CN100380857C - Pilot frequency for MIMO communication systems - Google Patents

Abstract

A multiple-access MIMO WLAN system that employs MIMO, OFDM, and TDD. The system (1) uses a channel structure with a number of configurable transport channels, (2) supports multiple rates and transmission modes, which are configurable based on channel conditions and user terminal capabilities, (3) employs a pilot structure with several types of pilot (e.g., beacon, MIMO, steered reference, and carrier pilots) for different functions, (4) implements rate, timing, and power control loops for proper system operation, and (5) employs random access for system access by the user terminals, fast acknowledgment, and quick resource assignments. Calibration may be performed to account for differences in the frequency responses of transmit/receive chains at the access point and user terminals. The spatial processing may then be simplified by taking advantage of the reciprocal nature of the downlink and uplink and the calibration.

Description

The pilot tone of MIMO communication system

The application requires in the 60/421st, No. 309, the 60/438th, 462, the 60/421st, the 428 and the 60/438th, 601 U.S. Provisional Application No., first three application submission date is on October 25th, 2002, last application submission date is on January 7th, 2003, described four applications are entitled as " MIMO WLAN SYSTEM " in order respectively, " Channel Calibration for a Time DivisionDuplexed Communication System ", " Channel Estimation and SpatialProcessing for TDD MIMO Systems " and " Pilots for MIMO CommunicationSystems ", all are transferred to assignee of the present invention and are incorporated herein by reference fully at this.

Background

The field

The present invention relates generally to data communication, and relate in particular to the pilot tone that is applicable in multiple-input and multiple-output (MIMO) communication system.

Background

Mimo system uses a plurality of (N _T) transmitting antenna and a plurality of (N _R) reception antenna is used for transfer of data.By N _TIndividual transmitting antenna and N _RThe mimo channel that individual reception antenna forms may be broken down into N _SIndividual independent channel, wherein N _S≤ min{N _T, N _R.N _SThe corresponding one dimension of each of individual independent channel.If utilize a plurality of additional dimension that antenna is set up that transmit and receive, then mimo channel can provide the performance (for example increasing transmission capacity and/or bigger reliability) of improvement.

In wireless communication system, the data that send at first are modulated on radio frequency (RF) carrier signal to generate the RF modulated signal, and the latter is more suitable in transmitting on wireless channel.For mimo system, can generate nearly N _TIndividual RF modulated signal, and can be simultaneously from N _TIndividual transmitting antenna is sent out.The RF modulated signal that sends can arrive N by a plurality of propagation paths in the wireless channel _RIndividual reception antenna.Propagation path characteristic is because a plurality of factors generally change the described factor such as decline, multipath and external disturbance in time.Therefore, the RF modulated signal of transmission may experience different channels condition (for example different declines and multipath effect) and can be associated with different complex gain and signal to noise ratio (snr)s.

In order to obtain higher performance, often need to describe radio channel response.For example, transmitter may need channel response to handle (following description) so that data are sent to receiver with the implementation space.Receiver also may need channel response to handle the data that send to recover to receiving the signal implementation space.

In many wireless communication systems, the pilot tone that is sent by transmitter helps receiver to realize a plurality of functions.Pilot tone generally generates and realizes in known manner based on known code element.Pilot tone can be used for that channel estimating, timing and frequency are obtained by receiver, data demodulates etc.

In the pilot configuration design of MIMO, a plurality of challenges are arranged.As a kind of consideration, pilot configuration need solve the additional dimension of a plurality of emissions and the foundation of a plurality of reception antenna.As another consideration, because pilot transmission is represented the expense in the mimo system, expectation minimizes pilot transmission as far as possible.And, if mimo system is to support and the multi-address system of a plurality of telex networks that then the major part that a plurality of users' pilot tone does not consume free system resources need be feasiblely supported in the pilot configuration design.

Therefore the mimo system pilot technique of considering more than in the field, needing to solve.

General introduction

Provide the pilot tone that is applicable in the mimo system at this.These pilot tones can be supported the various functions of appropriate system action need, such as regularly and frequency is obtained, channel estimating, calibration etc.It is also conceivable that the dissimilar pilot tones that design and use for difference in functionality.

Various types of pilot tones can comprise: beacon pilot frequency, MIMO pilot tone, manipulation benchmark or manipulation pilot tone and carrier pilot.Beacon pilot frequency is sent out from all transmitting antennas, and can be used for regularly and frequency is obtained.The MIMO pilot tone also is sent out from all transmitting antennas, but covers with the different orthogonal sign indicating number of distributing to transmitting antenna.The MIMO pilot tone can also be used for channel estimating.Handle benchmark and on the specific eigenmodes of mimo channel, be sent out, and be that user terminal is specific.Handling benchmark can be used for channel estimating and may be used for rate controlled.Carrier pilot can also be sent out on the subband/antenna of certain appointment, and can be used for the Phase Tracking of carrier signal.

Each pilot transmission schemes can be based on the combination of these different pilot type and is designed.For example, on down link, access point may be that all user terminals in its overlay area send beacon pilot frequency, MIMO pilot tone and carrier pilots, and will handle benchmark alternatively and send to any active user terminals of transmitting from the access point receiving downlink.On up link, user terminal may send the MIMO pilot tone and be used for calibration, and may send manipulation benchmark and carrier pilot (for example for down link and/or uplink data transmission) when being scheduled.The processing that sends and receive these type pilot tones is in following detailed description.

Various aspects of the present invention and embodiment are in following detailed description.

Brief description of the drawings

By the detailed description with the accompanying drawing that proposes below, it is more obvious that feature of the present invention, character and advantage will become, and identical symbol has identical sign in the accompanying drawing, wherein:

Fig. 1 illustrates the multiple access mimo system;

Fig. 2 is illustrated in the example frame structure that is used for transfer of data in the TDD MIMO-OFDM system;

Fig. 3 illustrates the down link and the uplink pilot transmission of example pilot transmission schemes;

Fig. 4 illustrates the block diagram of access point and user terminal;

Fig. 5 illustrates the TX spatial processor block diagram that can generate beacon pilot frequency;

Fig. 6 A illustrates the TX spatial processor block diagram that can generate the MIMO pilot tone;

Fig. 6 B illustrates based on receiving the RX spatial processor block diagram that the MIMO pilot tone provides channel response to estimate;

Fig. 7 A illustrates and can generate the TX spatial processor block diagram of handling benchmark; And

Fig. 7 B illustrates based on receiving and handles the RF spatial processor block diagram that benchmark provides channel response to estimate.

Describe in detail

Example " speech only is used in reference to " as example, example or explanation " at this.Any embodiment that describes in this conduct " example " not necessarily is understood that optimum or is better than other embodiment's.

Fig. 1 illustrates the multiple access mimo system 100 of supporting a plurality of users and realizing pilot tone described here.Mimo system 100 comprises a plurality of access points (AP) 110 of supporting a plurality of user terminals (UT) 120 communications.For simplicity, two access point 110a and 110b only are shown in Fig. 1.Access point generally is the fixed station that is used for user terminal communication.Access point can also be called as the base station or use some other terms.

User terminal 120 can be dispersed in the whole system.Each user terminal can be the fixing or portable terminal of communicating by letter with access point.User terminal can also be called as access terminal, mobile radio station, distant station, subscriber equipment (UE), wireless device or some other terms.Each user terminal can with one or may a plurality of access points on down link and/or up link, communicate by letter at any given time.Down link (being forward link) refers to the transmission from the access point to the user terminal, and up link (being reverse link) refers to the transmission from the user terminal to the access point.As used herein, " activity " user terminal is a terminal of transmitting and/or ul transmissions is sent to access point from the access point receiving downlink.

In Fig. 1, access point 110a communicates by letter to 120f with user terminal 120a, and access point 110b communicates by letter to 120k with user terminal 120f.User terminal is distributed to access point generally based on receiving signal strength signal intensity rather than distance.At any given time, user terminal can be from one or more access point receiving downlink transmission.System controller 130 is coupled to access point 110 and can be designed to realize a plurality of functions, coordinate and control to be coupled to its access point such as (1), (2) route data between these access points, and (3) insert communicating by letter by the user terminal of these access points services and control and these terminals.

I. pilot tone

Provide the pilot tone that is applicable to mimo system at this, such as what illustrate in Fig. 1.These pilot tones can be supported the function that various suitable system operations may need, such as regularly and frequency is obtained, channel estimating, calibration etc.Pilot tone can be considered to have being designed and be used for the dissimilar of difference in functionality.Form 1 is listed the Short Description of four types pilot tone and example pilot design.Can also define still less, difference and/or additional pilots type, and this is within the scope of the present invention.

Form 1-pilot type

Pilot type	Describe
		Beacon pilot frequency	Send and be used for regularly and pilot tone that frequency is obtained from all transmitting antennas
The MIMO pilot tone	Have the different orthogonal sign indicating number sent and be used for channel estimating from all transmitting antennas pilot tone
		Handle benchmark or handle pilot tone	On the specific eigenmodes on the mimo channel, send and be used for the pilot tone of channel estimating and possible rate controlled for specific user terminal
Carrier pilot	Be used for the pilot tone that carrier signal phase is followed the tracks of

Handling benchmark and handling pilot tone is synonym.

Can be based on the various pilot transmission schemes of the Combination Design of these different pilot type.For example, on down link, access point can send beacon pilot frequency, MIMO pilot tone and carrier pilot for all user terminals in its overlay area, and may send to any active user terminals from the transmission of access point receiving downlink with handling benchmark alternatively.On up link, user terminal can send the MIMO pilot tone and calibrate, and can send manipulation benchmark and carrier pilot (for example for down link and/or uplink data transmission) when scheduling.The processing that sends and receive these all kinds pilot tones is in following detailed description.

Pilot tone described here can be used for various types of mimo systems.For example, pilot tone can be used for (1) single carrier mimo system, (2) multi-carrier MIMO system, can use OFDM (OFDM) or some other multi-carrier modulation technologies, (3) mimo system of realization multiple access technology, such as frequency division multiple access (FDMA), time division multiple access (TDMA) and code division multiple access, (4) realization is used for the frequency division multiplex (FDM) of transfer of data, the mimo system of time division multiplexing (TDM) and/or code division multiplex (CDM), (5) time division duplex (time division duplexing) of realizing being used for transfer of data (TDD), the mimo system of Frequency Division Duplexing (FDD) (FDD) and/or code division duplex (CDD), and (6) other types mimo system.For clear, below at first describe to realize the pilot tone of the mimo system (being the MIMO-OFDM system) of OFDM, be the pilot tone of TDD MIMO-OFDM system then.

OFDM is divided into a plurality of (N with the total system bandwidth effectively _F) orthogonal subbands, subband also is called as accent, frequency zone or frequency subchannels frequently.For OFDM, each subband with corresponding on it subcarrier of modulating data be associated.For the MIMO-OFDM system, each subband can be associated with a plurality of eigenmodes, and each eigenmodes of each subband can be considered the independent transmission channel.

For clear, the special pilot structure that below has been example MIMO-OFDM system description.In this MIMO-OFDM system, it (is N that system bandwidth is divided into 64 orthogonal subbands _F=64), they are assigned with the index with-32 to+31.In these 64 subbands, 48 subbands (for example index be ± 1 ...; 6,8 ...; 20,22 ...; 26}) can be used for transfer of data; 4 subbands (for example index be ± { 7,21} can be used for carrier pilot and possible signaling, does not use DC subband (index is 0); and do not use remaining subband, they are as the protection subband.Therefore, in these 64 total subbands, 52 " can use " subbands comprise 48 data subbands and 4 pilot subbands, and remaining 12 subbands do not use.This OFDM sub band structure is described in further detail in aforesaid the 60/421st, No. 309 interim U. S. application.Can also realize subband and other OFDM sub band structure of different numbers for the MIMO-OFDM system, and this within the scope of the invention.

For OFDM, the data that send on each available subband are at first used certain modulation schemes (for example BPSK, QPSK or the M-QAM) modulation of selecting into this subband (promptly through symbol mapped).A modulated symbol can be sent out on each available subband in the period in each code element.Each modulated symbol is the complex values of the interior specified point of signal constellation (in digital modulation) of corresponding selected modulation scheme.Be that zero signal value can be sent out on obsolete subband.For each OFDM code element period, the modulated symbol of available subband and the signal values of zero of not using subband are (promptly to all N _FThe modulated symbol of individual subband and zero) using inverse fast fourier transform (IFFT) to be switched to is suitable for to obtain to comprise N _FCode element after the individual conversion that is suitable for sampling.For anti-intersymbol interference (ISI), each part that is converted code element often is repeated (this also is called as and adds Cyclic Prefix), and to form corresponding OFDM code element, it is sent out on wireless channel then.The OFDM code-element period also is called as code-element period at this, corresponding to the duration of an OFDM code element.

1. beacon pilot frequency

Beacon pilot frequency comprises from N _TThe special pilot code element set of each transmission of individual transmitting antenna.Identical pilot frequency code element is integrated into the N into beacon pilot frequency transmission appointment _BSend on the individual code-element period.General N _BCan be one or bigger any integer value.

In example embodiment, the set of the pilot frequency code element of beacon pilot frequency is 12 BPSK modulated symbol set of 12 particular sub-band, and this is called as " B " OFDM code element.The 12BPSK modulated symbol of B OFDM code element is presented in form 2.Signal values of zero is not used on the subband at remaining 52 and is sent out.

