JP3945623B2 - Frequency synchronization method and OFDM receiver using the same - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a frequency synchronization method and an OFDM receiver using the same, and more particularly to a frequency synchronization method and a receiver effective in an orthogonal frequency division multiplexing (OFDM) system.
[0002]
[Prior art]
The OFDM transmission system is a digital modulation system that uses a large number of carrier waves orthogonal to each other, and has features such as being less susceptible to interference with other services, less susceptible to interference, and having relatively good frequency utilization efficiency. Signal distortion is large and high-accuracy frequency synchronization is required. Conventional frequency synchronization techniques for OFDM are described in, for example, the literature “A Fast Synchronization Scheme of OFDM Signals for High-Rate Wireless LAN” T. Onizawa et.al, IEICE TRANS. COMMUN. VOL.E82-B. Has been.
[0003]
Hereinafter, a conventional frequency synchronization method will be described. FIG. 5 shows a transmission packet format for performing frequency synchronization using this frequency synchronization method. The transmission packet 10 includes a preamble 101 and data 102, and frequency synchronization is performed by estimating a frequency offset using the preamble 101 and correcting the frequency. The configuration of the preamble 101 is shown in FIG. The preamble 101 is composed of the same fixed signal series 20, 21, 22, 23, 24, 25, 26, 27, 28 and 29 having a length of 16 samples.
[0004]
Next, a conventional frequency synchronization method will be described with reference to FIG. In FIG. 3, s (n) is a received OFDM signal, and Re (s (n)) and Im (s (n)) represent the real part and imaginary part of s (n), respectively. Out (n) represents a signal after frequency correction. Here, n represents a discrete time on the receiving side where the sampling period is T. The error signal generator 30 calculates an error signal E (n) corresponding to the frequency offset amount from the received signal s (n) of the preamble 101. Next, the error signal conversion unit 31 estimates the frequency offset estimated value Δf from the error signal E (n). _EST Ask for. In the sine wave generator 32, Δf _EST A complex sine wave c (n) that oscillates at a frequency of is output. The c (n) and the input signal s (n) are multiplied by the complex multiplier 33 to obtain out (n) corrected for frequency offset.
[0005]
The configuration of the error signal generation unit 30 is shown in FIG. In the error signal generation unit 30, the delay unit 301 delays the input signal by 64 samples to obtain a delay signal s (n−64). For this s (n-64), a complex conjugate s (n-64) is obtained at the complex conjugate section 302. ^* The complex multiplication unit 303 calculates the input signal s (n) and the s (n−64) output from the complex conjugate unit 302. ^* To obtain the product S (n). Since the received preamble is a repetitive signal with a 64-sample period, s (n) and s (n−64) are the same except for noise components and S (n) is a real number in the absence of a frequency offset. However, in a state where there is a frequency offset Δf, s (n−64) becomes as shown in Expression (1), and a phase difference occurs between s (n) and s (n−64).
[0006]
s (n−64) = s (n) exp (j2π · 64TΔf) (1)
For this reason, S (n) has a phase component as shown in Equation (2).
S (n) = | S (n) | ² exp (j2π · 64TΔf) (2)
[0007]
The accumulating unit 304 accumulates S (n) obtained by the above method over 64 samples to obtain a correlation value ΣS (n). The dividing unit 305 obtains an error signal E (n) for the output ΣS (n) of the accumulating unit 304 using Equation (3).
E (n9 = Im (ΣS (n)) / Re (ΣS (n)) (3)
The error signal E (n) output from the division unit 305 can be correlated as shown in equations (4) and (5).
E (n) = tan (Δθ _EST (4)
Δθ _EST = 2π · 64TΔf _EST ... (5)
[0008]
Δθ _EST Is the phase shift between s (n) and s (n−64) estimated from the received preamble 101, and Δf _EST Is the frequency offset estimate. Therefore, the frequency offset estimated value Δf is obtained by performing the calculation of Expression (6) from the error signal E (n). _EST Is obtained. The error signal conversion unit 31 in FIG. 3 performs the calculation of Expression (6).
Δf _EST = Tan ^-1 (E (n)) / (2π · 64T) (6)
The above is the description of the conventional frequency synchronization method.
[0009]
[Problems to be solved by the invention]
The conventional frequency synchronization method performs frequency synchronization using a known signal sequence that is repeatedly transmitted as described above, and the error signal has a frequency offset value as shown in equations (4) and (5). Calculated as a tangent. Δθ represented by the phase component of the error signal from the periodicity of the tangent function _EST The range of values that can take is: −π / 2 ≦ Δθ _EST It is limited to ≦ π / 2. Therefore, from Equation (5), the range of frequency offset values that can be estimated is represented by Equation (7).
