CN101848183A - Channel estimation method and device in multiple input multiple output OFDM (Orthogonal Frequency Division Multiplexing) system - Google Patents
Channel estimation method and device in multiple input multiple output OFDM (Orthogonal Frequency Division Multiplexing) system Download PDFInfo
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Abstract
The invention relates to channel estimation method and device in a multiple input multiple output OFDM (Orthogonal Frequency Division Multiplexing) system. The method comprises the following steps that the system codes the pilot subcarrier data of each transmitting antenna to generate time domain OFDM signals and then transmitting the time domain OFDM signals to a receiving antenna; the system extracts continuous pilot subcarrier block data on each receiving antenna to obtain pilot receiving data on each transmitting antenna; the system obtains time domain channel response values after obtaining the frequency response of all pilot subcarriers on each transmitting antenna by carrying out frequency domain LS (Least Square) channel estimation on the pilot receiving data on each transmitting antenna; the system carries out peak search, peak point diffusion coefficient calculation and offset iteration on the obtained time domain channel response values and carries out FFT (Fast Fourier Transform Algorithm) transformation processing on the outputted valid time domain multipath channel response values to obtain channel frequency response values of each subcarrier on each transmitting antenna to complete channel estimation. By applying the invention, the problem of path diffusion phenomenon when the time domain channel estimation is carried out is solved, and meanwhile, partial noise is restrained, and finally, the channel estimation precision is improved.
Description
Technical field
The present invention relates to wireless communication field, relate to channel estimation methods and device in a kind of multi-input multi-output-orthogonal frequency-division multiplexing system especially.
Background technology
At the MIMO-OFDM that has empty subcarrier (multi-input multi-output-orthogonal frequency-division multiplexing) system, present existing channel estimation methods mainly is the frequency domain interpolation method, be linear interpolation, Gauss interpolation, Wiener filtering interpolation and transform domain interpolation, but existing domain of variation interpolation can only effectively suppress partial noise, but can't suppress because there is the time domain footpath diffusion effect that is caused in empty subcarrier, thereby make the time than high s/n ratio, " floor effect " appears in channel estimating, time domain directly spreads the mis-behave phenomenon of being brought, and makes that the channel estimated accuracy deviation is big.
This shows that the technical scheme of a kind of new channel estimating of current needs solves the problems referred to above that the frequency domain interpolation method that adopts in the MIMO-OFDM system of the empty subcarrier of current existence exists.
Summary of the invention
Technical problem to be solved by this invention provides channel estimation methods and device in a kind of multi-input multi-output-orthogonal frequency-division multiplexing system, solved the problem of footpath diffusion phenomena when suppressing to carry out the time domain channel estimation, simultaneously also can effectively suppress partial noise, thereby finally improve channel estimated accuracy.
In order to address the above problem, the invention provides channel estimation methods in a kind of multi-input multi-output-orthogonal frequency-division multiplexing system, comprising:
After the Walsh Walsh orthogonal code that system distributes the pilot sub-carrier data and the respective transmit antenna of each transmitting antenna is encoded, with the orthogonal frequency division multiplex OFDM signal of pilot sub-carrier piece behind the coding and data subcarrier composition frequency domain; After carrying out inverse fast fourier transformed IFFT conversion by the ofdm signal to every the above frequency domain of transmitting antenna, the ofdm signal that generates time domain is transferred to reception antenna;
System carries out fast fourier transform FFT conversion process to the time domain OFDM signal that receives on the every reception antenna, extract the continuous pilot block of sub-carriers data on the every reception antenna, the Walsh orthogonal code of the every transmitting antenna that is complementary with transmitting terminal multiplies each other and adds up, and obtains the pilot reception data on the every transmitting antenna;
System is by carrying out frequency domain LS channel estimating to the pilot reception data on the every transmitting antenna, obtain the frequency response of all pilot sub-carriers on the every transmitting antenna after, obtain the time domain channel response value according to the transform domain mode; Iteration is calculated and offset to the time domain channel response value that obtained by peak value searching, peak point diffusion coefficient, and the effective time domain multipath channel response of output obtains the channel frequency response value of each data subcarrier on each transmitting antenna, finishes channel estimating.