Table 2-pilot frequency code element

Subband index	Beacon pilot frequency b (k)	MIMO pilot tone p (k)	Subband index	Beacon pilot frequency b (k)	MIMO pilot tone p (k)	Subband index	Beacon pilot frequency b (k)	MIMO pilot tone p (k)	Subband index	Beacon pilot frequency b (k)	MIMO pilot tone p (k)
													0	0	-13	0	1-j	1	0	1-j	15	0	1+j
-26	0	-1-j	-12	-1-j	1-j	2	0	-1-j	16	1+j	-1+j
												-25	0	-1+j	-11	0	-1-j	3	0	-1-j	17	0	-1+j
-24	1+j	-1+j	-10	0	-1-j	4	-1-j	-1-j	18	0	1-j
												-23	0	-1+j	-9	0	1-j	5	0	-1+j	19	0	1+j
-22	0	1-j	-8	-1-j	-1-j	6	0	1+j	20	1+j	-1+j
												-21	0	1-j	-7	0	1+j	7	0	-1-j	21	0	1+j
-20	-1-j	1+j	-6	0	-1+j	8	-1-j	-1+j	22	0	-1+j
												-19	0	-1-j	-5	0	-1-j	9	0	-1-j	23	0	1+j
-18	0	-1+j	-4	1+j	-1+j	10	0	1+j	24	1+j	-1+j
												-17	0	1+j	-3	0	-1+j	11	0	1-j	25	0	1-j
-16	1+j	-1+j	-2	0	1-j	12	1+j	-1+j	26	0	-1-j
												-15	0	1-j	-1	0	-1+j	13	0	-1-j		0	0
-14	0	1+j	0	0	0	14	0	0

For the example embodiment that illustrates in the form 2, for beacon pilot frequency, BPSK modulated symbol (1+j) is at subband-24, is sent out in-16 ,-4,12,16,20 and 24, and BPSK modulated symbol-(1+j) at subband-20 is sent out on-12 ,-8 ,-4 and 8.Signal values of zero is sent out on 52 subbands of residue of beacon pilot frequency.

B OFDM code element is designed to make things convenient for client terminal system timing and frequency to obtain.For above-mentioned B OFDM example embodiment, only use 12 in 64 total subbands, and these intersubbands distances are four subbands.This 4 intersubband is apart from allowing user terminal that the nearly initial frequency errors of two subbands is arranged.Beacon pilot frequency allows user terminal to correct its initial coarse frequency error, and corrects its frequency, make the phase drift of beacon pilot frequency on the duration very little (for example the sampling rate of 20MHz be in beacon pilot frequency on the duration less than 45 degree).If the beacon pilot frequency duration is 8 μ sec, then equal 360 degree on 64 μ sec at 45 on 8 μ sec degree (or littler) phase drift, this is roughly 16kHz.

The 16kHz frequency error is generally excessive for operation.Can use MIMO pilot tone and carrier pilot to obtain additional frequency corrects.These pilot tones are topped the sufficiently long duration, make the user terminal frequency can be corrected in the expectation target (for example 250Hz).For example, if tdd frame is 2 milliseconds (as described below) and the user terminal frequency be accurate in the 250Hz, then on a tdd frame, have phase change less than half cycle.Phase difference between the tdd frame of beacon pilot frequency can be used for the clock of user terminal frequency lock to access point, thereby effectively frequency error is reduced to zero.

Generally, the pilot frequency code element set that is used for beacon pilot frequency can use any modulation scheme to derive.Therefore, can also use other OFDM code elements of BPSK or some other modulation schemes for beacon pilot frequency, and this within the scope of the present invention.

In example design, four transmitting antennas can be used for the beacon pilot frequency transmission.Form 4 is listed for the beacon pilot frequency transmission of topped two code-element periods will be from each OFDM code element that is sent out of four transmitting antennas.

Form 3-beacon pilot frequency

Code-element period	Antenna	1	Antenna 2	Antenna 3	Antenna 4
						1	B	B	B	B
2	B	B	B	B

2.MIMO pilot tone

The MIMO pilot tone comprises from N _TThe special pilot code element set of each transmission of individual transmitting antenna.For each transmitting antenna, be the N of MIMO pilot transmission appointment _PThe individual code element period sends the set of same pilot code element.Yet, the pilot frequency code element set of each transmitting antenna unique orthogonal sequence or the sign indicating number " covering " of distributing to this antenna.Covering is the given pilot tone that will send or data symbols L pilot/data code element set of identical value (or have) all L chip of multiply by L chip orthogonal sequence to obtain L the covering process that then is sent out of code element afterwards.Going to cover is the complementary process that covers, and L the chip that the code element that promptly receives multiply by identical L chip orthogonal sequence goes to cover code element to obtain L, and they are estimated with the pilot tone or the data symbols that obtain to send through adding up then.Cover and obtain from N _TThe N of individual transmitting antenna _TOrthogonality between individual pilot transmission, and allow receiver to distinguish single transmitting antenna, as described below.The spy of MIMO pilot transmission is depended on its use at the continuous time, and is as described below.General N _PCan be to be one or bigger any integer value.

One of pilot frequency code element set or different sets can be used for N _TIndividual transmitting antenna.In an example embodiment, a pilot frequency code element set is used for all N for the MIMO pilot tone _TIndividual transmitting antenna, and this set comprises 52 QPSK modulated symbols of 52 available subbands, this is called as " P " OFDM code element.52 QPSK modulated symbols of P OFDM code element provide in form 2.Be that zero signal value does not use on the subband at remaining 12 and sends.

52 QPSK modulated symbols form unique " word ", are used to make things convenient for the channel estimating of user terminal.This unique word is selected as having the variation of minimum peak to mean value in the waveform that generates based on 52 modulated symbols.

The crowd knows that OFDM generally compares flat variation the in higher peak than the transmitted waveform of other modulation techniques (for example CDMA) and is associated.Therefore, the circuit slicing (for example power amplifier) on the transmitting chain, then the OFDM code element generally sends with the power level that reduces, promptly from peak transmitted power level rollback.Rollback is used to consider the wave form varies of OFDM code element.Change by peak in the waveform that minimizes P OFDM code element is flat, the MIMO pilot tone can send (promptly the MIMO pilot tone being used less rollback) with higher power level.The transmitting power that the MIMO pilot tone is higher can cause the signal quality that receives in the improvement of the MIMO of receiver place pilot tone then.The flat variation in littler peak also can reduce distortion and the amount of nonlinearity that transmits and receives circuit generation in the chain.These various factors can cause the accuracy based on the channel estimating improvement of MIMO pilot tone acquisition.

Having the flat OFDM code element that changes of smallest peaks can obtain in every way.For example, can under a large amount of pilot frequency code element collection formation situations at random, carry out random search, and have the flat set that changes of smallest peaks to find through assessment.The POFDM code element form that illustrates in the form 2 can be used for the example OFDM code element of MIMO pilot tone.Generally, the pilot frequency code element set that is used for the MIMO pilot tone can use any modulation scheme to derive.Therefore, the various OFDM code elements of using QPSK or some other modulation schemes to derive also can be used for the MIMO pilot tone, and this within the scope of the present invention.

Can use various orthogonal codes to cover N _TThe P OFDM code element that sends on the individual transmitting antenna.This kind orthogonal code example comprises Walsh sign indicating number and orthogonal variable spreading factor (OVSF) sign indicating number.Pseudo noise code and quasiorthogonal code can also be used to cover P OFDM code element.One example of pseudorandom orthogonal code is a M sequence well-known in the art.The quasiorthogonal code example is the Quasi Orthogonal Function (QOF) of IS-2000 definition.Generally, can use various types of sign indicating numbers to be used for covering, some of them are in above description.For simplicity, at this use " orthogonal code " speech to refer to any code type that covers pilot frequency code element that is applicable to.Orthogonal code length (L) is selected as more than or equal to number of transmit antennas (L 〉=N for example _T), and L orthogonal code can be used.Each transmitting antenna is assigned with unique orthogonal code.At N from each transmitting antenna _PThe N that sends in the individual code-element period _PIndividual P OFDM code element covers with the orthogonal code of distributing to this transmitting antenna.

In example embodiment, four transmitting antennas can be used, and are assigned with 4 chip Walsh sequences, W for the MIMO pilot tone ₁=1111, W ₂=1010, W ₃=1100, W ₄=1001.For given Walsh sequence, value " 1 " indicates and sends P OFDM code element, and value " 0 " indicates transmission one P OFDM code element.For a P OFDM code element, each of 52 QPSK modulated symbols in the P OFDM code element is through counter-rotating (promptly multiply by-1).The result that each transmitting antenna covers is the P OFDM sequence of symhols that this transmitting antenna covers.Covering is actually each subband and separately realizes to generate the covering pilot frequency code element sequence of this subband.The covering pilot frequency code element sequence of all subbands forms and covers P OFDM sequence of symhols.

Form 4 is listed as the MIMO pilot transmission of crossing over four code-element periods will be from the OFDM code element of each transmission of four transmitting antennas.

Form 4-MIMO pilot tone

Code-element period	Antenna	1	Antenna 2	Antenna 3	Antenna 4
						1	+P	+P	+P	+P
2	+P	-P	+P	-P
					3	+P	+P	-P	-P
4	+P	-P	-P	+P

For this 4 chip Walsh arrangement set, the MIMO pilot transmission can occur in the integral multiple of four code-element periods to guarantee from the orthogonality between four pilot transmission of four transmitting antennas.The Walsh sequence simply repeats for the MIMO pilot transmission of being longer than the Walsh sequence length.

For subband index k ∈ K, wherein for exemplary sub-band structure K=described above ± { 1...26}, the wireless channel of MIMO-OFDM system can be used channel response matrix H(k) set description.Each subband matrix H(k) comprise N _TN _RIndividual value { h _{I, j}(k) }, i ∈ { 1...N wherein _RAnd j ∈ { 1...N _T, h wherein _{I, j}(k) channel gain between j transmitting antenna of expression and i reception antenna.

The MIMO pilot tone can be used to estimate the response of wireless channel by receiver.Particularly, for the pilot tone of recovering to send and recovered by reception antenna i from transmitting antenna j, the OFDM code element that receives on the antenna i at first multiply by the Walsh sequence of distributing to transmitting antenna j.All N of the MIMO pilot tone that adds up then _P" go cover " OFDM code element of individual code-element period, wherein add up can be individually to each realizations of 52 available subbands.Add up and can also the OFDM code element that receive be realized (after the Cyclic Prefix of having removed each OFDM code element) in time domain.Add up and also on the basis of each sampling on a plurality of OFDM of receiving code elements, realize, if realize then the corresponding different subband of sampling of each OFDM code element after wherein being accumulated in FFT, if realize then corresponding different time index before being accumulated in FFT.The result who adds up is

K ∈ K wherein, they are that the channel response from transmitting antenna j to reception antenna i is estimated for 52 available subbands.Can realize that identical processing is to estimate the channel response from each transmitting antenna to each reception antenna.Pilot tone is treated to each subband N is provided _TN _RIndividual complex values, wherein complex values is the channel response estimated matrix of this subband

Element.

Above-mentioned pilot tone is handled and can be realized estimating with the channel response that obtains up link by access point And can also realize estimating by user terminal with the channel response that obtains down link

3. handle benchmark or handle pilot tone

For the MIMO-OFDM system, the channel response matrix of each subband H(k) can " diagonalization " to obtain the N of this subband _SIndividual eigenmodes, wherein N _S≤ min{N _T, N _R.This can pass through channel response matrix H(k) realize singular value decomposition or right H(k) correlation matrix is realized eigen value decomposition and is realized that described correlation matrix is R(k)= H ^H(k) H(k).For clear, for singular value decomposition is used in following description.

Channel response matrix H(k) singular value decomposition can be expressed as:

H(k)＝ U(k) ∑(k) V ^H(k)，k∈K， (1)

Wherein U(k) be H(the N of left eigenvector (k) _R* N _R) unitary matrix;

∑(k) be H(the N of singular value (k) _R* N _T) diagonal matrix;

V(k) be H(the N of right eigenvector (k) _T* N _T) unitary matrix; And

" ^H" the expression conjugate transpose.

Unitary matrix MWith M ^H M= ICharacteristic description, wherein IIt is unit matrix.

Singular value decomposition further is entitled as " Linear Algebra and ItsApplications " second edition at Gilbert Strang, describe in further detail among the Academic Press 1980.Eigenmodes refers generally to The Theory Construction.Mimo channel can also be considered and comprise the N that can be used for data/pilot transmission _SIndividual space channel.Each space channel may or may not corresponding eigenmodes, and whether this spatial manipulation that depends on the transmitter place is successfully to the mimo channel diagonalization.For example, if transmitter is not known or have only the imperfection of mimo channel to estimate that then data flow is sent out on the space channel (and not being eigenmodes) of mimo channel.For simplicity, " eigenmodes " speech is used herein to the situation that the diagonalization mimo channel is attempted in expression, though it may the not exclusively success owing to the imperfection channel estimating.

The diagonal matrix of each subband ∑(k) comprise along cornerwise non-negative real-valued, all the other places are zero.These diagonal angle items are called as H(k) singular value, and represent the independent channel (or eigenmodes) of the mimo channel of k subband.

Eigen decomposition can be each channel response matrix of 52 available subbands H(k) the independent realization to determine the N of this subband _SIndividual eigenmodes.Each diagonal matrix ∑(k) singular value can make through ordering $\{{\mathrm{\σ}}_1\left(k\right)\≥{\mathrm{\σ}}_1\left(k\right)\≥...\≥{\mathrm{\σ}}_{N_S}\left(k\right)\},$ σ wherein ₁(k) be maximum singular value, σ ₂(k) be second largest singular value etc., and σ _NS(k) be the minimum singular value of k subband.When to each diagonal matrix ∑When singular value (k) sorts, correlation matrix U(k) and V(k) eigenvector (or row) correspondingly is sorted.After ordering, σ ₁(k) singular value of the best eigenmodes of expression subband k, this also is called as " master " eigenmodes.

" broadband " eigenmodes can be defined in the same order eigenmodes set of all subbands of ordering back.Therefore, m broadband eigenmodes comprises m eigenmodes of all subbands.The eigenmodes in each broadband is relevant with the corresponding eigenvector set of all subbands." master " eigenmodes is and each matrix of each subband afterwards that sorts

The eigenmodes that interior maximum singular value is relevant.