-1 / (256 · T) ≦ Δf ≦ 1 / (256 · T) (7)
[0010]
That is, the synchronization pull-in frequency range is limited to ± 1 / (256 · T), and there is a first problem that frequency synchronization becomes impossible when there is a frequency offset greater than this. For example, when the sampling frequency is 1 / T = 20 MHz, the synchronous pull-in frequency range is ± 78.5 KHz.
[0011]
In addition, if the frequency offset has a value near the limit of the synchronous pull-in frequency range, _EST Is a value close to π / 2. At this time, the absolute value of the real component Re (ΣS (n)) in the input ΣS (n) of the division unit 305 is very small. For this reason, the sign of the real component is easily inverted by the transmission line noise, and the obtained Δf _EST This also causes a second problem that the estimation error of the frequency offset becomes large.
[0012]
SUMMARY OF THE INVENTION An object of the present invention is to solve the above-described problems, to provide a frequency synchronization method capable of realizing a wide frequency synchronization pull-in range and suppressing a frequency offset estimation error, and a receiving apparatus using the same. . The above and other objects and novel features of the present invention will be apparent from the description of this specification and the accompanying drawings.
[0013]
[Means for Solving the Problems]
The outline of a typical invention among the inventions disclosed in the present application will be briefly described as follows. That is, a plurality of correlation value calculation units having different delay amounts, an error signal obtained from the correlation value obtained from each correlation value calculation unit, and an error signal used for frequency synchronization by comparing the size of a set determination threshold Select. By detecting a quadrant on the complex plane to which the plurality of correlation values belong, a correlation value to be used for frequency offset estimation is selected, and a frequency offset estimation value is selected from the selected correlation value and the quadrant on the complex plane to which the correlation value belongs. Ask for. In each of the error signal generation units described above, a plurality of correlation values having the same delay amount are calculated and averaged to obtain an error signal. In each of the error signal generation units, the absolute value of the input of the real number component is obtained before the division, and the imaginary number component is divided using this absolute value.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Exemplary embodiments of a frequency synchronization method and a receiving apparatus using the same according to the present invention will be explained below in detail with reference to the accompanying drawings.
[0015]
(Embodiment 1) FIG. 1 shows a configuration example of a frequency offset estimation unit according to the present invention. The frequency offset estimator receives the received signal s (n), and receives signals s (n-64), s (n-32), and s (n−) delayed by 64 samples, 32 samples, and 16 samples, respectively. 16) and correlation value calculation units 51, 52, and 53 for obtaining a correlation value between s (n) and correlation values ΣS (n) 64 and ΣS (n) 32 output from the correlation value calculation units 51, 52, and 53. , ΣS (n) 16 are input to obtain error signals E (n) 64, E (n) 32, E (n) 16 for these correlation values, so that the frequency offset estimation error is minimized. An error signal E (n) used for estimation is selected from among (n) 64, E (n) 32, and E (n) 16, and further, Δθ is obtained from this E (n). _EST Δθ _EST To the frequency offset estimate Δf _EST It is comprised from the determination / calculating part 54 which calculates and outputs.
[0016]
In FIG. 1, in the correlation value calculation units 51, 52, and 53, delay signals s (n-64), s (n-32), and s (n-16) whose delay amounts are 64 samples, 32 samples, and 16 samples, respectively. ) And the received signal s (n) are calculated as ΣS (n) 64, ΣS (n) 32, and ΣS (n) 16. These calculation results are input to the determination / calculation unit 54, which determines the error signal E corresponding to three types of correlation values ΣS (n) 64, ΣS (n) 32, and ΣS (n) 16. (N) 64, E (n) 32, E (n) 16 are obtained, and an error signal used for final frequency offset estimation is obtained from E (n) 64, E (n) 32, E (n) 16. Select and phase shift Δθ from the selected error signal _EST , And according to the selected error signal, the frequency offset estimate Δf using equation (8) _EST Is output. Here, N is the value of the number of delay samples corresponding to the selected correlation value, and takes a value of 16, 32, or 64 in this embodiment.
[0017]
Δf _EST = Δθ _EST / 2πTN (8)
The configuration of the correlation value calculation units 51, 52 and 53 is shown in FIG. The correlation value calculation unit 51 delays the received signal s (n) by 64 samples and outputs s (n-64), and a complex conjugate s (n-64) of s (n-64). ^* Complex conjugate part 512 for obtaining s (n) and s (n-64) ^* The complex multiplication unit 513 that obtains the product S (n) 64 by performing the complex multiplication and the accumulation unit 514 that accumulates S (n) 64 over 64 samples and outputs the correlation value ΣS (n) 64.
