CN101552622A - A method and device to estimate the frequency deviation in TD-CDMA access system - Google Patents
A method and device to estimate the frequency deviation in TD-CDMA access system Download PDFInfo
- Publication number
- CN101552622A CN101552622A CNA2009100797338A CN200910079733A CN101552622A CN 101552622 A CN101552622 A CN 101552622A CN A2009100797338 A CNA2009100797338 A CN A2009100797338A CN 200910079733 A CN200910079733 A CN 200910079733A CN 101552622 A CN101552622 A CN 101552622A
- Authority
- CN
- China
- Prior art keywords
- frequency offset
- frequency deviation
- estimation result
- offset estimation
- frequency
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
Links
Images
Landscapes
- Mobile Radio Communication Systems (AREA)
Abstract
The present invention provides a method ad device to estimate the frequency deviation in TD-CDMA access system and pertains to the technical field of wireless communication. This method includes: Step A: receive the data of the last 128 chips of Midamble code with frequency deviation, and calculate the first frequency deviation estimate result f<M> based on the data of the 128 chips and local basic Midamble code; Step B: Do frequency deviation compensation calculation of the data demodulated through joint detection and the first frequency deviation estimation result f<M> to get the result of frequency deviation compensation; Step C: Do frequency deviation estimate calculation of the result of frequency deviation compensation to get the second frequency deviation estimate result f<D>; Step D: Do cumulative calculation of f<M> and f<D> to get the third frequency deviation estimate result f<O>. In this way, it may realize large-range and high accuracy frequency deviation estimate in TD-SCDMA system to meet the needs of some special circumstances.
Description
Technical field
The invention belongs to wireless communication technology field, relate in particular to frequency deviation estimating method and device in a kind of TD-SCDMA (TimeDivision-Synchronous Code Division Multiple Access, TD SDMA inserts) system.
Background technology
At present, most communication system (for example TD-SCDMA system) all is to adopt the method for coherent detection to carry out data demodulates, promptly require receiver be used for receiving wireless signal frequency should and the carrier frequency of wireless signal is in full accord or between the two error very little.Therefore, in order to guarantee that receiving function accurately follows the tracks of carrier frequency, the frequency offset estimating of receiver is just important, because have only the frequency departure that estimates the two exactly in time to correct to reach the purpose of accurate tracking.
A kind of frequency offset estimating algorithm comparatively commonly used is to utilize the demodulating data after joint-detection to carry out frequency offset estimating in the TD-SCDMA system, yet the number of the data symbol of the employed close Midamble sign indicating number (training sequence) of this frequency offset estimating algorithm is few more, frequency offset estimation range is big more, and the precision of frequency offset estimating is poor more; Otherwise the number of used data symbol is many more, and frequency offset estimation range is more little, but the precision of frequency offset estimating is high more.Emulation shows that the number of desired data symbol is no less than 4 when using the method to carry out frequency offset estimating.When SF (spreading factor)=16, this moment Midamble both sides the number N=704/16=44 of data symbol, if when only using 4 the data symbols in Midamble sign indicating number both sides, frequency offset estimating can reach 1176Hz; If when using all 22 data symbols of Midamble sign indicating number both sides, frequency offset estimating has only about 300Hz, but the former frequency offset estimating error will be much larger than the latter.As shown in Figure 1; position view for 4 the data symbols in Midamble sign indicating number both sides in the TD-SCDMA system; a time slot is made up of 2 data parts (Data), 1 training sequence (Midamble sign indicating number) and 1 protection time slot (GP) in the TD-SCDMA system, and data division (Data) is distributed in the both sides of training sequence symmetrically.
In realizing process of the present invention, find that there are the following problems at least in the prior art: in most cases, stable in order to follow the tracks of, use all 22 data symbols of Midamble sign indicating number both sides to carry out frequency offset tracking usually, promptly sacrifice frequency offset estimation range and exchange frequency offset estimation accuracy for.This moment, the frequency offset estimation range of 300Hz can satisfy the demands, but in some special scene, high-speed mobile scene for example, the frequency offset estimation range of 300Hz is just much of that far from.When translational speed reached 430km/h, Doppler frequency shift just can reach 800Hz, and if the sub-district takes place at this moment switches, frequency deviation can reach 1600Hz at most.At this moment, also be not enough even use minimum data symbol to calculate its data area of frequency deviation.