Further, said method also can comprise, after the Walsh orthogonal code that described system distributes the pilot sub-carrier data and the respective transmit antenna of each transmitting antenna is encoded, with the ofdm signal of pilot sub-carrier piece behind the coding and data subcarrier composition frequency domain; After carrying out the IFFT conversion by the ofdm signal to every the above frequency domain of transmitting antenna, the ofdm signal that generates time domain is transferred to reception antenna, specifically is divided into following steps:
The Walsh orthogonal code that the continuous pilot block of sub-carriers data on the transmitting antenna and corresponding each transmitting antenna are distributed is encoded by described system, data on the data subcarrier in non-pilot sub-carrier in the continuous pilot piece and the non-pilot data piece are finished by constellation mapping by the bit stream on independent each transmitting antenna, and the data subcarrier after the pilot sub-carrier piece behind the coding and constellation mapping are finished is formed the ofdm signal of frequency domain;
After described system carries out the IFFT conversion to the ofdm signal of every the above frequency domain of transmitting antenna, carry out and go here and there after conversion adds Cyclic Prefix simultaneously, generate the ofdm signal of time domain, be transferred to reception antenna by wireless multiple-input, multiple-output mimo channel.
Further, said method can comprise that also described system carries out the FFT conversion process to the time domain OFDM signal that receives on the every reception antenna, extracts the continuous pilot block of sub-carriers data on the every reception antenna, specifically is meant:
After Cyclic Prefix and string and conversion are removed to the time domain OFDM signal that receives on the every reception antenna by described system, by the FFT conversion process, generate the ofdm signal of frequency domain on the every reception antenna, extract the continuous pilot block of sub-carriers data on the every reception antenna.
Further, said method also can comprise, described system is by carrying out frequency domain LS channel estimating to the pilot reception data on the every transmitting antenna, obtain the frequency response of all pilot sub-carriers on the every transmitting antenna after, obtain the time domain channel response value according to the transform domain mode, specifically be meant:
Described system is by carrying out frequency domain LS channel estimating to the pilot reception data on the every transmitting antenna, after obtaining the frequency response of all pilot sub-carriers on the every transmitting antenna, it is zero to insert several, and then carry out the IFFT conversion again, obtain the time domain channel response value, wherein, inserting zero number is to be counted and the insertion of pilot sub-carrier is determined at interval by pilot sub-carrier number, FFT.
Further, said method also can comprise, iteration is calculated and offset in described system to the time domain channel response value that is obtained by peak value searching, peak point diffusion coefficient, the effective time domain multipath channel response of output, obtain the channel frequency response value of each data subcarrier on each transmitting antenna, finish channel estimating, specifically be divided into following steps:
The time domain channel response value of described system to being obtained, by carrying out after peak value searching determines peak value and correspondence position thereof, calculate the diffusion coefficient of this position sampling point on all time domain sampling points, and it is offset from the initial time domain channel response value that obtains, carry out the peak value searching iteration of a new round again, drop to below the setting thresholding until this peak value that searches out, stop iteration, effective time domain multipath channel response to output is carried out the FFT conversion process, obtain the channel frequency response value of each data subcarrier on each transmitting antenna, finish channel estimating.
The present invention also provides channel estimating apparatus in a kind of multi-input multi-output-orthogonal frequency-division multiplexing system, comprises the antenna coding module, and antenna decoder module and footpath diffusion suppress module, wherein,
Described antenna coding module, after being used for the Walsh Walsh orthogonal code that the pilot sub-carrier data and the respective transmit antenna of each transmitting antenna are distributed encoded, the pilot sub-carrier piece behind the coding and data subcarrier are formed the orthogonal frequency division multiplex OFDM signal of frequency domain; After carrying out inverse fast fourier transformed IFFT conversion by the ofdm signal to every the above frequency domain of transmitting antenna, the ofdm signal that generates time domain is transferred to described antenna decoder module;
Described antenna decoder module, be used for time domain OFDM signal on the every reception antenna that receives is carried out fast fourier transform FFT conversion process, extract the continuous pilot block of sub-carriers data on the every reception antenna, the Walsh orthogonal code of the every transmitting antenna that is complementary with transmitting terminal multiplies each other and adds up, obtain the pilot reception data on the every transmitting antenna, and send to described footpath diffusion inhibition module;
The diffusion of described footpath suppresses module, is used for by the pilot reception data on the every transmitting antenna are carried out frequency domain LS channel estimating, obtain the frequency response of all pilot sub-carriers on the every transmitting antenna after, obtain the time domain channel response value according to the transform domain mode; Iteration is calculated and offset to the time domain channel response value that obtained by peak value searching, peak point diffusion coefficient, and the effective time domain multipath channel response of output obtains the channel frequency response value of each data subcarrier on each transmitting antenna, finishes channel estimating.