[0018]
In addition, the correlation value calculation unit 52 delays the received signal s (n) by 32 samples and outputs s (n−32), and a complex conjugate s (n−32) of s (n−32). ^* And s (n) and s (n-32). ^* The complex multiplier 523 that obtains the product S (n) 32 by performing the complex multiplication and the integrator 524 that accumulates S (n) 32 over 32 samples and outputs the correlation value ΣS (n) 32.
[0019]
Further, the correlation value calculation unit 53 delays the received signal s (n) by 16 samples and outputs s (n-16), and a complex conjugate s (n-16) of s (n-16). ^* Complex conjugate part 532 for obtaining s (n) and s (n-16) ^* The complex multiplication section 533 that obtains the product S (n) 16 by performing complex multiplication of the above and the accumulation section 534 that accumulates S (n) 16 over 16 samples and outputs the correlation value ΣS (n) 16.
[0020]
The operation of these correlation value calculation units will be described using the correlation value calculation unit 52 as an example. In the delay unit 521, the input signal s (n) is delayed by 32 samples to obtain s (n−32). S (n-32) complex conjugate s (n-32) in the complex conjugate section 522 ^* S (n) and s (n−32) in the complex multiplier 523 ^* To obtain a product S (n) 32. The accumulating unit 524 accumulates the S (n) 32 over 32 samples to obtain a correlation value ΣS (n) 32. The correlation value calculation units 51 and 53 perform the same operation except that the delay amount and the integrated sample number are 64 samples and 16 samples, respectively.
[0021]
Next, the configuration of the determination / calculation unit 54 in FIG. 1 will be described with reference to FIG. The determination / calculation unit 54 divides the imaginary part by the real part for phase detection for each of the three input correlation values, ΣS (n) 64, ΣS (n) 32, and ΣS (n) 16. From the error signals output from the division units 541, 542, 543 that output the error signals E (n) 64, E (n) 32, E (n) 16 and the division units 541, 542, 543, respectively, An error signal selection unit 544 that selects an error signal used for frequency offset estimation and outputs the error signal as E (n), and performs arctangent calculation on E (n). _EST Arc tangent calculation unit 545 for obtaining and outputting _EST And N, the frequency offset estimate Δf using equation (8) _EST It is comprised from the calculating part 546 which calculates. Note that N is supplied to the calculation unit 546 by the error signal selection unit 544.
[0022]
In order to obtain the phase component of the correlation value, the imaginary part of the correlation value is divided by the real part. This division is performed on the obtained three types of correlation values ΣS (n) 64, ΣS (n) 32, and ΣS (n) 16 using division units 541, 542, and 543, respectively, and an error signal E for each delay amount is obtained. (N) 64, E (n) 32, E (n) 16 are output. The error signal selection unit 544 inputs three types of error signals E (n) 64, E (n) 32, and E (n) 16, selects the one with the best frequency offset estimation accuracy, and selects E ( n) is output to the arctangent calculation unit 545.
[0023]
Δθ _EST To the estimated frequency offset Δf _EST In this case, the number N of delayed samples for the selected error signal is output to the calculation unit 546. E (n) obtained in this way is input to the arc tangent calculation unit 545, and the arc tangent calculation unit 545 calculates the equation (9) for E (n) output from the error signal selection unit 544. And Δθ _EST Is output to the calculation unit 546.
Δθ _EST = tan ^-1 (E (n)) (9)
[0024]
In the calculation unit 546, Δθ input from the arctangent calculation unit 545 _EST And the number of delay samples N input from the error signal selection unit 544, the calculation of Expression (8) is performed, and Δf _EST Ask for.
[0025]
Next, an error signal selection algorithm of the error signal selection unit 544 will be described. Since E (n) is expressed by Equation (3) and Equation (4), Δθ _EST Is -π / 2 ≦ Δθ _EST In the range of ≦ + π / 2, the value of E (n) increases as the frequency offset increases. Further, from the expressions (4), (5), and (6), when the delay amount is reduced, the pull-in frequency range is expanded. On the other hand, when the delay amount is increased, the noise component is suppressed, and the estimation accuracy within the pull-in frequency range is improved. Using these properties, the magnitudes of the values of E (n) 16 and E (n) 32 are observed, and Δθ _EST The error signal E (n) used for determining is selected.
[0026]
An error signal selection algorithm is shown in FIG. First, a determination threshold value is set, and a magnitude comparison with the absolute value of E (n) 16 is performed in processing block 81. If the absolute value of E (n) 16 is larger than the determination threshold, it is determined that the frequency offset is not within the drawing frequency range estimated by E (n) 32, and E (n) 16 having the widest drawing frequency range is selected. To estimate (processing block 85). If the determination threshold is greater than or equal to E (n) 16, then the processing block 82 compares the absolute value of E (n) 32 with the determination threshold.