Summary of the invention
In order to address the above problem, the purpose of this invention is to provide frequency deviation estimating method and device in a kind of TD-SCDMA system, thereby can be implemented in the TD-SCDMA system on a large scale, high-precision frequency offset estimating, satisfied the needs of some special screne.
In order to achieve the above object, the invention provides the frequency deviation estimating method in a kind of TD-CDMA access system, described method comprises:
Steps A, reception have back 128 chip data of the training sequence Midamble sign indicating number of frequency deviation, calculate the first frequency offset estimation result f according to described 128 chip data and local basic Midamble yardage
M
Step B, the data and the described first frequency offset estimation result f that will demodulate through joint-detection
MCarry out compensate of frequency deviation and calculate, obtain the compensate of frequency deviation result;
Step C, described compensate of frequency deviation result is carried out frequency offset estimating calculate, obtain the second frequency offset estimation result f
D
Step D, to the described first frequency offset estimation result f
MWith the described second frequency offset estimation result f
DCarry out accumulation calculating, obtain the 3rd frequency offset estimation result f
O
Preferably, described steps A specifically comprises:
Operator IFFT represents: fast adverse Fourier transform;
Operator FFT represents: fast fourier transform;
Operator ./expression: the contraposition of two sequences is divided by;
M represents: the basic Midamble sign indicating number in the TD-SCDMA system;
Expression: back 128 the chip data that have frequency deviation Midamble sign indicating number that the TD-SCDMA system terminal receives;
Steps A 4, at first utilize formula
Will
Sequence and
The conjugate multiplication of sequence, wherein X=[x
0, x
1... x
127], x is the sequence that comprises frequency deviation information; Pass through formula then
Calculate the plural variable C that comprises frequency deviation information
M, wherein i is a natural number;
Steps A 5, utilize formula
Calculate the first frequency offset estimation result f
M, wherein
T
CExpression: spreading rate;
Im (C
M): represent plural variable C
MImaginary part;
Re (C
M): represent plural variable C
MReal part.
Preferably, after described steps A 5, described steps A also comprises:
Steps A 6, by formula f
M=sign (f
M) * min (f
M, F), to the described first frequency offset estimation result f
MBe optimized processing, wherein
Sign (x) function representation: the symbol of getting variable x;
(x, y) function representation: get one less in two real numbers of x and y, x, y are real number to min;
F represents: the maximum frequency deviation of predicting in the TD-SCDMA system.
Preferably, described step B specifically comprises:
Step B1, the data sequence of reception after the joint-detection demodulation
Wherein
Be i demodulating data symbols in the code channel after the joint-detection demodulation, parameter i=0 wherein, 1, ..., N-1, N represents: the contained data symbol number of each code channel in the TD-SCDMA system, and N=704/SF, SF are the presently used spreading factor of TD-SCDMA system;
Step B2, whether judge parameter i less than N/2, if utilize formula
Calculate the compensate of frequency deviation result; Otherwise, utilize formula
Calculate the compensate of frequency deviation result.
Preferably, be each N of Midamble sign indicating number both sides when the data symbol that uses
DIn the time of/2,2≤N wherein
D≤ N, and N
DBe even number, N represents: the contained data symbol number of each code channel in the TD-SCDMA system, and N=704/SF, and SF is the presently used spreading factor of TD-SCDMA system, described step C specifically comprises:
Step C1, pass through formula
Carry out the hard decision of data symbol, wherein, d '
iBe the compensate of frequency deviation result who calculates among the step B2, i=0,1 ... N
D-1;
Step C2, at first according to formula
Calculate d
i' with
The y as a result of conjugate multiplication
i, then according to formula
Calculate the plural variable C that comprises frequency deviation information
D, i=0 wherein, 1 ... N
D-1;
Step C3, utilize formula
Calculate the described second frequency offset estimation result f
D, wherein
Wherein, T
CExpression: spreading rate;
Im (C
D) expression: plural variable C
DImaginary part;
Re (C
D) expression: plural variable C
DReal part.
N represents: the data symbol number in the TD-SCDMA system in each code channel, and N=704/SF, SF are the presently used spreading factor of TD-SCDMA system.
