CN1717900A - MIMO WLAN system - 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 MIMO wlan system

Require priority according to 35 U.S.C. § 119

The application requires the priority of the 60/421st, No. 309 U.S. Provisional Patent Application, and the latter is entitled as " MIMOWLAN system ", submits on October 25th, 2002.

Background

Technical field

The present invention relates generally to data communication, relate in particular to a multiple-input and multiple-output (MIMO) wireless lan (wlan) communication system.

Background technology

Wireless communication system is widely used for providing such as various types of communication such as voice, grouped datas.These systems can be can by share that the available system resource is supported sequentially or simultaneously with the multi-address system of a plurality of telex networks.The example of multi-address system comprises code division multiple access (CDMA) system, time division multiple access (TDMA) system and frequency division multiple access (FDMA) system.

Wireless lan (wlan) also is widely used in the communication that allows via Radio Link between radio-based electronic devices (for example computer).WLAN can adopt the access point (or base station) of working as hub, and provides connection for wireless device.Access point also can be linked WLAN (or " bridge joint ") wired lan, thereby makes wireless device can insert the LAN resource.

In wireless communication system, can be from radio frequency (RF) modulated signal of transmitter unit by a plurality of propagation paths arrival receiver units.Because all multifactor such as decline and multipath etc., the feature of propagation path can change along with the time.In order to provide with respect to the diversity of abominable path effects and to improve performance, can use many and transmit and receive antenna.If the propagation path that transmits and receives between the antenna is linearity independently (i.e. transmission on the paths is not the combination of transmitting on other paths), this sets up at least to a certain extent, then along with the increase of antenna amount, the probability that correctly receives transfer of data also improves.Generally speaking, along with the increase that transmits and receives antenna amount, diversity also increases, and performance also is improved.

Mimo system adopts many (N _T) transmitting antenna and Duo Gen (N _R) reception antenna carries out transfer of data.By N _TTransmit antennas and N _RThe mimo channel that the root reception antenna forms can be broken down into N _SIndividual space channel, N _S≤ min{N _T, N _R.N _SEach of individual space channel is all corresponding to a dimension.If use many to transmit and receive the additional dimension that antenna is created, mimo system just can provide improved performance (transmission capacity that has for example improved and/or higher reliability).

The resource of one given communication system generally is subjected to various regulations constraints and other actual Considerations are limit.Yet, may require system to support a plurality of terminals, various services are provided, realize specific performance properties target or the like.

Therefore, the MIMO wlan system that needs to support a plurality of users in this area and high systematic function is provided.

Summary of the invention

A kind of various abilities and can realize high performance multiple access MIMO wlan system of having have been described here.In one embodiment, system adopt MIMO and OFDM (OFDM) keep high-throughput, to the path effects of degeneration and other benefits are provided.Each access point in the system can be supported a plurality of user terminals.Requirement, channel condition and other factor of user terminal depended in the resource allocation of down link and up link.

The channel architecture of supporting effective down link and ul transmissions also is provided here.Channel architecture comprises a plurality of transmission channels that can be used for a plurality of functions, signaling, down link and the uplink data transmission of described a plurality of function ratio such as system parameters and resource allocation, access or the like at random of system.The various attributes of these transmission channels are configurable, and this makes system can easily adapt to the channel and the loading condition of variation.

The MIMO wlan system supports a plurality of speed and transmission mode so that keep high-throughput when channel condition and ability of user terminal support.Speed can be based on the estimation of channel condition and is disposed, and can independently select for down link and up link.Also can use different transmission modes, this depends on the number of antennas and the channel condition at user terminal place.Each transmission mode is all handled with the different spaces at transmitter and receiver place and is associated, and can be selected under the different conditions of work and use.For higher throughput and/or diversity, spatial manipulation is convenient to from the transfer of data of many transmit antennas and/or with the Data Receiving of many reception antennas.

In one embodiment, the MIMO wlan system is that down link and up link are used single frequency band, and down link and up link use time division duplex (TDD) to share same working band.For the TDD system, down link and uplink channel responses are reciprocal.Here provide collimation technique to determine and remedy the difference of frequency response of access point and user terminal place transmit.The reciprocal characteristic of utilizing down link and up link and the technology of calibrating the spatial manipulation of simplifying access point and user terminal place have also been described here.

Pilot configuration with the used a few class pilot tones of difference in functionality also is provided.For example, can use the MIMO pilot tone for channel estimating, can use controlled index (being controlled pilot tone) for improved channel estimating, and can use carrier pilot for Phase Tracking for frequency and system acquisition use beacon pilot frequency.

The various control loops that are used for correct system operation also are provided.Can on down link and up link, carry out rate controlled independently.Can carry out power control for specific transmission (for example service of fixed rate).Can use timing controlled for ul transmissions and remedy the different propagation delays of residing user terminal in the system.

The access technology at random that makes user terminal energy connecting system also is provided.The a plurality of user terminals of these technical supports are to the access of system, the quick affirmation of system's access attempts and the quick distribution of downlink/uplink resource.

Various aspects of the present invention and embodiment have been described in further detail below.

Description of drawings

In the detailed description that proposes in conjunction with the accompanying drawings, it is more obvious that feature of the present invention and character will become below, and reference number identical in the accompanying drawing is represented components identical, wherein:

Fig. 1 illustrates a MIMO wlan system;

Fig. 2 illustrates the layer structure of MIMO wlan system;

Fig. 3 A, 3B and 3C illustrate TDD-TDM frame structure, FDD-TDM frame structure and FDD-CDM frame structure respectively;

Fig. 4 illustrates the TDD-TDM frame structure of five transmission channel-BCH, FCCH, FCH, RCH and RACH;

Fig. 5 A illustrates variety of protocol data cell (PDU) form of five transmission channels to 5G;

Fig. 6 illustrates a kind of structure of FCH/RCH grouping;

Fig. 7 illustrates an access point and two user terminals;

Fig. 8 A, 9A and 10A illustrate three transmitter units that are respectively applied for diversity mode, space multiplexing mode and wave beam control model;

Fig. 8 B, 9B and 10B illustrate three transmit diversity processors that are respectively applied for diversity mode, space multiplexing mode and wave beam control model;

Fig. 8 C illustrates an OFDM modulator;

Fig. 8 D illustrates an OFDM code element;

Figure 11 A illustrates framing unit and the disarrangement device in the transmit data processor;

Figure 11 B illustrates encoder and the repetition/brachymemma unit in the transmit data processor;

Figure 11 C illustrates another transmit data processor that can be used for space multiplexing mode;

Figure 12 A and 12B illustrate the state diagram that is used for user terminal operations;

Figure 13 illustrates the timeline of RACH;

Figure 14 A and 14B illustrate the process of the transmission rate that is respectively applied for control down link and up link;

Figure 15 illustrates the operation of power control circuit; And

Figure 16 illustrates the process of the up link sequential that is used to regulate user terminal.

Describe in detail

Here use word " exemplary " to mean " serving as example, example or explanation ".Here any embodiment that is described as " exemplary " needn't be regarded as more more preferred or favourable than other embodiment or design.

1. total system

I. total system

Fig. 1 illustrates the MIMO wlan system 100 of supporting a plurality of users and realizing various aspects embodiment of the present invention.MIMO wlan system 100 comprises a plurality of access points (AP) 110 of the communication of supporting a plurality of user terminals.For simplicity, two access points 110 only are shown among Fig. 1.Access point generally is to be used for the fixed station that communicates with user terminal.Access point also can be called base station or some other term.

User terminal 120 can spread in the system.Each user terminal can be the fixing or mobile terminal that can communicate by letter with access point.User terminal also can be called mobile radio station, distant station, accesses terminal, subscriber equipment (UE), wireless device or some other term.Each user terminal can may communicate by a plurality of access points with one on down link and/or up link at arbitrary given time.Down link (being forward link) is meant the transmission from the access point to the user terminal, and up link (being reverse link) is meant the transmission from the user terminal to the access point.

Among Fig. 1, access point 110a communicates by letter with user terminal 120a by 120f, and access point 110b communicates by letter with user terminal 120f by 120k.According to the particular design of system 100, access point is (for example by a plurality of encoding channels or subchannel) or sequentially (for example via a plurality of time slots) and a plurality of user terminals communicate simultaneously.In arbitrary given moment, user terminal can receive the downlink transmission from one or more access points.From the downlink transmission of each access point can comprise will by overhead data that a plurality of user terminal received, will be by the customer-specific data that specific user terminal received, the data of other type or their arbitrary combination.Overhead data can comprise pilot tone, paging and broadcast, system parameters or the like.

The MIMO wlan system is based on a central authoritiesization controller network configuration.Like this, system controller 130 is coupled to access point 110, further is coupled to other system and network.For example, system controller 130 can be coupled to packet data network (PDN), cable LAN (LAN), wide area network (WAN), the Internet, public switch telephone network (PSTN), cellular communications network or the like.System controller 130 can be designed to a plurality of functions, such as (1) to the coordination and the control of the access point of its coupling, (2) are route data between these access points, (3) insert communicating by letter of the user terminal of serving with control and these access points, or the like.

Compare with conventional wlan system, perhaps the MIMO wlan system can provide covering power much bigger high-throughput.The MIMO wlan system can be supported synchronous, asynchronous with etc. the time the data/voice service.The MIMO wlan system can be designed to provide following feature:

High service reliability

Guaranteed service quality (QoS)

High instantaneous data rates

Spectral efficient

The coverage of expansion.

The MIMO wlan system can be operated in each frequency band (for example 2.4GHz and 5.xGHz U-NII frequency band), is subjected to bandwidth and radiation limitations for selected working band special use.System is designed to support the use of indoor and outdoors, and general maximum cell size is 1km or still less.The terminal applies that system's support is fixing, however a few thing pattern is also supported portable and limited move operation.

1.MIMO, MISO and SIMO

In certain embodiments, and as described in this specification, each access point all is equipped with four and transmits and receives antenna and carry out data and send and receive, and wherein uses four identical antennas to send and receive.System is the transmitting antenna and the not shared situation of reception antenna of support equipment (for example access point, user terminal) also, even the common ratio antenna of this configuration provides lower performance when sharing.The MIMO wlan system can also design like this: make each access point all be equipped with the transmit/receive antenna of some other quantity.Each user terminal can be equipped with single transmit/receive antenna or many transmit/receive antennas carry out data transmission and reception.The antenna amount that each type of user terminal adopted all depends on various factors, the service of supporting such as user terminal (for example voice, data or both), cost consideration, regulations constraint, safety problem or the like.

For given one-to-many antenna access point and many antennas user terminal, mimo channel is by the N that can be used for transfer of data _TTransmit antennas and N _RThe root reception antenna forms.Between access point and different many antennas user terminal, form different mimo channels.Each mimo channel can be broken down into N _SIndividual space channel, N _S≤ min{N _T, N _R.N _SIndividual data flow can be at N _SBe sent out on the individual space channel.Require spatial manipulation at the receiver place, may or may not carry out spatial manipulation so that at N at the transmitter place _SThe a plurality of data flow of emission on the individual space channel.

N _SIndividual space channel possibility is orthogonal or possibility is non-orthogonal.This depends on various factors, whether carries out spatial manipulation such as (1) at the transmitter place for obtaining orthogonal spatial channels, and (2) whether both locate to carry out spatial manipulation at transmitter and receiver when making space channel orthogonalization.If do not carry out spatial manipulation, then N at the transmitter place _SIndividual space channel can be used N _STransmit antennas is carried out, and can not be orthogonal.

As described below, decompose N by channel response matrix to mimo channel _SIndividual space channel can quadrature.If N _SIndividual space channel uses and decomposes and quadrature, and then each space channel all is called the eigenmodes of mimo channel, decomposes the spatial manipulation that requires the transmitter and receiver place.In this case, N _SIndividual data flow can be at N _SQuadrature sends on the individual eigenmodes.Yet eigenmodes generally is meant theoretical construct.Since a variety of causes, N _SIndividual space channel generally is not orthogonal fully.For example, if (1) transmitter is known mimo channel, perhaps (2) transmitter and/or receiver have the incomplete estimation of mimo channel, and then space channel can quadrature.For simplicity, in the following description, term " eigenmodes " is used for representing to attempt with decomposing the orthogonalized situation of space channel that makes, even attempt because former thereby incomplete successes such as incomplete channel estimating.

Give the antenna of determined number (for example four) for the access point place, each user terminal can with number of spatial channels depend on the number of antennas that user terminal adopts and the feature of the Technique of Wireless MIMO Channel of be coupled access point antenna and user terminal antenna.If user terminal is equipped with an antenna, then the single antenna at four of access point place antennas and user terminal place has formed the single delivery channel of many inputs (MISO) of down link and single input multiple-output channel (SIMO) of up link.

The MIMO wlan system can be designed to support multiple transmission mode.Table 1 is listed the transmission mode of being supported by the exemplary design of MIMOWLAN system.

Table 1

Transmission mode	Describe
		SIMO	For receive diversity, data are sent from single antenna, but may be received by many antennas.
Diversity	Data are sent so that diversity to be provided from many transmit antennas and/or a plurality of subband redundantly.
		Wave beam control	Data use the phase control information of the main eigenmodes of mimo channel to be sent out on single (the best) space channel with total power.
Spatial reuse	Data are sent out on a plurality of space channels to realize higher spectrum efficiency.

For simplicity, term " diversity " is meant the transmission diversity in the following description, unless specialize.

The down link of each user terminal and up link can with transmission mode depend on the number of antennas that the user terminal place adopts.Table 2 is listed the transmission mode that the different terminals type of down link and up link can be used, and supposing has many (for example four) antennas at the access point place.

Table 2

Transmission mode	Down link		Up link
					The single antenna user terminal	Many antennas user terminal	The single antenna user terminal	Many antennas user terminal
	MISO (on down link)/SIMO (on up link)	X	X	X					X
Diversity					X	X		X
	Wave beam control	X	X						X
Spatial reuse						X		X

For down link, all transmission modes except that space multiplexing mode all can be used for the single antenna user terminal, and all transmission modes all can be used for many antennas user terminal.For up link, all transmission modes can be used by many antennas user terminal, and the single antenna user terminal uses the MIMO pattern from available antenna transmission data.Receive diversity (promptly receiving transfer of data with many reception antennas) can be used for SIMO, diversity and wave beam control model.

The MIMO wlan system can be designed to also support various other transmission modes that this within the scope of the invention.For example, the beam shaping pattern can be used to send data on single eigenmodes, used the amplitude of this eigenmodes and phase information (rather than only use phase information, the latter be the wave beam control model all use).For another example, can define a kind of " uncontrolled " space multiplexing mode, wherein transmitter only sends a plurality of data flow (not carrying out any spatial manipulation) from many transmit antennas, and necessary spatial manipulation carried out by receiver so that the data flow of isolating and recovering to send from many transmit antennas.For also having an example, can define a kind of " multi-user " space multiplexing mode, wherein access point sends to a plurality of user terminals (using spatial manipulation) to a plurality of data flow from many transmit antennas concurrently on up link.For an example is arranged again, can define a kind of space multiplexing mode, wherein transmitter is carried out spatial manipulation attempting that a plurality of data flow that send on many transmit antennas are carried out orthogonalization (but may because incomplete channel estimating and not exclusively success), and receiver is carried out requisite space and handled and isolate and recovers from the data flow of many transmit antennas transmissions.Like this, for the spatial manipulation of carrying out via a plurality of data flow of many radical spaces channels transmit can carried out with upper/lower positions: (1) at both places of transmitter and receiver, (2) only at the receiver place, perhaps (3) are only at the transmitter place.Can use different spatial reuses according to following factor, for example the ability of access point and user terminal, available channel condition information, system requirements or the like.

Usually, access point and user terminal can be designed to any amount of transmitting antenna and reception antenna.For simplicity, be described below certain embodiments and design, wherein each access point is equipped with four transmit/receive antennas, and each user terminal all is equipped with four or less transmit/receive antenna.

2.OFDM

In one embodiment, the MIMO wlan system adopts OFDM that the total system bandwidth is divided into a plurality of (N effectively _F) orthogonal subbands.These subbands also can be called as tone, frequency band or frequency channels.According to OFDM, each subband all is associated with corresponding subcarrier, and subcarrier can be modulated with data.For the mimo system that uses OFDM, each space channel of each subband can be regarded as a transmission channel independently, and the complex gain that is associated with each subband is all constant on the subband bandwidth whereby.

In one embodiment, to be divided into 64 orthogonal subbands (be N to system bandwidth _F=64), be assigned to index-32 to+31.In these 64 subbands, for data use 48 subbands (for example index be ± 1 ...; 6,8 ...; 20; 22 ..., 26}); for pilot tone and possible signaling use 4 subbands (for example index be ± { 7; 21}), DC subband (index is 0) does not use, and the subband of adventure does not use yet and serves as the protection subband.This OFDM sub band structure is described in further detail in the document of ieee standard 802.11a, the document is entitled as " Part 11:Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) Specifications:High-Speed Physical Layer in the 5GHz Band; " propose in September, 1999, it can obtain for the public, and incorporated herein by reference.Also can use subband and various other OFDM sub band structure of varying number for the MIMO wlan system, this within the scope of the invention.For example, can make whole 53 index of index of reference from-26 to+26 for transfer of data.For another example, can use the structure of 128 subbands, the structure of 256 subbands and sub band structure with some other numbers of sub-band.For clear, the MIMO wlan system with above-mentioned 64 sub band structure is described below.

For OFDM, the data that send on each subband are at first modulated (being symbol mapped) with a certain modulation schemes of selecting for use for this subband.For untapped subband provides null value.For each code-element period, all the modulated symbol and the null value of NF subband all use invert fast fourier transformation (IFFT) to transform to time domain, so that obtain to comprise the conversion code element of NF time-domain sampling.The duration of each conversion code element all is inversely related with the bandwidth of each subband.In a particular design of MIMO wlan system, system bandwidth is 20MHz, NF=64, and the bandwidth of each subband is 312.5KHz, the duration of each conversion code element is 3.2 microseconds.

OFDM can provide specific advantage, and the ability such as the decline of contrary frequency selectivity is characterized in that at the different frequency place of total system bandwidth different channel gains being arranged.Be well known that frequency selective fading causes the interference (ISI) between code element, ISI is a kind of phenomenon of the interference of subsequent symbol during each code element in the received signal is all served as to received signal.The ISI distortion makes performance degradation by the ability that influence is correctly decoded receiving symbol.Part by repeating each conversion code element (or adhere to a Cyclic Prefix to it) forms corresponding OFDM code element, can easily tackle frequency selective fading with OFDM, and corresponding OFDM code element is sent out subsequently.

The length of the Cyclic Prefix of each OFDM code element (i.e. the amount that will repeat) depends on the delay expansion of wireless channel.Particularly, in order to resist ISI effectively, it is long that Cyclic Prefix should postpone expansion than the greatest expected of system.

In one embodiment, can use the Cyclic Prefix of different length for the OFDM code element, this depends on the delay expansion of expection.For above-mentioned specific MIMO wlan system, can select for 400 nanoseconds the Cyclic Prefix of (8 samplings) or 800 nanoseconds (16 samplings) for use for the OFDM code element." weak point " OFDM code element is used the Cyclic Prefix of 400 nanoseconds, and the duration is 3.6 microseconds." length " OFDM code element is used the Cyclic Prefix of 800 nanoseconds, and the duration is 4.0 microseconds.If the delay of greatest expected expansion then can be used short OFDM code element smaller or equal to 400 nanoseconds,, then can use long OFDM code element if postpone expansion greater than 400 nanoseconds.Can select different Cyclic Prefix for use for different transmission channels, Cyclic Prefix also can dynamically be selected, and is as described below.By may the time use short Cyclic Prefix can realize the higher system throughput because in a given Fixed Time Interval, can send short OFDM code element of more durations.

The MIMO wlan system can be designed to not use OFDM, and this within the scope of the invention.

The layer structure

Fig. 2 has illustrated the layer structure 200 that can be used for the MIMO wlan system.Layer structure 200 comprises: (1) approximate the 3rd layer of application and higher level protocol that reaches with upper strata (higher level) corresponding to the ISO/OSI reference model, (2) corresponding to the agreement and the service of the 2nd layer (link layer), and (3) are corresponding to the agreement and the service of the 1st layer (physical layer).

Higher level comprises various application and agreement, such as signaling service 212, data, services 214, voice service 216, circuit data applications or the like.Signaling generally is provided as message, and data generally are provided as grouping.Service in the higher level and the meaning of one's words and the sequential used according to communication protocol between access point and the user terminal begin and termination messages and grouping.Higher level is provided by the 2nd layer of service that is provided.

Support the message that higher level generated and the transmission of grouping for the 2nd layer.In the embodiment shown in Figure 2, the 2nd layer comprises link access control (LAC) sublayer 220 and medium access control (MAC) sublayer 230.LAC has realized the sublayer SDL, and the message that higher level generates can correctly be transmitted and transmit to this agreement.Media access control sublayer and the 1st layer of service that is provided are provided in the LAC sublayer.Media access control sublayer is responsible for using the 1st layer of service that is provided to come message transfer and grouping.Application and service in the media access control sublayer control RLP system higher level is to the access of the 1st layer of resource.Media access control sublayer can comprise radio link protocol (232), and this agreement is used to the retransmission mechanism that grouped data provides higher reliability.The 2nd course provides protocol Data Unit (PDU) for the 1st layer.

The 1st layer of transmission and reception that comprises physical layer 240 and support wireless signal between access point and the user terminal.Physical layer is carried out for each transmission channel and is encoded, interweaves, modulation and spatial manipulation, and described transmission channel is used for sending message and the grouping that higher level generates.In this embodiment, physical layer comprises a multiplex sublayer 242, and multiplex sublayer 242 is multiplexed into correct frame format to the PDU that handles for each transmission channel.The 1st layer is that unit provides data with the frame.

Fig. 2 illustrates the specific embodiment of the layer structure that can be used for the MIMO wlan system.Can also and use various other suitable layer structures for the MIMOWLAN system design, this within the scope of the invention.Every layer of performed function is described in further detail below.

4. transmission channel

A plurality of services and application can be supported by the MIMO wlan system.In addition, correct other required data of system operation may be sent and be exchanged between access point and user terminal by access point.Can define a plurality of transmission channels so that transmit Various types of data for the MIMO wlan system.Table 3 is listed one group of exemplary transmission channel, and the concise and to the point description of each transmission channel also is provided.

