.

According to the present invention, the first to Nth storage units 10, 12, ..., and 14 are distinguished by the lower n (where n = log ₂ N) bits of the address generated from the address generator 16. Can be. For example, when N = 4, n = 2. In this case, the first, second, third and fourth storage units may be distinguished by, for example, the lower two bits of each of the write and read addresses generated from the address generator 16, as shown in Table 1 below. .

Write or read address Type of storage "----------- 00" First storage "----------- 01" Secondary storage "----------- 10" Third storage "----------- 11" 4th storage

The address generator 16 according to the present invention needs N addresses for each of the N storage units. However, when the storage units are divided using the lower bits in the address as shown in Table 1, the address generator 16 may generate only one address corresponding to the Xn upper bits to access all N storage units. . Where X is log ₂ x and x is the number of points described above. For example, when n = 2 and the number of points is 2048, that is, the address generated from the address generator 16 is 11 (X = 11) bits, the address generator 16 corresponds to the upper 9 bits. Only one address may be generated to access all N storage units.

After step 60, the buffers 18 temporarily store the N PRSs read from the first to Nth storage units 10, 12, ..., and 14, and store the temporarily stored results in a correlation calculation unit ( 22) (step 62).

After operation 62, the PRS generator 20 generates the PRSs by itself and outputs the generated PRSs to the correlation calculator 22 as reference PRSs (step 64).

After the 64 th step, the correlation calculation unit 22 outputs the 2N PRSs and the PRS generation unit 20 outputted from the first to Nth storage units 10, 12,..., And 14 and the buffers 18. Sample correlations between the N reference PRSs output from the N-PRSs are calculated, and the calculated sample correlations are output to the integer frequency offset output unit 24 (step 66).

According to another embodiment of the present invention, unlike FIG. 1, the integer frequency offset estimation apparatus according to the present invention may not provide the buffers 18. In this case, the integer frequency offset estimation method shown in FIG. 2 does not provide a sixty-second step. At this time, after the 64th step, the correlation calculator 22 outputs the N PRSs read from the first to Nth storage units 10, 12,..., And 14 and the PRS generator 20. Sample correlations between the N reference PRSs are calculated, and the calculated sample correlations are output to the integer frequency offset output unit 24 (step 66).

According to the present invention, the correlation calculation unit 22 described above may calculate sample correlations by a partial correlation method. For example, the correlation calculation unit 22 may calculate the overall correlation or may calculate the partial correlation, but may typically adopt the partial correlation calculation that is less affected by other offsets such as timing.

In addition, according to the present invention, the correlation calculation unit 22 is a period of the frequency index among the 2N PRSs output from the first to Nth storage units 10, 12,..., And 14 and the buffers 18. Sample correlations between the N selected PRSs and the N reference PRSs, which are otherwise selected, are calculated, and the calculated sample correlations are output to the integer frequency offset output unit 24.

Hereinafter, assuming that N = 2 and the terrestrial DMB transmission system has '1536' sub transmission channels excluding DC, the operation of the correlation calculation unit 22 shown in FIG. 1 will be described.

FIG. 6 is a diagram for describing an operation example of the correlation calculator 22 illustrated in FIG. 1. Four buffers (F / F: flip flops) corresponding to the buffers 18 illustrated in FIG. 80, 82, 84, and 86). Here, PRSs read from the first, second, third and fourth storage units 10, 12, ..., and 14 are input through the input terminals IN ₁ , IN ₂ , IN _3, and IN ₄ , The PRSs are output to the correlation calculator 22 through the output terminals OUT ₁ , OUT ₂ , OUT ₃ , OUT ₄ , OUT ₅ , OUT ₆ , OUT _7, and OUT ₈ .

In a section in which the sub transmission frequency indicator varies from '-768' to '-1', the correlation calculation unit 22 calculates four sample correlations C1, C2, C3 and C4 at a time. In addition, in a section in which the sub transmission frequency indicator varies from '1' to '768', the correlation calculation unit 22 calculates four sample correlations C2, C3, C4 and C5 at a time. As such, the difference in the frequency index by one sample is different because the index '0' corresponding to the DC is omitted.

After operation 66, the integer frequency offset output unit 24 adds N sample correlations input from the correlation calculation unit 22 to generate a final correlation value. For example, the 512 final correlation values generated as described above are generated. The maximum value is determined as an integer frequency offset from among them, and the determined integer frequency offset is output through the output terminal OUT (step 68).

The above-described integer frequency offset estimating apparatus according to the present invention has a rough frequency offset among a fine frequency offset estimator (not shown) and a coarse frequency offset estimator (not shown) included in a DMB receiver. Play the role of estimator.

After all, when the number of sub transmission channels is '1536' and the range of integer frequency offset is '512', the calculation cycle required by the integer frequency offset estimating apparatus and method according to the present invention is (1536/4) × (512). / 4) = 49152. Therefore, the integer frequency offset can be estimated quickly by 1/16 as compared with the conventional method. In addition, in the case of power consumption, unlike the conventional method of performing only one access of the memory in one cycle, the memory, for example, accesses the storage four times in one cycle, and the size of the storage is reduced by 1 / N as compared to the conventional method. Therefore, the power consumption of the memory itself becomes relatively small.

As described above, the apparatus and method for estimating the integer frequency offset of the DMB receiver according to the present invention divides and stores the PRS and performs the correlation calculation by N at the same time. Not only can it be estimated at high speed by 1 / N ² , but it also has the effect of reducing power consumption to 1 / N or less than conventional.

Claims (9)

In the integer frequency offset estimation apparatus, First to N-th storage units for dividing the demodulated phase reference symbols PRS into N (where N is a positive integer of 2 or more); An address generator for writing the PRSs to the first to Nth storage units and generating addresses for reading the PRSs from the first to Nth storage units; A PRS generator which generates the PRSs by itself and outputs them as reference PRSs; A correlation calculator for calculating sample correlations between the N PRSs and the N reference PRSs read from the first to Nth storage units; And And an integer frequency offset output unit for generating final correlation values by adding the sample correlations, and outputting a maximum value as an integer frequency offset among the generated final correlation values. The method of claim 1, wherein the correlation calculation unit And the sample correlations are calculated by partial correlation. The apparatus of claim 1, wherein the integer frequency offset estimating apparatus And buffers for temporarily storing the N PRSs read from the first to Nth storage units, And the correlation calculation unit calculates sample correlations between the 2N PRSs and the reference PRSs output from the first to Nth storage units and the buffers. 2. The apparatus of claim 1, wherein the demodulated phase reference symbols are fast Fourier transformed results. The method of claim 3, wherein the correlation calculation unit Computing the sample correlations between the N PRSs and the reference PRSs, which are differently selected according to the interval of the frequency index among the 2N PRSs output from the first to Nth storage units and the buffers. Integer frequency offset estimation device. The integer frequency offset estimating apparatus according to claim 1, wherein N = 2. The integer frequency offset of claim 1, wherein the first to Nth storage parts are distinguished by lower n bits (where n = log ₂ N) bits of the address generated from the address generator. Estimation device. In the integer frequency offset estimation method, Dividing and storing the demodulated phase reference symbols PRS into N (where N is a positive integer of 2 or more); Generating the PRSs by itself; Obtaining sample correlations between the stored N PRSs and the self-generated N PRSs; And Adding the sample correlations to produce final correlation values, and determining a maximum value among the generated final correlation values as an integer frequency offset. The method of claim 8, wherein the integer frequency offset estimation method Temporarily storing the stored N PRSs, And the sample correlations between the partitioned and stored PRSs and the temporarily stored PRSs and the self-generated PRSs are obtained.

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