[0027]
Here, when the absolute value of E (n) 32 is larger than the determination threshold, it is determined that the frequency offset is not within the pull-in frequency range estimated by E (n) 64, and the second pull-in range An estimation is performed using the wide E (n) 32 (processing block 84). If the determination threshold is greater than or equal to E (n) 32 in the processing block 82, it is determined that the frequency offset is within the pull-in frequency range estimated by E (n) 64, and the estimation accuracy is the best. An estimation is performed using E (n) 64 as follows (processing block 83).
[0028]
(Embodiment 2) Another embodiment of the correlation value calculation unit according to the frequency synchronization method of the present invention will be described. The correlation value calculation unit 52 may be configured as shown in FIG. In addition to the delay unit 521, the complex conjugate unit 522, the complex multiplication unit 523, and the integration unit 524 of the above-described FIG. 6, the correlation value calculation unit shown in FIG. n-64) outputs a delay of 32 samples to the delay unit 525, s (n-64), and outputs a complex conjugate of s (n-96). S (n-96) ^* , S (n-64) and s (n-96) ^* Complex multiplication unit 528 that outputs a product S (n) 32 ″, integrates S (n) 32 ″ over 32 samples, and outputs a correlation value ΣS (n) 32 ″ Unit 529 and correlation value ΣS (n) 32 ′, which is the output of integrating unit 524, and correlation value ΣS (n) 32 ″, which is the output of integrating unit 529, are averaged to obtain correlation value ΣS ( n) It is composed of an averaging unit 520 that outputs 32.
[0029]
In the correlation value calculation unit shown in FIG. 9, the operation of the correlation value calculation unit 52 shown in FIG. 6 is performed not only on the reception signal s (n) but also on the signal s () obtained by delaying the reception signal by 64 samples. n-64), and the averaging unit 520 adds the obtained two correlation values and divides by a constant 2 to average the correlation values, thereby reducing the influence of transmission line noise and estimating. Accuracy can be improved. However, for the output ΣS (n) 32 of the correlation value calculation unit 52, since the imaginary part is divided by the real part in the determination / calculation unit 54 in FIG. ) 32 ′ and ΣS (n) 32 ″ are simply added, which is equivalent to averaging. An explanatory diagram of this processing is shown in FIG.
[0030]
Correlation value ΣS () of the 32-sample signal sequence S1 (n) composed of fixed signal sequences 20 and 21 in FIG. 2 and the 32-sample signal sequence S2 (n) composed of fixed signal sequences 22 and 23 in FIG. n) 32 'is obtained in the processing block 71, and further, a 32-sample signal sequence S3 (n) comprising the fixed signal sequences 24 and 25 in FIG. 2 and 32 samples comprising the fixed signal sequences 26 and 27 in FIG. The correlation value ΣS (n) 32 ″ with the signal sequence S4 (n) is obtained in the processing block 72. In a processing block 73, ΣS (n) 32 ′ and ΣS (n) 32 ″ are averaged (only addition may be performed) to obtain a correlation value ΣS (n) 32 used for frequency offset estimation. The above is the second embodiment according to the present invention.
[0031]
(Embodiment 3) Another embodiment of the determination / calculation unit according to the frequency synchronization method of the present invention will be described with reference to FIG. 10, the operations of the arctangent calculation unit 545 and the calculation unit 546 are the same as those shown in FIG.
[0032]
In FIG. 10, the determination / calculation unit 54 includes the arctangent calculation unit 545, the calculation unit 546, a correlation value selection unit 547 that selects a correlation value used for frequency offset estimation, and the correlation selected by the correlation value selection unit 547. A division unit 548 that divides the imaginary part of the value by the real part is configured.
[0033]
Furthermore, the configuration of the correlation value selection unit 547 is shown in FIG. The correlation value selection unit 547 multiplies the input real number part Re (ΣS (n)) 32 of ΣS (n) 32 and the real number part Re (ΣS (n)) 16 of ΣS (n) 16 by a determination threshold. , Products Re (ΣS (n)) 32TH and Re (ΣS (n)) 16TH, which respectively output multipliers 801 and 802, Im (ΣS (n)) 32Im (ΣS (n)) 16, and Re (ΣS (N)) 32TH and Re (ΣS (n)) 16TH are input, and any of ΣS (n) 64, ΣS (n) 32, and ΣS (n) 16 is used for frequency offset estimation. It is comprised from the determination part 803 which determines N.
[0034]
Next, a determination algorithm in the determination unit 803 will be described with reference to FIG. First, in processing block 804, the absolute value of Im (ΣS (n)) 16 and the absolute value of Re (ΣS (n)) 16TH are compared. If the absolute value of Im (ΣS (n)) 16 is greater than the absolute value of Re (ΣS (n)) 16TH, the frequency offset must be within the pull-in frequency range estimated by ΣS (n) 32. Judgment is made and estimation is performed using ΣS (n) 16 having the widest pull-in frequency range (processing block 808).