Further, said apparatus also can comprise, after the Walsh orthogonal code that described antenna coding module distributes the pilot sub-carrier data and the respective transmit antenna of each transmitting antenna is encoded, with the ofdm signal of pilot sub-carrier piece behind the coding and data subcarrier composition frequency domain; After carrying out the IFFT conversion by ofdm signal, generate the ofdm signal of time domain, specifically be meant every the above frequency domain of transmitting antenna:
Described antenna coding module is encoded the Walsh orthogonal code that the continuous pilot block of sub-carriers data on the transmitting antenna and corresponding each transmitting antenna are distributed, data on the data subcarrier in non-pilot sub-carrier in the continuous pilot piece and the non-pilot data piece are finished by constellation mapping by the bit stream on independent each transmitting antenna, and the data subcarrier after the pilot sub-carrier piece behind the coding and constellation mapping are finished is formed the ofdm signal of frequency domain; After the ofdm signal of every the above frequency domain of transmitting antenna carried out the IFFT conversion, carry out and go here and there after conversion adds Cyclic Prefix simultaneously, generate the ofdm signal of time domain.
Further, said apparatus can comprise that also described antenna decoder module carries out the FFT conversion process to the time domain OFDM signal that receives on the every reception antenna, extracts the continuous pilot block of sub-carriers data on the every reception antenna, specifically is meant:
After described antenna decoder module is removed Cyclic Prefix and string and conversion to the time domain OFDM signal that receives on the every reception antenna, by the FFT conversion process, generate the ofdm signal of frequency domain on the every reception antenna, extract the continuous pilot block of sub-carriers data on the every reception antenna.
Further, said apparatus also can comprise, the diffusion of described footpath suppresses module by the pilot reception data on the every transmitting antenna are carried out frequency domain LS channel estimating, after obtaining the frequency response of all pilot sub-carriers on the every transmitting antenna, obtain the time domain channel response value according to the transform domain mode, specifically be meant:
The diffusion of described footpath suppresses module by the pilot reception data on the every transmitting antenna are carried out frequency domain LS channel estimating, after obtaining the frequency response of all pilot sub-carriers on the every transmitting antenna, it is zero to insert several, and then carry out the IFFT conversion again, obtain the time domain channel response value, wherein, inserting zero number is to be counted and the insertion of pilot sub-carrier is determined at interval by pilot sub-carrier number, FFT.
Further, said apparatus also can comprise, the diffusion of described footpath suppresses module iteration is calculated and offset to the time domain channel response value that is obtained by peak value searching, peak point diffusion coefficient, the effective time domain multipath channel response of output, obtain the channel frequency response value of each data subcarrier on each transmitting antenna, specifically be meant:
The diffusion of described footpath suppresses the time domain channel response value of module to being obtained, by carrying out after peak value searching determines peak value and correspondence position thereof, calculate the diffusion coefficient of this position sampling point on all time domain sampling points, and it is offset from the initial time domain channel response value that obtains, carry out the peak value searching iteration of a new round again, drop to below the setting thresholding until this peak value that searches out, stop iteration, effective time domain multipath channel response to output is carried out the FFT conversion process, obtains the channel frequency response value of each data subcarrier on each transmitting antenna.
Compared with prior art, use the present invention, the footpath diffusion effect that the MIMO-OFDM system that has empty subcarrier occurs when the channel estimating has been carried out certain inhibition, weakened " floor effect " to a great extent, also suppressed simultaneously partial noise, effectively improved channel estimated accuracy, and its complexity is lower, realizes simple relatively.