Preferably, described step C is specially:
Step C4, employing cascade result's frequency offset estimating is to N1
DIndividual data symbol carries out frequency offset estimating and calculates, and obtains the 4th frequency offset estimation result, wherein N1
DBe even number;
Step C5, utilize described the 4th frequency offset estimation result all data symbols to be compensated the frequency offset estimation result after being compensated;
The frequency offset estimating of step C6, employing cascade structure is to the N2 in the frequency offset estimation result after the described compensation
DIndividual data symbol carries out frequency offset estimating, obtains the 5th frequency offset estimation result, wherein N2
DBe even number, and N2
DGreater than N1
D
Step C7, described the 4th frequency offset estimation result and described the 5th frequency offset estimation result addition are obtained the described second frequency offset estimation result f
D
The present invention also provides the frequency deviation estimation device in a kind of TD-CDMA access system, and described device comprises:
Midamble data frequency offset estimator is used to receive back 128 chip data of the training sequence Midamble sign indicating number that has frequency deviation, calculates the first frequency offset estimation result f according to described 128 chip data and local basic Midamble yardage
M
The compensate of frequency deviation device is used for data and the described first frequency offset estimation result f that will demodulate through joint-detection
MCarry out compensate of frequency deviation and calculate, obtain the compensate of frequency deviation result;
The demodulating data frequency offset estimator is used for that described compensate of frequency deviation result is carried out frequency offset estimating and calculates, and obtains the second frequency offset estimation result f
D
Accumulator is used for the described first frequency offset estimation result f
MWith the described second frequency offset estimation result f
DCarry out accumulation calculating, obtain the 3rd frequency offset estimation result f
O
At least one technical scheme in the technique scheme has following beneficial effect: by Midamble sign indicating number frequency offset estimating and demodulating data frequency offset estimating are combined, realized in the TD-SCDMA system on a large scale, high-precision frequency offset estimating, make the TD network can satisfy the needs of some special screne.
Description of drawings
The position view that Fig. 1 meets for 4 data in Midamble sign indicating number both sides in the prior art;
Fig. 2 is a frequency deviation estimation approach flow chart in the embodiments of the invention;
Fig. 3 is the device block diagram of frequency offset estimating in the embodiments of the invention.
Embodiment
In an embodiment of the present invention, by Midamble sign indicating number (training sequence) frequency offset estimating and demodulating data frequency offset estimating are combined, realized in the TD-SCDMA system on a large scale, high-precision frequency offset estimating.
For the purpose, technical scheme and the advantage that make the embodiment of the invention is clearer,, the embodiment of the invention is done explanation in further detail below in conjunction with embodiment and accompanying drawing.At this, illustrative examples of the present invention and explanation are used to explain the present invention, but not as a limitation of the invention.
Referring to Fig. 2, be frequency deviation estimation approach flow chart in the embodiments of the invention, concrete steps are as follows:
In the present embodiment, can come execution in step 21 by the Midamble frequency offset estimator, and step 21 can comprise following concrete steps:
Wherein, operator IFFT represents: fast adverse Fourier transform;
Operator FFT represents: fast fourier transform;
Operator ./expression: the contraposition of two sequences is divided by;
M represents: the basic Midamble sign indicating number in the TD-SCDMA system;
Expression: back 128 the chip data that have frequency deviation Midamble sign indicating number that the TD-SCDMA system terminal receives;
Step 211, original channel is estimated
Carry out noise removing, the channel estimating behind the noise that is eliminated
This step can realize by noise eliminator of the prior art, promptly eliminates original channel and estimates
In noise item, from multipath channel, select the effective diameter channel.Application number for example: 200310116920.1 denominations of invention: a kind of patent documentation that is used for the denoising method of wireless communication system discloses the denoising method in a kind of wireless communication system, this method comprises: at first the signal in the channel is done initial option, multipath channel in the selective channel, utilize the relation of the signal to noise ratio of channel impulse response to calculate the Noise gate limit value then, compare by power and this Noise gate limit value at last, with the noise remove in the channel multipath channel.Certainly, the method for carrying out noise removing for channel estimating also can adopt other prior art means to realize, no longer applies at this and states.
Step 212, right
Sequence is reconstructed calculating, obtains not having the received signal of frequency deviation
Can be reconstructed the calculating of the received signal of no frequency deviation in the present embodiment by formula (2).