[0035]
If the absolute value of Re (ΣS (n)) 16TH is greater than or equal to the absolute value of Im (ΣS (n)) 16, then at processing block 805, Im (ΣS (n)) The absolute value of 32 and the absolute value of Re (ΣS (n)) 32TH are compared in magnitude. When the absolute value of Im (ΣS (n)) 32 is larger than the absolute value of Re (ΣS (n)) 32TH, the frequency offset is not within the pull-in frequency range when estimated by ΣS (n) 64. And estimation is performed using ΣS (n) 32 having the second widest frequency range (processing block 807).
[0036]
When the absolute value of Re (ΣS (n)) 32TH is greater than or equal to the absolute value of Im (ΣS (n)) 32, the frequency offset is within the pull-in frequency range when estimated by ΣS (n) 64. And estimation is performed using ΣS (n) 64 that provides the best estimation accuracy (processing block 806). In this process, the real value part of the correlation value is multiplied by the determination threshold value and compared with the imaginary part of the correlation value. The imaginary part of the correlation value is divided by the real value part of the correlation value, Equivalent to comparing size. The above is the third embodiment according to the present invention.
[0037]
(Embodiment 4) Another embodiment of the determination / calculation unit according to the frequency synchronization method of the present invention will be described with reference to FIG. In the configuration of FIG. 13, the determination / calculation unit 54 includes a correlation value selection unit 549 that determines a correlation value used for frequency offset estimation, and an imaginary part Im (ΣS (n)) of the selected correlation value as a real part Re ( A division unit 548 that obtains an error signal E (n) by dividing by ΣS (n)), and performs arctangent operation on the obtained error signal E (n) to obtain Δθ _EST Arc tangent computing unit 545 for obtaining Δθ _EST And the frequency offset Δf from the quadrant information described below and N _EST It is comprised from the phase frequency conversion part 540 which calculates. Here, the operation of the division unit 548 and the operation of the arctangent calculation unit 545 are the same as those shown in FIG.
[0038]
Hereinafter, the operation of the determination / calculation unit 54 shown in FIG. 13 will be described. First, the correlation values ΣS (n964, ΣS (n) 32, ΣS (n) 16) obtained by the correlation value calculators 51, 52, and 53 are input to the correlation value selector 549. The correlation value selector 549. Then, the correlation value used for estimation is selected from the three types of correlation values input, and is output to the division unit 548. Further, the quadrant on the complex plane to which the selected correlation value belongs is determined, and quadrant information is obtained. The output is output to the phase frequency converter 540. Further, the selected correlation value is any of 64, 32, and 16 as N according to any of ΣS (n) 64, ΣS (n) 32, and ΣS (n) 16. Is output.
[0039]
In the phase frequency converter 540, Δθ obtained from the arctangent calculator 545 is obtained. _EST Δθ using the delay amount N obtained from the correlation value selection unit 549 and the quadrant information obtained from the correlation value selection unit 549 _EST To Δf _EST Is calculated and output.
[0040]
A correlation value selection algorithm used for estimation in the correlation value selection unit 549 will be described with reference to FIG. First, the processing block 111 determines whether Re (ΣS (n)) 16 is positive or negative. If it is negative, estimate using ΣS (n) 16 (processing block 115). If the value is positive or 0, processing block 112 determines whether Re (ΣS (n)) 32 is positive or negative. If Re (ΣS (n)) 32 is negative, it is estimated using ΣS (n) 32 (processing block 114). When Re (ΣS (n)) 32 is positive or 0, estimation is performed using ΣS (n) 64 (processing block 113).
[0041]
Further, a quadrant information determination method in the correlation value selection unit 549 will be described with reference to FIGS. 15, 16, and 17. Here, FIG. 15 shows a method for estimation using ΣS (n) 64, FIG. 16 shows a method for estimation using ΣS (n) 32, and FIG. 17 shows an estimation using ΣS (n) 16. Is the way.
[0042]
For example, when estimation is performed using ΣS (n) 64, quadrant information is obtained from the sign of Re (ΣS (n)) 64 and Im (ΣS (n)) 64. When Im (ΣS (n)) 64 is positive or 0, Δθ obtained from ΣS (n) 64 _EST The range (hereinafter referred to as Δθ64) is 0 ≦ Δθ64 ≦ π. At this time, the quadrant on the complex plane to which ΣS (n) 64 belongs is the first quadrant or the second quadrant.
[0043]
When Im (ΣS (n)) 64 is negative, the range of Δθ64 is −π <Δθ64 <0, and the quadrant on the complex plane to which ΣS (n) 64 belongs is the third quadrant or the fourth quadrant. . When Re (ΣS (n)) 64 is positive or 0, the range of Δθ64 is −π / 2 ≦ Δθ64 ≦ π / 2. At this time, the quadrant on the complex plane to which ΣS (n) 64 belongs is It becomes the first quadrant or the fourth quadrant.