Matrix V(k) comprise the N that can be used for transmitter place spatial manipulation _TIndividual eigenvector, wherein $\underset{\‾}{V}\left(k\right)=\left[\begin{array}{cccc}{\underset{\‾}{v}}_1\left(k\right)& {\underset{\‾}{v}}_2\left(k\right)& ...& {\underset{\‾}{v}}_{N_T}\left(k\right)\end{array}\right]$ And v _m(k) be V(k) m row, wherein V(k) be the eigenvector of m eigenmodes.For unitary matrix, eigenvector is mutually orthogonal.Eigenvector also is called as " manipulation " vector.

Handling benchmark (promptly handling pilot tone) comprises one or more from N _TThe pilot frequency code element set that individual transmitting antenna sends.In one embodiment, the set of pilot frequency code element is sent out by closing in a subband set of a broadband eigenmodes in given code-element period with the manipulation vector set implementation space processing of this broadband eigenmodes.In another embodiment, a plurality of pilot frequency code element set are handled and are sent out on a plurality of non-intersect sets of subbands of a plurality of broadbands eigenmodes in given code-element period by a plurality of manipulation vector set (use subband multiplexed, this is in the following description) implementation space with these broadband eigenmodes.For clear, below describe hypothesis and in given code-element period, on a broadband eigenmodes, send a pilot frequency code element set (that is, no subband is multiplexed).

In one embodiment, the pilot frequency code element of handling benchmark is gathered identical with the P OFDM code element that is used for the MIMO pilot tone.Yet various other OFDM code elements can also be used to handle benchmark, and this within the scope of the invention.

The manipulation benchmark (use beam shaping, this can in following description) that is the transmission of m broadband eigenmodes can be expressed as:

x _m(k)＝ v _m(k)·p(k)，k∈K， (2)

Wherein x _m(k) be (N of m eigenmodes of k subband _T* 1) emission vector;

v _m(k) be the manipulation vector of m eigenmodes of k subband; And

P (k) is the pilot frequency code element (for example as providing in the form 2) of k subband.

Vector x _m(k) comprise from the N of k subband _TThe N that individual transmitting antenna sends _TIndividual transmit symbol.

Handling benchmark can be used to estimate a vector by receiver, and this vector can be used for the spatial manipulation of Data Receiving and transmission, and is as described below.The processing of handling benchmark is described in further detail following.

4. carrier pilot

Above-mentioned example OFDM sub band structure comprises that having index is-21, four pilot subbands of-7,7 and 21.In one embodiment, carrier pilot is sent out on four pilot subbands in all are not used in the code-element period of some other types pilot tones.Carrier pilot can by receiver be used to follow the tracks of the RF carrier signal phase changes and transmitter and receiver place oscillator in drift.This can provide the data demodulates performance of improvement.

In one embodiment, carrier pilot comprises four pilot frequency sequence P _C1(n), P _C2(n), P _C3(n) and P _C4(n), they send on four pilot subbands.In one embodiment, four pilot frequency sequences are defined as follows:

P _c1(n)＝P _c2(n)＝P _c3(n)＝-P _c4(n)， (3)

Wherein n is the index of pilot period (or OFDM code element).

Pilot frequency sequence can be defined based on each data sequence.In one embodiment, pilot frequency sequence P _C1(n) based on multinomial G (x)=x ⁷+ x ⁴+ x generates.Wherein initial condition be set to complete one, and following signal value 1 -1 and 0  1 of being mapped to of output bit.Pilot frequency sequence P _C1(n), n={1 wherein, 2 ... 127}, and can be represented as:

P _c1(n)＝{1，1，1，1，-1，-1，-1，1，-1，-1，-1，-1，1，1，-1，1，-1，-1，1，1，-1，1，1，-1，1，1，1，1，1，1，-1，1，1，1，-1，1，1，-1，-1，1，1，1，-1，1，-1，-1，-1，1，-1，1，-1，-1，1，-1，-1，1，1，1，1，1，-1，-1，1，1，-1，-1，1，-1，1，-1，1，1，-1，-1，-1，1，1，-1，-1，-1，-1，1，-1，-1，1，-1，1，1，1，1，-1，1，-1，1，-1，1，

-1，-1，-1，-1，-1，1，-1，1，1，-1，1，-1，1，1，1，-1，-1，1，-1，-1，-1，1，1，1，-1，-1，-1，-1，-1，-1，1}

Pilot frequency sequence P _C1(n) Nei value " 1 " and " 1 " can use certain modulation schemes to be mapped to pilot frequency code element.For example use BPSK, " 1 " can be mapped to 1+j, and " 1 " can be mapped to-(1+j).If have more than 127 OFDM code elements, then pilot frequency sequence can be repeated, and makes P _C1(n)=P _C1(n mod 127), wherein n＞127.

In one embodiment, four pilot frequency sequence P _C1(n), P _C2(n), P _C3(n) and P _C4(n) four different sub-band/antennas on be sent out.Form 5 illustrates four pilot frequency sequences is assigned to four pilot subbands and four transmitting antennas.

Form 5

Subband	Antenna	1	Antenna 2	Antenna 3	Antenna 4
						-21	P c1(n)	-	-	-
-7	-	P c2(n)	-	-
					7	-	-	P c3(n)	-
21	-	-	-	P c4(n)

As pilot frequency sequence P is shown in the form 5 _C1(n) on the subband-21 of antenna 1, be sent out pilot frequency sequence P _C2(n) on the subband-7 of antenna 2, be sent out pilot frequency sequence P _C3(n) on the subband 7 of antenna 3, be sent out, and pilot frequency sequence P _C4(n) on the subband 21 of antenna 4, be sent out.Therefore each pilot frequency sequence is sent out on unique subband and unique antenna.If this carrier pilot transmission plan has been avoided the pilot frequency sequence interference that transmission can cause on a plurality of transmitting antennas on the given subband.

In another embodiment, four pilot frequency sequences are sent out on the main eigenmodes of the subband of its distribution.The spatial manipulation of carrier pilot code element is similar to the spatial manipulation of handling benchmark, and this can abovely describe and illustrate in equation (2).In order on main eigenmodes, to send carrier pilot, handle vector v ₁(k) be used for spatial manipulation.Therefore, pilot frequency sequence P _C1(n) with handling vector v ₁(26) through spatial manipulation, P _C2(n) with handling vector v ₁(7) through spatial manipulation, pilot frequency sequence P _C3(n) with handling vector v ₁(7) through spatial manipulation, pilot frequency sequence P _C4(n) with handling vector v ₁(26) through spatial manipulation.

II. the pilot tone of single carrier mimo system

Pilot tone described here can also be used for not using the single carrier mimo system of OFDM.In this case, above-mentioned many descriptions are still available but do not need subband index k.For beacon pilot frequency, special pilot modulated symbol b can be from N _TEach transmission of individual transmitting antenna.For the MIMO pilot tone, special pilot modulated symbol p can use N _TIndividual orthogonal sequence covers, and from N _TIndividual transmitting antenna sends.Pilot frequency code element b can be identical or different with pilot frequency code element p.Handling benchmark can be as the transmission that illustrates in the equation (2).Yet, send vector x _m, handle vector v _mWith pilot frequency code element p be not the function of subband index k.Carrier pilot can be sent out or can be omitted simply in the time division multiplexing mode.

For the MIMO-OFDM system, Cyclic Prefix generally is used to guarantee that the orthogonality of striding subband under the time delay expansion situation is arranged in system, and orthogonal code can identify single transmitting antenna.For the single carrier mimo system, orthogonal code relies on orthogonality and antenna sign.Therefore, the orthogonal code that is used in the single carrier mimo system covering pilot frequency code element can selectedly be to have good cross-correlation and peak value to sidelobe performance (very little when being correlated with between any two orthogonal sequences that promptly are used to cover has time delay expansion in system).The orthogonal code that this kind had cross-correlation and peak sidelobe performance is M sequence and its time shift version.Yet the other types sign indicating number also can be used to cover the pilot frequency code element of single carrier mimo system.

For the broadband single-carrier mimo system, handle benchmark and can be sent out in every way to consider frequency selective attenuation (promptly on working band not mild frequency response).Several schemes of manipulation benchmark that send in the broadband single-carrier mimo system are at following detailed description.Generally, transmitter can send reference waveform, and they are treated with the identical or similar mode of processing that is used for transmission data on the eigenmodes of specific broadband.Receiver can be relevant with the copy of the reference waveform of the local transmission that generates with receiving waveform, and extract the channel information that allows receiver estimation channel matched filter.

In first scheme, be that eigenmodes obtains to handle vector when transmitter begins v _m(k).Handle vector v _m(k) can be by periodically sending the OFDM pilot frequency code element, by not obtaining to the frequency-domain analysis that receives the MIMO pilot tone that sent by OFDM or by some modes.For each k value, wherein 1≤k≤N _F, v _m(k) be to have N _TThe N of individual transmitting antenna _TThe N of item _T-vector.This transmitter is then to handling vector v _m(k) N _TIndividual vector position carries out inverse fast fourier transform, and k is that IFFT calculates interior frequency variable to obtain the corresponding time domain pulse of associated transmit antennas.Vector v _m(k) each vector position comprises N _FThe N of individual frequency subband _FIndividual value, and corresponding time domain pulse is N _FIndividual time domain value sequence.Terminal appends to Cyclic Prefix this time domain pulse then to obtain the manipulation benchmark of transmitting antenna.For each eigenmodes generates N _TIndividual manipulation benchmark set, and can be from all N _TIndividual transmitting antenna is sent out in identical time slot.Can be for a plurality of eigenmodes generate a plurality of pulse collections, and can be sent out in the TDD mode.

For first scheme, receiver is to receiving signal sampling to obtain to receive vector τ _m(n), remove Cyclic Prefix and to receiving vector τ _m(n) each vector position realizes that fast fourier transform is to obtain H(k) v _m(k) respective items is estimated.Receive vector τ _m(n) each vector position (after Cyclic Prefix is removed) comprises N _FIndividual time-domain sampling.Receiver uses then H(k) v _m(k) estimation is with synthetic time domain matched filter, and described filter can be used for receiving transfer of data filtering.The time domain matched filter comprises the matched filtering pulse of each reception antenna.The time domain matched filter synthesizes in No. 10/017308 U.S. Patent application sequence of public distribution to be described, be entitled as " Time-Domain Transmit and Receive Processing with Channel Eigen-modeDecomposition for MIMO Systems ", be filed in December 7 calendar year 2001.

For first scheme, the transmitter processes of the manipulation benchmark in the single carrier mimo system is similar to the transmitter processes of the intrasystem manipulation benchmark of MIMO-OFDM.Yet other after handling benchmark are transmitted on the single carrier waveform and send, such as what describe in aforementioned No. 10/017308 U.S. Patent Application Serial Number.And receiver uses handles benchmark with the synchronous time domain matched filter, as mentioned above.

In alternative plan, transmitter is isolated the single multipath component of broad-band channel.This can be by for example receiving the MIMO pilot tone with slip (sliding) correlator search and realize to be similar in cdma system mode that the search multipath component often uses.The single manipulation vector of multipath component acquisition of each eigenmodes handled this multipath component and is then by transmitter as narrow band channel v _mEqually, can generate a plurality of manipulation vectors for a plurality of eigenmodes of this multipath component.

The pilot configuration of III.TDD MIMO-OFDM system

Pilot tone described here can be used for various MIMO and MIMO-OFDM system.These pilot tones can be used to use down link and up link is public or the system of separate bands.For clear, the example pilot configuration of example MIMO-OFDM system is in following description.For this MIMO-OFDM system, down link and up link are the time division duplexs (TDD) on the single frequency band.

Fig. 2 illustrates frame structure 200 embodiment that can be used for TDD MIMO-OFDM system.Transfer of data occurs in the tdd frame unit, and each frame strides across the specific duration (for example 2 milliseconds).Each tdd frame is divided into downlink phase and uplink phase.Downlink phase further is divided into a plurality of segmentations of a plurality of downlink transmission channel.Among the embodiment that illustrates in Fig. 2, downlink transmission channel comprises broadcast channel (BCH), forward control channel (FCCH) and forward channel (FCH).Similarly, uplink phase is divided into a plurality of segmentations of a plurality of uplink transmission channels.Among the embodiment that illustrates in Fig. 2, uplink transmission channels comprises backward channel (RCH) and Random Access Channel (RACH).

On down link, BCH segmentation 210 is used to send a BCH protocol Data Unit (PDU) 212, and this comprises beacon pilot frequency part 214, MIMO pilot portion 216 and BCH message part 218.BCH message is carried the system parameters of user terminal in the system.FCCH segmentation 220 is used to send a FCCH PDU, and it carries the distribution that is used for down link and uplink resource and carries other signalings for the user.FCH segmentation 230 is used to send one or more FCH PDU232.Can define dissimilar FCH PDU.For example, FCH PDU 232a comprises pilot portion 234a and packet part 236a.FCH PDU 232b comprises the single part 236b of packet.FCH PDU 232c comprises the single part 234c of pilot tone.

On up link, RCH segmentation 240 is used for sending one or more RCH PDU 242 on up link.Can also define dissimilar RCH PDU.For example, RCH PDU 242a comprises the single part 246a of packet.RCH PDU 242b comprises pilot portion 244b and packet part 246b.RCH PDU 242c comprises the single part 244c of pilot tone.RACH segmentation 250 is used for connecting system by user terminal and sends SMS message on up link.RACH PDU 252 can send and comprise pilot portion 254 and message part 256 in RACH segmentation 250.