Description of drawings
Fig. 1 is the flow chart of channel estimation methods in the multi-input multi-output-orthogonal frequency-division multiplexing system of the present invention;
Fig. 2 is the schematic diagram of channel estimating in the input multi-output-orthogonal frequency-division multiplexing system in the example;
Fig. 3 is a structural representation in the antenna coding module in the example;
Fig. 4 is a structural representation in the antenna decoder module in the example;
Fig. 5 is that the footpath diffusion suppresses structural representation in the module in the example.
Embodiment
The invention will be further described below in conjunction with the drawings and specific embodiments.
Implementation condition of the present invention is at the MIMO-OFDM system that has empty subcarrier.(wherein, mimo channel condition: piece decline (promptly the same sub-carrier upper frequency channel response in a plurality of OFDM symbols is constant)+white noise).Enforcement of the present invention can realize by memory and a plurality of calculator (as multiplier, adder etc.).
Below with N
T* N
RThe MIMO-OFDM system be example, (wherein, N
TBe transmitting antenna, N
RBe reception antenna) channel estimation methods in the multi-input multi-output-orthogonal frequency-division multiplexing system of the present invention, may further comprise the steps:
System is with N
T(wherein, pilot block length is N to continuous pilot block of sub-carriers on the root transmitting antenna
C, the data on each pilot sub-carrier are entirely for " 1 ") and (code length also is N for the Walsh orthogonal code of being distributed with corresponding each transmitting antenna
C) multiply each other (promptly encoding), finish by constellation mapping by the bit stream on independent each transmitting antenna for the data on the data subcarrier in non-pilot sub-carrier in the continuous pilot piece and the non-pilot data piece.
System is to carrying out N on the every transmitting antenna
FFTIFFT (inverse fast fourier transformed) conversion of point, again through and string become the ofdm signal of time domain after changing (P/S) and adding Cyclic Prefix (CP), be transferred to receiving terminal by wireless fading channel at last.
Cyclic Prefix (CP), string and conversion (S/P) are at first removed to the reception data on the every reception antenna by system, pass through N again
FFTThe FFT conversion process of point is extracted the continuous pilot block of sub-carriers data on the every reception antenna at last.
The Walsh orthogonal code of the every transmitting antenna that step 140, system will be complementary with transmitting terminal and extract after every reception antenna on the pilot sub-carrier blocks of data multiply each other and add up, obtain the pilot reception data on the every transmitting antenna;
The Walsh orthogonal code of the every transmitting antenna that system will be complementary with transmitting terminal, pilot sub-carrier blocks of data on the last every reception antenna that extracts in itself and the step 130 is multiplied each other and add up, thereby obtain the pilot reception data on the every transmitting antenna, promptly removed the interference that other transmitting antenna brings simultaneously.
System can at first obtain the frequency response of all pilot sub-carriers on the every transmitting antenna by frequency domain LS channel estimation methods, and inserting several, zero (number is by pilot sub-carrier number N
p, the FFT points N
FFTAnd the insertion interval delta N of pilot sub-carrier
fDetermine), and then carry out M again
FFTThe IFFT conversion of point.
The invention will be further described below in conjunction with instantiation.
Symbolic interpretation is as follows among Fig. 2:
N
t(n
t=1,2 ... N
T) n OFDM symbol block of frequency domain data vector forming by pilot sub-carrier and data subcarrier on the root transmitting antenna;
N OFDM symbol time-domain data blocks vector;
H (n): the time domain impulse response of Technique of Wireless MIMO Channel is expressed as with its discrete tapped delay line model usually
N
r(n
r=1,2 ... N
R) the root reception antenna frequency domain received signal behind the Cyclic Prefix (CP) that gets on;
N
tThe root transmitting antenna is to n
rTime domain channel impulse response between the root reception antenna;
N
tThe root transmitting antenna is to n
rThe frequency domain response of channel between the root reception antenna;
A: the antenna coding module, finish the orthogonal coding of the last pilot sub-carrier data of each transmitting antenna;
B: the antenna decoder module, promptly finish the contrary of modules A and handle, mainly form by multiplier and accumulator;
C: footpath diffusion suppresses module, finishes that time domain directly spreads, Noise Suppression.