Wherein, operator. * expression: the contraposition of two sequences is multiplied each other;
Step 213, extraction frequency deviation information;
At first utilize formula (3), will
Sequence and
The conjugate multiplication of sequence obtains X as a result;
X=[x wherein
0, x
1... x
128], wherein, x is a sequence that comprises frequency deviation information, thus can calculated complex variable C
M, also can be understood as an intermediate variable
And then calculate the plural variable C that comprises frequency deviation information by formula (4)
M,
Step 214, calculating frequency deviation;
Just adopt formula (5) to calculate the first frequency offset estimation result f
M,
Wherein, T
CExpression: spreading rate, T in the TD-SCDMA system
C=1.28 million per second chips;
Im (C
M) expression: plural variable C
MImaginary part;
Re (C
M) expression: plural variable C
MReal part.
After execution of step 214, if the maximum frequency deviation F in the known TD-SCDMA system, so by formula (6) to f
MValue be optimized processing.
f
M=sign (f
M) * min (f
M, F) formula (6)
Wherein, sign (x) function representation: the symbol of getting variable x;
(x, y) function representation: get one less in two real numbers of x and y, x, y are real number to min;
Parameter F is represented: the maximum frequency deviation of predicting in the TD-SCDMA system, certainly also be not limited to this, at the frequency acquisition of present embodiment in the stage, maximum frequency deviation is generally 6kHz, if be used for the frequency-tracking stage, maximum frequency deviation generally can not surpass 300Hz, but some special screne for tracking phase, high-speed mobile scene for example, maximum frequency deviation can reach 1.6kHz (when translational speed is 430km/h), but in formula 6 this parameter F also the use experience value bring into and be optimized calculating.The set-up mode of this empirical value can for: can be made as 6kHz at this empirical value of acquisition phase, and this empirical value of tracking phase can be made as 1kHz.
Can obtain the first frequency offset estimation result f by step 210~step 214
M, also can use additive method for Midamble sign indicating number frequency offset estimating certainly, for example the frequency offset estimating algorithm based on least square calculates the first frequency offset estimation result f
M
In the present embodiment, can come execution in step 22 by the compensate of frequency deviation device, and step 22 can comprise following concrete steps:
Step 220, at first receive data sequence after the joint-detection demodulation
Wherein
Be i demodulating data symbols in the code channel after the joint-detection demodulation, i=0 wherein, 1, ..., N-1, N represents: the data symbol number in the TD-SCDMA system in each code channel, and N=704/SF, SF is the presently used spreading factor of TD-SCDMA system, SF=1 in the TD-SCDMA system~16;
Whether the parameter i that step 221, judgement are chosen is less than N/2, if utilize formula (7) to calculate the compensate of frequency deviation result; Otherwise, utilize formula (8) to calculate the compensate of frequency deviation result.
In the present embodiment, the user can use the compensate of frequency deviation device to come performing step 220 and step 221, can carry out compensate of frequency deviation by following program this moment and calculate.
for?i=0:N-1
if?i<N/2
else
end
end
Though the first frequency offset estimation result f that obtains
MEstimation range can satisfy the requirement of high speed scene, but have the not high problem of estimated accuracy, therefore need further to improve estimated accuracy.Just execution in step 23.
Suppose that at first employed data symbol is each N of Midamble both sides
D/ 2,2≤N wherein
D≤ N, N
DBe even number, so the N that is got this moment
DIndividual symbol data is
I=0 wherein, 1 ..., N
D-1.Can finish by following three steps based on the demodulating data frequency offset estimating:
Step 231, symbol hard decision;
In the communication system, data symbol is owing to noise, decline, frequency deviation, reason such as synchronous, make the receiving terminal data symbol in planisphere the position and during its transmission the position of the planisphere at place produce certain deviation.This step is exactly that what symbol adjudicates this symbol be at transmitting terminal according to receiving the position of data symbol in planisphere, uses here
Expression d
i' court verdict:
At application number: 200710119527.6 denominations of invention: introduced the hard decision method in a kind of TD-SCDMA system in the patent documentation of a kind of quadrature amplitude modulation demodulation method that is applied to communication system and device, comprise the steps: step 1, receiving terminal adopts planisphere that the symbol that receives is shone upon, obtain the final symbol of described symbol, and to this final symbol operated in saturation; Step 2 is determined the predetermined thresholds at different levels of the soft bit demodulation of M unit quadrature amplitude modulation, goes out each bit of this final symbol according to the final sign computation after this predetermined threshold and the described operated in saturation.