[0044]
On the other hand, when Re (ΣS (n)) 64 is negative, the range of Δθ64 is −π <Δθ64 <−π / 2 or π / 2 <Δθ64 <π, and at this time, the complex to which ΣS (n) 64 belongs. The quadrant on the plane is the second quadrant or the third quadrant. From the above, as shown in FIG. 15, when Re (ΣS (n)) 64 is positive or 0, if Im (ΣS (n)) 64 is positive or 0, the first quadrant Im (ΣS ( n)) fourth quadrant if 64 is negative, second quadrant if Re (ΣS (n)) 64 is positive or 0, if Re (ΣS (n)) 64 is negative, Im (ΣS (n) ) If 64 is negative, it can be determined as the third quadrant.
[0045]
When estimation is performed using ΣS (n) 32, quadrant information is obtained from the positive / negative of Re (ΣS (n)) 32 and Im (ΣS (n)) 32, as shown in FIG. 16. That is, if Re (ΣS (n)) 32 is positive or 0, the first quadrant if Im (ΣS (n)) 32 is positive or 0, and the first if Im (ΣS (n)) 32 is negative. Judged as 4 quadrants. Also, when Re (ΣS (n)) 32 is negative, the second quadrant if Im (ΣS (n)) 32 is positive or 0, and the third quadrant if Im (ΣS (n)) 32 is negative. Is determined.
[0046]
Further, when estimation is performed using ΣS (n) 16, quadrant information is obtained from the positive / negative of Re (ΣS (n)) 16 and Im (ΣS (n)) 16 as shown in FIG. 17. That is, when Re (ΣS (n)) 16 is positive or 0, the first quadrant is obtained if Im (ΣS (n)) 16 is positive or 0, and the first is obtained if Im (ΣS (n)) 16 is negative. Judged as 4 quadrants. Further, when Re (ΣS (n)) 16 is negative, the second quadrant if Im (ΣS (n)) 16 is positive or 0, and the third quadrant if Im (ΣS (n)) 16 is negative. Is determined.
[0047]
Next, the operation of the phase frequency conversion unit 540 will be described. First, from the quadrant information obtained from the correlation value selection unit 549, the quadrant on the complex plane to which the selected correlation value belongs is determined. If the selected correlation value is in the fourth or first quadrant on the complex plane, ie Δθ _EST Is -π / 2 ≦ Δθ _EST When it is in the range of ≦ π / 2, Δf is calculated by the method described so far, that is, by the calculation of Equation 8. _EST Is required. Δθ _EST Is not within the above range, that is, when the selected correlation value is in the second quadrant or the third quadrant on the complex plane, the offset value is added and Δf _EST And The above is the fourth embodiment according to the present invention.
[0048]
(Embodiment 5) Another embodiment of the division unit according to the frequency synchronization method of the present invention will be described with reference to FIG. In FIG. 18, the division unit 548 includes an absolute value calculation unit 901 for obtaining an absolute value | Re (ΣS (n)) | of Re (ΣS (n)), and Im (ΣS (n)) as an absolute value calculation unit. The division unit 902 obtains an error signal E (n) by dividing by the output | Re (ΣS (n)) |.
[0049]
Δθ by the method of Examples 1 to 3 _EST In an ideal state, Δθ _EST The range that can be taken is −π / 2 ≦ Δθ _EST Since it is limited to ≦ π / 2, the real part of the correlation value ΣS (n) is always positive or 0 except for the transmission line noise component. However, since a noise component is added to the actual received signal, it may be a negative value if the value of the real part of the correlation value is small.
[0050]
This will be described with reference to FIG. 19, taking the division unit 548 as an example. For example, when the correlation value ΣS (n) is the point 91 in FIG. 19, due to the influence of noise, the obtained correlation value is actually the point 92, and the real part Re (ΣS (n)) is a negative value. May be taken. However, Δθ _EST The range that can be taken is −π / 2 ≦ Δθ _EST Since ≦ π / 2, as a result of dividing Im (ΣS (n9) by Re (ΣS (n)), the correlation value used for frequency offset estimation is point 93. At this time, the frequency offset estimation value is Compared with the true frequency offset, the sign itself is inverted, and the estimation error becomes very large.
[0051]
In order to reduce this influence, the dividing unit 548 is configured as shown in FIG. 18 according to the present embodiment, and Im (ΣS (n)) is divided by the absolute value | Re (ΣS (n)) | By obtaining the error signal E (n), the sign inversion of E (n) by the sign inversion of Re (ΣS (n)), that is, Δf _EST Sign inversion can be prevented, and deterioration in estimation accuracy can be suppressed. This configuration can also be applied to the other division units 541, 542, and 543. The above is the fifth embodiment according to the present invention.