For the embodiment shown in Fig. 2, beacon and MIMO pilot tone are sent out on down link in each tdd frame of BCH segmentation.Pilot tone may or may not be sent out in any given FCH/RCH PDU.If sent this pilot tone, then it may occupy all or the part of PDU, illustrates as Fig. 2.Pilot tone is sent out in RACH PDU to allow the associated vector between access point estimation access periods.Pilot portion also is called as " targeting sequencing ".The pilot tone that sends in any given FCH/RCH PDU can be to handle benchmark or MIMO pilot tone, and this depends on the purpose of using pilot tone.The pilot tone that sends in RACH PDU generally is to handle benchmark, can send the MIMO pilot tone though replace.Carrier pilot is in pilot subbands and be not used in the part of other pilot tones and be sent out.Carrier pilot does not illustrate in Fig. 2 for simplicity.The various piece duration in Fig. 2 does not draw in proportion.

Frame structure that illustrates in Fig. 2 and transmission channel are described in No. 60/421309 above-mentioned U.S. Provisional Patent Application.

1. calibration (calibration)

For having the TDD MIMO-OFDM system of sharing frequency band, down link and uplink channel responses can be assumed to be reciprocity each other.If promptly H(k) the channel response matrix of expression subband k from aerial array A to aerial array B, then reciprocal channel mean from array B to array A coupling by H ^T(k) provide, wherein H ^TExpression HTransposition.For TDD MIMO-OFDM system, the reciprocal channel characteristic can be utilized to simplify the spatial manipulation at channel estimating and transmitter and receiver place.

Yet the frequency response that transmits and receives chain at access point place generally is different from the frequency response that transmits and receives chain at user terminal place.Comprise applicable " effectively " downlink channel response that transmits and receives the chain response H _Dn(k) and the uplink channel responses of " effectively " H _Up(k) can be expressed as:

H _dn(k)＝ R _ut(k) H(k) T _ap(k)， k∈K， (4)

H _ap(k)＝ R _ap(k) H ^T(k) T _ut(k)，k∈K，

Wherein T _Ap(k) and R _Ap(k) be the frequency response N of subband k in access point place emission chain and the response of reception chain _Ap* N _ApDiagonal matrix;

T _Ut(k) and R _Ut(k) be that subband k is in user terminal place emission chain and reception chain corresponding N _Ut* N _UtDiagonal matrix;

N _ApIt is the antenna number at access point place; And

N _UtIt is the antenna number at user terminal place.

With the combination of the equation in the equation set (4), obtain following result:

H _up(k) K _ut(k)＝( H _dn(k) K _ap(k)) ^T，k∈K， (5)

Wherein K _Ut(k)= T _Ut ^-1(k) R _Ut(k) and K _Ap(k)= T _Ap ^-1(k) R _Ap(k).Because T _Ut(k), R _Ut(k), T _Ap(k) and R _Ap(k) be diagonal matrix, K _Ut(k) and K _Ap(k) also be diagonal matrix.

Can realize that calibration is to obtain actual diagonal matrix K _Ap(k) and K _Ut(k) estimation With

K ∈ K wherein.Matrix

With

The correction factor that comprises the difference of the frequency response of considering access point and user terminal place transmit.User terminal observed " calibration back " downlink channel response H _Cdn(k) and access point observed " calibration back " uplink channel responses H _Cup(k) can be expressed as:

${\underset{\‾}{H}}_{\mathrm{cdn}}\left(k\right)={\underset{\‾}{H}}_{\mathrm{dn}}\left(k\right){\underset{\‾}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right),k\∈K,---\left(6a\right)$

${\underset{\‾}{H}}_{\mathrm{cup}}\left(k\right)={\underset{\‾}{H}}_{\mathrm{up}}\left(k\right){\underset{\‾}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right),k\∈K,---\left(6b\right)$

${\underset{\‾}{H}}_{\mathrm{cdn}}\left(k\right)\≈{\underset{\‾}{H}}_{\mathrm{cup}}^T\left(k\right),k\∈K.---\left(6c\right)$

The accuracy that concerns in the equation (6c) depends on correlation matrix With

Accuracy, this then depends on and is used to derive active downlink and the uplink channel responses that these correct matrixes

With

Estimated quality.Correct vector

Can be defined as including only N _UtIndividual diagonal entry, and correct vector

Can be defined as including only

N _ApIndividual diagonal entry.Be aligned in aforesaid No. 60/421462 U.S. Patent Application Serial Number and describe in detail.

Pilot tone described here can also be used for not realizing the MIMO and the MIMO-OFDM system of calibrating.For clear, below describe hypothesis and realize calibration and correct matrix

With

Be respectively applied in the transmission path at access point and user terminal place.

2. beacon and MIMO pilot tone

As illustrating in Fig. 2, beacon pilot frequency and MIMO pilot tone are sent out on down link in the BCH of each tdd frame.Beacon pilot frequency can be used for regularly and frequency is obtained by user terminal.The MIMO pilot tone can be used for (1) by user terminal and obtain the downlink mimo channel estimating, and (2) handle vector for ul transmissions derives, and (3) are as described below for downlink transmission derivation matched filter.

In an example pilot transmission schemes, beacon pilot frequency is sent out in two code-element periods, and the MIMO pilot tone is sent out in eight code-element periods after the BCH segmentation begins.Form 6 illustrates the beacon and the MIMO pilot tone of this exemplary scenario.

The beacon of form 6-BCH and MIMO pilot tone

The beacon pilot frequency that sends on down link can be expressed as:

${\underset{\‾}{x}}_{\mathrm{dn},\mathrm{bp}}\left(k\right)={\underset{\‾}{\overset{^}{k}}}_{\mathrm{ap}}\left(k\right)b\left(k\right),k\∈K,---\left(7\right)$

Wherein x _{Dn, bp}(k) be the emission vector of the subband k of beacon pilot frequency; And

B (k) is the pilot frequency code element that beacon pilot frequency sends on subband k, and this provides in form 2.

As illustrating in the equation (7), beacon pilot frequency is by correcting vector

Through proportional zoom, but without any other spatial manipulation.

The MIMO pilot tone that sends on down link can be expressed as:

${\underset{\‾}{x}}_{\mathrm{dn},\mathrm{mp},n}\left(k\right)={\underset{\‾}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right){\underset{\‾}{w}}_{\mathrm{dn},n}p\left(k\right),k\∈K,---\left(8\right)$

Wherein x _{Dn, mp, n}(k) be (N of the subband k of downlink mimo pilot tone in code-element period n _Ap* 1) emission vector;

w _{Dn, n}Be downlink mimo pilot tone N at the access point place in code-element period n _ApIndividual transmitting antenna have a N _Ap(the N of individual Walsh chip _Ap* 1) vector; And

P (k) is the pilot frequency code element that the MIMO pilot tone sends on subband k, and this provides in form 2.

As illustrating in the equation (8), the MIMO pilot tone is by vector w _{Dn, n}Cover, and further by correcting matrix

Through proportional zoom, but without any other spatial manipulation.Identical Walsh vector w _{Dn, n}Be used for all subbands, and therefore w _{Dn, n}It or not the function of subband index k.Yet, because each Walsh sequence is unique sequence of 4 Walsh chips of 4 code-element periods, w _{Dn, n}It is the function of code-element period n.Vector w _{Dn, n}Therefore comprise the N that is used in the access point code-element period n _ApThe N of individual transmitting antenna _ApIndividual Walsh chip.For the scheme that illustrates in the form 6, four vectors of preceding four code-element periods of MIMO pilot transmission on BCH w _{Dn, n}, n={3 wherein, 4,5,6} is w ₃=[1 11 1], w ₄=[1-1 1-1], w ₅=[1 1-1-1] and w ₆=[1-1-1 1], and repeat for following four code-element periods, four vectors w _{Dn, n}(n={7 wherein, 8,9,10}) make w ₇= w ₃, w ₈= w ₄, w ₉= w ₅With w ₁₀= w ₆

The MIMO pilot tone that sends on up link can be represented as:

${\underset{\‾}{x}}_{\mathrm{up},\mathrm{mp},n}\left(k\right)={\underset{\‾}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right){\underset{\‾}{w}}_{\mathrm{up},n}p\left(k\right),k\∈K,---\left(9\right)$

Wherein x _{Up, mp, n}(k) be (N of the subband k of up link MIMO pilot tone in chip period n _Ut* 1) emission vector.The Walsh vector that is used for up link MIMO pilot tone w _{Up, n}Can with the Walsh vector that is used for up link MIMO pilot tone w _{Dn, n}Identical or different.For example, if user terminal only is equipped with two transmitting antennas, then w _{Up, n}Comprise that length is 2 or two bigger Walsh sequences.

3. spatial manipulation

As described above, the channel response matrix of each subband can be through diagonalization to obtain the N of this subband _SIndividual eigenmodes.Calibration back uplink channel responses matrix H _Cup(k) singular value decomposition can be expressed as:

${\underset{\‾}{H}}_{\mathrm{cup}}\left(k\right)={\underset{\‾}{U}}_{\mathrm{ap}}\left(k\right)\underset{\‾}{\mathrm{\Σ}}\left(k\right){\underset{\‾}{V}}_{\mathrm{ut}}^H\left(k\right),k\∈K,---\left(10\right)$

Wherein U _Ap(k) be H _Cup(the N of left eigenvector (k) _Ut* N _Ut) unitary matrix;

∑(k) be H _Cup(the N of singular value (k) _Ut* N _Ap) diagonal matrix; And

V _Ut(k) be H _Cup(k) (the N of right eigenvector _Ap* N _Ap) unitary matrix.

Similarly, calibration back downlink channel response matrix H _Cdn(k) singular value decomposition can be expressed as:

${\underset{\‾}{H}}_{\mathrm{cdn}}\left(k\right)={\underset{\‾}{V}}_{\mathrm{ut}}^{*}\left(k\right)\underset{\‾}{\mathrm{\Σ}}\left(k\right){\underset{\‾}{U}}_{\mathrm{ap}}^T\left(k\right),k\∈K,---\left(11\right)$

Matrix wherein V _Ut ^*(k) and U _Ap ^*(k) be respectively H _CdnThe unitary matrix of left and right sides eigenvector (k).

As illustrating in equation (10) and (11), and based on above description, for other links, the left and right sides eigenvector matrix of a link is respectively the complex conjugate of right left eigenvector matrix.For simplicity, to the matrix in the following description U _Ap(k) and V _Ut(k) reference can be with reference to its various other forms (for example V _Ut(k) can refer to V _Ut(k), V _Ut ^*(k), V _Ut ^T(k) and V _Ut ^H(k)).Matrix U _Ap(k) and V _Ut(k) can correspondingly be used for spatial manipulation by access point and user terminal, and show as its subscript.

In one embodiment, user terminal can estimate to calibrate the back downlink channel response based on the MIMO pilot tone that is sent by access point.User terminal can be carried out calibration back downlink channel response then and estimate Singular value decomposition, k ∈ K wherein is to obtain each subband

The diagonal matrix of left eigenvector

And matrix

This singular value decomposition can be given ${\underset{\‾}{\overset{^}{H}}}_{\mathrm{cdn}}\left(k\right)={\underset{\‾}{\overset{^}{V}}}_{\mathrm{ut}}^{*}\left(k\right)\underset{\‾}{\overset{^}{\mathrm{\Σ}}}\left(k\right){\underset{\‾}{\overset{^}{U}}}_{\mathrm{ap}}^T\left(k\right),$ Wherein to indicate it be the estimation of actual matrix to the cap symbol " ^ " of each matrix.Similarly, access point can be estimated calibration back uplink channel responses based on the MIMO pilot tone that user terminal sends.Access point can be realized calibrating the back channel response and estimate Singular value decomposition, k ∈ K wherein is to obtain each subband The diagonal matrix of left eigenvector

And matrix

This singular value decomposition can be given ${\underset{\‾}{\overset{^}{H}}}_{\mathrm{cup}}\left(k\right)={\underset{\‾}{\overset{^}{U}}}_{\mathrm{ap}}\left(k\right)\underset{\‾}{\overset{^}{\mathrm{\Σ}}}\left(k\right){\underset{\‾}{\overset{^}{V}}}_{\mathrm{ut}}^H\left(k\right).$ Access point and user terminal can also be based on handling the eigenvector that benchmark obtains requirement, as described below.

Transfer of data can occur on one or more broadbands eigenmodes of each up link.The specific quantity that is used for the broadband eigenmodes of transfer of data generally depends on channel condition, and can select in every way.For example, the broadband eigenmodes can be selected by using the process of pouring water of attempting the maximization total throughout, maximize throughput is an optimal set of selecting to use one or more broadbands eigenmodes by (1), and (2) distribute total transmitting power between selected broadband eigenmodes.

Therefore the MIMO-OFDM system can be designed to support a plurality of operator schemes, comprise:

● spatial multiplexing modes-be used on the eigenmodes of a plurality of broadbands, sending data, and

● beam steering pattern-be used for sends data leading on the eigenmodes of (the best) broadband.

Transfer of data on the eigenmodes of a plurality of broadbands can be by using matrix U _Ap(k) or V _Ut(k) a plurality of eigenvector set implementation space in is handled and is obtained, wherein k ∈ K (being eigenvector set of each broadband eigenmodes).Form 7 has summed up access point and user terminal is sentenced the spatial manipulation of carrying out transfer of data and spatial multiplexing modes.

The spatial manipulation of form 7-spatial multiplexing modes

In form 7, s(k) be N at subband k _SThe nearly N of the modulated symbol that sends on the individual eigenmodes _S" data " vector of individual nonzero term, x(k) be the emission vector of subband k, r(k) be the vector that receives of subband k, and (k) be the data vector that sends s(k) estimation.Corresponding expression down link of these vectorial subscripts " dn " and ul transmissions with " up ".

Transfer of data on a broadband eigenmodes can be passed through or " beam shaping " or " beam steering " obtains.For beam shaping, for main broadband eigenmodes, modulated symbol eigenvector

Or Spatial manipulation, wherein k ∈ K are carried out in set.For beam steering, modulated symbol is used

Or

" normalization " (or " saturated ") eigenvector set through spatial manipulation k ∈ K wherein.The normalization eigenvector

With Can derive as described below.