Step 232, extraction frequency deviation information;
In step 232, at first utilize formula (10) to calculate d
i' with
The y as a result of conjugate multiplication
i
Then, utilize formula (11) to calculate to comprise the plural variable C of frequency deviation information
D
Step 233, calculating frequency deviation;
Just adopt formula (12) to calculate the second frequency offset estimation result f
D
Wherein, T
CExpression: spreading rate, T in the TD-SCDMA system
C=1.28 million per second chips;
Im (C
D) expression: plural variable C
DImaginary part;
Re (C
D) expression: plural variable C
DReal part.
N represents: the data symbol number in the TD-SCDMA system in each code channel, and N=704/SF, SF are the presently used spreading factor of TD-SCDMA system;
As a kind of preferred version,, can adopt the frequency offset estimating of cascade structure in the present embodiment for frequency offset estimating based on demodulating data.Promptly use N1 earlier
DIndividual data symbol carries out frequency offset estimating, utilizes this estimated result that all symbols are compensated then, re-uses the N2 among the result after the compensation
D(N2
D>N1
D) individual data symbol carries out the frequency offset estimating second time, with twice estimated result addition as f
DCan effectively improve the precision of frequency offset estimating by execution in step 23.N1
DAnd N2
DBe even number, and N1
DEven number between preferred 8~20;
Promptly adopt the first frequency offset estimation result f of formula (13) with twice acquisition
MWith the second frequency offset estimation result f
DAdd up, and the result who obtains that will add up exports as last frequency offset estimation result.
f
O=f
M+ f
DFormula (13)
As shown from the above technical solution, by Midamble sign indicating number frequency offset estimating and demodulating data frequency offset estimating are combined, realized in the TD-SCDMA system on a large scale, high-precision frequency offset estimating, make the TD network can satisfy the needs of some special screne.
In order to realize above-mentioned method embodiment, other embodiment of the present invention also provide frequency deviation estimating method and the device in a kind of TD-CDMA access system.What need at first explanation in addition is; because following embodiment is for realizing aforesaid method embodiment; so this device all is to establish for each step that realizes preceding method; but the present invention is not limited to following embodiment, and any device of said method of realizing all should be contained in protection scope of the present invention.And in the following description, the content identical with preceding method omitted at this, to save length.
Referring to Fig. 2, be the device block diagram of the frequency offset estimating in the embodiments of the invention, by among the figure as can be known this device comprise:
Midamble data frequency offset estimator is used to receive back 128 chip data of the training sequence Midamble sign indicating number that has frequency deviation, calculates the first frequency offset estimation result f according to described 128 chip data and local basic Midamble yardage
M
The compensate of frequency deviation device is used for data and the described first frequency offset estimation result f that will demodulate through joint-detection
MCarry out compensate of frequency deviation and calculate, obtain the compensate of frequency deviation result;
The demodulating data frequency offset estimator is used for that described compensate of frequency deviation result is carried out frequency offset estimating and calculates, and obtains the second frequency offset estimation result f
DAnd
Accumulator is used for the described first frequency offset estimation result f
MWith the described second frequency offset estimation result f
DCarry out accumulation calculating, obtain the 3rd frequency offset estimation result f
O
Wherein, above-mentioned Midamble data frequency offset estimator can execution in step 210~step 214, and this moment, this Midamble data frequency offset estimator comprised:
Channel estimation module is used to pass through formula
Calculating original channel estimates
Wherein
Operator IFFT represents: fast adverse Fourier transform;
Operator FFT represents: fast fourier transform;
Operator ./expression: the contraposition of two sequences is multiplied each other;
M represents: the basic Midamble sign indicating number in the TD-SCDMA system;
Expression: back 128 the chip data that have frequency deviation Midamble sign indicating number that the TD-SCDMA system terminal receives;
Noise cancellation module is used for described original channel is estimated
Carry out noise removing, the channel estimating behind the noise that is eliminated
Reconstructed module is used to utilize formula
Right
Sequence is reconstructed calculating, obtains not having the received signal of frequency deviation
Operator wherein. * expression: the contraposition of two sequences is multiplied each other;
First extracts the frequency deviation information module, is used at first utilizing formula
Will
Sequence and
The conjugate multiplication of sequence, wherein X=[X
0, x
1... x
128], pass through formula then
Calculate the plural variable C that comprises frequency deviation information
M, wherein i is a natural number; And
First calculates the frequency deviation module, is used to utilize formula
Calculate the first frequency offset estimation result f
M, wherein
T
CExpression: spreading rate;
Im (C
M): represent plural variable C
MImaginary part;
Re (C
M): represent plural variable C
MReal part.