Table 3

Transmission channel		Describe
			Broadcast channel	BCH	Access point is used for a pilot tone and system parameters and sends to user terminal.
Forward control channel	FCCH	Access point is used for Resources allocation on down link and up link.Resource allocation can frame by frame be carried out.Also be used for providing affirmation for the message that receives on the RACH.
			Forward channel	FCH	Access point is used for customer-specific data is sent to user terminal, and may send user terminal and carry out the employed index of channel estimating (pilot tone).Also may be used for a paging and broadcast in broadcast mode sends to a plurality of user terminals.
Direct access communications channels	RACH	User terminal is used for obtaining sending to access point to the access of system and short message.
			Backward channel	RCH	User terminal is used for data are sent to access point.Can also transmit access point is the index that channel estimating is used.

As shown in table 3, the employed downlink transmission channel of access point comprises BCH, FCCH and FCH.The employed uplink transmission channels of user terminal comprises RACH and RCH.Each of these transmission channels all is described in further detail below.

The transmission channel of listing in the table 3 has represented to can be used for a specific embodiment of the channel architecture of MIMO wlan system.Also can for the use of MIMO wlan system definition less, additional and/or different transmission channels.For example, specific function can be supported by the transmission channel (for example pilot tone, paging, power control and synchronizing channel) of function special use.Like this, can be other channel architecture that the MIMO wlan system defines and use has different transmission channel groups, this within the scope of the invention.

5. frame structure

Can define a plurality of frame structures for transmission channel.The particular frame structure that is used for the MIMO wlan system depends on various factors, be that down link uses identical or different frequency bands with up link such as (1), and (2) is used for the multiplexing multiplexing scheme together of transmission channel.

If only there is a frequency band to use, then can use time division duplex (TDD) on the out of phase of a frame, to send down link and up link, as described below.If there are two frequency bands to use, then use Frequency Division Duplexing (FDD) (FDD) on different frequency bands, to send down link and up link.

For TDD and FDD, transmission channel can be multiplexed in together with time division multiplexing (TDM), code division multiplexing (CDM), frequency division multiplexing (FDM) or the like.For TDM, each transmission channel all is assigned to a different piece of a frame.For CDM, transmission channel is sent out concurrently, but each transmission channel all comes channelizing by a different channelization code, is similar to the channelizing of carrying out in code division multiple access (CDMA) system.For FDM, each transmission channel all is assigned to a different piece of link frequency bands.

Table 4 is listed the various frame structures that can be used to transmit transmission channel.Each of these frame structures all is described in further detail below.For clear, for this group transmission channel of listing in the table 3 has been described frame structure.

Table 4

	The shared frequency band of down link and up link	The separately frequency band of down link and up link
			Time diversity	The TDD-TDM frame structure	The FDD-TDM frame structure
Coded diversity	The TDD-CDM frame structure	The FDD-CDM frame structure

Fig. 3 A has illustrated the embodiment of a TDD-TDM frame structure 300a, and this structure can be used when using single frequency band for down link and up link.Transfer of data is that unit takes place with the tdd frame.Each tdd frame can be defined as striding across a special time duration.The frame duration can be selected based on various factors, the bandwidth of (1) working band for example, desired size of the PDU of (2) transmission channel or the like.The delay of minimizing can be provided than the short frame duration usually.Yet the long frame duration may be more effective, because header and expense can be represented the smaller portions of a frame.In a certain embodiments, the duration of each tdd frame is 2 milliseconds.

Each tdd frame all is divided into down link phase place and up link phase place.For three downlink transmission channel-BCH, FCCH and FCH, the down link phase place further is divided into three segmentations.For two uplink transmission channels-RCH and RACH, the up link phase place further is divided into two segmentations.

Fixedly duration that the segmentation of each transmission channel can be defined as changing frame by frame or variable duration.In one embodiment, the BCH segmentation has been defined as fixing duration, and FCCH, FCH, RCH and RACH segmentation have been defined as the variable duration.

The segmentation of each transmission channel can be used to transmit the one or more protocol Data Units (PDU) for this transmission channel.In the specific embodiment shown in Fig. 3 A, in the down link phase place, BCH PDU is sent out in first segmentation 310, and FCCH PDU is sent out in second segmentation 320, and one or more FCH PDU are sent out in the 3rd segmentation 330.On the up link phase place, one or more RCH PDU are sent out in the 4th segmentation 340, and one or more RACH PDU are sent out in the 5th segmentation 350 of tdd frame.

Frame structure 300a represents the particular topology of each transmission channel in the tdd frame.This layout can provide specific benefit for the transfer of data on down link and the up link, such as the delay that reduces.BCH at first is sent out in tdd frame, because he transmits the system parameters that can be used for the PDU of other transmission channel in the same tdd frame.FCCH then is sent out, because its transmission channel assignment information, described channel allocation information are illustrated in and have specified which user terminal to receive the down link data on the FCH in the current tdd frame and specified which user terminal to receive uplink data on the RCH.Also can and use other TDD-TDM frame structure for the definition of MIMO wlan system, this within the scope of the invention.

Fig. 3 B has illustrated the embodiment of the FDD-TDM frame structure 300b that may use when using two frequency bands that separate to send down link and up link.Down link data is sent out in descending chain circuit frame 302a, and uplink data is sent out in uplink frame 302b.Each down link and uplink frame can be defined the specific time remaining phase (for example 2 milliseconds) that strides across.For simplicity, down link can be defined as having the identical duration with uplink frame, and further is defined on the frame boundaries and aligns.Yet, also can use (i.e. skew) frame boundaries of different frame durations and/or non-alignment for down link and up link.

Shown in Fig. 3 B, for three downlink transmission channel, descending chain circuit frame is divided into three segmentations.For two uplink transmission channels, uplink frame is divided into two segmentations.The segmentation of each transmission channel can be defined as the fixing or variable duration, and can be used for transmitting one or more PDU for this transmission channel.

In the specific embodiment shown in Fig. 3 B, descending chain circuit frame transmits BCH PDU, a FCCH PDU and one or more FCH PDU respectively in segmentation 310,320 and 330.Uplink frame transmits one or more RCH PDU and one or more RACH PDU respectively in segmentation 340 and 350.This particular topology can provide the above-mentioned benefit delay of the minimizing of transfer of data (for example for).As described below, transmission channel has different PDU forms.Also can define and use other FDD-TDM frame structure for the MIMO wlan system, this within the scope of the invention.

Fig. 3 C has illustrated the embodiment of also operable FDD-CDM/FDM frame structure 300c when down link and up link use frequency band separately to send.Down link data can be sent out in descending chain circuit frame 304a, and uplink data can be sent out in uplink frame 304b.Down link can be defined as the identical duration (for example 2 milliseconds) and align at the frame boundaries place with uplink frame.

Shown in Fig. 3 C, in descending chain circuit frame, send three downlink transmission channel concurrently, in uplink frame, send two uplink transmission channels concurrently.For CDM, the transmission channel of each link comes " channelizing " with different channelization code, and described channelization code can be Walsh sign indicating number, orthogonal variable spreading factor (OVSF) sign indicating number, class orthogonal function (QOF) or the like.For FDM, the transmission channel of each link is assigned to the different piece of this link frequency bands.Also can use the transmitted power of varying number for the different transmission channels in each link.

Also can use other frame structure for down link and uplink transmission channels, this within the scope of the invention.In addition, may be down link and the dissimilar frame structure of up link use.For example, can be the frame structure of down link use, and be that up link is used the frame structure based on CDM based on TDM.

In the following description, suppose that the MIMO wlan system is that down link and ul transmissions are used a frequency band.For clear, the TDD-TDM frame structure shown in Fig. 3 A is used for the MIMO wlan system.For clear, the specific implementation of TDD-TDM frame structure is described in this manual.Realize that for this duration of each tdd frame all is fixed to 2 milliseconds, the OFDM number of symbols of every tdd frame is the function of the used paging prefix length of OFDM code element.The fixedly duration of BCH is 80 microseconds, and is that the OFDM code element of being launched is used the paging prefix of 800 nanoseconds.If use the paging prefix of 800 nanoseconds, then the remainder of tdd frame comprises 480 code elements, if use the Cyclic Prefix of 400 nanoseconds, then the remainder of tdd frame comprises the excessive time that 533 OFDM code elements add 1.2 microseconds.This excessive time can be added to protection in the end of RACH segmentation at interval.Also can use other frame structure and other realization, this within the scope of the invention.

II. transmission channel

Transmission channel is used for sending Various types of data, and can be classified as two groups: Common transport channel and dedicated transmission channel.Owing to, therefore can use different processing, following being described in further detail for these two groups of transmission channels for various objectives has been used public and dedicated transmission channel.

Common transport channel.Common transport channel comprises BCH, FCCH and RACH.These transmission channels are used for data are sent to a plurality of user terminals or receive data from a plurality of user terminals.For improved reliability, BCH and FCCH are sent with diversity mode by access point.On up link, RACH is sent with wave beam control model (if user terminal support) by user terminal.BCH makes user terminal need not any additional information receive and treatments B CH with known fixed rate work.FCCH and RACH support a plurality of speed to allow higher efficient.As used herein, each " speed " or " rate set " and a specific code rate (or encoding scheme) and a specific modulation scheme are associated.

Dedicated transmission channel.Dedicated transmission channel comprises FCH and RCH.These transmission channels are commonly used to customer-specific data is sent to specific user terminal.As required with according to available situation, FCH and RCH can be dynamically allocated to user terminal.FCH can also be used for an expense, paging and broadcast and send to user terminal in broadcast mode.Usually, before the arbitrary customer-specific data on the FCH, send expense, paging and broadcast.

Fig. 4 has illustrated the exemplary transmission on BCH, FCCH, FCH, RCH and RACH based on TDD-TDM frame structure 300a.In this embodiment, a BCH PDU 410 and a FCCH PDU 420 are sent out in BCH segmentation 310 and FCCH segmentation 320 respectively.FCH segmentation 330 can be used for sending one or more FCH PDU 430, and each FCH PDU 430 can point to a specific user terminal or a plurality of user terminal.Similarly, one or more RCH PDU 440 can be sent out in RCH segmentation 340 by one or more user terminals.The beginning of each FCH/RCH PDU all is offset by the FCH/RCH that finishes from last segmentation to be represented.RACH PDU 450 can be sent in RACH segmentation 350 so that connecting system and/or send SMS message is as described below by a plurality of user terminals.

For clear, for the specific T DD-TDM frame structure shown in Fig. 3 A and 4 has been described transmission channel.

1. broadcast channel (BCH)-down link

Access point uses BCH that beacon pilot frequency, MIMO pilot tone and system parameters are sent to user terminal.User terminal uses beacon pilot frequency to come capture systems sequential and frequency.User terminal uses the MIMO pilot tone to estimate the mimo channel that the antenna by access point antenna and they self forms.Be described in further detail beacon pilot frequency and MIMO pilot tone below.System parameters has been specified each attribute of down link and ul transmissions.For example, because the duration of FCCH, FCH, RACH and RCH segmentation is variable, then in BCH, be sent as the system parameters that current tdd frame is specified the length of each in these segmentations.

Fig. 5 A has illustrated the embodiment of BCH PDU 410.In this embodiment, BCH PDU 410 comprises leader part 510 and message part 516.Leader part 512 also comprises beacon pilot frequency part 512 and MIMO pilot portion 514.Part 512 transmits beacon pilot frequency, and fixedly the duration is the TCP=8 microsecond.Part 514 transmits the MIMO pilot tone, and fixedly the duration is the TMP=32 microsecond.Part 516 transmits BCH message, and fixedly the duration is the TBM=40 microsecond.The duration of BCH PDU is fixed on the TCP+TMP+TBM=80 microsecond.

Leader can be used for sending the pilot tone and/or the out of Memory of a class or multiclass.Beacon pilot frequency comprises the one group of specific modulated symbol that sends from whole transmitting antennas.The MIMO pilot tone comprises one group of specific modulated symbol of encoding and sending from whole transmitting antennas with different orthogonal, makes to receive the pilot tone that functional recovery sends from every antenna.For beacon and MIMO pilot tone can be used not on the same group modulated symbol.The generation of beacon and MIMO pilot tone is described in further detail below.

BCH message transfer service configuration information.Table 5 has been listed each field of an exemplary BCH message message format.

Table 5-BCH message

Field/parameter name	Length (bit)	Describe
			Frame counter	4	The tdd frame counter
Network ID	10	Network identifier (ID)
			AP ID	6	Access point ID
AP Tx Lvl	4	The access point launching electrical level
			AP Rx Lvl	3	The access point incoming level
FCCH length	6	The duration of FCCH (unit is the OFDM code element)
			FCCH speed	2	The physical layer rate of FCCH
FCH length	9	The duration of FCH (unit is the OFDM code element)
			RCH length	9	The duration of RCH (unit is the OFDM code element)
RACH length	5	The duration of RACH (unit is the RACH time slot)
			RACH time slot size	2	The duration of each RACH time slot (unit is the OFDM code element)
RACH protects at interval	2	Protection interval in RACH end
			The Cyclic Prefix duration	1	The Cyclic Prefix duration
The paging bit	1	The broadcast " 1 " of the last transmission of " 0 "=FCH=do not have beep-page message to send
			The broadcasting bit	1	The broadcast " 1 " of the last transmission of " 0 "=FCH=do not have broadcast to send
The RACH acknowledgement bit	1	The RACH affirmation " 1 " of the last transmission of " 0 "=FCH=do not have RACH to confirm and to send
			CRC	16	The crc value of BCH message
The tail bit	6	The tail bit of convolution coder
			Keep	32	Be retained for using in the future

Frame counter can be used to each process (for example pilot tone, scrambler, overlay code or the like) at synchronous access point and user terminal place.Frame counter can be realized with 4 bit counter of wraparound.This counter increases one when the beginning of each tdd frame, Counter Value is included in the frame counter field.The network ID field has been represented the identifier (ID) of access point belonging network.The AP id field has been represented the ID of access point in the network ID.AP Tx Lvl and AP Rx Lvl field have been represented the maximum transit power level at access point place and the received power level of expectation respectively.User terminal can use the received power level of expectation to determine the initial uplink transmitted power.

FCCH length, FCH length and RCH length field have been represented FCCH, the FCH of current tdd frame and the length of RCH field respectively.The length of these fields is that unit provides with the OFDM code element.The OFDM code element duration of BCH is fixed on 4.0 microseconds.The OFDM code element duration of all other transmission channels (being FCCH, FCH, RACH and RCH) all is variable, and depends on selected Cyclic Prefix, and Cyclic Prefix is specified by Cyclic Prefix duration field.The FCCH speed field has been represented the employed speed of the FCCH of current tdd frame.

The RACH length field has been represented the length of RACH field, and it is that unit provides with the RACH time slot.The duration of each RACH time slot is provided by RACH time slot size field, and unit is the OFDM code element.RACH protection interval field has been represented the time quantum of the BCH segmentation of a last RACH time slot and next tdd frame between beginning.Each field of this of RACH is described in further detail below.

Paging bit and broadcasting bit have represented whether sent beep-page message and broadcast on the FCH respectively in current tdd frame.These two bits can be provided with independently for tdd frame.The RACH acknowledgement bit represented in current tdd frame to send on the FCCH before the tdd frame, whether send the affirmation to PDU on RACH.

Crc field comprises the crc value of whole BCH message.This crc value can be used for determining that the BCH message that receives is correctly decoded (promptly being) or quilt decoding (promptly being wiped free of) mistakenly by user terminal.The tail bit field comprises one group of null value, and this group null value is used in the end of BCH message convolution coder being reset to known state.

As shown in table 5, BCH message comprises 120 bits altogether.By using the processing of describing in detail below, these 120 bits can be sent out with 10 OFDM code elements.

Table 5 illustrates a specific embodiment of the form of BCH message.Can also define and use other BCH message format with less, additional and/or different field, this within the scope of the invention.

2. forward control channel (FCCH)-down link

In one embodiment, access point can frame by frame be FCH and RCH Resources allocation.The resource allocation (being channel allocation) that access point uses FCCH to pass on FCH and RCH.

Fig. 5 B has illustrated the embodiment of FCCH PDU 420.In this embodiment, FCCH PDU only comprises the part 520 of FCCH message.FCCH message has the variable duration that can change along with the variation of frame, and this depends on the schedule information amount that transmits on the FCCH of this frame.The FCCH message duration is an even number OFDM code element, and is provided by the FCCH length field on the BCH message.Use the duration of the message (for example BCH and FCCH message) of diversity mode transmission to provide with even number OFDM code element, because it is diversity mode sends the OFDM code element in couples, as described below.

In one embodiment, FCCH can send with four possible speed.The employed special speed of FCCH PDU is represented with the FCCH multiplicative model in the BCH message (Phy Mode) field in each tdd frame.Each FCCH speed is all corresponding to a specific code rate and a specific modulation scheme, and further is associated with specific transmission mode, and is shown in table 26.

FCCH message can comprise zero, one or more information element (IE).Each information element can be associated with a specific user terminal, and is used for providing expression FCH/RCH the information of resource allocation for this user terminal.Table 6 has been listed each field of an exemplary FCCH message format.

Table 6-FCCH message

Field/parameter name	Length (bit)	Describe
			N_IE	6	The IE number that comprises in the FCCH message

N_IE information element, each all comprises:

The IE type	4	The IE type
			MAC ID	10	Distribute to the ID of user terminal
Control field	48 or 72	The control field that is used for channel allocation
			Filling bit	Variable	In FCCH message, realize the filling bit of even number OFDM code element
CRC	16	The crc value of FCCH message
			The tail bit	6	The tail bit of convolution coder

The N_IE field shows the information element number that comprises in the FCCH message that sends in the current tdd frame.For each information element (IE) that comprises in the FCCH message, the IE type field shows the particular type of this IE.Defined a plurality of IE types and be used for to dissimilar transmission Resources allocation, as described below.

MAC IE field has been represented the specific user terminal that information element is pointed.Each user terminal is all registered to access point when communication session begins, and is access in and a little is assigned to unique MAC ID.This MAC ID is used for identifying subscriber terminal during session.

Control field is used for transmitting the channel allocation information of user terminal, and describes in detail below.The filling bit field comprises the filling bit of sufficient amount, makes that the total length of FCCH message is an even number OFDM code element.The FCCH crc field comprises a crc value, and user terminal can use described crc value to determine that the FCCH message that receives still is by decoded in error by decoding correctly.The tail bit field comprises the null value that is used in ending place of FCCH message convolution coder being reset to known state.Some fields in these fields have been described in further detail below.

As shown in table 1, the MIMO wlan system is that FCH and RCH support a plurality of transmission modes.In addition, user terminal can be activity or idle during connecting., defined multiclass IE and be used for distributing the FCH/RCH resource into dissimilar transmission.Table 7 is listed one group of exemplary IE type.

Table 7-FCCH IE type

The IE type	IE size (bit)	The IE type	Describe
				0	48	Diversity mode	Diversity mode only
1	72	Space multiplexing mode	Space multiplexing mode-variable rate services
				2	48	Idle pulley	Idle condition-variable rate services
3	48	RACH confirms	RACH affirmation-diversity mode
				4		The wave beam control model	The wave beam control model
5-15	-	Keep	Keep for using in the future

For IE type 0,1 and 4, for FCH and RCH give specific user terminal (promptly with channel form being distributed) resource allocation.For IE type 2, on FCH and RCH, give minimum resource allocation user terminal to keep the latest estimated of link.The example format of each IE type is described below.Usually, the speed of FCH and RCH and duration can be distributed to user terminal independently.

A.IE type 0,4-diversity/wave beam control model

IE type 0 and 4 is used for being diversity mode and wave beam control model distribution FCH/RCH resource respectively.For fixing Low rate services (for example voice), speed was maintained fixed for the duration of calling out.For variable rate services, speed can be selected independently to FCH and RCH.FCCH IE represents to distribute to the position of the FCH and the RCH PDU of user terminal.Table 8 is listed exemplary IE type 0 and each field of 4 information elements.

Table 8-FCCH IE type 0 and 4

Field/parameter name	Length (bit)	Describe
			The IE type	4	The IE type
MAC ID	10	Distribute to the interim ID of user terminal
			The FCH skew	9	The FCH that begins from tdd frame is offset (representing with the OFDM code element)
FCH leader type	2	FCH leader size (representing) with the OFDM code element
			FCH speed
	4	The speed of FCH
			The RCH skew	9	The RCH that begins from tdd frame is offset (representing with the OFDM code element)
RCH leader type	2	RCH leader size (representing) with the OFDM code element
			RCH speed
	4	The speed of RCH
			RCH regularly regulates	2	Parameter is regulated in the timing of RCH
The control of RCH power	2	The power control bit of RCH

FCH and RCH offset field are represented the time migration that branch is clipped to the beginning of FCH and RCH PDU that begins from current tdd frame, are distributed by information element.FCH and RCH speed field are represented the speed of FCH and RCH respectively.

FCH and RCH leader type field are represented the size of leader among FCH and the RCH PDU respectively.Table 9 is listed FCH and the value of RCH leader type field and relevant leader size.

Table 9-leader type

Type	Bit	The leader size
			0	00	0 OFDM code element
1	01	1 OFDM code element
			2	10	4 OFDM code elements
3	11	8 OFDM code elements

RCH regularly regulates field and comprises two bits from the timing of the ul transmissions of user's terminal that are used for regulating by MAC id field sign.This regularly regulates the interference in the frame structure (than frame structure as shown in Figure 3A) that is used for reducing based on TDD, and wherein down link and ul transmissions are time division duplexs.Table 10 is listed RCH and is regularly regulated the value of field and relevant action.

Table 10-RCH regularly regulates

Bit	Describe
		00	Keep current timing
01	Up link is sent 1 sampling of timing advance
		10	Up link is sent 1 sampling of constant time lag
11	Do not use

RCH power control field comprises two bits that are used for regulating from the transmitted power of the ul transmissions of institute's identifying subscriber terminal.This power control field is used for reducing the interference on the up link.Table 11 is listed the value and relevant action of RCH power control field.