The process of the signal flow of describing among Fig. 2 is:
(1) modules A is exported the pilot sub-carrier data on each transmitting antenna;
(2) generation of time domain transmission signal on each transmitting antenna:
(3) above-mentioned transmission signal is through after the Technique of Wireless MIMO Channel, in the reception form of receiving terminal is:
(4) further the reception data on the above-mentioned every reception antenna being carried out the FFT change process can obtain its frequency domain and receive vector and be:
(5) module B carries out the quadrature separation to pilot sub-carrier data on each antenna that is extracted;
(6) module C is output as effective time domain multipath channel response, and passes through N
FFTPoint FFT conversion obtains the channel frequency response of each data subcarrier on final each transmitting antenna:
Internal structure as shown in Figure 3 in the modules A.
Symbolic interpretation is as follows among Fig. 3:
N
t(n
t=1,2 ... N
T) the root transmitting antenna Walsh orthogonal code of being distributed, and have
Wherein, each transmitting antenna distributes different Walsh orthogonal codes to have following orthogonal property, promptly
N
t(n
t=1,2 ... N
T) encoded back k on the root transmitting antenna
pThe time-domain data blocks of individual pilot sub-carrier, and have
The signal flow process of describing among Fig. 3 is:
Promptly
Internal structure as shown in Figure 4 among the module B.
Symbolic interpretation is as follows among Fig. 4:
N
r(n
r=1,2 ... N
R) k that extracted in the root received signal
pThe continuous pilot piece vector at individual pilot sub-carrier place, and have
Perhaps
N
t(n
t=1,2 ... N
T) the root transmitting antenna is to n
r(n
r=1,2 ... N
R) k between the root reception antenna
p(p=0,1 ... N
P-1) the reception data at individual pilot sub-carrier place.
Internal structure as shown in Figure 5 among the module C.
Symbolic interpretation is as follows among Fig. 5:
N
t(n
t=1,2 ... N
T) the root transmitting antenna is to n
r(n
r=1,2 ... N
R) time domain channel impulse response initial between the root reception antenna estimates;
n
Max (m): the peak point position after the m time iteration,
After M iteration offset, n
t(n
t=1,2 ... N
T) the root transmitting antenna is to n
r(n
r=1,2 ... N
R) the time domain channel impulse response is estimated between the root reception antenna.
The signal flow process of describing among Fig. 5 is:
(3) calculate diffusion coefficient,
Channel estimating apparatus in a kind of multi-input multi-output-orthogonal frequency-division multiplexing system of the present invention comprises the antenna coding module, and antenna decoder module and footpath diffusion suppress module, wherein,
Described antenna coding module, after being used for the Walsh Walsh orthogonal code that the pilot sub-carrier data and the respective transmit antenna of each transmitting antenna are distributed encoded, the pilot sub-carrier piece behind the coding and data subcarrier are formed the orthogonal frequency division multiplex OFDM signal of frequency domain; After carrying out inverse fast fourier transformed IFFT conversion by the ofdm signal to every the above frequency domain of transmitting antenna, the ofdm signal that generates time domain is transferred to described antenna decoder module;
Described antenna decoder module, be used for time domain OFDM signal on the every reception antenna that receives is carried out fast fourier transform FFT conversion process, extract the continuous pilot block of sub-carriers data on the every reception antenna, the Walsh orthogonal code of the every transmitting antenna that is complementary with transmitting terminal multiplies each other and adds up, obtain the pilot reception data on the every transmitting antenna, and send to described footpath diffusion inhibition module;
The diffusion of described footpath suppresses module, is used for by the pilot reception data on the every transmitting antenna are carried out frequency domain LS channel estimating, obtain the frequency response of all pilot sub-carriers on the every transmitting antenna after, obtain the time domain channel response value according to the transform domain mode; Iteration is calculated and offset to the time domain channel response value that obtained by peak value searching, peak point diffusion coefficient, and the effective time domain multipath channel response of output obtains the channel frequency response value of each data subcarrier on each transmitting antenna, finishes channel estimating.