[0052]
(Embodiment 6) The configuration of an OFDM receiver using the frequency synchronization method according to the present invention will be described. FIG. 20 is a block diagram of an OFDM signal receiving apparatus. An RF unit 61 that converts the frequency of the received signal input from the antenna 60, and an A / D that samples the analog signal and converts it to a digital signal s (n). A converter 62, a timing synchronization unit 63 for detecting the start timing of the received packet, and an estimated value Δf by estimating a frequency offset from s (n). _EST A frequency offset estimator 64 for outputting? _EST A frequency offset correction unit 65 that multiplies the received signal by a sine wave that vibrates at a frequency of 1 to correct the frequency offset, an FFT operation unit 66 that performs an FFT operation, and a Viterbi decoder 67 that performs error correction.
[0053]
The frequency synchronization unit 68 includes a frequency offset estimation unit 64 and a frequency offset correction unit 65. In the present embodiment, the frequency offset estimation method described in any one of 1 to 5 is applied to the frequency offset estimation unit 64.
[0054]
In FIG. 20, the received OFDM signal is input to the RF unit 61. The RF unit 61 converts the input received OFDM signal into an analog complex baseband signal using a local signal that is almost similar to a carrier wave. The A / D converter 62 samples and quantizes the analog complex baseband signal obtained by the RF unit 61, and outputs a digital received signal s (n).
[0055]
s (n) is input to the timing synchronization unit 63 and the frequency offset estimation unit 64. The timing synchronization unit 63 detects the start position of the preamble in the received signal, and determines the operation start timing of the frequency offset estimation unit 64 and the FFT operation unit 66. The frequency offset estimation unit 64 receives the signal s (n), estimates the frequency offset at the timing indicated by the timing detection unit 63, and estimates the value Δf _EST Is output.
[0056]
Further, in the frequency offset correction unit 65, Δf obtained by the frequency offset estimation unit 64 is obtained. _EST , A corresponding sine wave is generated and complex-multiplied with the received signal s (n) to correct the frequency offset. The FFT operation unit 66 performs an FFT operation on the frequency offset corrected signal, and the Viterbi decoder 67 performs error correction.
[0057]
The OFDM receiver of FIG. 20 can realize frequency synchronization with a wider frequency pull-in range than before or frequency estimation with a smaller frequency offset estimation error by using the frequency synchronization method according to the present invention. The demodulated signal can be obtained.
[0058]
In the first to fifth embodiments, the delay amount is set to three types of 64 samples, 32 samples, and 16 samples. However, the present invention is not limited to this. That is, generally, when the configuration of preamble 101 is R repetitions of the same fixed signal sequence having an L sample length, the delay amount can be L, 2L... (R / 2) L. The above is the sixth embodiment according to the present invention.
[0059]
【The invention's effect】
According to the present invention, a rough frequency offset is estimated, and if it is determined that the frequency offset is sufficiently small, the frequency offset is estimated using an error signal with a narrower synchronization pull-in frequency range (higher estimation accuracy). To do. Thereby, when the frequency offset is small, high-accuracy frequency synchronization can be established, and frequency synchronization when the frequency offset is large, that is, a wide frequency acquisition range can be realized.
[0060]
Furthermore, according to the present invention, the influence of the noise component in the frequency offset estimation can be suppressed by obtaining a plurality of correlation values and calculating the error signal of the frequency offset estimation using the average value. As a result, high-accuracy frequency synchronization can be established.
[0061]
Furthermore, according to the present invention, by performing division with the absolute value of the real part of the correlation value, it is possible to prevent the inversion of the sign of the error signal due to transmission line noise, so that the frequency offset is near the limit of the synchronous pull-in frequency range. Even in the case of having a value, it is possible to suppress degradation in estimation accuracy.
[0062]
Furthermore, according to the present invention, Δθ is obtained from the correlation value. _EST By detecting the quadrant to which the frequency offset belongs, the frequency offset estimation pull-in range can be expanded.
[Brief description of the drawings]
FIG. 1 is a block diagram of a frequency offset estimation unit according to the present invention.
FIG. 2 is a configuration diagram of a preamble according to the present invention.
FIG. 3 is a block diagram showing a configuration of a conventional frequency synchronization circuit.
FIG. 4 is a block diagram of an error signal generator in a conventional frequency synchronization circuit.
FIG. 5 is a configuration diagram of a packet transmitted in the OFDM system.
FIG. 6 is a block diagram of a correlation value calculation unit in a frequency offset estimation unit according to the present invention.
FIG. 7 is a block diagram of a frequency offset estimation unit according to the present invention.