Table 11-RCH decides power control

Bit	Describe
		00	Keep current transmitted power
01	Up-link transmit power is improved δ dB, and wherein δ is a system parameters.
		10	Up-link transmit power is reduced δ dB, and wherein δ is a system parameters.
11	Do not use

The channel allocation of institute's identifying subscriber terminal can provide in every way.In one embodiment, user terminal only is assigned to the FCH/RCH resource for current tdd frame.In another embodiment, before cancellation, give terminal the FCH/RCH resource allocation for each tdd frame.In also having an embodiment, give user terminal the FCH/RCH resource allocation for every n tdd frame, this is called as " extraction " scheduling of tdd frame.Different types of assignment can be shown by the distribution type field in the FCCH information element.

B.IE Class1-space multiplexing mode

IE Class1 usage space multiplexer mode is given user terminal the FCH/RCH resource allocation.The speed of these user terminals is variable, and can select independently for FCH and RCH.Table 12 is listed each field of an exemplary IE Class1 information element.

Table 12-FCCH IE Class1

Field/parameter name	Length (bit)	Describe
			The IE type	4	The IE type
MAC ID	10	Distribute to the interim ID of user terminal
			The FCH skew	9	FCH skew (representing) from the FCCH ending with the OFDM code element
FCH leader type	2	FCH leader size (representing) with the OFDM code element
			FCH space channel 1 speed	4	The FCH speed of space channel 1
FCH space channel 2 speed	4	The FCH speed of space channel 2
			FCH space channel 3 speed	4	The FCH speed of space channel 3
FCH space channel 4 speed	4	The FCH speed of space channel 4
			The RCH skew	9	RCH skew (representing) from the FCH ending with the OFDM code element
RCH leader type	2	RCH leader size (representing) with the OFDM code element
			RCH space channel 1 speed	4	The RCH speed of space channel 1
RCH space channel 2 speed	4	The RCH speed of space channel 2
			RCH space channel 3 speed	4	The RCH speed of space channel 3
RCH space channel 4 speed	4	The RCH speed of space channel 4
			RCH regularly regulates	2	Parameter is regulated in the timing of RCH
Keep
		2	Keep for using in the future

For the IE Class1, the speed of each space channel can be selected on FCH and RCH independently.The speed decipher of space multiplexing mode is normally because it can specify the speed (nearly four space channels being arranged for the embodiment shown in the table 12) of each space channel.If transmitter is carried out spatial manipulation so that send data on eigenmodes, then provide speed according to each eigenmodes.If transmitter only sends data and receiver is carried out spatial manipulation so that isolate and restore data (for uncontrolled space multiplexing mode) from transmitting antenna, then provide speed according to every antenna.

Information element comprises the speed of the space channel that all is activated, and is null value for the channel that is not activated.Have the user terminal that is less than four transmit antennas untapped FCH/RCH space channel speed field is made as zero.Because access point is equipped with four transmit/receive antennas, therefore has more than the user terminal of four transmit antennas and can launch nearly four independent data streams with them.

C.IE type 2-idle pulley

IE type 2 is used for providing control information (as described below) for the user terminal that is operated under the idle condition.In one embodiment, when user terminal is in idle condition, upgrade the dominant vector that is used for carrying out spatial manipulation by access point and user terminal constantly, make transfer of data when continuing, can begin fast.Table 13 is listed each field of exemplary IE type 2 information elements.

Table 13-FCCH IE type 2

Field/parameter name	Length (bit)	Describe
			The IE type	4	The IE type
MAC ID	10	Distribute to the interim ID of user terminal
			The FCH skew	9	The FCH skew (representing) that white FCCH has ended up with the OFDM code element
FCH leader type	2	FCH leader size (representing) with the OFDM code element
			The RCH skew	9	RCH skew (representing) from the FCH ending with the OFDM code element
RCH leader type	2	RCH leader size (representing) with the OFDM code element
			Keep	12	Keep for using in the future

D.IE type 3-RACH confirms fast

IE type 3 is used for providing quick affirmation for attempting by the user terminal of RACH connecting system.Send SMS message for the access of the system of acquiring or to access point, user terminal can send RACHPDU on up link.After user terminal had sent RACH PDU, it monitored that BCH is to determine whether to be provided with the RACH acknowledgement bit.If arbitrary user terminal has successfully inserted system and on FCCH at least one user terminal has sent affirmation, then this bit is by the access point setting.If be provided with this bit, user terminal is just handled FCCH for FCCH goes up the affirmation that sends.If access point is wished not Resources allocation and confirms the RACH PDU that it is correctly decoded from user terminal that then IE type 3 information elements are sent out.Table 14 is listed each field of exemplary IE type 3 information elements.

Table 14-FCCH ID type 3

Field/parameter name	Length (bit)	Describe
			The IE type	4	The IE type
MAC ID	10	Distribute to the interim ID of user terminal
			Keep	34	Keep for using in the future

Can on FCCH, define and send the affirmation of single or multiple types.For example, can define one confirms and an affirmation based on distribution fast.Affirmation can be used for only confirming that RACH PDU has been access in a reception fast, and does not distribute the FCH/RCH resource to user terminal.Comprise distribution based on the affirmation that distributes for the FCH and/or the RCH of current tdd frame.

FCCH can otherwise realize, also can be sent out in every way.In one embodiment, FCCH is sent out with the single speed that transmits in BCH message.All users' that this speed can be sent in current tdd frame based on for example FCCH lowest signal is selected noise and interference ratio (SNR).According to the channel adjustment of receiver's user terminal in each tdd frame, can use different speed for different tdd frames.

In another embodiment, FCCH realizes with a plurality of (for example four) FCCH subchannel.Each FCCH subchannel all is sent out with a different speed, and the required SNR different with is relevant, so that recover subchannel.The FCCH subchannel is sent out with the order of minimum speed limit to flank speed.Each FCCH subchannel may or may in given tdd frame, not be sent out.The one FCCH subchannel (having minimum speed limit) at first is sent out, and can be received by all user terminals.Whether this FCCH channel can show can send each remaining FCCH subchannel in current tdd frame.Each user terminal can be handled the FCCH subchannel that is sent and obtain its FCCH information element.Each user terminal can when following any point takes place the processing of termination FCCH: (1) fails the FCCH subchannel of decoding current, (2) in current FCCH channel, receive its FCCH information element, or the FCCH subchannel of (3) all transmissions is all processed.As long as user terminal runs into the processing that FCCH decoding failure just can stop FCCH, because the FCCH subchannel is sent out with the speed that rises, the follow-up FCCH subchannel that user terminal can not be able to be decoded and be sent with higher rate.

3. direct access communications channels (RACH)-up link

User terminal uses RACH to obtain to send SMS message to the access of system and to access point.The operation of RACH is based on the Aloha arbitrary access agreement of branch time slot, and this is described below.

Fig. 5 C has illustrated the embodiment of RACH PDU 450.In this embodiment, RACH PDU comprises leader part 552 and message part 554.If user terminal has many antennas, then leader part 552 can be used for sending a controlled benchmark.The pilot tone that controlled benchmark is made up of one group of special modulated symbol, it was subjected to spatial manipulation before sending on up link.Spatial manipulation is sent out pilot tone on a specific eigenmodes of mimo channel.Be described in further detail the processing of controlled benchmark below.Leader part 552 has the fixedly duration of at least 2 OFDM code elements.Message part 554 transmits a RACH message, and has the variable duration.Therefore the duration of RACH PDU is variable.

In one embodiment, support four different speed for RACH.The employed special speed of each RACH message is represented by the RACH data rate indicator (DRI) of one 2 bits.In one embodiment, also support four different message sizes for RACH.The size of each RACH message is all represented by the message part field that is included in the RACH message.Each support 1,2,3 of RACH speed or whole 4 message sizes.Table 15 is listed the message size that four RACH speed, their relevant codings and modulation parameter and these RACH speed are supported.

Table 15

RACH speed				RACH message size (is unit with bit and OFDM code element)
								Bps/Hz	Code rate	Modulation	DRI	96 bits	192 bits	384 bits	768 bits
0.25	0.25	BPSK	(1，1)	8	n/a	n/a	n/a
								0.5	0.5	BPSK	(1，-1)	4	8	n/a	n/a
1	0.5	QPSK	(-1，1)	2	4	8	n/a
								2	0.5	16QAM	(-1，-1)	1	2	4	8

RACH message sends from the short message of user's terminal and inserts request.Table 16 is listed each each field size of each field of an exemplary RACH message and four different messages sizes.

Table 16

Field/parameter name	The RACH message size				Describe
						96 bits	192 bits	384 bits	768 bits
	The message duration	2	2	2						2	The message duration
MAC PDU type					4	4	4	4	The RACH type of message
	MAC ID	10	10	10						10	MAC ID
Time slot ID					6	6	6	6	Tx time slot ID
	Pay(useful) load	44	140	332						716	Information bit
CRC					24	24	24	24	The crc value of RACH message
	The tail bit	6	6	6						6	The tail bit

Message duration field list is understood the size of RACH message.MAC PDU type field shows the RACH type of message.The MAC id field comprises the MAC ID that the energy unique identification sends the user terminal of RACH message.Between the starter system access periods, unique MAC ID is not assigned to user terminal.Under this situation, can in the MAC id field, comprise a registration MAC ID (for example particular value that keeps for the registration purpose).The time slot id field is represented the RACH time slot that begins, sends RACH PDU (describe below RACH regularly and transmission) on it.The pay(useful) load field comprises the information bit of RACH message.Crc field comprises the crc value of RACH message, tail bit field be used for the resetting convolution coder of RACH.Be described in further detail the operation of RACH below and be used for BCH and the FCCH that system inserts.

RACH also can realize with " fast " RACH (F-RACH) and " slowly " RACH (S-RACH).F-RACH and S-RACH can be designed to support effectively user terminal under the different operating state.For example, F-RACH can be used by user terminal: (1) to system registry, and (2) regularly compensate their round-trip delay (RTD) by their transmission in advance correctly, and (3) realize required SNR for the operation on the F-RACH.S-RACH can be used the user terminal of F-RACH to use in no instance.

Can for F-RACH and S-RACH use different designs so that whenever may be just connecting system apace, and make and realize the required amount minimum of arbitrary access.For example, F-RACH can use short PDU, adopts more weak encoding scheme, requires F-RACH PDU time proximity to arrive the access point place alignedly, and uses the Aloha random access scheme of dividing time slot.S-RACH can use long PDU, adopts stronger encoding scheme, allows S-RACH PDU to arrive access point in non-alignment ground in time, and uses the Aloha random access scheme that is regardless of time slot.

For simplicity, below description is assumed to the MIMO wlan system and uses single RACH.

4. forward channel (FCH)-down link

Access point uses FCH that customer-specific data is sent to specific user terminal, and paging/broadcast is sent to a plurality of user terminals.FCH can frame by frame be assigned with.Provide a plurality of FCH PDU types to adapt to the different purposes of FCH.Table 17 is listed one group of exemplary FCH PDU type.

Table 17-FCH PDU type

Coding	FCH PDU type	Describe
			0	Only can message	FCH broadcasting/paging service/user message
1	Message and leader	The FCH user message
			2	Only can leader	The FCH idle condition

FCH PDU type 0 is used for sending paging/broadcast and user message/grouping on FCH, and only comprises message/packet.(data of specific user terminal can be used as a message or a grouping is sent out, and these two terms are in this commutative use.) FCH PDU Class1 is used for sending user grouping and comprises a leader.FCHPDU type 2 only comprises leader and does not comprise any message/packet, and is associated with idle condition FCH traffic.

Fig. 5 D has illustrated the embodiment of the FCH PDU 430a of FCH PDU type 0.In this embodiment, FCH PDU 430a only comprises a message part 534a of paging/broadcast or user grouping.Message/packet can have length variable, and this length is provided by the FCH message length field among the FCH PDU.Message-length provides (describing below) with an integer PHY frame.Specify and described the speed and the transmission mode of paging/broadcast below.The speed and the transmission mode of user grouping in relevant FCCH information element, have been specified.

Fig. 5 E has illustrated the embodiment of the FCH PDU 430b of FCH PDU Class1.In this embodiment, FCH PDU 430b comprises a leader part 532b and a message/packet part 534b.Leader part 532b is used for sending MIMO pilot tone or controlled benchmark, and has length variable, and variable-length is provided by the FCH leader type field in the relevant FCCH information element.Part 534b is used for sending the FCH grouping, and also has length variable (representing with an integer PHY frame), and variable-length is provided by the FCH message length field among the FCH PDU.The FCH grouping sends with the speed and the transmission mode of relevant FCCH information element appointment.

Fig. 5 F has illustrated the embodiment of the FCH PDU 430c of FCH PDU type 2.In this embodiment, FCH PDU 430c only comprises leader part 532c, and does not comprise message part.The length of leader part is indicated by FCCH IE.FCH PDU type 2 can be used to make user terminal can upgrade its channel estimating in idle condition following time.

Provide a plurality of FCH type of messages to adapt to the different purposes of FCH.Table 18 has been listed one group of exemplary FCH type of message.

Table 18-FCH type of message

Coding	The FCH type of message	Describe
			0	Beep-page message	Beep-page message-diversity mode, speed=0.25bps/Hz
1	Broadcast	Broadcast-diversity mode, speed=0.25bps/Hz
			2	User grouping	The PDU that dedicated channel operation-user terminal is specific, the speed of appointment among the FCCH
3-15	Keep	Keep for using in the future

A beep-page message can be used for a plurality of user terminals of paging, and sends with FCH PDU type 0.If be provided with the paging bit in the BCH message, then at first on FCH, send one or more FCH PDU (i.e. " paging PDU ") with pilot tone message.In same frame, can send a plurality of paging PDU.The minimum speed limit of diversity mode and 0.25bps/Hz is used in the transmission of paging PDU, so that improve the correct probability that receives of user terminal.

One broadcast can be used to information is sent to a plurality of user terminals, and sends with FCH PDU type 0.If be provided with the broadcasting bit in the BCH message, then and then FCH goes up after any paging PDU that sends, and sends the one or more FCH PDU (i.e. " broadcasting PDU ") that have broadcast on FCH.The minimum speed limit of diversity mode and 0.25bps/Hz is also used in the transmission of broadcasting PDU, so that improve the correct probability that receives.

One user grouping can be used to send customer-specific data, and can send with FCH PDU Class1 or 2.Send on FCH after any paging and the broadcasting PDU, Class1 and 2 user PDU are sent out on FCH.Each user PDU can send with diversity, wave beam control or space multiplexing mode.The FCCH information element has been specified employed speed of each user PDU and the transmission mode that sends on FCH.

The message of the last transmission of FCH or grouping comprise an integer PHY frame.In one embodiment, as described below, each PHY frame can comprise a crc value, and this value makes can check and retransmit independent PHY frame among the FCH PDU in necessary formula.For asynchronous service, can adopt RLP that the PHY frame in the given FCH PDU is carried out segmentation, retransmits and ressembles.In another embodiment, provide a crc value for each message or grouping rather than for each PHY frame.

Fig. 6 has illustrated an embodiment of the structure of FCH grouping 534.The FCH grouping comprises an integer PHY frame 610.Each PHY frame 610 comprises pay(useful) load field 622, crc field 624 and tail bit field 626.The one PHY frame of FCH grouping also comprises header fields 620, its expression type of message and duration.Last PHY frame in the FCH grouping also comprises filling bit field 628, and this field 628 comprises the null value filling bit in ending place of pay(useful) load, so that fill last PHY frame.In one embodiment, each PHY frame comprises 6 OFDM code elements.The bit number that comprises in each PHY frame depends on the employed speed of this PHY frame.

Table 19 is listed each field of the exemplary FCH PDU form of FCH PDU type 0 and 1.

Table 19-FCH PDU form

	Field/parameter name	Length (bit)	Describe
				The one PHY frame	The FCH type of message	4	The FCH type of message
The FCH message-length	16	Byte number among the FCH PDU
			Pay(useful) load		Variable	The pay(useful) load bit
CRC	16	The crc value of PHY frame (optional)
			The tail bit		6	The tail bit of convolution coder
PHY frame in the middle of each	Pay(useful) load	Variable					The pay(useful) load bit
			CRC	16	The crc value of PHY frame (optional)
	The tail bit	6				The tail bit of convolution coder

Last PHY frame	Pay(useful) load	Variable	The pay(useful) load bit
				Filling bit	Variable	Fill up the filling bit of PHY frame
	CRC	16	The crc value of PHY frame (optional)
				The tail bit	6	The tail bit of convolution coder

FCH type of message and FCH message length field are sent out in the header of the PHY frame of FCH PDU.Pay(useful) load, CRC and tail bit field are included in each PHY frame.The pay(useful) load of each FCH PDU partly transmits the information bit of paging/broadcast or user's packet dedicated.Filling bit is used for filling as required last PHY frame of FCH PDU.

Also can define the OFDM code element that the PHY frame comprises some other quantity (for example 1,2,4,8 or the like).Because for diversity mode OFDM code element is to send in pairs, so the PHY frame can define with even number OFDM code element, and diversity mode can be used for FCH and RCH.The PHY frame size can be selected based on the traffic of expection, makes the ineffectivity minimum.Particularly, if frame size is excessive, then produce ineffectivity by using a big PHY frame to send low volume data.Perhaps, if frame size is too small, then expense has been represented the most of frame.

5. backward channel (RCH)-up link

User terminal uses RCH that uplink data and pilot tone are sent to access point.RCH can be assigned with according to each tdd frame.Can specify one or more user terminals in arbitrary given tdd frame, on RCH, to send.Provide multiple RCH PDU type to adapt to different working modes on the RCH.Table 20 has been listed one group of exemplary RCH PDU type.

Table 20-RCH PDU type

Coding	RCH PDU type	Describe
			0	Message only	The RCH user message, no leader
1	Message and leader, not idle	The RCH user message has leader
			2	Message and leader, the free time	The RCH idle condition message that leader is arranged

RCH PDU type 0 is used for sending message/packet on RCH, and does not comprise leader.The RCHPDU Class1 is used for sending message/packet, and comprises leader.RCH PDU type 2 comprises leader and short message, and is associated with the RCH traffic of idle condition.

Fig. 5 D has illustrated the embodiment of the RCH PDU of RCH PDU type 0.In this embodiment, RCH PDU only comprises the message part 534a of variable-length RCH grouping, and this grouping is provided with an integer PHY frame by the RCH message length field among the RCH PDU.The speed of RCH grouping is specified in relevant FCCH information element with transmission mode.

Fig. 5 E has illustrated the embodiment of the RCH PDU of RCH PDUY Class1.In this embodiment, RCH PDU comprises leader partly 532b and grouping part 534b.Leader partly 532b is used for sending a benchmark (for example MIMO pilot tone or controlled benchmark), and has length variable, and described length is provided by the RCH leader type field in the relevant FCCH information element.Partly 534b is used for sending RCH grouping, and has length variable, and described variable-length is provided by the RCH message length field among the RCH PDU.The RCH grouping uses the speed and the transmission mode of appointment in the relevant FCCH information element to send.

Fig. 5 G has illustrated the embodiment of the RCH PDU 350d of RCH PDU type 2.In this embodiment, RCH PDU comprises leader partly 532d and message part 535d.Leader partly 532d is used for sending a benchmark, and length is 1,4 or 8 OFDM code element.Partly 536d is used for sending a short RCH message, and has the regular length of an OFDM code element.Short RCH message sends (for example speed 1/2 or speed 1/4 and BPSK modulation) with particular rate and transmission mode.

The grouping of the last transmission of RCH (for PDU type 0 and 1) comprises an integer PHY frame.Fig. 6 illustrates the structure of RCH grouping (for PDU type 0 and 1, for the FCH grouping equally so.The RCH grouping comprises an integer PHY frame 610.Each PHY frame comprises pay(useful) load field 622, crc field 624 and the tail bit field 626 chosen wantonly.PHY frame in the RCH grouping also comprises header part 620, and last the PHY frame in the grouping also comprises filling bit field 628.

Table 21 is listed each field of the exemplary RCH PDU form of RCH PDU type 0 and 1.

Table 21-RCH PDU form (PDU type 0 and 1)

	Field/parameter name	Length (bit)	Describe
				The one PHY frame	The RCH type of message	4	The RCH type of message
The RCH message-length	16	Byte number among the RCH PDU
			The FCH rate indicator		16	Show that FCH goes up the maximum rate of each space channel
Pay(useful) load	Variable	The pay(useful) load bit
			CRC		16	The crc value of PHY frame (optional)
The tail bit	6	The tail bit of convolution coder
			PHY frame in the middle of each		Pay(useful) load	Variable	The pay(useful) load bit
CRC	16	The crc value of PHY frame (optional)
				The tail bit	6	The tail bit of convolution coder

Last PHY frame	Pay(useful) load	Variable	The pay(useful) load bit
				Filling bit	Variable	Fill up the filling bit of PHY frame
	CRC	16	The crc value of PHY frame (optional)
				The tail bit	6	The tail bit of convolution coder

RCH type of message, RCH message-length and FCH rate indicator field are sent out in the header of the PHY frame of RCH PDU.FCH rate indicator field is used for a FCH rate information (for example each space channel support maximum rate) and is sent to access point.

Table 22 has been listed each field of the exemplary RCH PDU form of RCH PDU type 2.

The RCH message of table 22-RCH PDU type 2

Field/parameter name	Length (bit)	Describe
			The FCH rate indicator	16	Expression FCH goes up the maximum rate of each space channel
The RCH request	1	Send the user terminal requests of additional data
			Keep	1	Keep for using in the future
The tail bit	6	The tail bit of convolution coder

User terminal use RCH request field is asked the additional capacity on the up link.This weak point RCH message does not comprise CRC, and is sent out in single OFDM code element.

6. dedicated channel activity

Transfer of data on RCH and the RCH can take place independently.According to for RCH and RCH use the transmission mode of selecting, one or more space channels (controlling and diversity mode for wave beam) can be movable, and are used for the transfer of data of each dedicated transmission channel.Each space channel can be associated with a particular rate.

As FCH only or when only whole four speed of RCH are set as zero, user terminal is idle on this link.Non-occupied terminal still can send an idle PDU on RCH.When whole four speed of FCH and RCH all were set as zero, access point and user terminal were all closed and are not sent.The user terminal that is less than four transmit antennas is made as zero to obsolete speed field.Use more than the user terminal of four transmit antennas and to be no more than four space channels and to send data.Transmission rate and channel activity when table 23 is illustrated in speed on whole four space channels of one of FCH or RCH (or both) and is set as zero.