In another embodiment of the present invention, this Midamble data frequency offset estimator also comprises the first frequency deviation result optimizing module, is used for by formula f
M=sign (f
M) * min (f
M, F), to the described first frequency offset estimation result f
MBe optimized processing, wherein
Sign (x) function representation: the symbol of getting variable x;
(x, y) function representation: get one less in two real numbers of x and y, x, y are real number to min;
F represents: the maximum frequency deviation of predicting in the TD-SCDMA system.
Above-mentioned demodulating data frequency offset estimator comprises:
Symbol hard decision module is used to pass through formula
Carry out the hard decision of data symbol, i=0 wherein, 1 ... N
D-1;
Second extracts the frequency deviation information module, is used at first according to formula
Calculate d
i' with
The y as a result of conjugate multiplication
i, then according to formula
Calculate the plural variable C that comprises frequency deviation information
D, i=0 wherein, 1 ... N
D-1; And
Second calculates the frequency deviation module, is used to utilize formula
Calculate the described second frequency offset estimation result f
D, wherein
Wherein, T
CExpression: spreading rate;
Im (C
D) expression: plural variable C
DImaginary part;
Re (C
D) expression: plural variable C
DReal part.
N represents: the data symbol number in the TD-SCDMA system in each code channel, and N=704/SF, SF are the presently used spreading factor of TD-SCDMA system;
By Midamble sign indicating number frequency offset estimating and demodulating data frequency offset estimating are combined, realized in the TD-SCDMA system on a large scale, high-precision frequency offset estimating, make the TD network can satisfy the needs of some special screne.
The above only is a preferred implementation of the present invention; should be pointed out that for those skilled in the art, under the prerequisite that does not break away from the principle of the invention; can also make some improvements and modifications, these improvements and modifications also should be considered as protection scope of the present invention.
Claims (7)
1. the frequency deviation estimating method in the TD-CDMA access system is characterized in that described method comprises:
Steps A, reception have back 128 chip data of the training sequence Midamble sign indicating number of frequency deviation, calculate the first frequency offset estimation result f according to described 128 chip data and local basic Midamble yardage
M
Step B, the data and the described first frequency offset estimation result f that will demodulate through joint-detection
MCarry out compensate of frequency deviation and calculate, obtain the compensate of frequency deviation result;
Step C, described compensate of frequency deviation result is carried out frequency offset estimating calculate, obtain the second frequency offset estimation result f
D
Step D, to the described first frequency offset estimation result f
MWith the described second frequency offset estimation result f
DCarry out accumulation calculating, obtain the 3rd frequency offset estimation result f
O
2. method according to claim 1 is characterized in that, described steps A specifically comprises:
Operator IFFT represents: fast adverse Fourier transform;
Operator FFT represents: fast fourier transform;
Operator ./expression: the contraposition of two sequences is divided by;
M represents: the basic Midamble sign indicating number in the TD-SCDMA system;
Expression: back 128 the chip data that have frequency deviation Midamble sign indicating number that the TD-SCDMA system terminal receives;
Steps A 2, described original channel is estimated
Carry out noise removing, the channel estimating behind the noise that is eliminated
Steps A 3, utilize formula
Right
Sequence is reconstructed calculating, obtains not having the received signal of frequency deviation
Operator wherein. * expression: the contraposition of two sequences is multiplied each other;
Steps A 4, at first utilize formula
Will
Sequence and
The conjugate multiplication of sequence, wherein X=[x
0, x
1... x
127], x is the sequence that comprises frequency deviation information; Pass through formula then
Calculate the plural variable C that comprises frequency deviation information
M, wherein i is a natural number;
Steps A 5, utilize formula
Calculate the first frequency offset estimation result f
M, wherein
T
CExpression: spreading rate;
Im (C
M): represent plural variable C
MImaginary part;
Re (C
M): represent plural variable C
MReal part.