The spatial manipulation of spatial multiplexing and beam steering pattern is described in aforesaid the interim the 60/421309th and No. 60/421428 U.S. Patent Application Serial Number.The manipulation benchmark of spatial multiplexing and beam steering pattern as described below.

4. manipulation benchmark

For reciprocal channel (reciprocal) (for example after the difference that realizes calibrating with the transmit of considering access point and user terminal place), handling benchmark can be sent and be used for obtaining by access point by user terminal

With Estimation, k ∈ K wherein, and do not need to estimate mimo channel or carry out singular value decomposition.Similarly, handling benchmark can be used for obtaining by the access point transmission and by user terminal

With

Estimation, k ∈ K wherein.

In one embodiment, handle benchmark and be included in the pilot frequency code element set (for example P OFDM code element) that sends on the inherent broadband eigenmodes of given code-element period, this is by carrying out spatial manipulation and realize with gathering without normalization or through normalized eigenvector of this broadband eigenmodes.In another embodiment, handle benchmark and be included in a plurality of pilot frequency code elements set that send on same symbol cycle inherent a plurality of broadbands eigenmodes, this is to carry out spatial manipulation and realize by a plurality of the set without normalization or through normalized eigenvector with these broadband eigenmodes.In either case, handle benchmark at the access point place from all N _ApIndividual antenna transmission (for down link), and at the user terminal place from all N _UtIndividual antenna transmission (for up link).For clear, below describing hypothesis manipulation benchmark is that a broadband eigenmodes sends in given code-element period.

A. down link is handled benchmark-spatial multiplexing modes

For spatial multiplexing modes, the down link that is sent by access point on m broadband eigenmodes is handled benchmark and can be expressed as:

${\underset{\‾}{x}}_{\mathrm{dn},\mathrm{sr},m}\left(k\right)={\underset{\‾}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right){\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},m}^{*}\left(k\right)p\left(k\right),k\∈K,---\left(12\right)$

Wherein x _{Dn, sr, m}(k) be the emission vector of k subband of m broadband eigenmodes;

It is the eigenvector of k subband of m broadband eigenmodes; And

P (k) is will be for handle the pilot frequency code element (for example as providing in the form 2) that benchmark sends on subband k.

Handle vector

It is matrix M row, wherein ${\underset{\‾}{\overset{^}{U}}}_{\mathrm{ap}}^{*}\left(k\right)=\left[\begin{array}{cccc}{\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},1}^{*}\left(k\right)& {\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},2}^{*}\left(k\right)& ...& {\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},N_{\mathrm{ap}}}^{*}\left(k\right)\end{array}\right].$

The down link that receives at the user terminal place of spatial multiplexing modes is handled benchmark and can be expressed as:

${\underset{\‾}{r}}_{\mathrm{dn},\mathrm{sr},m}\left(k\right)={\underset{\‾}{H}}_{\mathrm{dn}}\left(k\right){\underset{\‾}{x}}_{\mathrm{dn},\mathrm{sr},m}\left(k\right)+{\underset{\‾}{n}}_{\mathrm{dn}}\left(k\right),k\∈K,$ (13)

$\≈{\underset{\‾}{\overset{^}{v}}}_{\mathrm{ut},m}^{*}\left(k\right){\mathrm{\σ}}_m\left(k\right)p\left(k\right)+{\underset{\‾}{n}}_{\mathrm{dn}}\left(k\right)$

σ wherein _m(k) be the singular value of k subband of m broadband eigenmodes.

B. down link is handled benchmark-beam steering pattern

For the beam steering pattern, the spatial manipulation at transmitter place is to use " normalization " eigenvector set of main broadband eigenmodes to realize.Have the normalization eigenvector

Total transfer function be different from and have without the normalization eigenvector

Total transfer function (promptly ${\underset{\‾}{H}}_{\mathrm{dn}}\left(k\right){\underset{\‾}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right){\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},1}^{*}\left(k\right)\≠{\underset{\‾}{H}}_{\mathrm{dn}}\left(k\right){\underset{\‾}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right){\underset{\‾}{\overset{~}{u}}}_{\mathrm{ap}}\left(k\right)$ )。Use the manipulation benchmark of the normalization eigenvector set generation of main broadband eigenmodes can be used to the beam steering pattern to derive matched filter by the transmitter transmission and by receiver then.

For the beam steering pattern, the down link that is sent by access point on the eigenmodes of main broadband is handled benchmark and can be expressed as:

${\underset{\‾}{\overset{~}{x}}}_{\mathrm{dn},\mathrm{sr}}\left(k\right)={\underset{\‾}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right){\underset{\‾}{\overset{~}{u}}}_{\mathrm{ap}}\left(k\right)p\left(k\right),k\∈K,---\left(14\right)$

Wherein

Be the normalization eigenvector of k subband of main broadband eigenmodes, this can be expressed as:

${\underset{\‾}{\overset{~}{u}}}_{\mathrm{ap}}\left(k\right)={\left[\begin{array}{cccc}{\mathrm{Ae}}^{{\mathrm{j\θ}}_{n1}\left(k\right)}& {\mathrm{Ae}}^{{\mathrm{j\θ}}_{n2}\left(k\right)}& ...& {\mathrm{Ae}}^{{\mathrm{j\θ}}_{{\mathrm{nN}}_{\mathrm{ap}}}\left(k\right)}\end{array}\right]}^T,$

Wherein A is constant (for example A=1); And

θ _Ui(k) be the phase place of k subband of i transmitting antenna, this can be given:

${\mathrm{\θ}}_{\mathrm{ui}}\left(k\right)=\∠{\hat{u}}_{\mathrm{ap},1,i}^{*}\left(k\right)={\tan }^{-1}\left(\frac{\mathrm{Im}\left\{{\hat{u}}_{\mathrm{ap},1,i}^{*}\left(k\right)\right\}}{\mathrm{Re}\left\{{\hat{u}}_{\mathrm{ap},1,i}^{*}\left(k\right)\right\}}\right)$

As equation (15) vector is shown N _ApIndividual unit have identical amplitude, but phase place may be different.As in the equation (16) vector being shown

The phase place of each interior element is from vector

Corresponding element obtains (is θ _Ui(k) be from Middle acquisition, wherein ${\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},1}^{*}\left(k\right)={\left[\begin{array}{cccc}{\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},\mathrm{1,1}}^{*}\left(k\right)& {\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},\mathrm{1,2}}^{*}\left(k\right)& ...& {\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},1,N_{\mathrm{ap}}}^{*}\left(k\right)\end{array}\right]}^T$ )。

Receiving down link for the user terminal place of beam steering pattern handles benchmark and can be expressed as:

${\underset{\‾}{\overset{~}{r}}}_{\mathrm{dn},\mathrm{sr}}\left(k\right)={\underset{\‾}{H}}_{\mathrm{dn}}\left(k\right){\underset{\‾}{\overset{~}{x}}}_{\mathrm{dn},\mathrm{sr}}\left(k\right)+{\underset{\‾}{n}}_{\mathrm{dn}}\left(k\right),k\∈K.---\left(17\right)$

$\≈{\underset{\‾}{H}}_{\mathrm{cdn}}\left(k\right){\underset{\‾}{\overset{~}{u}}}_{\mathrm{ap}}\left(k\right)p\left(k\right)+{\underset{\‾}{n}}_{\mathrm{dn}}\left(k\right)$

C. up link is handled benchmark-spatial multiplexing modes

For spatial multiplexing modes, the up link manipulation benchmark that is sent on m broadband eigenmodes by user terminal can be represented as:

${\underset{\‾}{x}}_{\mathrm{up},\mathrm{sr},m}\left(k\right)={\underset{\‾}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right){\underset{\‾}{\overset{^}{v}}}_{\mathrm{ut},m}\left(k\right)p\left(k\right),k\∈K.---\left(18\right)$

Vector

It is matrix

M row, wherein ${\underset{\‾}{\overset{^}{V}}}_{\mathrm{ut}}\left(k\right)=\left[\begin{array}{cccc}{\underset{\‾}{\overset{^}{v}}}_{\mathrm{ut},1}\left(k\right)& {\underset{\‾}{\overset{^}{v}}}_{\mathrm{ut},2}\left(k\right)& ...& {\underset{\‾}{\overset{^}{v}}}_{\mathrm{ut},N_{\mathrm{ut}}}\left(k\right)\end{array}\right].$

The up link that the access point place of spatial multiplexing modes receives is handled benchmark and can be expressed as:

${\underset{\‾}{r}}_{\mathrm{up},\mathrm{sr},m}\left(k\right)={\underset{\‾}{H}}_{\mathrm{up}}\left(k\right){\underset{\‾}{x}}_{\mathrm{up},\mathrm{sr},m}\left(k\right)+{\underset{\‾}{n}}_{\mathrm{up}}\left(k\right),k\∈K.---\left(19\right)$

$\≈{\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},m}\left(k\right){\mathrm{\σ}}_m\left(k\right)p\left(k\right)+{\underset{\‾}{n}}_{\mathrm{ap}}\left(k\right)$

D. up link is handled benchmark-beam steering pattern

For the beam steering pattern, the up link that is sent by user terminal on the eigenmodes of main broadband is handled benchmark and can be expressed as:

${\underset{\‾}{\overset{~}{x}}}_{\mathrm{up},\mathrm{sr}}\left(k\right)={\underset{\‾}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right){\underset{\‾}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)p\left(k\right),k\∈K---\left(20\right)$

The normalization eigenvector of k subband of main broadband eigenmodes Can be expressed as:

${\underset{\‾}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)={\left[\begin{array}{cccc}{\mathrm{Ae}}^{{\mathrm{j\θ}}_{v1}\left(k\right)}& {\mathrm{Ae}}^{{\mathrm{j\θ}}_{v2}\left(k\right)}& ...& {\mathrm{Ae}}^{{\mathrm{j\θ}}_{{\mathrm{vN}}_{\mathrm{ut}}}\left(k\right)}\end{array}\right]}^T,---\left(21\right)$

Wherein

${\mathrm{\θ}}_{\mathrm{vi}}\left(k\right)=\∠{\hat{v}}_{\mathrm{ut},1,i}\left(k\right)={\tan }^{-1}\left(\frac{\mathrm{Im}\left\{{\hat{v}}_{\mathrm{ut},1,i}\left(k\right)\right\}}{\mathrm{Re}\left\{{\hat{v}}_{\mathrm{ut},1,i}\left(k\right)\right\}}\right)---\left(22\right)$

As in the equation (22) vector being shown

Each element phase place from eigenvector

Corresponding element obtain.

The access point place of beam steering pattern receives up link manipulation benchmark and can be expressed as:

${\underset{\‾}{\overset{~}{r}}}_{\mathrm{up},\mathrm{sr}}\left(k\right)={\underset{\‾}{H}}_{\mathrm{up}}\left(k\right){\underset{\‾}{\overset{~}{x}}}_{\mathrm{up},\mathrm{sr}}\left(k\right)+{\underset{\‾}{n}}_{\mathrm{up}}\left(k\right),k\∈K$

$\≈{\underset{\‾}{H}}_{\mathrm{cup}}\left(k\right){\underset{\‾}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)p\left(k\right)+{\underset{\‾}{n}}_{\mathrm{up}}\left(k\right)$ (23)

Form 8 has been summed up the spatial manipulation of the manipulation benchmark of spatial multiplexing and beam steering pattern at access point and user terminal place.

Form 8-handles the spatial manipulation of benchmark

E. handle the benchmark transmission

For the example frame structure that illustrates in Fig. 2, handling benchmark can transmission in the targeting sequencing of FCH PDU (for down link) or RCH PDU (for up link) or pilot portion.Handling benchmark can be sent out in every way.

In one embodiment, for spatial multiplexing modes, handling benchmark is one or more broadbands eigenmodes transmission of each tdd frame.The specific broadband eigenmodes quantity that sends in each tdd frame can depend on the duration of handling benchmark.For the example design that has four transmitting antennas, form 9 is listed the broadband eigenmodes of the manipulation benchmark in the targeting sequencing of the FCH/RCH PDU that is used for different targeting sequencing sizes.

Form 9

Targeting sequencing	The broadband eigenmodes of using
		0 OFDM code element	There is not leading sequence
1 OFDM code element	Broadband eigenmodes m, wherein m=frame count mod 4
		4 OFDM code elements	In targeting sequencing, cycle through all 4 broadband eigenmodes
8 OFDM code elements	In targeting sequencing, cycle through all 4 broadband eigenmodes twice

As illustrating in the form 9, when being four or eight code-element periods, leading sequence size in identical tdd frame, handles benchmark for all four broadband eigenmodes send.The manipulation benchmark that is sent in the targeting sequencing of FCH PDU by access point in n code-element period can be expressed as:

${\underset{\‾}{x}}_{\mathrm{dn},\mathrm{sr},n}\left(k\right)={\underset{\‾}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right){\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},\left[(n-1)\mathrm{mod}4\right]+1}^{*}\left(k\right)p\left(k\right),k\∈K,n\∈\{1...L\},---\left(24\right)$

Wherein L is targeting sequencing size (for example for the example design L=0 that illustrates in the form 9,1,4 or 8).

N the interior manipulation benchmark that is sent in the targeting sequencing of RCH PDU by user terminal of code-element period can be expressed as:

${\underset{\‾}{x}}_{\mathrm{up},\mathrm{sr},n}\left(k\right)={\underset{\‾}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right){\underset{\‾}{\overset{^}{v}}}_{\mathrm{ut},\left[(n-1)\mathrm{mod}4\right]+1}\left(k\right)p\left(k\right),k\∈K,n\∈\{1...L\}---\left(25\right)$

In equation (24) and (25), four broadband eigenmodes operate in circulation in each 4 code-element period by " mod " that handles vector.If channel changes more quickly and/or during the communication session early part, can use this scheme when needs obtain better channel estimating fast for the appropriate system operation.