FIG. 8 is a flowchart showing an error signal selection algorithm according to the present invention.
FIG. 9 is a block diagram of a correlation value calculation unit in a frequency offset estimation unit according to the present invention.
FIG. 10 is a block diagram of a determination / calculation unit in a frequency offset estimation unit according to the present invention.
FIG. 11 is a block diagram of a correlation value selection unit in a frequency offset estimation unit according to the present invention.
FIG. 12 is a flowchart showing a correlation value selection algorithm according to the present invention.
FIG. 13 is a block diagram of a determination / calculation unit in a frequency offset estimation unit according to the present invention.
FIG. 14 is a flowchart showing a correlation value selection algorithm according to the present invention.
FIG. 15 is an explanatory diagram showing a quadrant determination method to which a correlation value belongs according to the present invention.
FIG. 16 is an explanatory diagram showing a quadrant determination method to which a correlation value belongs according to the present invention.
FIG. 17 is an explanatory diagram showing a quadrant determination method to which a correlation value belongs according to the present invention.
FIG. 18 is a block diagram of a division unit in the frequency offset estimation circuit according to the present invention.
FIG. 19 is an explanatory diagram showing the influence of transmission line noise in correlation value calculation.
FIG. 20 is a block diagram of an embodiment of an OFDM signal receiving apparatus according to the present invention.
FIG. 21 is an explanatory diagram of correlation value calculation in a frequency offset estimation unit according to the present invention.
[Explanation of symbols]
51, 52, 53... Correlation value calculation unit, 54... Determination / calculation unit, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29... Fixed signal sequence in preamble, 30. Error signal generation unit 31... Error signal conversion unit 32... Sine wave generation unit 33... Complex multiplication unit 301... Delay unit 302. ... Integration unit, 305... Division unit, 10... Packet transmitted in OFDM system, 101... Preamble unit of packet transmitted in OFDM system, 102. 521, 531 ... delay unit, 512, 522, 532 ... complex conjugate unit, 513, 523, 533 ... complex multiplication unit, 514, 524, 534 ... integration , 541, 542, 543... Division unit, 544... Error signal selection unit, 545... Arc tangent calculation unit, 546. (N) Decision branch processing for 32, 83, 84, 85... Error signal determination result 525, 526... Delay unit, 527... Complex conjugate unit, 528. ... Averaging unit, 547... Correlation value selection unit, 548... Division unit, 801, 802... Multiplying unit, 803 ... Determination unit, 804. Decision branch processing for ΣS (n) 32, 806, 807, 808... Correlation value selection result, 549... Correlation value selection section, 540... Phase frequency conversion section, 111. 1 2... Decision branch processing for .SIGMA.S (n) 32, 113, 114, 115... Correlation value selection result, 901... Absolute value calculation unit, 902. , 92... Representing a correlation value obtained in a state affected by noise, 93... Representing a correlation value used for estimation when the real part becomes negative due to the influence of noise. …… Antenna, 61 …… RF unit, 62 …… A / D converter, 63 …… Timing synchronization unit, 64 …… Frequency offset estimation unit, 65 …… Frequency offset correction unit, 66 …… FFT operation unit, 67 ... Viterbi decoder, 68... Frequency synchronization unit, 71 and 72... Correlation value calculation processing block, and 73.

Claims (4)

The transmitting side transmits a preamble that repeats a fixed signal sequence a plurality of times, and the receiving side is applied to an OFDM transmission system that corrects a frequency offset based on the received signal of the preamble transmitted on the transmitting side for establishing frequency synchronization,
In the frequency synchronization method of obtaining a correlation value between a received signal and its delayed signal on the receiving side of the system, and using the phase component of the obtained correlation value as an error signal, and estimating the frequency offset from the error signal,
A plurality of correlation values having different delay amounts between the received signal of the preamble and the delayed signal are obtained, a plurality of error signals are calculated based on each of the plurality of correlation values, and the plurality of correlation values or the plurality of errors are calculated. Select the error signal to use for frequency offset estimation based on the signal, estimate the frequency offset ,
A correlation value for obtaining a frequency offset estimation value is selected from the plurality of correlation values by detecting which quadrant on the complex plane of at least one correlation value among the plurality of correlation values. and, frequency synchronization method of the this selected correlation value, wherein Rukoto calculated frequency offset estimate based on the value of said detected quadrant. In claim 1,
At least one of the error signals is a value obtained by dividing the imaginary part of the correlation value by the absolute value of the real part. In any one of Claims 1 thru | or 2 .
At least one of the error signals calculates a plurality of correlation values having the same delay amount between the received signal and the delayed signal, and is calculated based on an average value thereof. OFDM receiving apparatus characterized by including a circuit for correcting the frequency offset using the frequency synchronization method of claims 1 to 3.

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