After the Walsh orthogonal code that described antenna coding module distributes the pilot sub-carrier data and the respective transmit antenna of each transmitting antenna is encoded, with the ofdm signal of pilot sub-carrier piece behind the coding and data subcarrier composition frequency domain; After carrying out the IFFT conversion by ofdm signal, generate the ofdm signal of time domain, specifically be meant every the above frequency domain of transmitting antenna:
Described antenna coding module is encoded the Walsh orthogonal code that the continuous pilot block of sub-carriers data on the transmitting antenna and corresponding each transmitting antenna are distributed, data on the data subcarrier in non-pilot sub-carrier in the continuous pilot piece and the non-pilot data piece are finished by constellation mapping by the bit stream on independent each transmitting antenna, and the data subcarrier after the pilot sub-carrier piece behind the coding and constellation mapping are finished is formed the ofdm signal of frequency domain; After the ofdm signal of every the above frequency domain of transmitting antenna carried out the IFFT conversion, carry out and go here and there after conversion adds Cyclic Prefix simultaneously, generate the ofdm signal of time domain.
Described antenna decoder module carries out the FFT conversion process to the time domain OFDM signal that receives on the every reception antenna, extracts the continuous pilot block of sub-carriers data on the every reception antenna, specifically is meant:
After described antenna decoder module is removed Cyclic Prefix and string and conversion to the time domain OFDM signal that receives on the every reception antenna, by the FFT conversion process, generate the ofdm signal of frequency domain on the every reception antenna, extract the continuous pilot block of sub-carriers data on the every reception antenna.
The diffusion of described footpath suppresses module by the pilot reception data on the every transmitting antenna are carried out frequency domain LS channel estimating, obtain the frequency response of all pilot sub-carriers on the every transmitting antenna after, obtain the time domain channel response value according to the transform domain mode, specifically be meant:
The diffusion of described footpath suppresses module by the pilot reception data on the every transmitting antenna are carried out frequency domain LS channel estimating, after obtaining the frequency response of all pilot sub-carriers on the every transmitting antenna, it is zero to insert several, and then carry out the IFFT conversion again, obtain the time domain channel response value, wherein, inserting zero number is to be counted and the insertion of pilot sub-carrier is determined at interval by pilot sub-carrier number, FFT.
The diffusion of described footpath suppresses module iteration is calculated and offset to the time domain channel response value that is obtained by peak value searching, peak point diffusion coefficient, the effective time domain multipath channel response of output, obtain the channel frequency response value of each data subcarrier on each transmitting antenna, specifically be meant:
The diffusion of described footpath suppresses the time domain channel response value of module to being obtained, by carrying out after peak value searching determines peak value and correspondence position thereof, calculate the diffusion coefficient of this position sampling point on all time domain sampling points, and it is offset from the initial time domain channel response value that obtains, carry out the peak value searching iteration of a new round again, drop to below the setting thresholding until this peak value that searches out, stop iteration, effective time domain multipath channel response to output is carried out the FFT conversion process, obtains the channel frequency response value of each data subcarrier on each transmitting antenna.
The above; only for the preferable embodiment of the present invention, but protection scope of the present invention is not limited thereto, and anyly is familiar with the people of this technology in the disclosed technical scope of the present invention; the variation that can expect easily or replacement all should be encompassed within protection scope of the present invention.Therefore, protection scope of the present invention should be as the criterion with the protection range of claim.
Claims (10)
1. channel estimation methods in the multi-input multi-output-orthogonal frequency-division multiplexing system is characterized in that, comprising:
After the Walsh Walsh orthogonal code that system distributes the pilot sub-carrier data and the respective transmit antenna of each transmitting antenna is encoded, with the orthogonal frequency division multiplex OFDM signal of pilot sub-carrier piece behind the coding and data subcarrier composition frequency domain; After carrying out inverse fast fourier transformed IFFT conversion by the ofdm signal to every the above frequency domain of transmitting antenna, the ofdm signal that generates time domain is transferred to reception antenna;
System carries out fast fourier transform FFT conversion process to the time domain OFDM signal that receives on the every reception antenna, extract the continuous pilot block of sub-carriers data on the every reception antenna, the Walsh orthogonal code of the every transmitting antenna that is complementary with transmitting terminal multiplies each other and adds up, and obtains the pilot reception data on the every transmitting antenna;
System is by carrying out frequency domain LS channel estimating to the pilot reception data on the every transmitting antenna, obtain the frequency response of all pilot sub-carriers on the every transmitting antenna after, obtain the time domain channel response value according to the transform domain mode; Iteration is calculated and offset to the time domain channel response value that obtained by peak value searching, peak point diffusion coefficient, and the effective time domain multipath channel response of output obtains the channel frequency response value of each data subcarrier on each transmitting antenna, finishes channel estimating.