Table 23

FCH speed	RCH speed	Channel activity	Transmission state
				At least one speed ≠ 0 on the FCH	At least one speed ≠ 0 on the RCH	FCH and RCH are movable	FCH and/or RCH send
At least one speed ≠ 0 on the FCH	Whole speed=0 on the RCH	The FCH activity, the RCH free time
			Whole speed=0 on the FCH	At least one speed ≠ 0 on the RCH	The FCH free time, the RCH activity
Whole speed=0 on the FCH	Whole speed=0 on the RCH	FCH and RCH close				Not transmission

Have RCH and FCH all idle (promptly not sending data) but still send the situation of leader.This is called idle condition.As shown in table 13, in FCCH IE type 2 information elements, provide the control field that is used to support the user terminal under the idle condition.

7. other design

For simplicity, specific PDU type, PDU structure, message format or the like have been described for exemplary design.Also can define and use less, additional and/or different type, structure and forms, this within the scope of the invention.

The III.OFDM sub band structure

In the foregoing description, use identical OFDM sub band structure for whole transmission channels.By using different OFDM sub band structure can realize improved efficient for different transmission channels.For example, can use 64 sub band structure, can use the structure of 256 subbands for some other transmission channels for some transmission channels, or the like.In addition, can use a plurality of OFDM sub band structure for a given transmission channel.

For given system bandwidth W, the duration of OFDM code element is depended on sub-band sum.If sub-band sum is N, then each is N/W microsecond (if the unit of W is WHz) through the duration of conversion code element (not having Cyclic Prefix).Add a Cyclic Prefix to each through the code element of conversion and form corresponding OFDM code element.The length of Cyclic Prefix is determined by the desired delay spread of system.Cyclic Prefix is represented expense, and expense is the expense that each OFDM code element needs for the contrary frequency selective channel.If code element is very short, this expense is represented the OFDM code element of big percentage, if code element is very long, this expense is just represented the OFDM code element of less percentage.

Because different transmission channels can be associated with dissimilar traffic data, therefore can select a suitable OFDM sub band structure to be used for each transmission channel, so that be complementary with the traffic data type of expecting.If expection has mass data to send on given transmission channel, then can define bigger sub band structure and be used for this transmission channel.Under this situation, Cyclic Prefix can be represented the OFDM code element of less percentage and realize bigger efficient.On the contrary, if expection will send low volume data on a given transmission channel, then can define less sub band structure and be used for this transmission channel.Under this situation,, reduce the quantity of excessive capacity, still can realize higher efficient by using less OFDM code element size even Cyclic Prefix has been represented the big percentage of OFDM code element.Therefore, the OFDM code element can be regarded as one " boxcar (boxcar) ", can select " boxcar " of just size according to the data volume that expection will send for each transmission channel.

For example, for the above embodiments, the data on FCH and the RCH are sent out in the PHY frame, and each PHY frame all is made up of 6 OFDM code elements.Under this situation, can define another OFDM structure to be used for FCH and RCH.For example, can define the structure of 256 subbands for FCH and RCH." greatly " OFDM code element of 256 sub band structure can be approximate four times of 64 sub band structure " little " OFDM code element on the duration, but also can be four times on data transmission capacity.Yet, only need a Cyclic Prefix for a big OFDM code element, and need four Cyclic Prefix for four little OFDM code elements of equivalence.Like this, by using 256 bigger sub band structure can reduce by 75% cyclic redundancy expense number.

This notion can be expanded, thereby can use different OFDM sub band structure for same transmission channel.For example, RCH supports different PDU types, and each type all is associated with a specific size.Under this situation, can use bigger sub band structure for the RCH PDU type of large-size, and can use less sub band structure for the RCHPDU type of reduced size.Also can use the combination of different sub-band structure for given PDU.For example, if a long OFDM code element is equivalent to four weak points (OFDM) code element, then can use N _LargeIndividual big OFDM code element and N _SmallIndividual little OFDM code element sends PDU, wherein N _Large〉=0 and 3 〉=N _Small〉=0.

Different OFDM sub band structure is associated with the OFDM code element of different length.Like this, if be that different transmission channel (and/be same transmission channel) uses different OFDM sub band structure, then the FCH of FCH and RCHPDU and RCH skew meeting need be specified with correct temporal resolution, and this temporal resolution is less than an OFDM code-element period.Particularly, the incremental time of FCH and RCH PDU can provide with an integer circulating prefix-length, rather than the OFDM code-element period.

IV. speed and transmission mode

Above-mentioned transmission channel is used for being various services and function transmission Various types of data.Each transmission channel can be designed to support one or more speed and one or more transmission mode.

1. transmission mode

For transmission channel is supported multiple transmission mode.As described below, each transmission mode is all handled with the particular space at transmitter and receiver place and is associated.Table 24 is listed the transmission mode that each transmission channel is supported.

Table 24

Transmission channel	Transmission mode
					SIMO	Send diversity	Wave beam control	Spatial reuse
	BCH	-	X						-
FCCH					-	X	-	-
	RACH	X	-	X					-
FCH					-	X	X	X
	RCH	X	X	X					X

For diversity mode, for implementation space, frequency and/or time diversity, each data symbols all sends in many transmit antennas, a plurality of subband, a plurality of code-element period or their combination redundantly.For the wave beam control model, a first space channel is used for transfer of data (generally be best space channel), each data symbols all use transmitting antenna can with full transmitted power on single space channel, be sent out.For space multiplexing mode, a plurality of space channels are used for transfer of data, and each data symbols all is sent out on a space channel, and wherein a space channel is corresponding to an eigenmodes, a transmitting antenna or the like.The wave beam control model can be regarded as the special circumstances of space multiplexing mode, wherein only uses a space channel to carry out transfer of data.

Diversity mode can be used for the Common transport channel (BCH and FCCH) of the down link from the access point to the user terminal.Diversity mode also can be used for dedicated transmission channel (FCH and RCH).Diversity mode is consulted when the use on FCH and the RCH can be in call setup.Diversity mode uses a pair of antenna to go up one " spatial model " for each subband and sends data.

The wave beam control model can be adopted by the user terminal with many transmit antennas on RACH.User terminal can be gone up the MIMO pilot tone that sends based on BCH and estimate mimo channel.This channel estimating is used for carrying out wave beam control for system inserts then on RACH.The wave beam control model also can be used for dedicated transmission channel (FCH and RCH).By utilizing the gain of transmitter place antenna array, perhaps the wave beam control model can realize that than diversity mode higher signal is to noise and interference ratio (SNR) at the receiver place.In addition, because controlled benchmark only comprises the code element of single " controlled " antenna, so the leader of PDU partly can reduce.Diversity mode also can be used for RACH.

When channel condition was supported, space multiplexing mode can be used for FCH and RCH realizes higher throughput.Space multiplexing mode and wave beam control model are that benchmark drives, and correct operation is required closed-loop control.Like this, user terminal all is assigned to resource with the support space multiplexer mode on FCH and RCH.On FCH and RCH, can support nearly four space channels (being subjected to access point place antenna amount limits).

2. coding and modulation

For transmission channel is supported a plurality of different speed.Each speed and a specific code rate and a specific modulation scheme are associated, the back both in conjunction with producing a specific frequency spectrum efficient (or data rate).Table 25 is listed each speed that system supports.

Table 25

The speed word	Spectrum efficiency (bps/Hz)	Code rate	Modulation scheme	Information bit/OFDM code element	Coded-bit/OFDM code element
						0000	0.0	-	Do not have	-	-
0001	0.25	1/4	BPSK	12	48
						0010	0.5	1/2	BPSK	24	48
0011	1.0	1/2	QPSK	48	96
						0100	1.5	3/4	QPSK	72	96
0101	2.0	1/2	16 QAM	96	192
						0110	2.5	5/8	16 QAM	120	192
0111	3.0	3/4	16 QAM	144	192
						1000	3.5	7/12	64 QAM	168	288
1001	4.0	2/3	64 QAM	192	288
						1010	4.5	3/4	64 QAM	216	288
1011	5.0	5/6	64 QAM	240	288
						1100	5.5	11/16	256 QAM	264	384
1101	6.0	3/4	256 QAM	288	384
						1110	6.5	13/16	256 QAM	312	384
1111	7.0	7/8	256 QAM	336	384

Each Common transport channel is all supported one or more speed and transmission mode (or may be a plurality of, such as the situation of RACH).BCH uses diversity mode to be sent out with fixed rate.Use diversity mode, FCCH can be sent out with one of four possible speed, and is represented such as the FCCH multiplicative model field in the BCH message.In one embodiment, RACH can be sent out with one of four possible speed, and the RACH DRI that embeds in the leader as RACH PDU is indicated, and each RACH message all is one of four possible sizes.In another embodiment, RACH is sent out with single speed.Table 26 is listed coding, modulation and transmission parameter and the message size that each Common transport channel is supported.

The parameter of table 26-Common transport channel

Transmission channel	Spectrum efficiency (bps/Hz)	Code rate	Modulation scheme	Transmission mode	Message size
							RCH	0.25	1/4	BPSK	Diversity	120	10
RCCH	0.25	1/4	BPSK	Diversity	Variable	Variable
							“	0.5	1/2	BPSK	Diversity	Variable	Variable
“	1.0	1/2	QPSK	Diversity	Variable	Variable
							“	2.0	1/2	16QAM	Diversity	Variable	Variable
RACH	0.25	1/4	BPSK	Wave beam control	96	8
							“	0.5	1/2	BPSK	Wave beam control	96，192	4，8
“	1.0	1/2	QPSK	Wave beam control	96，192，384	2，4，8
							“	2.0	1/2	16QAM	Wave beam control	96，192， 384，768	1，2，4，8

The size of FCCH message is variable, and provides with even number OFDM code element.

Whole speed of listing in FCH and the RCH support matrix 25.Table 27 is listed coding, modulation and transmission parameter and the message size that FCH and RCH support.

The parameter of table 27-FCH and RCH

					The physical frame size
								Coded-bit	Modulated symbol	The OFDM code element
					0.25 A	1/4	BPSK				72	72	144	288	6
0.5	1/2	BPSK	144	144				288	288	6
					1.0	1/2	QPSK				288	288	576	288	6
1.5	3/4	QPSK	432	144				576	288	6
					2.0	1/2	16 QAM				576	576	1152	288	6
2.5	5/8	16 QAM	720	432				1152	288	6
					3.0	3/4	16 QAM				864	288	1152	288	6
3.5	7/12	64 QAM	1008	720				1728	288	6

4.0	2/3	64 QAM	1152	576	1728	288	6
								4.5	3/4	64 QAM	1296	432	1728	288	6
5.0	5/6	64 QAM	1440	288	1728	288	6
								5.5	11/16	256 QAM	1584	720	2304	288	6
6.0	3/4	256 QAM	1728	576	2304	288	6
								6.5	13/16	256 QAM	1872	432	2304	288	6
7.0	7/8	256 QAM	2016	288	2304	288	6

Annotate A: all on two subbands, repeat in each speed 1/2, so that obtain efficient coding speed 1/4.The redundant bit that the parity bits presentation code is introduced, and be used for the error correction of receiver.

PHY frame size in the table 27 is represented the number of coded-bit, modulated symbol and the OFDM code element of each PHY frame.If transfer of data has been used 48 data subbands, then each OFDM code element comprises 48 modulated symbols.For diversity and wave beam control model, send a code element stream, and the PHY frame size is corresponding to single speed that this code element stream adopted.For space multiplexing mode, a plurality of code element stream can be sent out on a plurality of space channels, and total PHY frame size can be determined by the PHY frame size sum of independent space channel.The PHY frame size of each space channel is determined by the speed that this space channel adopted.

For example, suppose mimo channel can be supported in 0.5,1.5,4.5 and the spectrum efficiency of 5.5bps/Hz under four spatial sub-channels of working.So shown in the table 28 be four speed that four space channels are selected.

Table 28-instance space multiplexing transmission

The space channel index	Spectrum efficiency (bps/Hz)	Code rate	Modulation scheme	Pay(useful) load (bit/PHY frame)	The PHY frame size
								Coded-bit	Modulated symbol	The OFDM code element
					1	0.5	1/2				BPSK	144	288	288	6
2	1.5	3/4	QPSK	432				576	288	6
					3	4.5	3/4				64 QAM	1296	1728	288	6
4	5.5	11/16	256 QAM	1584				2304	288	6

So total PHY frame size is 144+432+1296+1584 information bit or 288+576+1728+2304 coded-bit.Even each of four space channels is all supported the pay(useful) load bit of varying number, Zong the PHY frame also can be sent out (for example 24 microseconds are supposed 4 microseconds/OFDM code element) in 6 OFDM code elements.

V. physical layer process

Fig. 7 illustrates access point 110x in the MIMO wlan system and the block diagram of two user terminal 120x and 120y one embodiment.

On down link,, send (TX) data processor 710 and receive from the traffic data (being information bit) of data source 708 and come self-controller 730 and the signaling and the out of Memory of possible scheduler 734 at access point 110x place.This Various types of data can be sent out on different transmission channels.Send 710 pairs of data of data processor carry out " framing " (if necessary), to framing/data of separating frame upset, to encode through the data that upset, to encoded data interweave (i.e. rearrangement) and data map through interweaving to modulated symbol.For simplicity, " data symbols " is meant the modulated symbol of traffic data, and " pilot frequency code element " is meant the modulated symbol of pilot tone.Upset is the data bit randomization.Coding has improved reliability of data transmission.Interweaving provides time, frequency and/or space diversity for the bit of having encoded.Upset, encode and modulate and to carry out based on the control signal that controller 730 is provided, be described in further detail below.Send data processor 710 and provide a modulation, symbol streams for employed each space channel of transfer of data.

Send spatial processor 720 and receive one or more modulation, symbol streams, and modulated symbol is carried out spatial manipulation so that four transmitter code flow filaments are provided, a stream is arranged for every transmit antennas from sending data processor 710.Be described in further detail spatial manipulation below.

Each modulator (MOD) 722 receives and handles a corresponding transmitter code flow filament so that a corresponding OFDM code element stream is provided.Each OFDM code element stream all is further processed, so that a corresponding downstream link modulated signal is provided.Send four the down link modulated signals of automodulation device 722a then respectively to 722d from four antenna 724a to 724d.

At each user terminal 120 place, one or more antenna 752 receives the down link modulated signal that is sent, and every reception antenna all provides a received signal to corresponding demodulator (DEMOD) 754.Each demodulator 754 is carried out the opposite processing of carrying out with modulator 722 places of processing, and receiving symbol is provided.Then, receive 720 pairs of receiving symbols from all demodulators 754 of (RX) spatial processor and carry out spatial manipulation so that the code element through recovering to be provided, the code element through recovering is the estimation of the modulated symbol that sends of access point.

Receiving data processor 770 receptions decomposes in their corresponding transmission channels through the code element of recovery and with its multichannel.The code element through recovering of each transmission channel can be conciliate through symbol de-maps, deinterleaving, decoding and be upset, so that provide data through decoding for this transmission channel.Each transmission channel can comprise grouped data through recovering, message, signaling or the like through decoded data, the latter is provided for data sink 722 and preserves, and/or be provided for controller 780 and further handle.

The access point 110 of down link and the processing of terminal 120 have been described in further detail below.The processing of up link can be identical or different with the processing of down link.

For down link,, receive spatial processor 760 further estimating down-ward links to obtain channel condition information (CSI) at each active user terminals 120 place.CSI can comprise SNR that channel response is estimated, received or the like.Receiving data processor 770 can also provide the state of each packet/frame that receives on the down link.Controller 780 receiving channel state informations and packet/frame state, and the definite feedback information that will be beamed back access point.Feedback information is handled by sending data processor 790 and sending spatial processor 792 (if existence), is regulated by one or more modulators 754, and is beamed back access point via one or more antenna 752.

At access point 110 places, the uplink signal that is sent by antenna 724 receive, by demodulator 722 demodulation, and handle in the opposite mode of carrying out with the user terminal place of mode by receiving spatial processor 740 and receiving data processor 742.Then the feedback information through recovering is offered controller 730 and scheduler 734.

Scheduler 734 uses feedback information to carry out multiple function, select one group of user terminal to be used for transfer of data on down link and up link such as (1), (2) be each selected user terminal selecting transmission rate and transmission mode, and (3) the FCH/RCH resource that can use to selected terminal distribution.Scheduler 734 and/or controller 730 further use from the information (for example dominant vector) of ul transmissions acquisition handles downlink transmission, following being described in further detail.

Support multiple transmission mode for the transfer of data on down link and the up link.Be described in further detail down each processing of these transmission modes.

1. diversity mode-transmission is handled

Fig. 8 A illustrates and can carry out the block diagram that sends transmitter unit 800 1 embodiment that handle for diversity mode.Transmitter 800 can be used for the transmitter part of access point and user terminal.

In sending data processor 710a, the data of 808 pairs of each groupings that will send on FCH or RCH in framing unit are carried out framing.Framing need not to carry out for other transmission channel.Framing can be carried out as shown in Figure 6, so that generate one or more PHY frames for each user grouping.Then, disarrangement device 810 is upset for the data of the framing of each transmission channel/separate frame, so that make the data randomization.

Encoder 812 receives through the data of upset and according to selected encoding scheme described data is encoded, so that encoded bit is provided.Then, some coded-bits of 814 repetitions of repetition/brachymemma unit or brachymemma (i.e. deletion) are with the code rate of the expectation of acquisition expectation.In one embodiment, encoder 812 is that speed is 1/2, limited length is 7 binary convolutional encoder.By each coded-bit is repeated once can obtain code rate 1/4.By can obtain code rate from encoder 812 some coded-bits of deletion greater than 1/2.The particular design of framing unit 808, disarrangement device 810, encoder 812 and repetition/brachymemma unit 814 is described below.

Then, interleaver 818 based on selected interleaving scheme to the coded-bit from unit 814 interweave (i.e. rearrangement).In one embodiment, every group of 48 continuous programming code bits that send on a given space channel reportedly send subband (or abbreviating data subband as) to go up expansion in 48 numbers, so that frequency diversity is provided.Be described in further detail interleaving process below.

Symbol mapped unit 820 then shines upon data through interweaving so that modulated symbol to be provided according to a specific modulation scheme.Shown in table 26, according to selected speed, diversity mode can use BPSK, 4 QAM or 16QAM.In diversity mode, for all data subbands use same modulation scheme.Symbol mapped can be by following realization: each group of (1) tissue B bit to be to form the B bit value, B 〉=1 wherein, and (2) each B bit value be mapped in the signal group of stars corresponding with selected modulation scheme a bit.Each mapped signaling point all is a complex values, and corresponding to a modulated symbol.Symbol mapped unit 820 provides a modulation, symbol streams to sending diversity processor 720a.

In one embodiment, diversity mode is that two diversity that send are used space time transmit diversity (STTD) according to each subband.STTD supports to transmit when independently code element stream is on two transmit antennas, and keeps the orthogonality at receiver place simultaneously.

The following running of STTD scheme.Suppose and on a given subband, to send two modulated symbols, be labeled as s ₁And s ₂Transmitter generates two vector: x ₁=[s ₁s ₂] ^TWith ${\underset{\&OverBar;}{x}}_2={\left[\begin{array}{cc}{\mathrm{<figure-callout\; id="2"\; label="s"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">s</figure-callout>}}_2^{*}& -{\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">s</figure-callout>}}_1^{*}\end{array}\right]}^T,$ Wherein " * ' the expression complex conjugate, " T " represents transposition.Each vector is included in the code-element period two element (that is vector x, will sending from two transmit antennas ₁In first code-element period, send vector x from two antennas ₂In next code-element period, send) from two antennas.

If receiver is equipped with single reception antenna, then receiving symbol can be expressed as:

r ₁＝h ₁s ₁+h ₂s ₂+n ₁， (1)

${\mathrm{<figure-callout\; id="2"\; label="r"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">r</figure-callout>}}_2=h_1{\mathrm{<figure-callout\; id="2"\; label="s"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">s</figure-callout>}}_2^{*}-h_2{\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">s</figure-callout>}}_1^{*}+{\mathrm{<figure-callout\; id="2"\; label="n"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">n</figure-callout>}}_2,$

R wherein ₁And r ₂Be that receiver is in two code elements that receive in two continuous code-element periods;

h ₁And h ₂Be for the path gain of subband in considering, suppose that wherein path gain is constant on this subband, and on the cycle of 2 code elements, keep static from two transmit antennas to reception antenna; And

n ₁And n ₂Be respectively with two receiving symbol r ₁And r ₂The noise that is associated.