In another embodiment, be that a broadband eigenmodes sends the manipulation benchmark in each tdd frame.The manipulation benchmark of four broadband eigenmodes can cycle through four tdd frames.For example, can be that four continuous T DD frames use the manipulation vector by user terminal

With

The particular manipulation vector that is used to handle benchmark in each tdd frame can be stipulated that this counting can send by frame counter in BCH message.This scheme allows for FCH and RCH PDU uses shorter targeting sequencing.Yet, may need the longer time cycle to estimate to obtain good channel.

For the beam steering pattern, the normalization of main broadband eigenmodes is handled vector and is used to handle benchmark, as illustrating in equation (14) and (20).Handling the duration of benchmark can select based on for example channel condition.

When operating in the beam steering pattern, user terminal can send a plurality of manipulation reference symbols, for example one or more use normalization eigenvectors

Code element, the eigenvector of the main eigenvector of one or more uses Code element and the code element of the eigenvector of possible one or more other eigenmodes of use.With

The manipulation reference symbol that generates can be used to derive up link matched filter vector by access point.This vector is used to use beam steering to realize the matched filtering of the uplink data transmission that user terminal sends by access point.With

The manipulation reference symbol that generates can be used for obtaining It can be used to derive the normalization eigenvector that is used for beam steering on the down link

For other eigenmodes, use eigenvector Arrive

The manipulation reference symbol that generates can be used for obtaining by access point

Arrive

And the estimation of singular values of these other eigenmodes.Information can be used to be defined as downlink transmission by access point, and to be to use spatial multiplexing modes still be the beam steering pattern.

For down link, user terminal can be estimated based on calibration back downlink channel response

For the beam steering pattern derives down link matched filter vector.Particularly, user terminal have from

Singular value decomposition And can derive eigenvector after the normalization

User terminal can with

Multiply by

To obtain

Perhaps, handle vector and can use the normalization eigenvector by access point

Send, and this manipulation benchmark can be handled in the above described manner by user terminal, with the down link matched filter vector of acquisition beam steering pattern.

F. the subband of handling benchmark is multiplexed

For spatial multiplexing and beam steering pattern, the manipulation benchmark can also use subband to be multiplexed in the given code-element period and send for a plurality of broadbands eigenmodes.The subband that uses can be divided into a plurality of non-intersect sets of subbands, for handling set of each broadband eigenmodes that the benchmark transmission is selected for use.Each sets of subbands can be used to relevant broadband eigenmodes to send then and handle benchmark.For simplicity, only on a subclass of all available subbands, be sent out even handle benchmark, but at this use " broadband eigenmodes " speech.

For example, handling benchmark can send on all four broadband eigenmodes in a code-element period.In this case, 52 available subbands can be divided into four disjoint sets (for example being designated as set 1,2,3 and 4), and each set comprises 13 subbands.13 subbands in each set can be evenly distributed on 52 available subbands.The manipulation benchmark of main broadband eigenmodes can be sent out on 13 subbands of set 1 then, the manipulation benchmark of the second broadband eigenmodes can be sent out on 13 subbands in the set 2, the manipulation benchmark of the 3rd broadband eigenmodes can be sent out on 13 subbands of set 3, and the manipulation benchmark of the 4th broadband eigenmodes can be sent out on 13 subbands of set 4.

Only be sent out on a subclass of all available subbands for given broadband eigenmodes if handle benchmark, then interpolation or some other technologies subband that can be used to obtain to be not used in the manipulation benchmark transmission of this broadband eigenmodes is estimated.

Generally, a plurality of sets of subbands can comprise the subband of identical or different quantity.For example, the number of sub-bands that is included in each set can depend on the SNR that gathers relevant broadband eigenmodes (for example can give the set that is associated with poor quality broadband eigenmodes with more allocation of subbands).And the subband in each set can be evenly or is distributed in unevenly on the available subband.A plurality of sets of subbands can also be associated with identical or different pilot frequency code element set.

The multiplexed amount of overhead that can be used to reduce transmission manipulation benchmark needs of subband, this can improve the efficient of system.

G. have the channel estimating of handling benchmark

Illustrate as equation (13), at the user terminal place, the down link of the reception of spatial multiplexing modes is handled benchmark (having under the noise situations) and is roughly

Similarly, illustrate as equation (19), at access point, the up link of the reception of spatial multiplexing modes is handled benchmark (having under the noise situations) and is roughly

Therefore access point obtains based on the manipulation benchmark that user terminal sends

With Estimation, vice versa.

Various technology are used to handle the manipulation benchmark.For clear, below describe at up link and handle the benchmark processing.The vector that the access point place receives provides in equation (19), for ${\underset{\‾}{r}}_{\mathrm{up},\mathrm{sr},m}\left(k\right)\≈{\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},m}\left(k\right){\mathrm{\σ}}_m\left(k\right)p\left(k\right)+{\underset{\‾}{n}}_{\mathrm{up}}\left(k\right).$

In one embodiment, in order to obtain

Estimation, the manipulation benchmark that on m broadband eigenmodes, sends receive vector r _{Up, sr, m}(k) at first multiply by the complex conjugate p of pilot frequency code element ^*(k), it is used to handle benchmark.The result handles on the reference symbol utmost point integration to obtain for each broadband eigenmodes a plurality of receiving then Estimation, this is a m broadband eigenmodes

Through proportional zoom left side eigenvector.Vector

N _ApEach of item is based on vector r _{Up, m}(k) N _ApOne and obtain, wherein r _{Up, m}(k) N _ApItem is from access point N _ApThe code element that individual antenna receives.Because eigenvector has unit power, then singular value σ _m(k) can estimate that this can measure for each subband of each broadband eigenmodes based on handling the receiving power of benchmark.Estimation of singular values

The amplitude that equals pilot frequency code element p (k) then is divided by the square root that receives power.

In another embodiment, least mean-square error (MMSE) technology is used for based on the vector that receives of handling benchmark r _{Up, sr, m}(k) obtain vector

Estimation.Because known pilot symbols p (k), access point can be derived

Estimation, the pilot frequency code element that make to receive is (to receiving vector r _{Up, sr, m}(k) realized obtaining after the matched filtering) and the pilot frequency code element that sends between mean square error minimize.The use of MMSE technology that is used for receiver place spatial manipulation is No. 09/993087 public description of U.S. Patent Application Serial Number, be entitled as " Multiple-AccessMultiple-Input Multiple-Output (MIMO) Communication System ", be filed in November 6 calendar year 2001.

Handling benchmark is that a broadband eigenmodes sends (multiplexed without subband) in any given code-element period, and then can be used to each subband of this broadband eigenmodes to obtain an eigenvector estimation.Therefore, receiver can obtain the estimation of a unique eigenvector in the unitary matrix in any given code-element period.Because a plurality of eigenvectors of unitary matrix are estimated to obtain on a plurality of code-element periods, and because the noise in the wireless channel and other deterioration sources, the estimation eigenvector of unitary matrix (this is derived separately) can not be mutually orthogonal.After this eigenvector of estimating may be used to the spatial manipulation in the matched filtering of the transfer of data that receives on the same link and/or the transfer of data that sends on other links.In this case, any error of orthogonality can cause cross-talk between the data flow that sends on the eigenmodes of corresponding eigenvector between the eigenvector of these estimations.Cross-talk may degrade performance.

In an embodiment, the estimation eigenvector of each unitary matrix is forced to mutually orthogonal.The orthogonality of eigenvector can use Gram-Schmidt technology or other technologies to obtain, and the former describes in detail in the reference of above-mentioned Gilbert Strang.

Can also use other to handle the technology of handling benchmark, and this within the scope of the present invention.

Access point therefore can be based on the manipulation base estimation of user terminal transmission

With

And do not need to estimate channel response or realization

Singular value decomposition.

Handle benchmark at user terminal place estimated matrix based on down link

With

Processing (wherein k ∈ K) can realize to be similar to the above benchmark description of mode handle to(for) up link.

For the beam steering pattern, on up link, handle the vector that receives of benchmark

Can handle in a similar manner to obtain by access point

Estimation.The conjugate transpose of this estimation is the ul transmissions matched filter in the beam steering pattern then.On down link, handle the vector that receives of benchmark

Can handle in a similar manner to obtain by user terminal

Estimation.The conjugate transpose of this estimation is the matched filter of downlink transmission in the beam steering pattern.

5. carrier pilot

On pilot subbands, send in every way in the tdd frame structure that carrier pilot can illustrate in Fig. 2.In one embodiment, four pilot frequency sequences are reseted for each transmission channel.Therefore, on down link, pilot frequency sequence is that an OFDM code element of BCH message is reseted, and is an OFDM code element of FCCH message last reset again, and resets for an OFDM code element that sends on FCH.In another embodiment, pilot frequency sequence is reset at the place that begins of each tdd frame, and is repeated on demand.For this embodiment, pilot frequency sequence can partly stop (stalled) at the targeting sequencing of BCH and FCH.Carrier pilot can also otherwise be sent out, and this within the scope of the present invention.

6. pilot transmission schemes

Below describe four types of pilot tones, and can be used for MIMO and ofdm system.These four kinds of different pilot type can send in every way.

Fig. 3 illustrates the down link and the uplink pilot transmission of example pilot transmission schemes.Generally, frame 310 corresponding system access phases, frame 320 corresponding calibration phases, and frame 330 corresponding normal operation phase.

Beacon pilot frequency and MIMO pilot tone send (frame 312) by access point and obtain system frequency and timing and estimating down-ward link channel (frame 314) with all user terminals in the permission system on down link in each tdd frame.Frame 314 can be realized with connecting system on demand.

Can realize before normal running that calibration is to be aligned in the poor of access point and user terminal place transmit.For calibration, the MIMO pilot tone can be realized (frame 322 and 326) together by access point and user terminal.Up link MIMO pilot tone can be used to derive uplink channel estimation (frame 324) by access point, and the downlink mimo pilot tone can be used to derive or upgrade the estimation (frame 328) of downlink channel by user terminal.Down link and uplink channel estimation are used for access point then and user terminal is derived the correction factor.

During normal running, handling benchmark can be sent by user terminal on up link, its condition following both one of: (1) is and if when the user terminal expected data was transmitted, or (2) carried out transfer of data (frame 332) if user terminal is scheduled.Up link is handled benchmark and can is used to user terminal to estimate relevant unitary matrix and diagonal matrix (frame 334) by access point.Handle benchmark and can send to user terminal (illustrating) by access point alternatively as frame of broken lines 336.User terminal can upgrade its Downlink channel estimation continuously and handle relevant unitary matrix of benchmark renewal and diagonal matrix (if transmission) (frame 338) based on down link based on the downlink mimo pilot tone.Carrier pilot is sent on pilot subbands by access point (frame 340) and user terminal (frame 334) during being not used in the part of other pilot tones.The downlink carrier pilot tone is used to follow the tracks of downlink carrier signal phase (frame 342) by user terminal, and the uplink carrier pilot tone is used to follow the tracks of uplink carrier signal phase (frame 346) by access point.

For the pilot transmission schemes that illustrates in Fig. 3, user terminal is based on the response of downlink mimo pilot tone estimating down-ward link channel and send the manipulation benchmark on up link, and this benchmark is used to user terminal to estimate relevant unitary matrix and diagonal matrix by access point then.Under a stable condition, user terminal can obtain the bad of downlink channel response to be estimated, in this case, down link is handled benchmark may be bad comparably or may be even worse.Under worst condition, the wave beam that the manipulation vector that user terminal uses can cause pointing to access point is zero.If this thing happens, then access point can not detect up link and handle benchmark.For fear of this situation, detect access point at user terminal and correctly receive not handle under the base case, user terminal may disturbance he be used to handle the N of the manipulation vector of benchmark _UtIndividual element phase place.For example,, user terminal sends the part of up link manipulation benchmark as system's access procedure if specifying, and if not acquisition system access after the access attempts of specific times, then user terminal may begin the phase place that vector element is handled in disturbance.

Can also be MIMO and various other pilot transmission schemes of MIMO-OFDM system realization, and this within the scope of the present invention.For example, beacon and carrier pilot can be combined into single pilot tone, can be used for frequency and regularly obtain and carrier phase tracking.As an other example, active user terminals can send the MIMO pilot tone rather than handle benchmark on up link.

The IV.MIMO-OFDM system

Fig. 4 illustrates access point 110x in the MIMO-OFDM system 100 and the embodiment block diagram of user terminal 120x.For clear, in this embodiment, access point 110x is equipped with four antennas that can be used for transfer of data and reception, and user terminal 120x also is equipped with four antennas that are used for transfer of data/reception.Generally, access point and user terminal each any amount of transmitting antenna and any amount of reception antenna can be equipped with.

On up link, at access point 110x place, emission (TX) data processor 414 receives traffic data and slave controller 430 reception signaling and other data from data source 412.414 pairs of data of TX data processor format, encode, interweave and modulate (being symbol mapped) so that modulated symbol to be provided.TX spatial processor 420 usefulness pilot frequency code elements are realized the spatial manipulation of requirement to multiplexed from the modulated symbol of TX data processor 414, and provide four transmitter code flow filaments to four transmitting antennas.

Each modulator (MOD) 422 receives and handles corresponding transmitter code flow filament so that corresponding down link modulated signal to be provided.Correspondingly be sent out to 424d then to four down link modulated signals of 422d from modulator 422a from antenna 424a.