2. channel estimation methods as claimed in claim 1 is characterized in that,
After the Walsh orthogonal code that described system distributes the pilot sub-carrier data and the respective transmit antenna of each transmitting antenna is encoded, with the ofdm signal of pilot sub-carrier piece behind the coding and data subcarrier composition frequency domain; After carrying out the IFFT conversion by the ofdm signal to every the above frequency domain of transmitting antenna, the ofdm signal that generates time domain is transferred to reception antenna, specifically is divided into following steps:
The Walsh orthogonal code that the continuous pilot block of sub-carriers data on the transmitting antenna and corresponding each transmitting antenna are distributed is encoded by described system, data on the data subcarrier in non-pilot sub-carrier in the continuous pilot piece and the non-pilot data piece are finished by constellation mapping by the bit stream on independent each transmitting antenna, and the data subcarrier after the pilot sub-carrier piece behind the coding and constellation mapping are finished is formed the ofdm signal of frequency domain;
After described system carries out the IFFT conversion to the ofdm signal of every the above frequency domain of transmitting antenna, carry out and go here and there after conversion adds Cyclic Prefix simultaneously, generate the ofdm signal of time domain, be transferred to reception antenna by wireless multiple-input, multiple-output mimo channel.
3. channel estimation methods as claimed in claim 1 or 2 is characterized in that,
Described system carries out the FFT conversion process to the time domain OFDM signal that receives on the every reception antenna, extracts the continuous pilot block of sub-carriers data on the every reception antenna, specifically is meant:
After Cyclic Prefix and string and conversion are removed to the time domain OFDM signal that receives on the every reception antenna by described system, by the FFT conversion process, generate the ofdm signal of frequency domain on the every reception antenna, extract the continuous pilot block of sub-carriers data on the every reception antenna.
4. channel estimation methods as claimed in claim 1 is characterized in that,
Described system is by carrying out frequency domain LS channel estimating to the pilot reception data on the every transmitting antenna, obtain the frequency response of all pilot sub-carriers on the every transmitting antenna after, obtain the time domain channel response value according to the transform domain mode, specifically be meant:
Described system is by carrying out frequency domain LS channel estimating to the pilot reception data on the every transmitting antenna, after obtaining the frequency response of all pilot sub-carriers on the every transmitting antenna, it is zero to insert several, and then carry out the IFFT conversion again, obtain the time domain channel response value, wherein, inserting zero number is to be counted and the insertion of pilot sub-carrier is determined at interval by pilot sub-carrier number, FFT.
5. as claim 1 or 4 described channel estimation methods, it is characterized in that,
Iteration is calculated and offset in described system to the time domain channel response value that is obtained by peak value searching, peak point diffusion coefficient, the effective time domain multipath channel response of output, obtain the channel frequency response value of each data subcarrier on each transmitting antenna, finish channel estimating, specifically be divided into following steps:
The time domain channel response value of described system to being obtained, by carrying out after peak value searching determines peak value and correspondence position thereof, calculate the diffusion coefficient of this position sampling point on all time domain sampling points, and it is offset from the initial time domain channel response value that obtains, carry out the peak value searching iteration of a new round again, drop to below the setting thresholding until this peak value that searches out, stop iteration, effective time domain multipath channel response to output is carried out the FFT conversion process, obtain the channel frequency response value of each data subcarrier on each transmitting antenna, finish channel estimating.