Receiver then can two transmit symbol s of following derivation ₁And s ₂Estimation:

${\hat{s}}_1=\frac{{\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_1^{*}{r}_1-h_2{\mathrm{<figure-callout\; id="2"\; label="r"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">r</figure-callout>}}_2^{*}}{{\left|{\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_1\right|}^2+{\left|{\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_2\right|}^2}={\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">s</figure-callout>}}_1+\frac{{\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_1^{*}{n}_1-h_2{\mathrm{<figure-callout\; id="2"\; label="n"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">n</figure-callout>}}_2^{*}}{{\left|{\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_2\right|}^2+{\left|{\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_2\right|}^2},---\left(2\right)$

${\hat{s}}_2=\frac{{\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_2^{*}{\mathrm{<figure-callout\; id="1"\; label="r"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">r</figure-callout>}}_1+h_1{\mathrm{<figure-callout\; id="2"\; label="r"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">r</figure-callout>}}_2^{*}}{{\left|{\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_1\right|}^2+{\left|{\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_2\right|}^2}={\mathrm{<figure-callout\; id="2"\; label="s"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">s</figure-callout>}}_2+\frac{{\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_2^{*}{\mathrm{<figure-callout\; id="1"\; label="n"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">n</figure-callout>}}_1+h_1{\mathrm{<figure-callout\; id="2"\; label="n"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">n</figure-callout>}}_2^{*}}{{\left|{\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_1\right|}^2+{\left|{\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_2\right|}^2}$

Perhaps, transmitter can generate two vectors ${\underset{\&OverBar;}{x}}_1={\left[\begin{array}{cc}{s}_1& -{\mathrm{<figure-callout\; id="2"\; label="s"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">s</figure-callout>}}_2^{*}\end{array}\right]}^T$ With ${\underset{\&OverBar;}{x}}_2={\left[\begin{array}{cc}{s}_2& {\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">s</figure-callout>}}_1^{*}\end{array}\right]}^T,$ And in two code-element periods, sequentially send this two vectors from two transmit antennas.So receiving symbol can be expressed as:

${\mathrm{<figure-callout\; id="1"\; label="r"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">r</figure-callout>}}_1=h_1{s}_1-h_2{\mathrm{<figure-callout\; id="2"\; label="s"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">s</figure-callout>}}_2^{*}+{\mathrm{<figure-callout\; id="1"\; label="n"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">n</figure-callout>}}_1,$

${\mathrm{<figure-callout\; id="2"\; label="r"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">r</figure-callout>}}_2=h_1{s}_2-h_2{\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">s</figure-callout>}}_1^{*}+{\mathrm{<figure-callout\; id="2"\; label="n"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">n</figure-callout>}}_2.$

Receiver is followed the estimation of two transmit symbol of following derivation:

${\hat{s}}_1=\frac{{\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_1^{*}{\mathrm{<figure-callout\; id="1"\; label="r"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">r</figure-callout>}}_1+h_2{\mathrm{<figure-callout\; id="2"\; label="r"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">r</figure-callout>}}_2^{*}}{{\left|{\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_1\right|}^2+{\left|{\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_2\right|}^2}={\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">s</figure-callout>}}_1+\frac{{\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_1^{*}{\mathrm{<figure-callout\; id="1"\; label="n"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">n</figure-callout>}}_1+h_2{\mathrm{<figure-callout\; id="2"\; label="n"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">n</figure-callout>}}_2}{{\left|{\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_2\right|}^2+{\left|{\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_2\right|}^2},$

${\hat{s}}_2=\frac{-h_2{\mathrm{<figure-callout\; id="1"\; label="r"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">r</figure-callout>}}_1^{*}+{\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_1^{*}{\mathrm{<figure-callout\; id="2"\; label="r"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">r</figure-callout>}}_2}{{\left|{\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_1\right|}^2+{\left|{\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_2\right|}^2}={\mathrm{<figure-callout\; id="2"\; label="s"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">s</figure-callout>}}_2+\frac{{\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_1^{*}{n}_2-h_2{\mathrm{<figure-callout\; id="1"\; label="n"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">n</figure-callout>}}_1}{{\left|{\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_1\right|}^2+{\left|{\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_2\right|}^2}$

Foregoing description can be expanded and be used to have two or many transmit antennas, N _RThe MIMO-OFDM system of root reception antenna and a plurality of subbands.Two transmit antennas have been used for arbitrary given subband.Suppose on a given subband k to send two modulated symbols, be labeled as s ₁(k) and s ₂(k).Transmitter generates two vectors x ₁=[s ₁(k) s ₂(k)] ^TWith ${\underset{\&OverBar;}{x}}_2={\left[\begin{array}{cc}{\mathrm{<figure-callout\; id="2"\; label="s"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">s</figure-callout>}}_2^{*}& -{\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">s</figure-callout>}}_1^{*}\left(k\right)\end{array}\right]}^T,$ Perhaps Deng Jia two code-element sets $\left\{x_i\left(k\right)\right\}=\left\{\begin{array}{cc}{s}_1\left(k\right)& {\mathrm{<figure-callout\; id="2"\; label="s"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">s</figure-callout>}}_2^{*}\left(k\right)\end{array}\right\}$ With $\left\{x_j\left(k\right)\right\}=\left\{\begin{array}{cc}{s}_2\left(k\right)& -{\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">s</figure-callout>}}_1^{*}\left(k\right)\end{array}\right\}.$ Each code-element set is included in last two elements that send in proper order from corresponding transmitting antenna of subband k in two code-element periods (be code-element set { x _i(k) } in two code-element periods, sending code-element set { x on the subband k from antenna i _j(k) } in 2 same code-element periods, sending on the subband k) from antenna j.

The vector of the receiving symbol at two interior reception antenna places of code-element period can be expressed as:

r ₁(k)＝ h _i(k)s ₁(k)+ h _j(k)s ₂(k)+ n ₁(k)，

${\underset{\&OverBar;}{r}}_2\left(k\right)={\underset{\&OverBar;}{h}}_i\left(k\right){\mathrm{<figure-callout\; id="2"\; label="s"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">s</figure-callout>}}_2^{*}\left(k\right)-{\underset{\&OverBar;}{h}}_j\left(k\right){\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">s</figure-callout>}}_1^{*}\left(k\right)+{\underset{\&OverBar;}{n}}_2\left(k\right),$

Wherein r ₁(k) and r ₂(k) be the symbol vector that receives at the receiver place in two continuous code-element periods on the subband k, each vector all comprises N _RThe N of root reception antenna _RIndividual receiving symbol;

h _i(k) and h _j(k) be for subband k from two transmit antennas i and j to N _RThe vector of the path gain of root reception antenna, each vector all comprise from relevant transmitting antenna to N _RThe channel gain of each root of root reception antenna supposes that wherein path gain is constant on this subband and keep static on 2 code-element periods; And

n ₁(k) and n ₂(k) be to receive vector with two respectively r ₁(k) and r ₂(k) noise vector that is associated.

Then, receiver can two transmit symbol s of following derivation ₁(k) and s ₂(k) estimation:

${\hat{s}}_1\left(k\right)=\frac{{\underset{\&OverBar;}{\overset{^}{h}}}_i^H\left(k\right){\underset{\&OverBar;}{r}}_1\left(k\right)-{\underset{\&OverBar;}{r}}_2^H\left(k\right){\underset{\&OverBar;}{\overset{^}{h}}}_j\left(k\right)}{{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_i\left(k\right)\left|\right|}^2+{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_j\left(k\right)\left|\right|}^2}=s_1\left(k\right)+\frac{{\underset{\&OverBar;}{\overset{^}{h}}}_i^H\left(k\right){\underset{\&OverBar;}{n}}_1\left(k\right)-{\underset{\&OverBar;}{n}}_2^H\left(k\right){\underset{\&OverBar;}{\overset{^}{h}}}_j\left(k\right)}{{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_i\left(k\right)\left|\right|}^2+{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_j\left(k\right)\left|\right|}^2},$

${\hat{s}}_2\left(k\right)=\frac{{\underset{\&OverBar;}{\overset{^}{h}}}_j^H\left(k\right){\underset{\&OverBar;}{r}}_1\left(k\right)-{\underset{\&OverBar;}{r}}_2^H\left(k\right){\underset{\&OverBar;}{\overset{^}{h}}}_i\left(k\right)}{{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_i\left(k\right)\left|\right|}^2+{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_j\left(k\right)\left|\right|}^2}=s_2\left(k\right)+\frac{{\underset{\&OverBar;}{\overset{^}{h}}}_j^H\left(k\right){\underset{\&OverBar;}{n}}_1\left(k\right)-{\underset{\&OverBar;}{n}}_2^H\left(k\right){\underset{\&OverBar;}{\overset{^}{h}}}_i\left(k\right)}{{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_i\left(k\right)\left|\right|}^2+{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_j\left(k\right)\left|\right|}^2}$

Perhaps, transmitter can generate two code-element set { x _i(k) }={ s ₁(k) s ₂(k) } and $\left\{x_j\left(k\right)\right\}=\left\{\begin{array}{cc}-{\mathrm{<figure-callout\; id="2"\; label="s"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">s</figure-callout>}}_2^{*}\left(k\right)& {\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">s</figure-callout>}}_1^{*}\left(k\right)\end{array}\right\},$ And send this two code-element sets from two transmit antennas i and j.So the vector of receiving symbol can be expressed as:

$r_1\left(k\right)={\underset{\&OverBar;}{h}}_i\left(k\right)s_1\left(k\right)-{\underset{\&OverBar;}{h}}_j\left(k\right){\mathrm{<figure-callout\; id="2"\; label="s"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">s</figure-callout>}}_2^{*}\left(k\right)+{\underset{\&OverBar;}{n}}_1\left(k\right),$

${\underset{\&OverBar;}{r}}_2\left(k\right)={\underset{\&OverBar;}{h}}_i\left(k\right)s_2\left(k\right)+{\underset{\&OverBar;}{h}}_j\left(k\right){\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">s</figure-callout>}}_1^{*}\left(k\right)+{\underset{\&OverBar;}{n}}_2\left(k\right).$

Then, the estimation that receiver can two transmit symbol of following derivation:

${\hat{s}}_1\left(k\right)=\frac{{\underset{\&OverBar;}{\overset{^}{h}}}_i^H\left(k\right){\underset{\&OverBar;}{r}}_1\left(k\right)-{\underset{\&OverBar;}{r}}_2^H\left(k\right){\underset{\&OverBar;}{\overset{^}{h}}}_j\left(k\right)}{{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_i\left(k\right)\left|\right|}^2+{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_j\left(k\right)\left|\right|}^2}=s_j\left(k\right)+\frac{{\underset{\&OverBar;}{\overset{^}{h}}}_i^H\left(k\right){\underset{\&OverBar;}{n}}_1\left(k\right)-{\underset{\&OverBar;}{n}}_2^H\left(k\right){\underset{\&OverBar;}{\overset{^}{h}}}_j\left(k\right)}{{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_i\left(k\right)\left|\right|}^2+{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_j\left(k\right)\left|\right|}^2},$

${\hat{s}}_2\left(k\right)=\frac{{\underset{\&OverBar;}{\overset{^}{h}}}_j^H\left(k\right){\underset{\&OverBar;}{r}}_2\left(k\right)-{\underset{\&OverBar;}{r}}_1^H\left(k\right){\underset{\&OverBar;}{\overset{^}{h}}}_j\left(k\right)}{{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_i\left(k\right)\left|\right|}^2+{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_j\left(k\right)\left|\right|}^2}=s_2\left(k\right)+\frac{{\underset{\&OverBar;}{\overset{^}{h}}}_i^H\left(k\right){\underset{\&OverBar;}{n}}_2\left(k\right)-{\underset{\&OverBar;}{n}}_1^H\left(k\right){\underset{\&OverBar;}{\overset{^}{h}}}_j\left(k\right)}{{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_i\left(k\right)\left|\right|}^2+{\left|\right|{\underset{\&OverBar;}{\overset{^}{h}}}_j\left(k\right)\left|\right|}^2},$

The STTD scheme is described in the paper that is entitled as " A Simple Transmit Diversity Technique forWireless Communications " by S.M.Alamouti, this paper publishing is on the IEEE periodical in the selected field of relevant communication, in October, 1998 No. 8 the 16th volume, the 1451-1458 page or leaf.The STTD scheme is also described in the U.S. Patent application of following common transfer: in the 09/737th of submission on January 5 calendar year 2001, No. 602 applications are entitled as " Method and System for Increased Bandwidth Efficiency in Multiple Input-Multiple Output Channels "; And, be entitled as " Diversity Transmission Modes for MIMO OFDM Communication Systems " in the 10/179th, No. 439 application that on June 24th, 2002 submitted to.

The STTD scheme sends a modulated symbol by two transmit antennas in each subband in each code-element period.Yet, the distributed intelligence in each modulated symbol on two continuous OFDM code elements of STTD scheme.Like this, the symbol recovery at receiver place is carried out based on two OFDM code elements that receive continuously.

The STTD scheme is used a pair of transmitting antenna for each data subband.Because access point comprises four transmit antennas, therefore can select every antenna to be used for half of 48 data subbands.Table 29 is listed the exemplary subband-antenna assignment scheme of STTD scheme.

Table 29

Subband index	Transmitting antenna	Bit index	Subband index	Transmitting antenna	Bit index	Subband index	Transmitting antenna	Bit index	Subband index	Transmitting antenna	Bit index
												-	-	-	-13	1，2	26	1	3，4	1	15	1，2	33
-26	1，2	0	-12	3，4	32	2	1，2	7	16	2，4	39

-25	3，4	6	-11	1，3	38	3	2，4	13	17	1，3	45
												-24	1，3	12	-10	2，4	44	4	1，3	19	18	2，3	5
-23	2，4	18	-9	1，4	4	5	2，3	25	19	1，4	11
												-22	1，4	24	-8	2，3	10	6	1，4	31	20	3，4	17
-21	1	P0	-7	2，	P1	7	3	P2	21	4	P3
												-20	2，3	30	-6	1，2	16	8	3，4	37	22	1，2	23
-19	1，2	36	-5	3，4	22	9	1，2	43	23	2，4	29
												-18	3，4	42	-4	1，3	28	10	2，4	3	24	1，3	35
-17	1，3	2	-3	2，4	34	11	1，3	9	25	2，3	41
												-16	2，4	8	-2	1，4	40	12	2，3	15	26	1，4	47
-15	1，4	14	-1	2，3	46	13	1，4	21	-	-	-
												-14	2，3	20	0	-	-	14	3，4	27	-	-	-

Shown in table 29, transmitting antenna 1 and 2 is used for index and is-26 ,-19 ,-13 etc. subband, and transmitting antenna 2 and 4 is used for index and is-25 ,-18 ,-12 etc. subband, and transmitting antenna 1 and 3 is used for index and is-24 ,-17 ,-11 etc. subband, and the rest may be inferred.Four transmit antennas has six different antennas right.Two right each of antenna all are used for 8 data subbands, 8 data subband approximate intervals equably on 48 data subbands.Antenna makes to the distribution to subband and uses different antennas for adjacent sub-bands that this can provide bigger frequency and space diversity.For example, antenna 1 and 2 is used for subband-26, and antenna 3 and 4 is used for subband-25.

Antenna-allocation of subbands in the table 29 makes also and is the whole four transmit antennas of each coded-bit use of minimum speed limit 1/4 that this makes the antenna diversity maximum.For speed 1/4, each coded-bit all is repeated and sends (being also referred to as Shuangzi band repeated encoding) on two subbands.It is right that two used subbands of each coded-bit are mapped to different big lines, makes to use four whole antennas to send this coded-bit.For example, the bit index 0 in the table 29 and 1 is corresponding to the same coded-bit under the diversity mode, and wherein index is that 0 bit sends from antenna 1 and 2 on subband-26, and index is that 1 bit sends from antenna 3 and 4 on subband 1.For another example, the bit index 2 in the table 29 and 3 is corresponding to same coded-bit, and wherein index is that 2 bit sends from antenna 1 and 3 on subband-17, and index is that 3 bit sends from antenna 2 and 4 on subband 10.

System can support other to send diversity scheme, and this within the scope of the invention.For example, system can support a space-frequency to send diversity (SFTD), and it can be according to each subband to coming implementation space and frequency diversity.The one exemplary following running of SFTD scheme.Suppose to generate two modulated symbol s (k) and s (k+1), and they are mapped to two adjacent sub-bands of OFDM code element.For SFTD, launching opportunity is sent code element s (k) and s (k+1) from two antennas on subband k, and can send code element s from two identical antennas on subband k+1 ^*(k+1) and-s ^*(k).Because the supposition channel response keeps constant for two right transmissions of code element, so modulated symbol is to having used adjacent subband.It is identical with the processing of STTD scheme that the receiver place is used for recovering the processing of modulated symbol, except the receiving symbol of the receiving symbol of handling two subbands rather than two OFDM code-element periods.

Fig. 8 B illustrates the block diagram of an embodiment of the transmission diversity processor 720a of the STTD scheme that can realize under the diversity mode.

In sending diversity processor 720a, demultiplexer 832 receives modulation, symbol streams s (n) from sending data processor 710a, and its multichannel is resolved into 48 son streams for 48 data subbands, is labeled as s ₁(n) to s ₁(n).Each modulated symbol stream comprises a modulated symbol for a code-element period, corresponding to chip rate (T _OFDM) ^-1, T wherein _OFDMIt is the duration of an OFDM code element.Each modulation, symbol streams is provided for corresponding transmission subband diversity processor 840.

In each sent subband diversity processor 840, demultiplexer 842 resolved into two sequence of symhols to the modulated symbol multichannel of this subband, and the chip rate of each sequence is (2T _OFDM) ^-1Space Time Coding device 850 receives these two modulated symbol sequences, and for each 2 code-element period, uses two code element s in these two sequences ₁And s ₂Be that two transmit antennas form two code-element sets $\left\{x_i\right\}=\left\{\begin{array}{cc}{s}_1& {\mathrm{<figure-callout\; id="2"\; label="s"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">s</figure-callout>}}_2^{*}\end{array}\right\}$ With $\left\{x_J\right\}=\left\{\begin{array}{cc}{s}_2& -{\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">s</figure-callout>}}_1^{*}\end{array}\right\}.$ Each code-element set comprises two code elements, and each code element is from one of two sequences.By code element s at first is provided ₁Next provides code element s ₂ ^*And generation code-element set { x _i, wherein obtain s by switch 856a ₁, by getting s with unit 852a ₂Conjugation and with delay cell 854a with code-element period of symbol delay of conjugation and obtain s ₂ ^*Shown in table 29, two code-element set { x _iAnd { x _jWill send from two antenna i and the j that distributes to subband.Space Time Coding device 850 for the first transmit antennas i first code-element set $\left\{x_i\right\}=\left\{\begin{array}{cc}{s}_1& {\mathrm{<figure-callout\; id="2"\; label="s"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">s</figure-callout>}}_2^{*}\end{array}\right\}$ Offer buffer/multiplexer 870, for the second transmit antennas j second code-element set $\left\{x_j\right\}=\left\{\begin{array}{cc}{s}_2& {-\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">s</figure-callout>}}_1^{*}\end{array}\right\}$ Offer another buffer/multiplexer 870.Controlled encoder 850 is called as the STTD code element for two code elements that each code-element period provides.

Buffer/multiplexer 870a is used for the STTD code element from all diversity processors 840 is cushioned with multiplexed to 870d.According to determining of table 29, each buffer/multiplexer 870 receives pilot frequency code element and STTD code element from suitable transmission subband diversity processor 840.For example, buffer/multiplexer 870a receives subband-26,-24,-22, the modulated symbol of-19 etc. (promptly being mapped to all subbands of antenna 1), buffer/multiplexer 870b receives subband-26,-23,-20, the modulated symbol of-19 etc. (promptly being mapped to all subbands of antenna 2), buffer/multiplexer 870c receives subband-25,-24,-20, the modulated symbol of-18 etc. (promptly being mapped to all subbands of antenna 3), buffer/multiplexer 870d receives subband-25,-23,-22, the modulated symbol of-18 etc. (promptly being mapped to all subbands of antenna 4).

Then for each code-element period, each buffer/multiplexer 870 is respectively four pilot subbands, 24 data subbands and 36 and does not use multiplexed four pilot tones of subband, 24 STTD code elements and 36 zero, so that be the sequence that 64 total subbands form one 64 transmit symbol.Although always have 48 data subbands, for diversity mode, only used 24 subbands for every transmit antennas, therefore, it is 36 rather than 12 that every antenna does not use the substantial amt of subband.Each transmit symbol all is the complex values (can be zero for untapped subband) that sends on a subband in a code-element period.Each buffer/multiplexer 870 provides a transmitter code flow filament x for a transmit antennas _i(n).Each transmitter code flow filament comprises the modular cascade sequence of 64 transmit symbol, and a code-element period has a sequence.Refer back to Fig. 8 A, send diversity processor 720a and provide four transmitter code flow filament x to 722d to four OFDM modulator 722a ₁(n) to x ₄(n).

Fig. 8 C illustrates the block diagram of OFDM modulator 722x one embodiment, and this modulator can be used for each OFDM modulator 722a among Fig. 8 A to 722d.In OFDM modulator 722x, invert fast fourier transformation (IFFT) unit 852 receives a transmitter code flow filament x _iAnd use one 64 invert fast fourier transformation that the sequence of each 64 transmit symbol is converted to its time-domain representation (calling the code element through conversion) (n).Each code element through conversion comprises corresponding to 64 time-domain samplings of 64 subbands altogether.

For each code element through conversion, Cyclic Prefix maker 854 repeat a part through the conversion code element to form corresponding OFDM code element.As mentioned above, can use one of two different circulating prefix-lengths.The Cyclic Prefix of BCH is fixed, and is 800nsec.The Cyclic Prefix of all other transmission channels all is optional (or 400nsec or 800nsec), and is represented by the Cyclic Prefix duration field of BCH message.For bandwidth is that 20MHz, sampling period are the system of 50nsec and 64 fields, each is 3.2 milliseconds (promptly 64 * 50nsec) through the duration of conversion code element, duration of each OFDM code element or be 3.6 milliseconds or be 4.0 milliseconds, what this depended on that the OFDM code element uses is 400nsec or the Cyclic Prefix of 800nsec.

Fig. 8 D has illustrated an OFDM code element.The OFDM code element is partly formed by two: the duration be 400 or the Cyclic Prefix (8 or 16 samplings) of 800nsec and duration be 3.2 microseconds through conversion code element (64 samplings).Cyclic Prefix is through the copy of last 8 or 16 samplings of conversion code element (i.e. circulation continues), and is inserted in the front through the conversion code element.Cyclic Prefix quebaoOFDM1 code element can keep its orthogonality when having the multidiameter expansion, thereby has improved the performance of the harmful path effects of antagonism, and described ill-effect is such as multipath that is caused by frequency selective fading and channel diffusion.

Cyclic Prefix maker 854 provides an OFDM code element stream to transmitter (TMTR) 856.Transmitter 856 is converted to one or more analog signals to the OFDM code element stream, and to analog signal amplification further, filtering and up-conversion, is convenient to send from relevant antenna so that generate a modulated signal.

The baseband waveform of OFDM code element can be expressed as:

$x_n\left(t\right)=\underset{k=-N_{\mathrm{ST}}/2,k\&NotEqual;0}{\overset{N_{\mathrm{ST}}/2}{\mathrm{\&Sigma;}}}{c}_n\left(k\right){\mathrm{\&Psi;}}_n(k,t),---\left(3\right)$

Wherein n represents code-element period (being the OFDM symbol index);

K represents subband index;

N _STIt is the number of pilot tone and data subband;

c _n(k) the subband k that is illustrated in code-element period n goes up the code element that sends; And

T wherein _CPIt is the Cyclic Prefix duration;

T _SIt is the OFDM code element duration; And

Δ f is the bandwidth of each subband.