3. method according to claim 2 is characterized in that, after described steps A 5, described steps A also comprises:
Steps A 6, by formula f
M=sign (f
M) * min (f
M, F), to the described first frequency offset estimation result f
MBe optimized processing, wherein
Sign (x) function representation: the symbol of getting variable x;
(x, y) function representation: get one less in two real numbers of x and y, x, y are real number to min;
F represents: the maximum frequency deviation of predicting in the TD-SCDMA system.
4. method according to claim 1 is characterized in that, described step B specifically comprises:
Step B1, the data sequence of reception after the joint-detection demodulation
Wherein
Be i demodulating data symbols in the code channel after the joint-detection demodulation, parameter i=0 wherein, 1, ..., N-1, N represents: the contained data symbol number of each code channel in the TD-SCDMA system, and N=704/SF, SF are the presently used spreading factor of TD-SCDMA system;
Step B2, whether judge parameter i less than N/2, if utilize formula
Calculate the compensate of frequency deviation result; Otherwise, utilize formula
Calculate the compensate of frequency deviation result.
5. method according to claim 4 is characterized in that, when the data symbol that uses is each N of Midamble sign indicating number both sides
DIn the time of/2,2≤N wherein
D≤ N, and N
DBe even number, N represents: the contained data symbol number of each code channel in the TD-SCDMA system, and N=704/SF, and SF is the presently used spreading factor of TD-SCDMA system, described step C specifically comprises:
Step C1, pass through formula
Carry out the hard decision of data symbol, wherein, d '
iBe the compensate of frequency deviation result who calculates among the step B2, i=0,1 ... N
D-1;
Step C2, at first according to formula
Calculate d
i' with
The y as a result of conjugate multiplication
i, then according to formula
Calculate the plural variable C that comprises frequency deviation information
D, i=0 wherein, 1 ... N
D-1;
Step C3, utilize formula
Calculate the described second frequency offset estimation result f
D, wherein
Wherein, T
CExpression: spreading rate;
Im (C
D) expression: plural variable C
DImaginary part;
Re (C
D) expression: plural variable C
DReal part;
N represents: the data symbol number in the TD-SCDMA system in each code channel, and N=704/SF, SF are the presently used spreading factor of TD-SCDMA system.
6. method according to claim 1 is characterized in that, described step C is specially:
Step C4, employing cascade result's frequency offset estimating is to N1
DIndividual data symbol carries out frequency offset estimating and calculates, and obtains the 4th frequency offset estimation result, wherein N1
DBe even number;
Step C5, utilize described the 4th frequency offset estimation result all data symbols to be compensated the frequency offset estimation result after being compensated;
The frequency offset estimating of step C6, employing cascade structure is to the N2 in the frequency offset estimation result after the described compensation
DIndividual data symbol carries out frequency offset estimating, obtains the 5th frequency offset estimation result, wherein N2
DBe even number, and N2
DGreater than N1
D
Step C7, described the 4th frequency offset estimation result and described the 5th frequency offset estimation result addition are obtained the described second frequency offset estimation result f
D
7. the frequency deviation estimation device in the TD-CDMA access system is characterized in that described device comprises:
Midamble data frequency offset estimator is used to receive back 128 chip data of the training sequence Midamble sign indicating number that has frequency deviation, calculates the first frequency offset estimation result f according to described 128 chip data and local basic Midamble yardage
M
The compensate of frequency deviation device is used for data and the described first frequency offset estimation result f that will demodulate through joint-detection
MCarry out compensate of frequency deviation and calculate, obtain the compensate of frequency deviation result;
The demodulating data frequency offset estimator is used for that described compensate of frequency deviation result is carried out frequency offset estimating and calculates, and obtains the second frequency offset estimation result f
D
Accumulator is used for the described first frequency offset estimation result f
MWith the described second frequency offset estimation result f
DCarry out accumulation calculating, obtain the 3rd frequency offset estimation result f
O