At user terminal 120x place, four antenna 452a receive the down link modulated signals that send to 452d, and the corresponding demodulator of each day alignment (DEMOD) 454 provides and receives signal.Each demodulator 454 is realized with the complementary processing that realizes at modulator 422 places and provides receiving code element.Receive (RX) spatial processor 460 then to handling so that the code element of recovery to be provided to the code element implementation space that receives of 454d from all demodulator 454a, this modulated symbol that is access point sends is estimated.RX data processor 470 is also handled (for example code element is gone mapping, deinterleaved and decode) and is recovered code element so that decoding back data to be provided, these data be provided for then data sink 472 be used for storage with and/or offer controller 480 and further handle.

The processing of up link can be identical or different with the processing of down link.Data and signaling are handled (for example encode, interweave and modulate) by TX data processor 488, and be multiplexed with pilot frequency code element, and further carry out spatial manipulation by TX spatial processor 490.Transmit symbol from TX spatial processor 490 is further handled to generate four up link modulated signals to 454d by modulator 454a, and they are sent out to 452d by antenna 452a then.

At access point 410 places, the up link modulated signal is received to 424d by antenna 424a, by demodulator 422a to the 422d demodulation, and by RX spatial processor 440 and RX data processor 442 to handle with mode in the complementation of user terminal place realization.After the decoding of up link data can be provided for data sink 444 with storage with and/or offer controller 430 and further handle.

Controller 430 and 480 is controlled the operation of each processing unit respectively at access point and user terminal place.Memory cell 432 and 482 is storage control 430 and 480 employed data and program codes respectively.

Fig. 5 illustrates the TX spatial processor 420a that can generate beacon pilot frequency, and this can realize in the TX spatial processor 420 in Fig. 4.Processor 420a comprises a plurality of beacon pilot frequency subband processor 510a to 510k, and each is used to send one of the subband of beacon pilot frequency.Each subband processor 510 receives the pilot frequency code element b (k) of beacon pilot frequency and the correlation matrix of relevant subbands

In each subband processor 510, pilot frequency code element b (k) is used for from matrix to 514d by four multiplier 514a

Four correct the factors

Arrive

Corresponding to proportional zoom.The corresponding plural number of each multiplier 514 usefulness is corrected the complex multiplication that the factor realizes plural pilot frequency code element.From the pilot frequency code element behind proportional zoom of multiplier 514a then by corresponding four buffers/multiplier 520a that offers to 520d, the pilot frequency code element that they also receive through proportional zoom from other subband processor 510.Each buffer/multiplexer 520 will be used for beacon pilot frequency transmission all subbands through the proportional zoom pilot frequency code element and do not use the multiplexed and provide the transmitter code flow filament for the transmitting antenna that is associated of subband as signal values of zero.

Fig. 6 A illustrates the TX spatial processor 420b block diagram that can generate the MIMO pilot tone.Processor 420b realizes in can the TX spatial processor 420 or 490 in Fig. 4, but for the clear following realization of describing in the TX spatial processor 420.Processor 420b comprises a plurality of MIMO pilot subbands processor 610a to 610k, and each is used to send one of the subband of MIMO pilot tone.Each subband processor 610 receives the pilot frequency code element p (k) of MIMO pilot tone and the correction matrix of relevant subbands

Each subband processor 610 also receives four Walsh sequence w ₁To w ₄, they are assigned to four transmitting antennas at the access point place.

In each subband processor 610, plural pilot frequency code element p (k) correspondingly passes through four Walsh sequence w by four complex multiplier 612a to 612d ₁To w ₄Cover.The pilot frequency code element that covers further is used for from matrix to 614d by four complex multiplier 614a

Four plural numbers correct the factors

Arrive

Correspondingly through proportional zoom.Correspondingly offered four buffers/multiplier 620a then to 620d from multiplier 614a to the pilot frequency code element behind proportional zoom of 614d.Processing is described as the above Fig. 5 of being in succession.

Realize that for the processor 420b in the TX spatial processor 490 the Walsh sequence number of use depends on the number of transmit antennas that the user terminal place is available.And proportional zoom is used for from the matrix of user's terminal

The correction factor realize.

Fig. 6 B illustrates can provide the block diagram of the RX spatial processor 460b that channel response estimates based on receiving the MIMO pilot tone.Processor 460b can realize in the RX of Fig. 4 spatial processor 440 or 460, but for the clear following realization of describing RX spatial processor 460.Processor 460b comprises a plurality of MIMO pilot subbands processor 650a to 650k, and each is used for one of the subband of MIMO pilot transmission.Each MIMO pilot subbands processor 650 receives vector r(k) and the conjugation pilot frequency code element p of the subband that is associated ^*(k).Each subband processor 650 also receives four Walsh sequence w that distribute to four transmitting antennas in access point place ₁To w ₄

Each MIMO pilot subbands processor 650 is included in four the MIMO pilot subbands/antenna processing device 660a of four reception antennas in user terminal place to 660d.Each processor 660 receives vector r(k) a r _i(k).In each processor 660, the code element r that receives _i(k) at first multiply by the pilot frequency code element p of conjugation by complex multiplier 662 ^*(k).The output of multiplier 662 further by four complex multiplier 664a to a 664d quadruplication Walsh sequence w correspondingly ₁To w ₄In the MIMO pilot transmission duration, correspondingly add up to 666d by accumulator 666a then to the output of 664d from multiplier 664a.666 pairs in each multiplier 664 and accumulator are realized the covering of going of the transmitting antenna in access point place.Represent the channel gain estimation of subband k from the output of each accumulator 666 from transmitting antenna j to reception antenna i Channel response is estimated

(i={1 wherein, 2,3,4} and j={1,2,3,4}) can further on a plurality of MIMO pilot transmission, average (in Fig. 6 B, not illustrating) and estimate so that channel response to be provided more accurately.

As illustrating in Fig. 6 B, each MIMO pilot subbands/antenna processing device 660 provides the row vector for the reception antenna i that is associated ${\hat{h}}_{\mathrm{cdn},i}\left(k\right)=\left[\begin{array}{cccc}{\hat{h}}_{i,1}\left(k\right)& {\hat{h}}_{i,2}\left(k\right)& {\hat{h}}_{i,3}\left(k\right)& {\hat{h}}_{i,4}\left(k\right)\end{array}\right],$ Wherein Be that channel response is estimated after the calibration of down link

I capablely (suppose that access point used it and corrected matrix

).Processor 660a provides calibration back channel response matrix together to 660d

Four lines.

Fig. 7 A illustrates and can generate the TX spatial processor 420c block diagram of handling benchmark.Realize in the TX spatial processor 420 or 490 that processor 420c can also illustrate in Fig. 4, but for the clear following realization of describing TX spatial processor 420.Processor 420c comprises a plurality of manipulation benchmark subband processor 710a to 710k, and each is used to send one of subband handling benchmark.Handle benchmark in order to generate for spatial multiplexing modes, each subband processor 710 receives pilot frequency code element p (k), handles vector for each broadband eigenmodes that the manipulation benchmark sends thereon

And the subband that is to be associated receives and corrects matrix

In each subband processor 710, pilot frequency code element p (k) correspondingly multiply by the manipulation vector of m broadband eigenmodes to 712d by four complex multiplier 712a

Four elements

Arrive

Further be used for from matrix to 714d to the output of 712d from multiplier 712a by four complex multiplier 714a

Four correct the factors

Arrive Through proportional zoom.Then correspondingly be provided for four buffers/multiplier 720a to 720d to 714d through the proportional zoom code element from multiplier 714a.Handle as described above in succession.

In order to generate the manipulation benchmark on the down link for the beam steering pattern, each subband processor 710 can receive normalized manipulation vector

Rather than without normalized manipulation vector

Realize that for the processor 420c in the TX spatial processor 490 each subband processor 710 can receive (1) to spatial multiplexing modes, be used to handle the manipulation vector of each broadband eigenmodes of benchmark

Or (2) are for the manipulation vector of beam steering pattern

If use subband multiplexed to handling benchmark, the manipulation vector of then a plurality of broadbands eigenmodes can be used for the disjoint set of a plurality of subbands, as mentioned above.

Fig. 7 B illustrates and can handle the RX spatial processor 460c that benchmark provides manipulation vector sum estimation of singular values based on receiving.Processor 460c can realize in the RX spatial processor 440 or 460 in Fig. 4, but for clear, below be described in the realization in the RX spatial processor 460.Processor 460c comprises a plurality of manipulation benchmark subband processor 750a to 750k, and each is used to handle one of the subband of benchmark transmission.Each subband processor 750 receives vector rAnd be that relevant subbands receives conjugation pilot frequency code element p (k), ^*(k).

In each subband processor 750, receive vector r(k) Nei four code elements correspondingly multiply by conjugation pilot frequency code element p by complex multiplier 762a to 762d ^*(k).Multiplier 762a is correspondingly added up in the transmitting continuous time for the manipulation benchmark of each broadband eigenmodes to 764d by accumulator 764a then to the output of 762d.As illustrating in the form 9, can be that a plurality of broadbands eigenmodes sends and handles benchmark in identical manipulation benchmark transmission, in this case, separate realization for each of these broadband eigenmodes and add up.Yet a plurality of manipulation reference symbols of any given broadband eigenmodes (this can send in one or more manipulation benchmark transmission) can be estimated to obtain higher quality through adding up.Accumulator 764a provides to 764d Four elements of estimation, as illustrating in the equation (13).

Because eigenvector has unit power, the singular value of each broadband eigenmodes

Can estimate based on handling the receiving power of benchmark.Power calculation unit 766 receives the 762d of the power P that receives multiplier 762a handles benchmark to output and the calculating of to(for) each eigenmodes of subband k _m(k).Singular value Equal to handle the square root that receives power that benchmark calculates then (promptly divided by the pilot frequency code element amplitude ${\widehat{\mathrm{\σ}}}_m\left(k\right)=\sqrt{P_m\left(k\right)}/\left|p\left(k\right)\right|$ ), wherein $P_k\left(k\right)=\underset{i=1}{\overset{N_R}{\mathrm{\Σ}}}{\left|r_i\left(k\right)\right|}^2,$ And r _i(k) be the code element that receives on the subband k of reception antenna i.

Accumulator 766a is contrary by estimation of singular values then to the output of 766d

And multiplier 768a thinks that through proportional zoom each eigenmodes provides the estimation of handling vector to 768d is corresponding,

${\underset{\‾}{\overset{^}{v}}}_{\mathrm{ut},m}^{*}\left(k\right)=\left[\begin{array}{cccc}{\hat{v}}_{\mathrm{ut},1,m}^{*}\left(k\right)& {\hat{v}}_{\mathrm{ut},2,m}^{*}\left(k\right)& {\hat{v}}_{\mathrm{ut},3,m}^{*}\left(k\right)& {\hat{v}}_{\mathrm{ut},4,m}^{*}\left(k\right)\end{array}\right].$

The manipulation benchmark of beam steering is handled and may be realized in a similar fashion.The processing of handling benchmark on the up link can also realize in a similar fashion thinking that each eigenmodes obtains to handle the estimation of vector,

${\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},m}^{*}\left(k\right)=\left[\begin{array}{cccc}{\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},1,m}^{*}\left(k\right)& {\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},2,m}^{*}\left(k\right)& {\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},3,m}^{*}\left(k\right)& {\underset{\‾}{\overset{^}{u}}}_{\mathrm{ap},4,m}^{*}\left(k\right)\end{array}\right].$

Pilot tone described here can be realized by various means.For example, all kinds pilot tone at access point place and user terminal place is handled and can be realized with hardware, software or their combination.For hardware is realized, be used to handle pilot tone and can in following equipment, realize: one or more application specific integrated circuits (ASIC), digital signal processor (DSP), digital signal processing appts (DSPD), programmable logic device (PLD), field programmable gate array (FPGA), processor, controller, microcontroller, microprocessor, be designed to carry out other electronic unit of function described here or their combination with the element that transmits and/or receive.

For software was realized, some of all kinds pilot tone were handled (for example the spatial manipulation of pilot transmission and/or based on the channel estimating that receives pilot tone) and can be realized with the module (for example process, function or the like) of execution function described here.Software code can be stored in the memory cell (for example memory cell among Fig. 4 432 or 482), and can be carried out by processor (for example controller 430 or 480).Memory cell can realize in processor or realize that under latter instance, it can be coupled to processor by mode known in the various fields outside processor.

Here the title that comprises supplies to quote, and helps the specific chapters and sections in location.These titles do not limit its scope of described notion down, and these notions can be applicable to other chapters and sections in the entire description.

The description of above preferred embodiment makes those skilled in the art can make or use the present invention.The various modifications of these embodiment are conspicuous for a person skilled in the art, and Ding Yi General Principle can be applied among other embodiment and not use creativity here.Therefore, the embodiment that the present invention is not limited to illustrate here, and will meet and the principle and the novel feature the most wide in range consistent scope that disclose here.

Claims (56)

1. in wireless MIMO communication systems, generate the method for handling pilot tone, it is characterized in that comprising:

Acquisition will be from first pilot frequency code element of a plurality of antenna transmission;

For vector is handled in first space channel acquisition first of the multi-input multi-ouput channel in the multi-input multi-output system; And

To obtain the first transmitter code tuple, each of a plurality of antennas is all to there being a transmit symbol with the first manipulation Vector Processing, first pilot frequency code element, and wherein the first transmitter code tuple is the manipulation pilot tone that is used for first space channel.

2. the method for claim 1 is characterized in that also comprising:

Acquisition will be from second pilot frequency code element of a plurality of antenna transmission;

Obtain the second manipulation vector of second space channel of multi-input multi-ouput channel; And

Use the second manipulation vector to handle second pilot frequency code element, be used for the second transmitter code tuple of the manipulation pilot tone of second space channel with acquisition.

3. method as claimed in claim 2 is characterized in that also comprising:

In first code-element period, launch the first transmitter code tuple from a plurality of antennas; And

In second code-element period from a plurality of antenna transmission second transmitter code tuples.