2. space multiplexing mode-transmission is handled

Fig. 9 A illustrates and can carry out the block diagram that sends the transmitter unit of handling 900 for space multiplexing mode.Transmitter unit 90 is transmitter another embodiment partly of access point and user terminal.For space multiplexing mode, same supposition has four transmit antennas and four reception antennas to use, and data can nearly send on four space channels.For each space channel uses different speed according to its transmission capacity.Each rate domain one specific code rate and modulation scheme is associated, and is as shown in Table 25.In the following description, suppose selection N _EIndividual space channel uses for transfer of data, wherein N _E≤ N _S≤ min{N _T, N _R.

In sending data processor 710b, framing unit 808 carries out framing to the data of each FCH/RCH grouping so that be the one or more PHY frames of this grouping generation.Each PHY frame all is included in can be at whole N in 6 OFDM code elements _EThe data bit number that sends in the individual space channel.Disarrangement device 810 is upset the data of each transmission channel.Encoder 812 receives through the data of upset and according to selected encoding scheme it is encoded, so that coded-bit is provided.In one embodiment, use a common encoding scheme to be all N _EThe data of individual space channel are encoded, and by coming the brachymemma coded-bit with different brachymemma patterns, thereby are that different space channels obtains different code rates.Therefore, brachymemma unit 814 brachymemma coded-bits are so that obtain the code rate of expectation for each space channel.Be described in further detail the brachymemma of space multiplexing mode below.

Demultiplexer 816 is 814 received code bits from the brachymemma unit, and multichannel decomposes described coded-bit so that the N for selecting for use _EIndividual space channel provides N _EIndividual coded bit stream.Each coded bit stream all is provided for a corresponding interleaver 818, the interleaver coded-bit in this stream that interweaves on 48 data subbands.Be described in further detail the coding of space multiplexing mode below and interweave.The data through interweaving from each interleaver 818 are provided for corresponding symbol mapped unit 820.

In space multiplexing mode,, can use nearly four different speed for these space channels according to being the reception SNR that four space channels are realized.Each speed is associated with a specific modulation scheme, and is as shown in Table 25.Each symbol mapped unit 820 is according to the data of shining upon for the certain modulation schemes of correlation space channel selection through interweaving, so that modulated symbol is provided.In whole four space channels of selecting for use, symbol mapped unit 820a provides four modulation, symbol streams of four space channels to 820d to sending spatial processor 720b.

Sending spatial processor 720b is that space multiplexing mode is carried out spatial manipulation.For simplicity, below description is assumed to transfer of data utilization rate four transmit antennas, four reception antennas and 48 data subbands.The data subband index is provided by set K, wherein for above-mentioned OFDM sub band structure, and K=± 1 ..., and 6,8..., 20,22 ... 26}.

The model of MIMO-OFDM system can be expressed as:

r(k)＝ H(k) x(k)+ n(k)， k∈K， (5)

Wherein r(k) be to have four " reception " vectorial (promptly for the code element that four reception antennas by subband k receive r(k)=[r ₁(k) r ₂(k) r ₃(k) r ₄(k)] ^T);

x(k) be to have four " transmission " vectorial (promptly for the code element that the four transmit antennas by subband k sends x(k)=[x ₁(k) x ₂(k) x ₃(k) x ₄(k)] ^T);

H(k) be (N of subband k _R* N _T) channel response matrix; And

n(k) be the vector of the Additive White Gaussian Noise (AWGN) of subband k.

Suppose noise vector n(k) component has zero-mean, and covariance matrix is Λ _n=σ ² I, wherein IBe unit matrix, σ ²It is noise variance.

The channel response matrix of subband k H(k) can be expressed as:

$\underset{\&OverBar;}{H}\left(k\right)=\left[\begin{array}{cccc}{\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_{\mathrm{1,1}}\left(k\right)& {\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_{\mathrm{1,2}}\left(k\right)& {\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_{\mathrm{1,3}}\left(k\right)& {\mathrm{<figure-callout\; id="1"\; label="h"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">h</figure-callout>}}_{\mathrm{1,4}}\left(k\right)\\ {\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_{\mathrm{2,1}}\left(k\right)& {\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_{\mathrm{2,2}}\left(k\right)& {\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_{\mathrm{2,3}}\left(k\right)& {\mathrm{<figure-callout\; id="2"\; label="h"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">h</figure-callout>}}_{\mathrm{2,4}}\left(k\right)\\ h_{\mathrm{3,1}}\left(k\right)& h_{\mathrm{3,2}}\left(k\right)& h_{\mathrm{3,3}}\left(k\right)& h_{\mathrm{3,4}}\left(k\right)\\ {\mathrm{<figure-callout\; id="4"\; label="h"\; filenames="A20038010456001411.png"\; state="\{\{state\}\}">h</figure-callout>}}_{4,1}\left(k\right)& {\mathrm{<figure-callout\; id="4"\; label="h"\; filenames="A20038010456001411.png"\; state="\{\{state\}\}">h</figure-callout>}}_{\mathrm{4,2}}\left(k\right)& {\mathrm{<figure-callout\; id="4"\; label="h"\; filenames="A20038010456001411.png"\; state="\{\{state\}\}">h</figure-callout>}}_{\mathrm{4,3}}\left(k\right)& {\mathrm{<figure-callout\; id="4"\; label="h"\; filenames="A20038010456001411.png"\; state="\{\{state\}\}">h</figure-callout>}}_{\mathrm{4,4}}\left(k\right)\end{array}\right],k\&Element;K---\left(6\right)$

H wherein _Ij(k) be the transmitting antenna i of subband k and the connection item between the reception antenna j (being complex gain) (for i ∈ 1,2,3,4} and j ∈ 1,2,3,4}).For simplicity, suppose channel response matrix H(k) (for k ∈ K) is known, perhaps can both determine by transmitter and receiver.

The channel response matrix of each subband H(k) can be by " diagonalization ", so that be this subband acquisition N _SIndividual eigenmodes.This can pass through correlation matrix H(k) carry out eigen value decomposition and realize, R(k)= H ^H(k) H(k), wherein H ^H(k) expression H(k) conjugate transpose.Correlation matrix R(k) eigen value decomposition can be expressed as:

R(k)＝ V(k) D(k) V ^H(k)， k∈K， (7)

Wherein V(k) be (a N _T* N _T) unitary matrix, its row are R(k) eigenvector (promptly V(k)=[ v ₁(k) v ₂(k) v ₃(k) v ₄(k)], wherein each v _i(k) be the eigenvector of an eigenmodes); And

D(k) be R(k) (the N of eigenvalue _T* N _T) diagonal matrix.

The characteristic of unitary matrix is M ^H M= IEigenvector v _i(k) (for i ∈ 1,2,3,4}) be also referred to as the transmission space vector of each space channel.

Channel response matrix H(k) also can come diagonalization, be expressed as follows with singular value decomposition:

H(k)＝ U(k) ∑(k) V ^H(k)， k∈K， (8)

Wherein V(k) be to classify as HThe matrix of right eigenvector (k);

∑(k) be to comprise HThe diagonal matrix of singular value (k), they are DDiagonal element (k) ( R(k) positive square root eigenvalue); And

U(k) be to classify as HThe matrix of left eigenvector (k).

Singular value decomposition is described Academic publishing house second edition in 1980 by Gilbert Strang in the book that is entitled as " Linear Algebra and Its Applications ".Shown in formula (7) and (8), matrix V(k) row are R(k) eigenvector and H(k) right eigenvector.Matrix U(k) row are H(k) H ^H(k) eigenvector and H(k) left eigenvector.

The diagonal matrix of each subband D(k) comprise the null value of non-negative real-valued and other position on the diagonal. R(k) eigenvalue is marked as { { λ ₁(k), λ ₂(k), λ ₃(k), λ ₄Or { λ (k) } _i(k) }, for i ∈ 1,2,3,4}.

For 48 data subbands each, can be channel response matrix H(k) carry out eigen value decomposition independently, (suppose each matrix so that determine four eigenmodes for this subband H(k) all be full arrangement).Each diagonal matrix D(k) four eigenvalues can be sorted, feasible { λ ₁(k) 〉=λ ₂(k) 〉=λ ₃(k) 〉=λ ₄(k) }, wherein for subband k, λ ₁(k) be dominant eigenvalue, λ ₄(k) be smallest eigen.When each diagonal matrix DWhen eigenvalue (k) is sorted, correlation matrix V(k) also correspondingly ordering of eigenvector (or row).

The set (being that broadband eigenmodes m comprises the eigenmodes m in all subbands) of the eigenmodes of phase same order in all subbands after " broadband " eigenmodes can be defined as sorting." mainly " broadband eigenmodes be after ordering with each matrix In the eigenmodes that is associated of maximum singular value.

Form vector then d ^m, comprise that the m of all 48 data subbands arranges eigenvalue.This vector d ^mCan be expressed as:

d ^m＝[λ _m(-26)...λ _m(-22)...λ _m(22)...λ _m(26)]，m＝{1，2，3，4} (9)

Vector d ¹The eigenvalue that comprises the best or main broadband eigenmodes.For the MIMO-OFDM system that four transmit antennas and four reception antennas are arranged (i.e. 4 * 4 systems), nearly four broadband eigenmodes are arranged.

If the noise variance at receiver place is constant and known for transmitter on working band, then pass through eigenvalue λ _m(k) divided by noise variance σ ²Can determine the reception SNR of each subband of each broadband eigenmodes.For simplicity, suppose that it (is σ that noise variance equals 1 ²=1).

For space multiplexing mode, total transmitted power P that can use for transmitter _TotalCan be assigned to the broadband eigenmodes based on various power allocation schemes.In a kind of scheme, total transmitted power P _TotalDistributed to all four broadband eigenmodes equably, made P _m=P _Total/ 4, P wherein _mIt is the transmitted power that is assigned to broadband eigenmodes m.In another kind of scheme, use water filling (water-filling) process total transmitted power P _TotalDistribute to four broadband eigenmodes.

The injecting process distributes power, makes the broadband eigenmodes with higher-wattage receive the most of total transmitted power.The amount of transmit power of distributing to a given broadband eigenmodes depends on that it receives SNR, receives the power gain (or eigenvalue) that SNR depends on whole subbands of this broadband eigenmodes again.The injecting process can distribute the null value transmitted power to the broadband eigenmodes with enough poor reception SNR.The injecting process is that four broadband eigenmodes receive β={ β ₁, β ₂, β ₃, β ₄, wherein β m is the normalization factor of broadband eigenmodes m, and can be expressed as:

${\mathrm{\&beta;}}_m=\frac{1}{\underset{k\&Element;K}{\mathrm{\&Sigma;}}{{\mathrm{\&lambda;}}_m}^{-1}\left(k\right)},m=\left\{\mathrm{1,2,3,4}\right\}.---\left(10\right)$

As described below, normalization factor β _mAfter using the channel counter-rotating, the transmitted power of distributing to broadband eigenmodes m is remained unchanged.As shown in Equation (10), normalization factor β _mCan be based on vector d ^mIn eigenvalue and the hypothesis noise variance to equal 1 (be σ ²=1) derives.

Then, the injecting process makes and can optimize spectrum efficiency or some other standard based on total transmitted power that set β determines to be assigned to each broadband eigenmodes.The transmitted power that the injecting process is distributed to broadband eigenmodes m can be expressed as:

P _m＝α _mP _total， m＝{1，2，3，4} (11)

The power division of four broadband eigenmodes can be by α={ α ₁, α ₂, α ₃, α ₄Provide, wherein $\underset{m=1}{\overset{4}{\mathrm{\&Sigma;}}}{\mathrm{\&alpha;}}_m=1$ And $\underset{m=1}{\overset{4}{\mathrm{\&Sigma;}}}{P}_m=P_{\mathrm{total}}.$ If set αIn a more than value is arranged is non-zero, then can select space multiplexing mode for use.

The process of carrying out water filling is well known in the art, no longer describes here.A bibliography of describing water filling is " the Information Theory and Reliable Communication " that Robert G.Gallager is shown, JohnWiley and Sons publishing house, and 1968, it is incorporated into this by reference.

For space multiplexing mode, the rate selection of each space channel or broadband eigenmodes can based on: this space channel/broadband eigenmodes is assigned to transmitted power P at it _mThe reception SNR of Shi Shixian.For simplicity, the transfer of data of supposing on the eigenmodes of broadband is below described.The reception SNR of each broadband eigenmodes can be expressed as:

${\mathrm{\&gamma;}}_m=\frac{P_m{\mathrm{\&beta;}}_m}{{\mathrm{\&sigma;}}^2},m=\{\mathrm{1,2},3,4\}---\left(12\right)$

In one embodiment, the speed of each broadband eigenmodes determines based on a form, and this form comprises the speed that system supports and the SNR scope of each speed.This form can obtain by Computer Simulation, experiment measuring or the like.The special speed that each broadband eigenmodes will be used is the speed in this form, has the SNR of the certain limit of the reception SNR that comprises the broadband eigenmodes.In another embodiment, the speed of each broadband eigenmodes is based on the selection of getting off: the reception SNR of (1) broadband eigenmodes, (2) be used for remedying the variability of evaluated error, mimo channel and the SNR skew of other factors, and (3) speed supported and the form of their required SNR.For this embodiment, calculate the average received SNR of each broadband eigenmodes at first as described above, perhaps as on average the calculating of the reception SNR of broadband all subbands of eigenmodes (being unit with dB).In either case, then calculate an operating SNR, equal to receive SNR and SNR skew sum (both all are unit with dB).The required SNR of each speed that operating SNR and system are supported compares then.Be the flank speed in the broadband eigenmodes selection form then, its required SNR is less than or equal to operating SNR.The speed that sends diversity mode and wave beam control model also can be determined in a similar manner.

Transmitted power P for each broadband eigenmodes distribution _mCan be distributed in 48 data intersubbands of this broadband eigenmodes, make the reception SNR approximately equal of all subbands.This power is called as the channel counter-rotating in the non-homogeneous distribution of intersubband.Distribute to the transmitted power P of each subband _m(k) can be expressed as:

$P_m\left(k\right)=\frac{{\mathrm{\&beta;}}_m{P}_m}{{\mathrm{\&lambda;}}_m\left(k\right)},k\&Element;K,m=\left\{\mathrm{1,2,3,4}\right\},---\left(13\right)$

β wherein _mIn formula (10), provide.

As shown in Equation (13), transmitted power P _mChannel power gain based on them anisotropically is distributed between data subband, and channel power gains by eigenvalue λ _m(k) provide, for k ∈ K.Distribute power makes and all realizes approximately equalised reception SNR at the receiver place for all data subbands of each broadband eigenmodes.The counter-rotating of this channel is carried out independently for each of four broadband eigenmodes.Be reversed in by the channel of broadband eigenmodes in the U.S. Patent application of following common transfer and be described in further detail: submitted on August 27th, 2002 the 10/229th, No. 209 U.S. Patent applications are entitled as " Coded MIMO Systems with Selective Channel Inversion AppliedPer Eigenmode ".

The channel counter-rotating can be carried out in various manners.For all channel counter-rotating, if selected a broadband eigenmodes for use, then all data subbands all are used for transfer of data.For the selective channel counter-rotating, can select to use whole or subclass of data available subband for each broadband eigenmodes.The selective channel counter-rotating abandons and receives the bad subband that SNR is lower than certain threshold level, and only selected subband is carried out the channel counter-rotating.The selective channel counter-rotating of each broadband eigenmodes is also at the 10/229th of common transfer, describe in No. 209 U.S. Patent applications, this patent was submitted on August 27th, 2002, was entitled as " Coded MIMO Systems with Selective Channel InversionApplied Per Eigenmode ".For simplicity, below description is assumed to each broadband eigenmodes of selecting for use and carries out all channel counter-rotating.

The used gain of each subband of each broadband eigenmodes can be based on the transmitted power P that distributes to this subband _m(k) determine.The gain g of each data subband _m(k) can be expressed as:

$g_m\left(k\right)=\sqrt{P_m\left(k\right)},k\&Element;K,m=\left\{\mathrm{1,2,3,4}\right\}.---\left(14\right)$

Can define a diagonal angle gain matrix for each subband G(k).This matrix G(k) comprise the gain of four eigenmodes of subband k along diagonal, and can be expressed as: G(k)=diag[g ₁(k), g ₂(k), g ₃(k), g ₄(k)]

For space multiplexing mode, the transmission vector of each data subband x(k) can be expressed as:

x(k)＝ V(k) G(k) s(k)，k∈K， (15)

Wherein

s(k)＝[s ₁(k) s ₂(k) s ₃(k) s ₄(k)] ^T，

x(k)＝[x ₁(k) x ₂(k) x ₃(k) x ₄(k)] ^T

Vector s(k) comprise four modulated symbols that will on four eigenmodes of subband k, send, vector x(k) comprise four transmission code elements sending from four antennas of subband k.For simplicity, formula (15) does not comprise the employed correction factor of difference of the transmission chain/reception chain that remedies access point and user terminal place, describes in detail below.

Fig. 9 B illustrates the block diagram that can carry out transmission spatial processor 720b one embodiment of spatial manipulation for space multiplexing mode.For simplicity, below describe supposition and selected all four broadband eigenmodes for use.Yet, also can select for use to be less than four broadband eigenmodes.

In processor 720b, demultiplexer 932 receives four modulation, symbol streams that will send and (is labeled as s on four broadband eigenmodes ₁(n) to s ₄(n)), for 48 data subbands 48 sons of each stream demultiplexer are flowed, and four modulation, symbol streams of each data subband are offered corresponding transmission subband spatial processor 940.Each processor 940 is that a subband is carried out the processing shown in the formula (15).

Send 940, four modulated symbol of subband spatial processor stream at each and (be labeled as s ₁(k) to s ₄(k)) be provided for four multiplier 942a to 942d, multiplier also receives the gain g of four eigenmodes of relevant subbands ₁(k), g ₂(k), g ₃(k) and g ₄(k).Each g that gains _m(k) can be based on the transmitted power P that distributes to this subband/eigenmodes _m(k) determine, as shown in Equation (14).Each its g that gains of multiplier 942 usefulness _m(k) come its modulated symbol of convergent-divergent so that modulated symbol through convergent-divergent is provided.Multiplier 942a supplies with four beam-shaper 950a to 950d to 942d indescribably with four sub-flow points of the modulated symbol through convergent-divergent.

Each beam-shaper 950 is carried out beam shaping, sends a code element stream on an eigenmodes of a subband.Each beam-shaper 950 receives a code element stream s of relevant eigenmodes _m(k) and an eigenvector v _m(k).Particularly, beam-shaper 950a receives the eigenvector of first eigenmodes v ₁(k), beam-shaper 950d receives the eigenvector of second eigenmodes v ₂(k), the rest may be inferred.Beam shaping uses the eigenvector of relevant eigenmodes to carry out.

In each beam-shaper 950, be provided for four multiplier 952a to 952d through the modulated symbol of convergent-divergent, multiplier also receives relevant eigenmodes v _mFour element v of eigenvector (k) _{M, 1}(k), v _{M, 2}(k), v _{M, 3}(k) and v _{M, 4}(k).Then, each its eigenvector value of multiplier 952 usefulness v _{M, j}(k) multiply by through the modulated symbol of convergent-divergent so that " through beam shaping " code element to be provided.Multiplier 952a offers adder 960a to four code element son streams (they will send from four antennas) through beam shaping respectively to 960d to 952d.

Each adder 960 receives four code elements through beam shaping of four eigenmodes of each code-element period, and provides through preregulated code element with their additions so that for relevant transmitting antenna.Adder 960a supplies with buffer/multiplexer 970a to four of four transmit antennas to 970d through the sub-flow point of preregulated code element indescribably to 960d.

Each buffer/multiplexer 970 is that 48 data subbands are from sending subband spatial processor 940a to 940k reception pilot frequency code element with through preregulated code element.Then, for each code-element period, each buffer/multiplexer 970 is respectively 4 pilot subbands, 48 data subbands and 12 and does not use multiplexed 4 pilot frequency code elements of subband, 48 through preregulated code element and 12 zero, so that form the sequences of one 64 transmission code elements for this code-element period.Each buffer/multiplexer 970 provides one to send code element stream x for a transmit antennas _i(n), wherein send code element stream and comprise 64 modular cascade sequences that send code element.Send code element and can use the correction factor convergent-divergent, so that remedy the poor, as described below of access point and user terminal place transmission chain/reception chain.Describe each above and sent the follow-up OFDM modulation of code element stream.

Paralleled code element stream also can send from four transmit antennas, and does not use the spatial manipulation of uncontrolled space multiplexing mode at the access point place.For this pattern, can omit beam-shaper 950 and carry out from channel Umklapp process and beam shaping.Flow through further OFDM of each modulated symbol handles, and sends from corresponding transmitting antenna.

Uncontrolled space multiplexing mode can be used for various occasions, supports wave beam to control under the situation of necessary spatial manipulation such as not carrying out at transmitter to decompose based on eigenmodes.This may be because transmitter is not carried out calibration process as yet, and can not generate the enough good estimation of channel, does not perhaps calibrate with eigenmodes and handles.For uncontrolled space multiplexing mode, spatial reuse still is used for improving transmittability, but receiver is carried out spatial manipulation so that separate independent code element stream.

For uncontrolled space multiplexing mode, spatial manipulation carried out by receiver so that the code element stream of recovering to be sent.Particularly, user terminal can be realized channel correlation matrix counter-rotating (CCMI) technology, least mean-square error (MMSE) technology, interference cancellation receiver treatment technology or some other receiver space treatment technology one by one.These technology are the 09/993rd of common transfer the, describe in detail in No. 087 U.S. Patent application, this patent was submitted to November 6 calendar year 2001, was entitled as " Multiple-Access Multiple-Input Multiple-Output (MIMO) Communication System ".Uncontrolled space multiplexing mode can be used for down link and ul transmissions.

The Multi-User Dimension multiplexer mode supports to arrive simultaneously on the down link transfer of data of a plurality of user terminals based on " space characteristics " of user terminal.The space characteristics of user terminal is provided by the channel response vector between access point antenna and each user terminal antenna (for each subband).Access point can obtain space characteristics based on the controlled benchmark that user terminal sent.Access point can be handled the space characteristics of the user terminal of expected data transmission, with: transfer of data when (1) selects one group of user terminal to be used on the down link, and (2) derive dominant vector for each independent data stream that will be sent to the selected user terminal.