6. channel estimating apparatus in the multi-input multi-output-orthogonal frequency-division multiplexing system is characterized in that,
Comprise the antenna coding module, antenna decoder module and footpath diffusion suppress module, wherein,
Described antenna coding module, after being used for the Walsh Walsh orthogonal code that the pilot sub-carrier data and the respective transmit antenna of each transmitting antenna are distributed encoded, the pilot sub-carrier piece behind the coding and data subcarrier are formed the orthogonal frequency division multiplex OFDM signal of frequency domain; After carrying out inverse fast fourier transformed IFFT conversion by the ofdm signal to every the above frequency domain of transmitting antenna, the ofdm signal that generates time domain is transferred to described antenna decoder module;
Described antenna decoder module, be used for time domain OFDM signal on the every reception antenna that receives is carried out fast fourier transform FFT conversion process, extract the continuous pilot block of sub-carriers data on the every reception antenna, the Walsh orthogonal code of the every transmitting antenna that is complementary with transmitting terminal multiplies each other and adds up, obtain the pilot reception data on the every transmitting antenna, and send to described footpath diffusion inhibition module;
The diffusion of described footpath suppresses module, is used for by the pilot reception data on the every transmitting antenna are carried out frequency domain LS channel estimating, obtain the frequency response of all pilot sub-carriers on the every transmitting antenna after, obtain the time domain channel response value according to the transform domain mode; Iteration is calculated and offset to the time domain channel response value that obtained by peak value searching, peak point diffusion coefficient, and the effective time domain multipath channel response of output obtains the channel frequency response value of each data subcarrier on each transmitting antenna, finishes channel estimating.
7. channel estimating apparatus as claimed in claim 6 is characterized in that,
After the Walsh orthogonal code that described antenna coding module distributes the pilot sub-carrier data and the respective transmit antenna of each transmitting antenna is encoded, with the ofdm signal of pilot sub-carrier piece behind the coding and data subcarrier composition frequency domain; After carrying out the IFFT conversion by ofdm signal, generate the ofdm signal of time domain, specifically be meant every the above frequency domain of transmitting antenna:
Described antenna coding module is encoded the Walsh orthogonal code that the continuous pilot block of sub-carriers data on the transmitting antenna and corresponding each transmitting antenna are distributed, data on the data subcarrier in non-pilot sub-carrier in the continuous pilot piece and the non-pilot data piece are finished by constellation mapping by the bit stream on independent each transmitting antenna, and the data subcarrier after the pilot sub-carrier piece behind the coding and constellation mapping are finished is formed the ofdm signal of frequency domain; After the ofdm signal of every the above frequency domain of transmitting antenna carried out the IFFT conversion, carry out and go here and there after conversion adds Cyclic Prefix simultaneously, generate the ofdm signal of time domain.
8. as claim 6 or 7 described channel estimating apparatus, it is characterized in that,
Described antenna decoder module carries out the FFT conversion process to the time domain OFDM signal that receives on the every reception antenna, extracts the continuous pilot block of sub-carriers data on the every reception antenna, specifically is meant:
After described antenna decoder module is removed Cyclic Prefix and string and conversion to the time domain OFDM signal that receives on the every reception antenna, by the FFT conversion process, generate the ofdm signal of frequency domain on the every reception antenna, extract the continuous pilot block of sub-carriers data on the every reception antenna.
9. channel estimating apparatus as claimed in claim 6 is characterized in that,
The diffusion of described footpath suppresses module by the pilot reception data on the every transmitting antenna are carried out frequency domain LS channel estimating, obtain the frequency response of all pilot sub-carriers on the every transmitting antenna after, obtain the time domain channel response value according to the transform domain mode, specifically be meant:
The diffusion of described footpath suppresses module by the pilot reception data on the every transmitting antenna are carried out frequency domain LS channel estimating, after obtaining the frequency response of all pilot sub-carriers on the every transmitting antenna, it is zero to insert several, and then carry out the IFFT conversion again, obtain the time domain channel response value, wherein, inserting zero number is to be counted and the insertion of pilot sub-carrier is determined at interval by pilot sub-carrier number, FFT.
10. as claim 6 or 9 described channel estimating apparatus, it is characterized in that,
The diffusion of described footpath suppresses module iteration is calculated and offset to the time domain channel response value that is obtained by peak value searching, peak point diffusion coefficient, the effective time domain multipath channel response of output, obtain the channel frequency response value of each data subcarrier on each transmitting antenna, specifically be meant:
The diffusion of described footpath suppresses the time domain channel response value of module to being obtained, by carrying out after peak value searching determines peak value and correspondence position thereof, calculate the diffusion coefficient of this position sampling point on all time domain sampling points, and it is offset from the initial time domain channel response value that obtains, carry out the peak value searching iteration of a new round again, drop to below the setting thresholding until this peak value that searches out, stop iteration, effective time domain multipath channel response to output is carried out the FFT conversion process, obtains the channel frequency response value of each data subcarrier on each transmitting antenna.
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