4. method as claimed in claim 2 is characterized in that also comprising:

On first subband from a plurality of antenna transmission first transmitter code tuples; And

On second subband from a plurality of antenna transmission second transmitter code tuples.

5. method as claimed in claim 4 is characterized in that the described first and second transmitter code tuples are sent out in a code-element period.

6. method as claimed in claim 2, it is characterized in that described first and second handle vector and correspondingly are associated with first and second eigenmodes of the channel response matrix of multi-input multi-ouput channel, and corresponding corresponding first and second eigenmodes of wherein said first and second space channels.

7. method as claimed in claim 2 is characterized in that the described first and second manipulation vectors are mutually orthogonal.

8. the method for claim 1 is characterized in that the described first manipulation vector obtains based on eigenvector in the unitary matrix of the channel response matrix of multi-input multi-ouput channel.

9. the method for claim 1 is characterized in that the described first manipulation vector comprises a plurality of elements that amplitude is identical, and each of a plurality of antennas is all to there being an element.

10. the method for claim 1 is characterized in that the described first manipulation vector is associated with the main eigenmodes of the channel response matrix of multi-input multi-ouput channel.

11. the device in the wireless MIMO communication systems is characterized in that comprising:

Acquisition will be from the device of first pilot frequency code element of a plurality of antenna transmission;

Obtain the device of the first manipulation vector for first space channel of multi-input multi-ouput channel in the multi-input multi-output system; And

To obtain the device of the first transmitter code tuple, each of a plurality of antennas is all to there being a transmit symbol with the first manipulation Vector Processing, first pilot frequency code element, and wherein the first transmitter code tuple is the manipulation pilot tone that is used for first space channel.

12. device as claimed in claim 11 is characterized in that also comprising:

The device of second pilot frequency code element that acquisition will be sent out from a plurality of antennas; And

Obtain the device of the second manipulation vector for second space channel of multi-input multi-ouput channel; And

Be used for handling the device of Vector Processing second pilot frequency code element with the second transmitter code tuple of the manipulation pilot tone that obtains to be used for second space channel with second.

13. in utilizing the wireless MIMO communication systems of orthogonal frequency division multiplex OFDM, generate the method for handling pilot tone, it is characterized in that comprising:

Acquisition will be gathered from first set of the pilot frequency code element of a plurality of antenna transmission at first of subband;

Acquisition be used for subband first the set first space channel the manipulation vector first the set; And

First set with the first process of aggregation pilot frequency code element of handling vector is gathered to obtain first of symbol vector, each subband in first set of subband is all to a symbol vector in first set that symbol vector should be arranged, wherein each symbol vector in first of the symbol vector set comprises a plurality of transmit symbol of a plurality of antennas, and corresponding to the manipulation pilot tone of first space channel of the subband that is associated with symbol vector.

14. method as claimed in claim 13 is characterized in that also comprising:

Obtain to handle second set of vector for first second space channel of gathering of subband; And

First set with the second process of aggregation pilot frequency code element of handling vector is gathered to obtain second of symbol vector, and wherein each symbol vector in second of the symbol vector set is corresponding to the manipulation pilot tone of second space channel of the subband that is associated with symbol vector.

15. method as claimed in claim 14 is characterized in that also comprising:

In first code-element period, in first set of subband, gather from first of a plurality of antenna transmission symbol vector; And

In second code-element period, in first set of subband, gather from second of a plurality of antenna transmission symbol vector.

16. method as claimed in claim 13 is characterized in that also comprising:

Acquisition will be gathered from second set of the pilot frequency code element of a plurality of antenna transmission at second of subband;

Acquisition be used for subband second the set first space channel the manipulation vector second the set; And

Second set with the second process of aggregation pilot frequency code element of handling vector is gathered to obtain second of symbol vector, each subband in second set of subband is all to a symbol vector in second set that symbol vector should be arranged, and wherein each symbol vector in second of the symbol vector set is corresponding to the manipulation pilot tone of first space channel of the subband that is associated with symbol vector.

17. method as claimed in claim 16 is characterized in that also comprising:

In first set of subband, gather from first of a plurality of antenna transmission symbol vector; And

In second set of subband, gather from second of a plurality of antenna transmission symbol vector.

18. method as claimed in claim 17 is characterized in that second of first set of described symbol vector and symbol vector is integrated in the code-element period and is sent out.

19. method as claimed in claim 13 is characterized in that the selected tool of pilot frequency code element in described first set has the flat variation in little peak in the waveform that generates based on pilot frequency code element.

20. one receives the method for handling pilot tone in wireless MIMO communication systems, it is characterized in that comprising:

The first manipulation pilot tone that receives for first space channel by multi-input multi-ouput channel in the multi-input multi-output system receives first set of symbols from a plurality of antennas, and the wherein said first manipulation pilot tone is handled vector based on first of the pilot frequency code element and first space channel and generated;

Handle first set of symbols to obtain second set of symbols with pilot frequency code element;

Determine first scale factor based on the symbol power of estimating in first group; And

With first scale factor code element in second group is carried out proportional zoom and handle vector to obtain being used for second of first space channel.

21. method as claimed in claim 20 is characterized in that the described first manipulation pilot tone is sent out in a plurality of code-element periods, described method also comprises:

Code element in second group of a plurality of code-element periods adds up.

22. method as claimed in claim 20 is characterized in that also comprising:

Handling vector based on second is that first space channel is derived matched filter.

23. method as claimed in claim 20 is characterized in that described second handles the vectorial spatial manipulation that is used for by the transfer of data of multi-input multi-ouput channel transmission.

24. method as claimed in claim 20 is characterized in that also comprising:

Handling vector based on second of first space channel is that first space channel is derived the time domain matched filter.

25. method as claimed in claim 24 is characterized in that described time domain matched filter comprises each matched filtering pulse of a plurality of antennas.

26. method as claimed in claim 20 is characterized in that also comprising:

The second manipulation pilot tone that receives for second space channel by multi-input multi-ouput channel receives the 3rd set of symbols from a plurality of antennas, and the wherein said second manipulation pilot tone is handled vector based on first of the pilot frequency code element and second space channel and generated;

Handle the 3rd set of symbols to obtain the 4th set of symbols with pilot frequency code element;

Determine second scale factor based on the symbol estimation power in the 3rd group; And

With second scale factor code element in the 4th group is carried out proportional zoom and handle vector to obtain being used for second of second space channel.

27. one is used for the method that first entity in wireless MIMO communication systems is managed pilot tone everywhere, it is characterized in that comprising:

A plurality of orthogonal sequences based on first pilot frequency code element and a plurality of antennas generate a plurality of orthogonal guide frequencies that are used for mimo pilot, and wherein a plurality of orthogonal guide frequencies are specified on first link and transmit from a plurality of antennas; And

The manipulation pilot tone that second entity of processing by the space channel on second link receives, wherein said manipulation pilot tone generates based on the manipulation of second pilot frequency code element and space channel vector, and wherein said manipulations is vectorial obtains based on mimo pilot.

28. method as claimed in claim 27 is characterized in that described first link is that interior down link of multi-input multi-output system and described second link are the up link in the multi-input multi-output system.

29. method as claimed in claim 27 is characterized in that described first and second links time division duplex on single frequency band.

30. method as claimed in claim 29 is characterized in that described first and second links are through calibration and the estimation of first link and the second link reciprocity.

31. method as claimed in claim 27 is characterized in that also comprising:

Generate beacon pilot frequency based on the 3rd pilot frequency code element, wherein said beacon pilot frequency comprises the public guide frequency that is suitable on first link from each transmission of a plurality of antennas.

32. method as claimed in claim 27 is characterized in that

Generation is suitable for the carrier pilot that transmits on first link, and described carrier pilot is used for Phase Tracking by second entity.

33. method as claimed in claim 27 is characterized in that described generation mimo pilot comprises:

Acquisition is used for a plurality of orthogonal sequences of a plurality of antennas, and wherein a plurality of antennas are assigned with the different orthogonal sequence, and

Cover first pilot frequency code element to obtain corresponding in a plurality of orthogonal guide frequencies with each of a plurality of orthogonal sequences.

34. method as claimed in claim 33 is characterized in that described a plurality of orthogonal sequence is the Walsh sequence.

35. method as claimed in claim 27 is characterized in that the described treated estimation that is used at least one manipulation vector of first link with acquisition of manipulation pilot tone that receives from second entity.

36. method as claimed in claim 27 is characterized in that described multi-input multi-output system utilizes OFDM.

37. method as claimed in claim 36 is characterized in that described mimo pilot is sent out on a plurality of subbands.

38. method as claimed in claim 36 is characterized in that described manipulation pilot tone is received on a plurality of subbands.

39. one manages the method for pilot tone everywhere at first entity in wireless MIMO communication systems, it is characterized in that comprising:

Generate beacon pilot frequency based on first pilot frequency code element, wherein said beacon pilot frequency comprises the public guide frequency that is suitable on the down link of multi-input multi-output system from each transmission of a plurality of antennas;

A plurality of orthogonal sequences based on second pilot frequency code element and a plurality of antennas generate a plurality of orthogonal guide frequencies that are used for mimo pilot, and wherein a plurality of orthogonal guide frequencies are specified on the down link and transmit from a plurality of antennas; And

The manipulation pilot tone that processing receives from second entity by space channel on the up link in multi-input multi-output system, wherein said manipulation pilot tone generates based on the manipulation of the 3rd pilot frequency code element and described space channel vector, and wherein said manipulations is vectorial obtains based on mimo pilot.

40. method as claimed in claim 39 is characterized in that the described treated estimation that is used at least one manipulation vector of down link with acquisition of manipulation pilot tone that receives from second entity.

41. method as claimed in claim 39, it is characterized in that described multi-input multi-output system utilizes OFDM, wherein said beacon pilot frequency generates based on first set of pilot frequency code element, and be sent out in first set of subband, and wherein said mimo pilot is based on the second set generation and the transmission in second set of subband of pilot frequency code element.

42. one generates the method for handling pilot tone in wireless MIMO communication systems, it is characterized in that comprising:

Estimate the channel response of first link in the multi-input multi-output system;

Obtain the manipulation vector set of second link in the multi-input multi-output system based on the estimation channel response of first link; And

Based on the vectorial manipulation pilot tone of handling in the vector set that generates the space channel of second link of manipulation.

43. method as claimed in claim 42 is characterized in that also comprising:

On second link, send and handle pilot tone.

44. method as claimed in claim 42 is characterized in that also comprising:

On first link, receive mimo pilot, wherein said mimo pilot comprises a plurality of orthogonal guide frequencies that generate based on a plurality of orthogonal sequences, and be sent out on first link by a plurality of antennas, and wherein the channel response of first link is estimated based on receiving mimo pilot.

45. method as claimed in claim 42, the manipulation vector set that it is characterized in that described second link are by being that the estimation channel response of first link is carried out channel response matrix and decomposed and obtain.

46. method as claimed in claim 42 is characterized in that described first link is that interior down link of multi-input multi-output system and described second link are the up links in the multi-input multi-output system.

47. method as claimed in claim 42 is characterized in that described generation comprises:

With the amplitude of handling vector and phase information pilot frequency code element is carried out beam shaping and handle vector to generate.

48. method as claimed in claim 42 is characterized in that described generation comprises:

With the phase information of handling vector pilot frequency code element is carried out beam steering and handle pilot tone to generate.

49. the access point in the wireless MIMO communication systems is characterized in that comprising:

The emission space processor, be used for generating a plurality of orthogonal guide frequencies that are used for mimo pilot based on a plurality of orthogonal sequences of first pilot frequency code element and a plurality of antennas, wherein a plurality of orthogonal guide frequencies are specified on the interior down link of multi-input multi-output system and transmit from a plurality of antennas; And

Receive spatial processor, be used to handle the manipulation pilot tone that receives from terminal by space channel on the up link in multi-input multi-output system, wherein said manipulation pilot tone is generated based on the manipulation of second pilot frequency code element and described space channel vector by terminal, and wherein said manipulations is vectorial is obtained based on the mimo pilot that receives by down link by terminal.

50. access point as claimed in claim 49, it is characterized in that described emission space processor also is used for generating beacon pilot frequency based on the 3rd pilot frequency code element, wherein said beacon pilot frequency comprises the public guide frequency that is applicable to each transmission of a plurality of antennas from the down link.

51. access point as claimed in claim 49 is characterized in that described a plurality of orthogonal sequence is the Walsh sequence.

52. access point as claimed in claim 49, it is characterized in that described multi-input multi-output system utilizes Orthodoxy Frequency Division Multiplex, first set that wherein is subband generates described mimo pilot, and wherein said manipulation pilot tone is received in second set of subband.

53. the terminal in the wireless MIMO communication systems is characterized in that comprising:

Receive spatial processor, being used to handle the mimo pilot that access point receives on the down link in multi-input multi-output system estimates with the channel response that obtains down link, wherein said mimo pilot comprises based on pilot frequency code element with at access point distributes to a plurality of orthogonal sequences of a plurality of antennas and a plurality of orthogonal guide frequencies of generating, and each of a plurality of antennas is all to there being an orthogonal guide frequency; And

The emission space processor is used for generating the manipulation pilot tone based on the manipulation vector of the space channel on second pilot frequency code element and the up link in multi-input multi-output system.

54. terminal as claimed in claim 53 is characterized in that also comprising:

Controller is used to be based upon that described channel response that down link obtains is estimated and the manipulation vector of deriving the above space channel of up link.

55. terminal as claimed in claim 54 is characterized in that described controller is used to realize that the channel response estimated channel response matrix of down link decomposes to derive the manipulation vector of space channel on the up link.

56. terminal as claimed in claim 53, it is characterized in that described multi-input multi-output system utilizes Orthodoxy Frequency Division Multiplex, wherein each the described channel response that obtains to be used for more than first subband based on the mimo pilot that receives on the subband is estimated, and wherein is that each of more than second subband generates described manipulation pilot tone.

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