The dominant vector of Multi-User Dimension multiplexer mode can be derived in every way.Two exemplary schemes are described below.For simplicity, below describe, suppose that each user terminal all is equipped with single antenna at a subband.

In first kind of scheme, access point uses the channel counter-rotating to obtain dominant vector.Access point can be selected N _ApTransmission when individual single antenna user terminal is used on the down link.Access point obtains one 1 * N for each selected user terminal _ApThe capable vector of channel response, and form a N _Ap* N _ApChannel response matrix H _Mu, this matrix has N _ApThe N of individual user terminal _ApIndividual row vector.Then, access point is N _ApIndividual selected user terminal obtains N _ApThe matrix of individual dominant vector H _Steer, ${\underset{\&OverBar;}{H}}_{\mathrm{steer}}={\underset{\&OverBar;}{H}}_{\mathrm{mu}}^{-1}.$ Access point also can send a controlled benchmark to each selected user terminal.Its controlled benchmark of each user terminal processes is estimated channel gain and phase place, and is its single antenna demodulate reception code element with channel gain and phase estimation, to obtain the code element through recovering.

In second kind of scheme, access point is decoded in advance and will be sent to N _ApThe N of individual user terminal _ApIndividual code element stream makes these code element stream be subjected to cross-talk hardly at the user terminal place.Access point can be N _ApIndividual selected user terminal forms channel response matrix H _Mu, and right H _MuCarry out the OR factor and decompose, make H _Mu= F _Tri Q _Mu, wherein T _TriWith Q _MuIt is unitary matrix.Access point is then used matrix T _TriN in advance decodes _ApIndividual data code element stream is to obtain N _ApIndividual code element stream through pre decoding a, and use unitary matrix Q _MuThe code element stream of further handling through pre decoding supplies to send to N with acquisition _ApThe N of individual user terminal _ApIndividual transmission code element stream.Equally, access point also can send a controlled benchmark to each user terminal.Each user terminal use controlled benchmark to its receiving symbol coherent demodulation so that obtain code element through recovering.

For the up link in the Multi-User Dimension multiplexer mode, access point can handle with the MMSE receiver, interference cancellation or some other receiver treatment technology recover by N one by one _ApThe N that individual user terminal sends simultaneously _ApIndividual code element stream.Access point can be estimated the uplink channel responses of each user terminal, and uses channel response estimation carrying out receiver space processing and come the scheduling uplink transmission.Each single antenna user terminal can send an orthogonal guide frequency on up link.From N _ApThe uplink pilot of individual user terminal can be in time and/or quadrature on the frequency.Time quadrature is realized like this: cover its uplink pilot by making each terminal with an orthogonal sequence distributing to this user terminal.Frequency orthogonal realizes like this: make each user terminal send its uplink pilot on a different set of subband.Ul transmissions from user terminal should be in access point place time proximity alignment (for example time unifying in the paging prefix).

3. wave beam control model-transmission is handled

Figure 10 A illustrates and can carry out the block diagram that sends the transmitter unit of handling 1000 for the wave beam control model.Transmitter unit 1000 is embodiment in addition of the transmitter section of access point and user terminal.

In sending data processor 710c, framing unit 808 to the data framing of each FCH/RCH grouping so that be the one or more PHY frames of this grouping generation.Disarrangement device 810 is then upset for the data of each transmission channel.Encoder 812 is then encoded through the data of framing according to selected encoding scheme, so that coded-bit is provided.Then, brachymemma unit 814 brachymemma coded-bits are so that be the code rate that the used broadband eigenmodes of transfer of data obtains expectation.Coded-bit from brachymemma unit 818 is interleaved between all data subbands.Then, symbol mapped unit 820 shines upon the data through interweaving so that modulated symbol is provided according to selected modulation scheme.Then, for the wave beam control model, send spatial processor 720c modulated symbol is carried out the transmission processing.

The wave beam control model can be used to send data-described space channel on a space channel or broadband eigenmodes or the broadband eigenmodes generally is the space channel that is associated with the dominant eigenvalue of all data subbands.If the transmit power assignment to the broadband eigenmodes is only being gathered aMiddle of generating non-zero then can select the wave beam control model.And space multiplexing mode is carried out beam shaping based on its eigenvector to each selected eigenmodes of each subband, the wave beam control model is carried out wave beam control based on " standardized " eigenvector, and its principle is to make the eigenmodes of each subband send data on this single eigenmodes.

For main eigenmodes, each eigenvector v ₁(k) four elements of (for k ∈ K) have different sizes.Thereby, four every day line the transmission vector have different sizes, each is described send vector all comprise a given transmitting antenna all data subbands through preregulated code element.If the transmitted power of each transmitting antenna is restricted the restriction of power amplifier (for example because), the beam forming technique gross power that may not exclusively use every antenna to use then.

The wave beam control model is only used the eigenvector from main eigenmodes v ₁(k) phase information of (for k ∈ K), and, make that whole four units in the eigenvector have equal size to each eigenvector standardization.Subband k through standardized eigenvector

Can be expressed as:

$\underset{\&OverBar;}{\overset{~}{v}}\left(k\right)={\left[\begin{array}{cccc}A{e}^{j{\mathrm{\&theta;}}_1\left(k\right)}& A{e}^{j{\mathrm{\&theta;}}_2\left(k\right)}& A{e}^{j{\mathrm{\&theta;}}_3\left(k\right)}& A{e}^{j{\mathrm{\&theta;}}_4\left(k\right)}\end{array}\right]}^T,---\left(16\right)$

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

θ _i(k) be the phase place of the subband k of transmitting antenna i, be expressed as:

${\mathrm{\&theta;}}_i\left(k\right)=\&angle;{\mathrm{<figure-callout\; id="1"\; label="v"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">v</figure-callout>}}_{1.i}\left(k\right)={\tan }^{-1}\left(\frac{\mathrm{Im}\left\{{\mathrm{<figure-callout\; id="1"\; label="v"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">v</figure-callout>}}_{1,i}\left(k\right)\right\}}{\mathrm{Re}\left\{{\mathrm{<figure-callout\; id="1"\; label="v"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">v</figure-callout>}}_{1,i}\left(k\right)\right\}}\right)---\left(17\right)$

As shown in Equation (17), vector In the phase place of each element all from eigenvector v 1(k) respective element obtains (that is θ, _i(k) from v _{1, i}(k) obtain, wherein v ₁(k)=[v _1,1(k) v _1,2(k) v _1,3(k) v _1,4(k)] ^T).

Also can carry out the channel counter-rotating, make and to use a common speed for all data channels for the wave beam control model.For the wave beam control model, distribute to the transmitted power of each data subband Can be expressed as:

${\tilde{P}}_1\left(k\right)=\frac{{\widetilde{\mathrm{\&beta;}}}_1{\tilde{P}}_1}{{\widetilde{\mathrm{\&lambda;}}}_1\left(k\right)},k\&Element;K,---\left(18\right)$

Wherein

Be to use the constant normalization factor of the channel counter-rotating back total transmitted power of maintenance;

It is the transmitted power of distributing to each root of four antennas; And

It is power gain for the subband k of the main eigenmodes of wave beam control model.

Normalization factor Can be expressed as:

${\widetilde{\mathrm{\&beta;}}}_1=\frac{1}{\underset{k\&Element;K}{\mathrm{\&Sigma;}}{{\widetilde{\mathrm{\&lambda;}}}_1}^{-1}\left(k\right)}---\left(19\right)$

Transmitted power

Can be given P ₁=P _Total/ 4 (being the uniform distribution of total transmitted power between four transmit antennas).Power gain Can be expressed as:

${\widetilde{\mathrm{\&lambda;}}}_1\left(k\right)={\underset{\&OverBar;}{\overset{~}{v}}}^H\left(k\right){\underset{\&OverBar;}{H}}^H\left(k\right)\underset{\&OverBar;}{H}\left(k\right)\underset{\&OverBar;}{\overset{~}{v}}\left(k\right)---\left(20\right)$

For 48 data subbands, the channel counter-rotating causes Power division, for k ∈ K.So the gain of each data subband can be given $\tilde{g}\left(k\right)=\sqrt{{\tilde{P}}_1\left(k\right)}.$

For the wave beam control model, the transmission vector of each subband x(k) can be expressed as:

$\underset{\&OverBar;}{x}\left(k\right)=\underset{\&OverBar;}{\overset{~}{v}}\left(k\right)\tilde{g}\left(k\right)s\left(k\right),k\&Element;K.---\left(21\right)$

Be for simplicity equally, formula (21) does not comprise the correction factor of the difference of the transmission chain/reception chain that is used to remedy access point and user terminal place.

As shown in Equation (16), the standardization dominant vector of each subband Four elements have equal size, but have different phase places.Therefore, wave beam is controlled to be each subband and generates a transmission vector x(k), x(k) four elements have identical size but have different phase places.

Figure 10 B illustrates the block diagram that can carry out transmission spatial processor 720c one embodiment of spatial manipulation for the wave beam control model.

In processor 720c, demultiplexer 1032 receives modulation, symbol streams s (n) and its multichannel is resolved into 48 son streams (being labeled as s (1) to s (k)) of 48 data subbands.The sub-stream of each code element is provided for corresponding transmission subband wave beam processor controls 1040.Each processor 1040 is that a subband is carried out the processing shown in the formula (14).

In each sent subband wave beam processor controls 1040, the sub-stream of modulated symbol was provided for multiplier 1042, and multiplier 1042 also is relevant subband receiving gain Then, multiplier 1042 usefulness gain The convergent-divergent modulated symbol is to obtain the modulated symbol through convergent-divergent, and the latter then is provided for wave beam control unit 1050.

Wave beam control unit 1050 also receives the standardization eigenvector of relevant subbands

In wave beam control unit 1050, be provided for four multiplier 1052a to 1052d through the modulated symbol of convergent-divergent, the latter is acceptance criteria eigenvector respectively also

Four elements

With Its standardization eigenvector value of each multiplier 1052 usefulness

Multiply by its through the modulated symbol of convergent-divergent to provide through preregulated code element.Multiplier 1052a supplies with buffer/multiplexer 1070a to four to 1070d through the sub-flow point of preregulated code element indescribably to 1052d.

For 48 data subbands, each buffer/multiplexer 1070 is from sending subband wave beam processor controls 1040a to 1040k reception pilot frequency code element with through preregulated code element, pilot tone and multiplexed, and provide one to send code element stream x for a transmit antennas for each code-element period through preregulated code element and null value _i(n).Each follow-up OFDM that sends code element stream modulates as mentioned above.

The processing of wave beam control model is described in further detail in the common U.S. Patent application of transferring the possession of, this patent was submitted on August 27th, 2002, sequence number is 10/228,393, is entitled as " Beam-Steering and Beam-Formingfor Wideband MIMO Systems ".System also can be designed to support the beam shaping pattern, uses eigenvector rather than standardized vector to send data flow whereby on main eigenmodes.

4.PHY the framing of frame

Figure 11 A illustrates an embodiment of framing unit 808, and framing unit 808 is used for before sending data processor to carry out subsequent treatment the data of each FCH/RCH grouping being carried out framing.This framing function goes up the message that sends and bypass for BCH, FCCH and RACH.The framing unit generates an integer PHY frame for each FCH/RCH grouping, and wherein for embodiment described here, each PHY frame strides across 6 OFDM code elements.

For diversity and wave beam control model, only use a space channel or broadband eigenmodes for transfer of data.The speed of this pattern is known, can calculate the information bit that may send in the pay(useful) load of each PHY frame.For space multiplexing mode, can use a plurality of space channels for transfer of data.Because the speed of each space channel is known,, can calculate the information bit that in the pay(useful) load of each PHY frame, sends therefore for all space channels.

Shown in Figure 11 A, the information bit of each FCH/RCH grouping (is labeled as i ₁i ₂i ₃i ₄...) offer CRC maker 1102 and multiplexer 1104 in the framing unit 808.CRC maker 1102 is for the bit in the header (if there is) of each PHY frame and the pay(useful) load field generates a crc value, and the CRC bit is offered multiplexer 1104.Multiplexer 1104 receives information bit, CRC bit, preamble bit and filling bit (for example null value), and provides these bits based on the PHY control frame signal with correct order, as shown in Figure 6.By directly providing information bit by multiplexer 1104, can bypass framing function.Through framing and not the bit of framing (be labeled as d ₁d ₂d ₃d ₄...) be provided for disarrangement device 810.

5. upset

In one embodiment, the data bit of each transmission channel is in the encoder multilated.Upset makes the data randomization the complete one or entirely zero long sequence of forming not send.This can reduce the variation of the peak value of OFDM waveform to average power.Upset can be omitted one or more transmission channels, and also can optionally be enabled and forbid.

Figure 11 A also illustrates an embodiment of disarrangement device 810.In this embodiment, disarrangement device 810 is realized a maker multinomial:

G(x)＝x ⁷+x ⁴+x (22)

Also can use other maker multinomial, this within the scope of the invention.

Shown in Figure 11 A, disarrangement device 810 comprises that seven delay element 1112a of order coupling are to 1112g.For each clock cycle, two bits preserving among 1114 couples of delay element 1112d of adder and the 1112g are carried out mould 2 and are added, and a upset bit is offered delay element 1112a.

Through framing/bit (d of framing not ₁d ₂d ₃d ₄) being provided for adder 1116, the corresponding bit of upsetting of adder 1116 usefulness is to each bit d _nExecution mould 2 adds, so that the bit q through upsetting is provided _n Disarrangement device 810 provides once the sequence that upsets bit, is labeled as q ₁q ₂q ₃q ₄....

At the place that begins of each tdd frame, the initial condition of disarrangement device (being the content of delay element 1112a to 1112g) is set as the non-zero number of one 7 bits.As shown in BCH message, three highest significant positions (MSB) (being that delay element 1112e is to 1112f) always are set as one (" 1 "), and four least significant bits (LSB) are set as the tdd frame counter.

6. coding/brachymemma

In one embodiment, use single base sign indicating number before transmission, data to be encoded.This base sign indicating number is that a code rate generates coded-bit.Other code rate of all that system supported (as shown in Table 25) can by or the repeated encoding bit or or the brachymemma coded-bit obtain.

Figure 11 B illustrates an embodiment of basic yard encoder 812 of the system that can realize.In this embodiment, base sign indicating number is that speed is 1/2, limited length is the convolutional encoding of 7 (K=7), and maker is 133 and 171 (octal system).

In encoder 812, multiplexer 1120 receives and multiplexed bit and tail bit (for example null value) through upsetting.Encoder 812 comprises that also six delay element 1122a of order coupling are to 1122f.Four adder 1124a are coupled to 1124d also order, and are used for realizing first maker (133).Similarly, four adder 1126a are coupled to 1126d also order, and are used for realizing second maker (171).Shown in Figure 11 B, adder further is coupled to delay element in the mode that realizes two makers 133 and 171.

Bit through upsetting is offered the first delay element 1122a and adder 1124a and 1126a.For each clock cycle, adder 1124a carries out moulds 2 to 1124d to four previous bits preserving among the bit that arrives and delay element 1122b, 1122c, 1122e and the 1122f and adds, so that provide first coded-bit for this clock cycle.Similarly, adder 1126a carries out moulds 2 to 1126d to four previous bits preserving among the bit that arrives and delay element 1122a, 1122b, 1122c and the 1122f and adds, so that provide second coded-bit for this clock cycle.The coded-bit that first maker is generated is marked as a ₁a ₂a ₃a ₄..., the coded-bit that second maker is generated is marked as b ₁b ₂b ₃b ₄....Then, multiplexer 1128 receives two coded bit streams from two makers, and they are multiplexed into single encoded bit stream, and the latter is marked as a ₁b ₁a ₂b ₂a ₃b ₃a ₄b ₄....For each bit q through upsetting _n, generate two coded-bit a _nAnd b _n, this produces code rate 1/2.

Figure 11 B also illustrates an embodiment that can generate the employed repetition of other code rate/brachymemma unit 814 based on 1/2 basic bit rate.In unit 814, be provided for repetitive 1132 and brachymemma 1134 from the coded-bit of the speed 1/2 of encoder 812.Repetitive 1132 repeats each speed 1/2 coded-bit once, to obtain efficient coding speed 1/4.The coded-bit of some speed 1/2 is deleted based on specific brachymemma pattern in brachymemma unit 1134, so that the code rate of expectation is provided.

Table 30 is listed the exemplary brachymemma pattern that can be used for the various code rates that system supports.Also can use other brachymemma pattern, this within the scope of the invention.

Table 30

Code rate	The brachymemma pattern
		1/2	11
7/12	11111110111110
		5/8	1110111011
2/3	1110
		11/16	1111101111111010011100
3/4	111001
		13/16	01111011111101110000101100
5/6	1110011001
		7/8	11101010011001

In order to obtain code rate k/n, brachymemma unit 1134 provides n coded-bit for the coded-bit of every group of 2k speed 1/2 receiving from encoder 812.Like this, 2k-n coded-bit of deletion from every group of 2k coded-bit.To come mark by zero the brachymemma pattern from the bit of every group of deletion.For example, for obtaining code rate 7/12, always delete two bits in every group of 14 coded-bits of own coding device 812, the bit of being deleted is the 8th and the 14th coded-bit in the group, as brachymemma pattern " 11111110111110 " institute mark.If the code rate of expectation is 1/2, then do not carry out brachymemma.

Multiplexer 1136 receives from repetitive 1132 with from the coded bit stream of brachymemma unit 1134.Then, if the expectation code rate is 1/4, then multiplexer 1136 provides the coded-bit from repetitive 1132, if the expectation code rate is 1/2 or higher, then multiplexer 1136 provides the coded bit stream from brachymemma unit 1134.

Except above-mentioned coding and brachymemma pattern, also can use other coding and brachymemma pattern, this is within the scope of the invention.For example, can use Turbo code, block encoding, some other yards or their combination in any to come data are encoded.Equally, can use different encoding schemes for different transmission channels.For example, can use conventional coding, can use the Turbo coding for dedicated transmission channel for Common transport channel.

7. interweave

In one embodiment, the coded-bit that be sent out is interleaved at 48 data intersubbands.For diversity and wave beam control model, between all data subbands, send and the coded bit stream that interweaves.For space multiplexing mode, nearly can send nearly four coded bit streams on four space channels.Interweave and to carry out independently for each space channel, make each coded bit stream all between all data subbands of the space channel that is used to send this bit stream, be interleaved.Table 29 illustrates the exemplary coded-bit-allocation of subbands that interweaves that can be used for all transmission modes.

In one embodiment, in each interweaves at interval, interweave in all 48 data intersubbands execution.For this embodiment, every group of 48 coded-bits are all expanded on 48 data subbands in the stream, so that frequency diversity to be provided.48 coded-bits in every group can be assigned to index 0 to 47.Each coded-bit index all is associated with a corresponding subband.All coded-bits with a particular index all are sent out on relevant subband.For example, first coded-bit (index is 0) in every group is sent out on subband-26, and second coded-bit (index is 14) is sent out on subband 1, and the 3rd coded-bit (index is 2) is sent out on subband-17, and the rest may be inferred.This interleaving scheme can be used for diversity mode, wave beam control model and space multiplexing mode.Other interleaving scheme that is used for spatial reuse is described below.

Interweave or or can carry out in time in addition.For example, after interweaving between data subband, the coded-bit of each subband can further be interweaved (for example on a PHY frame or PDU) so that time diversity to be provided.For space multiplexing mode, also can on a plurality of space channels, carry out and interweave.

In addition, can on the dimension of QAM code element, adopt to interweave, make the coded-bit that forms the QAM code element be mapped as the different bit positions of QAM code element.

8. symbol mapped

Table 31 illustrates the symbol mapped of each modulation scheme that system supports.For each modulation scheme (except BPSK), the bit of half is mapped as homophase (I) component, and second half bit is mapped as quadrature (Q) component.

In one embodiment, can define the signal group of stars of each modulation scheme of supporting based on Gray (Gray) mapping.According to gray mappings, the consecutive points in the signal group of stars (in I and the Q component) only differ a bit position.Gray mappings has reduced number of bit errors for situation about more may make mistakes, and error situation is mapped as near the tram a position corresponding to receiving symbol, only can mistake receive a coded-bit under this situation.

Table 31

BPSK
			b	I	Q
0	-1	0
			1	1	0

QPSK
				b 0	I	b 1	Q
0	-1	0	-1
				1	1	1	1

16 QAM
				b 0b 1	I	b 2b 3	Q
00	-3	00	-3
				01	-1	01	-1
11	1	11	1
				10	3	10	3

256 QAM
				b 0b 1b 2b 3	I	b 4b 5b 6b 7	Q
0000	-15	0000	-15
				0001	-13	0001	-13
0011	-11	0011	-11
				0010	-9	0010	-9
0110	-7	0110	-7
				0111	-5	0111	-5
0101	-3	0101	-3
				0100	-1	0100	-1
1100	1	1100	1
				1101	3	1101	3
1111	5	1111	5
				1110	7	1110	7
1010	9	1010	9
				1011	11	1011	11
1001	13	1001	13
				1000	15	1000	15

64 QAM
				b 0b 1b 2	I	b 3b 4b 5	Q
000	-7	000	-7
				001	-5	001	-5
011	-3	011	-3
				010	-1	010	-1
110	1	110	1
				111	3	111	3
101	5	101	5
				100	7	100	7

The I of each modulation scheme shown in the table 31 and Q value are all used a normalization factor k _NormConvergent-divergent makes that the average power of all signaling points equals one in the coherent signal group of stars.Also can use the quantized value of the normalization factor of the modulation scheme of supporting.So the modulated symbol s in the signal specific group of stars has following form:

s＝(I+jQ)·K _norm，

Wherein I and Q are the values of a signal group of stars in the table 31.

For given PDU, being modulated at may be different between PDU, and also may be different for the employed a plurality of space channels of transfer of data.For example, for BCH PDU, can use different modulation schemes for beacon pilot frequency, MIMO pilot tone and BCH message.

9. the processing of space multiplexing mode

For space multiplexing mode, a PDU can be sent out on a plurality of space channels.Can use various schemes to come deal with data, be used on a plurality of space channels, sending.Two specific processing schemes of space multiplexing mode are described below.