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN200910079733A CN101552622B (en) | 2009-03-09 | 2009-03-09 | Method and device to estimate the frequency deviation in TD-CDMA access system |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN200910079733A CN101552622B (en) | 2009-03-09 | 2009-03-09 | Method and device to estimate the frequency deviation in TD-CDMA access system |
Publications (2)
Publication Number | Publication Date |
---|---|
CN101552622A true CN101552622A (en) | 2009-10-07 |
CN101552622B CN101552622B (en) | 2012-10-24 |
Family
ID=41156643
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN200910079733A Expired - Fee Related CN101552622B (en) | 2009-03-09 | 2009-03-09 | Method and device to estimate the frequency deviation in TD-CDMA access system |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN101552622B (en) |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102111351A (en) * | 2009-12-23 | 2011-06-29 | 联芯科技有限公司 | Method and system for processing high-order modulated DC component |
CN102594738A (en) * | 2011-01-05 | 2012-07-18 | 中兴通讯股份有限公司 | Method and device for estimating frequency offset |
CN102647377A (en) * | 2012-05-18 | 2012-08-22 | 天津理工大学 | Method and device for frequency deviation correction based on data field partitioning |
-
2009
- 2009-03-09 CN CN200910079733A patent/CN101552622B/en not_active Expired - Fee Related
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102111351A (en) * | 2009-12-23 | 2011-06-29 | 联芯科技有限公司 | Method and system for processing high-order modulated DC component |
CN102594738A (en) * | 2011-01-05 | 2012-07-18 | 中兴通讯股份有限公司 | Method and device for estimating frequency offset |
CN102594738B (en) * | 2011-01-05 | 2015-05-13 | 中兴通讯股份有限公司 | Method and device for estimating frequency offset |
CN102647377A (en) * | 2012-05-18 | 2012-08-22 | 天津理工大学 | Method and device for frequency deviation correction based on data field partitioning |
CN102647377B (en) * | 2012-05-18 | 2016-05-18 | 天津理工大学 | A kind of frequency deviation correcting method and device based on data field piecemeal |
Also Published As
Publication number | Publication date |
---|---|
CN101552622B (en) | 2012-10-24 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN1555640B (en) | Method and apparatus for cancelling co-channel interference in a receiving system using spatio-temporal whitening | |
CN101124800B (en) | Coarse timing estimation system and methodology for wireless symbols | |
KR101004101B1 (en) | Apparatus and method for IEEE 802.15.4 LR-WPAN BPSK receiver | |
CN101444055A (en) | Delay-Doppler channel response demodulation method and apparatus | |
CN100389552C (en) | Timing estimating apparatus and method in direct sequence spread spectrum communication system | |
CN111147102B (en) | Low signal-to-noise ratio code capturing method based on frequency modulation signal | |
CN113141195B (en) | Demodulation method for dispreading in direct sequence spread spectrum system and storage medium | |
CN101133562A (en) | Method for restraining user signal interference from neighbor subdistrict | |
CN101147371B (en) | Channel estimating method and device | |
CN107370705A (en) | FFT optimization method in the capture of high dynamic weakly continuous phase modulated signal | |
CN107682294B (en) | FPGA-based phase ambiguity correction method for high-speed 16apsk signal | |
CN101552622B (en) | Method and device to estimate the frequency deviation in TD-CDMA access system | |
CN102215184B (en) | Method and system for estimating uplink timing error | |
CN104378317A (en) | Burst signal frequency deviation correction method applied to satellite phones | |
CN102655491A (en) | Frequency shift estimation method and system for coherent demodulation frequency shift keying modulating signals | |
CN101345549B (en) | Frequency deviation estimation method and apparatus used for time division-synchronous code division multiple access system | |
CN101909028B (en) | Single carrier demodulation method and system, transmitter and receiver | |
CN101646232B (en) | Method, device and communication equipment for estimating frequency deviations | |
CN101594167A (en) | The method of allied signal detection and Frequency Estimation in a kind of wireless network | |
CN100521554C (en) | Frequency domain channel estimation method based on two-value full-pass sequence protection interval filling | |
WO2001052493A1 (en) | Method for blind modulation detection | |
CN101267228A (en) | A multi-path search and tracking method in WCDMA base station receiver based on DSP | |
CN100512035C (en) | Block decision feedback method for TD-SCDMA reception signal demodulation | |
CN103227759B (en) | A kind of detection method for subscriber signal and equipment | |
CN100486147C (en) | Channel estimation method suitable for GSM and enhanced data rate for GSM evolution |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
C06 | Publication | ||
PB01 | Publication | ||
C10 | Entry into substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20121024 Termination date: 20180309 |