In first kind of processing scheme, carry out coding and brachymemma by each space channel, so that realize the code rate of expectation for each space channel.The N that transfer of data will be used _EIndividual space channel is arranged from being up to minimum reception SNR.At first encode the data of whole PDU to obtain speed 1/2 coded bit stream.The brachymemma coded-bit is so that obtain the code rate of expectation for each space channel then.

For N _EIndividual space channel, brachymemma can be carried out with order, from the space channel of best (i.e. the highest SNR) to the poorest (being minimum SNR).Particularly, brachymemma is at first carried out for the optimal spatial channel with the highest reception SNR in the brachymemma unit.When having generated the coded-bit of correct number for the optimal spatial channel, brachymemma is just carried out for having time inferior good space channel of high reception SNR in the brachymemma unit.This process continues, up to all N _ETill the coded-bit of individual space channel has all generated.The order of brachymemma is to receive SNR to minimum receive SNR from maximum, and no matter how much employed specific coding speed of each space channel is.

For the example shown in the table 28, at first 3456 information bits that will send in total PHY frame are encoded, so that obtain 6912 coded-bits with the base sign indicating number of speed 1/2.Preceding 3168 coded-bits come brachymemma to obtain 2304 coded-bits with the brachymemma pattern of code rate 11/16, and the latter provides in the PHY of first space channel frame.Carry out brachymemma to obtain 1728 coded-bits with the brachymemma pattern of code rate 3/4 to following 2592 coded-bits then, the latter provides in the PHY of second space channel frame.Then 864 coded-bits are to obtain 576 coded-bits then to come brachymemma with the brachymemma pattern of code rate 3/4, and the latter provides in the PHY of the 3rd space channel frame.Last 288 coded-bits that come brachymemma PHY frame with the brachymemma pattern of code rate 1/2 to be obtaining 288 coded-bits then, and the latter in the end provides in the PHY frame of a space channel.These four independent PHY frames are further processed and are sent out on four space channels.Carry out the brachymemma of next total PHY frame then in a similar manner.First kind of processing scheme can realize with the transmission data processor 710b among Fig. 9 A.

In second kind of processing scheme, be encoding and brachymemma of subband to carrying out.In addition, coding and brachymemma are in the whole selected space channel cocycle of every pair of subband.

Figure 11 C illustrates a block diagram, and it has illustrated the transmission data processor 710d that realizes second kind of processing scheme.812 pairs of convolutional encodings of carrying out speed 1/2 from the bit through upsetting of disarrangement device 810 of encoder.Each space channel all is assigned to a special speed, and this special speed is associated with the particular combinations of code rate and modulation scheme, and is as shown in Table 25.Make b _mExpression is for the number of coded bits of each modulated symbol of space channel m (or ground of equal value, the number of coded bits that sends on each data subband of space channel m), r _mThe employed code rate of representation space channel m.b _mValue depend on the group of stars size of the employed modulation scheme of space channel m.Particularly, for BPSK, QPSK, 16-QAM, 64-QAM and 256-QAM, b _mEqual 1,2,4,6 and 8 respectively.

Encoder 812 provides a speed 1/2 coded bit stream to demultiplexer 816, and demultiplexer 816 resolves into the coded bit stream multichannel that receives four son streams of four space channels.Multichannel is decomposed feasible preceding 4b ₁r ₁Individual coded-bit is sent to the buffer 813a of space channel 1, then 4b ₂r ₂Individual coded-bit is sent to the buffer 813b of space channel 2, and the rest may be inferred.Whenever demultiplexer 816 during all four space channel cocycles one time, each buffer 813 just receives 4b _mr _mIndividual coded-bit.For each cycle, total total $b_{\mathrm{total}}=\underset{m=1}{\overset{4}{\mathrm{\&Sigma;}}}{4b}_m{r}_m$ The coded-bit of individual speed 1/2 is provided for four buffer 813a to 813d.Therefore, for every b _TotalIndividual coded-bit, demultiplexer 816 circulations are through whole four positions of four space channels, b _TotalThe number of coded bits that is to use whole four space channels on a pair of subband, to send.

In case each buffer 813 is all used the 4b of correlation space channel _mr _mIndividual coding chip is filled, and the coded-bit in just can the brachymemma buffer is so that obtain the code rate of this space channel.Because 4b _mr _mThe coded-bit of individual speed 1/2 has striden across an integer truncated human cyclin of each brachymemma pattern, therefore after the brachymemma of each space channel m, in fact provides 2b _mIndividual coded-bit.Then, the 2b of each space channel _mIndividual coded-bit just distributes (or interweaving) on data subband.

In one embodiment, once in one group of 6 subband, each space channel execution is interweaved.Coded-bit after the brachymemma of each space channel can sequence arrangement be c _i, for i=0,1,2 ....For each space channel is kept a counter C _mSo that every group of 6b that the brachymemma unit is provided for this space channel _mIndividual coded-bit is counted.For example, for b _m=2 QPSK, the coded-bit c that is provided for the brachymemma unit ₀To c ₁₁, counter can be set as C _m=0, for coded-bit c afterwards ₁₂To c ₂₃, can be set as C _m=1, the rest may be inferred.The Counter Value C of space channel m _mCan be expressed as:

In order to determine coded-bit c _iBe assigned to which subband, the code index of at first following definite coded-bit:

Bit index=(i mod 6)+6C _m(24)

Then, bit index use table 29 is mapped to corresponding subband.

For last example, first group of 6 coded-bit c ₀To c ₅Be associated second group of 6 coded-bit c respectively with bit index 0 to 5 ₆To c ₁₁Also be associated to 5 with bit index 0 respectively.Shown in table 29, coded-bit c ₀And c ₆Can be mapped to subband-26, coded-bit c ₁And c ₇Can be mapped to subband 1, the rest may be inferred.Begin spatial manipulation for these first group of 6 subband then.The 3rd group of 6 coded-bit c ₁₂To c ₁₇(C _m=1) is associated the 4th group of 6 coded-bit c respectively with bit index 6 to 11 ₁₈To c ₂₃Also be associated to 11 with bit index 6 respectively.Coded-bit c ₁₂And c ₁₈Can be mapped to subband-25, coded-bit c ₁₃And c ₁₉Can be mapped to subband 2, the rest may be inferred.Begin spatial manipulation for 6 subbands of this next group then.

Numeral 6 in the formula (24) comes to carry out in the group of 6 subbands and interweaves.(mod8) computing in the formula (23) comes from for 48 data subbands 8 groups that interweave.Because each circulation of the demultiplexer 816 shown in Figure 11 C all produces two subbands that enough coded-bits are filled each broadband eigenmodes, therefore need altogether 24 cycles to provide 48b for an OFDM code element of each space channel _mIndividual coded-bit.

Once in the group of 6 subbands, interweave and to reduce processing delay.Particularly, in case every group of 6 subbands are available, can begin spatial manipulation.

In other embodiments, once can be at N _BCarry out for each space channel in the group of individual subband and interweave, wherein N _BCan be that arbitrary integer is (for example for interweaving N on whole 48 data subbands _BCan equal 48).

VI. calibration

For the TDD system, down link and up link are shared identical frequency band in the mode of time division duplex.Under this situation, there is height correlation in half between the channel response of down link and up link.Should relevant can be used to simplify channel estimating and spatial manipulation.For the TDD system, each subband of supposing Radio Link is reciprocal.Just, if H(k) expression for subband k the channel response matrix from antenna array A to antenna array B, then reciprocal channel mean from antenna array B to antenna array A joint by H(k) transposition provides, promptly H ^T(k).

Yet the transmission of access point place generally sends different with the response of reception chain with the response that receives chain (gain and phase place) with the user terminal place.Can carry out calibration and determine frequency response poor of transmission/the receptions chain at access point and user terminal place, and remedy this difference, feasible can be through the down link and the uplink response of calibrating according to representing each other.In case calibrated and remedied transmission/reception chain, the dominant vector that just can use the tolerance of a link (for example down link) to derive another link (for example up link).

" effectively " down link and uplink channel responses H _Dn(k) and H _Up(k) comprise transmission that access point and user terminal place are available and receive the response of chain, and be expressed as:

H _dn(k)＝ R _ut(k) H(k) T _ap(k)， k∈K， (25)

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

Wherein T _Ap(k) and R _Ap(k) be N _Ap* N _ApDiagonal matrix, its be for subband k, respectively with the N of access point place _ApThe item of the complex gain that the transmission chain of root antenna and reception chain are associated;

T _Ut(k) and R _Ut(k) be N _Ut* N _UtDiagonal matrix, its be for subband k, respectively with the N of user terminal place _UtThe item of the complex gain that the transmission chain of root antenna and reception chain are associated; And

H(k) N of foot line link _Ut* N _ApChannel response matrix.

Two formula in the combinatorial formula collection (25) obtain following relational expression:

H _up(k) K _ut(k)＝( H _dn(k) K _ap(k)) ^T， k∈K， (26)

Wherein ${\underset{\&OverBar;}{K}}_{\mathrm{ut}}\left(k\right)={\underset{\&OverBar;}{T}}_{\mathrm{ut}}^{-1}\left(k\right){\underset{\&OverBar;}{R}}_{\mathrm{ut}}\left(k\right)$ And ${\underset{\&OverBar;}{K}}_{\mathrm{ap}}\left(k\right)={\underset{\&OverBar;}{T}}_{\mathrm{ap}}^{-1}\left(k\right){\underset{\&OverBar;}{R}}_{\mathrm{ap}}\left(k\right).$

The channel response of " reality " calibration on the up link is represented on the left side of formula (26), and the transposition of the channel response of " reality " calibration on the down link is represented on the right.Shown in formula (26), use diagonal matrix respectively to effective down link and uplink channel responses K _Ap(k) and K _Ut(k), the enough transposition each other of energy are represented the channel response of the calibration of down link and up link.(the N of access point _Ap* N _Ap) diagonal matrix is to receive the chain response R _Ap(k) with the response of transmission chain T _Ap(k) ratio (promptly ${\underset{\&OverBar;}{K}}_{\mathrm{ap}}\left(k\right)=\frac{{\underset{\&OverBar;}{R}}_{\mathrm{ap}}\left(k\right)}{{\underset{\&OverBar;}{T}}_{\mathrm{ap}}\left(k\right)},$ ) wherein this ratio one by one element draw.

Similarly, (the N of user terminal _Ut* N _Ut) diagonal matrix is to receive the chain response R _Ut(k) with the response of transmission chain T _Ut(k) ratio.

Matrix K _Ap(k) and K _Ut(k) comprise the value of the difference that can remedy access point and user terminal place transmission/reception chain.So this can be represented the channel response of a link by the channel response of another link, shown in formula (26).

Can carry out calibration and determine matrix K _Ap(k) and K _Ut(k).Generally speaking, real channel response H(k) and transmission/reception chain response be unknown, can not be accurately or easily determine them.But can estimate effective down link and uplink channel responses based on the pilot tone that sends on down link and the up link respectively H _Dn(k) and H _Up(k), as described below.As described below then, can estimate based on down link and uplink channel responses With

Come derivational matrix K _Ap(k) and K _Ut(k) estimation, the latter is called correction matrix

With

Matrix With The correction factor that comprises the difference that can remedy access point and user terminal place transmission/reception chain.

" calibration " down link and uplink channel responses that user terminal and access point observe are expressed as respectively:

${\underset{\&OverBar;}{H}}_{\mathrm{cdn}}\left(k\right)={\underset{\&OverBar;}{H}}_{\mathrm{dn}}\left(k\right){\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right),k\&Element;K,$

${\underset{\&OverBar;}{H}}_{\mathrm{cup}}\left(k\right)={\underset{\&OverBar;}{H}}_{\mathrm{up}}\left(k\right){\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right),k\&Element;K,---\left(27\right)$

Wherein H _Cdn ^T(k) and H _Cup(k) be the estimation of the channel response expression formula of " reality " calibration in the formula (26).The expression formula of use formula (26) is come two formula in the combinatorial formula collection (27), can get ${\underset{\&OverBar;}{H}}_{\mathrm{cup}}\left(k\right)\&ap;{\underset{\&OverBar;}{H}}_{\mathrm{cdn}}^T\left(k\right).$ Relational expression ${\underset{\&OverBar;}{H}}_{\mathrm{cup}}\left(k\right){\&ap;\underset{\&OverBar;}{H}}_{\mathrm{cdn}}^T\left(k\right)$ Accuracy depend on matrix

With Accuracy, the latter depends on again that generally down link and uplink channel responses estimate

With

Quality.

Calibration can use various schemes to carry out.For clear, a specific calibration program is described below.In order to carry out calibration, user terminal is at first gone up timing and the frequency that the beacon pilot frequency that sends obtains access point based on BCH.Then, user terminal sends a message so that the calibration process of beginning and access point on RACH.Calibration can be carried out concurrently with registration/checking.

Because the frequency response of access point and user terminal place transmission/reception chain is level and smooth on the frequency band that great majority are noted generally, therefore phase place/the gain inequality of transmission/reception chain can characterize with a small amount of subband.Calibration can to 4,8,16,48 or the subband of some other quantity carry out, this quantity is specified in being sent out with the message that begins to calibrate.Calibration also can be carried out pilot subbands.The calibration constants of clearly not carrying out the subband of calibration on it can be by calculating the subband interpolation of calibration.For clear, below be assumed to all data subbands and all carry out calibration.

For calibration, access point distributes the time of sufficient amount to user terminal on RACH, add a message so that transmission has the up link MIMO pilot tone of enough durations.The duration of up link MIMO pilot tone may be depended on the sub band number of carrying out calibration thereon.For example, if four subbands are carried out calibration, then 8 OFDM code elements can be that enough, more subbands may need more (for example 20) OFDM code element.Total transmitted power is generally fixed, if therefore send the MIMO pilot tone on a small amount of subband, then can use the transmitted power of a greater number for each of these subbands, and the SNR of each subband is very high.On the contrary, if on a large amount of subbands, send the MIMO pilot tone, then can be for each subband use more a spot of transmitted power, the SNR of each subband is very poor.If the SNR of each subband is enough high, then for the MIMO pilot tone sends more OFDM code element, and in these OFDM code elements of receiver place integration so that be the higher total SNR of this subband acquisition.

Then, user terminal sends a MIMO pilot tone on RCH, and access point uses it to derive for each data subband the estimation of efficient uplink channel response

Uplink channel responses is estimated to be quantized (for example be quantified as the complex values of 12 bits, have homophase (I) and quadrature (Q) component) and to be sent to user terminal.

User terminal is also gone up the estimation that the downlink mimo pilot tone that sends to derive for each data subband the active downlink channel response based on BCH Obtaining the estimation of effective up link and downlink channel response for all data subbands With

After, user terminal is determined correction factor for each data subband With

They are access in respectively a little and user terminal uses.Can be updating vector

Only be defined as and comprise

Diagonal element, and updating vector

Only be defined as and comprise

Diagonal element.

Correction factor can derive in every way, comprises by the matrix ratio calculating and MMSE calculating.These two kinds of computational methods all are described in further detail below.Also can use other computational methods, this within the scope of the invention.

1. the matrix ratio calculates

In order to estimate according to effective down link and uplink channel responses With

Determine updating vector With At first calculate (a N for each data subband _Ut* N _Ap) matrix C(k), as follows:

$\underset{\&OverBar;}{C}\left(k\right)=\frac{{\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{up}}^T\left(k\right)}{{\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{dn}}\left(k\right)},k\&Element;K,---\left(28\right)$

Wherein ratio one by one element draw.Therefore C(k) each element can followingly calculate:

$c_{i,j}\left(k\right)=\frac{{\hat{h}}_{\mathrm{upi},j}\left(k\right)}{{\hat{h}}_{\mathrm{dni},j}\left(k\right)},i=\{1...N_{\mathrm{ut}}\},j=\{1...N_{\mathrm{ap}}\},---\left(29\right)$

Wherein Be The (i, j) individual (OK, row) element,

Be

(i, j) individual element, c _{I, j}(k) be C(k) (i, j) individual element.

So, the updating vector of access point

Equal CThe average of standardization row (k).At first use first element in the delegation to N in this row _ApEach of individual element is carried out convergent-divergent, thereby right C(k) the column criterionization of whenever advancing.Like this, if c _i(k)=[c _{I, 1}(k)/c _{I, 1}(k) ... c _{I, j}(k)/c _{I, 1}(k) ... c _{I, Nap}(k)/c _{I, 1}(k)] be C(k) i is capable, then standardized row Can be expressed as:

${\underset{\&OverBar;}{\overset{~}{c}}}_i\left(k\right)=[c_{i,1}\left(k\right)/c_{i,1}\left(k\right)...c_{i,j}\left(k\right)/c_{i,1}\left(k\right)...c_{i,N_{\mathrm{ap}}}\left(k\right)/c_{i,1}\left(k\right)]---\left(30\right)$

So the average of standardization row is N _UtIndividual standardization row sum is divided by N _Ut, be expressed as follows:

${\underset{\&OverBar;}{\overset{~}{k}}}_{\mathrm{ap}}\left(k\right)=\frac{1}{N_{\mathrm{ut}}}\underset{i=1}{\overset{N_{\mathrm{ut}}}{\mathrm{\&Sigma;}}}{\underset{\&OverBar;}{\overset{~}{c}}}_i\left(k\right),k\&Element;K---\left(31\right)$

Since standardization, therefore

First element be one.

The updating vector of user terminal

Equal CThe average of the inverse of standardization row (k).At first use vector

J element (mark K _{Ap, j, j}(k) be) each element in the row is carried out convergent-divergent, thus right C(k) every row carry out standardization.Like this, if c _j(k)=[c _{1, j}(k) ... c _{Nut, j}(k)] ^TBe C(k) j is capable, then standardized row

Can be expressed as:

So the average of the inverse of standardization row is N _ApThe sum reciprocal of individual standardization row is divided by N _Ap, be expressed as follows:

Wherein standardization is listed as

Inverse carry out by element.

2.MMSE calculate

Calculate correction factor for MMSE

With

Estimate from effective down link and uplink channel responses

With

In derive, thereby make mean square error (MSE) minimum between the uplink channel responses of the downlink channel response of calibration and calibration.This condition can be expressed as follows:

$\min |{\left({\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{dn}}\left(k\right){\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right)\right)}^T-\left({\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{up}}\left(k\right){\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right)\right){|}^2,k\&Element;K,---\left(34\right)$

Also can write:

$\min {|{\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right){\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{dn}}^T\left(k\right)-{\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{up}}\left(k\right){\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{nt}}\left(k\right)|}^2,k\&Element;K,$

Wherein because

Be a pair of angular moment battle array, therefore

Formula (34) suffers restraints: First element be set as one (promptly ${\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ap},\mathrm{0,0}}\left(k\right)=1$ )。If there is not this constraint, then can obtain common separating, matrix

With

All elements all be set as zero.In formula (34), at first obtain matrix Y (k): $\underset{\&OverBar;}{Y}\left(k\right)={\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right){\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{dn}}^T\left(k\right)-{\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{up}}\left(k\right){\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right).$ Then be the N of matrix Y (k) _ApN _UtIndividual each obtain absolute value square.

Carrying out MMSE for the subband of each appointment calculates to obtain the correction factor of this subband

With

The MMSE that a subband is described below calculates.For simplicity, omit subband index k in the following description.Equally for simplicity, downlink channel response is estimated Element be marked as { a _Ij, uplink channel responses is estimated Element be marked as { b _Ij, matrix

Diagonal element be marked as { u _i, matrix Diagonal element be marked as { v _i, i={1...N wherein _ApAnd j={1...N _Ut.

Can rewrite mean square error from formula (34), as follows:

$\mathrm{MSE}=\underset{j=1}{\overset{N_{\mathrm{ut}}}{\mathrm{\&Sigma;}}}\underset{i=1}{\overset{N_{\mathrm{ap}}}{\mathrm{\&Sigma;}}}{|a_{\mathrm{ij}}{u}_i-b_{\mathrm{ij}}{v}_j|}^2---\left(35\right)$

Same constraints is u ₁=1.The local derviation of getting formula (35) by reference u and v goes out and partial derivative is made as zero, thereby obtains least mean-square error.The result of these computings is following formulary:

$\underset{j=1}{\overset{N_{\mathrm{ut}}}{\mathrm{\&Sigma;}}}(a_{\mathrm{ij}}{u}_i-b_{\mathrm{ij}}{v}_j)\&CenterDot;a_{\mathrm{ij}}^{*}=0,i\&Element;\{2...N_{\mathrm{ap}}\},---\left(36a\right)$

$\underset{i=1}{\overset{N_{\mathrm{ap}}}{\mathrm{\&Sigma;}}}(a_{\mathrm{ij}}{u}_i-b_{\mathrm{ij}}{v}_j)\&CenterDot;b_{\mathrm{ij}}^{*}=0,j\&Element;\{1...N_{\mathrm{ut}}\}.---\left(36b\right)$

In formula (36a), u ₁=1, so do not have partial derivative under this situation, index i gets N from 2 _Ap

Formulary (36a) and (36b) in (N _Ap+ N _Ut-1) set of individual formula can be represented more easily with matrix form, and is as follows:

A y＝ z， (37)

Wherein

$\underset{\&OverBar;}{A}=\left[\begin{array}{cccccccc}\underset{j=1}{\overset{N_{\mathrm{ut}}}{\mathrm{\&Sigma;}}}{\left|a_{2j}\right|}^2& 0& ...& 0& {-b}_{21}{a}_{21}^{*}& ...& & -b_{{2N}_{\mathrm{ap}}}{a}_{{2N}_{\mathrm{ut}}}^{*}\\ 0& \underset{j=1}{\overset{N_{\mathrm{ut}}}{\mathrm{\&Sigma;}}}{\left|a_{3j}\right|}^2& 0& ...& ...& ...& & ...\\ ...& 0& ...& 0& & & & -b_{N_{\mathrm{ap}}{N}_{\mathrm{ut}}}{a}_{N_{\mathrm{ap}}{N}_{\mathrm{ut}}}^{*}\\ 0& ...& 0& \underset{j=1}{\overset{N_{\mathrm{ut}}}{\mathrm{\&Sigma;}}}{\left|a_{N_{\mathrm{ap}}j}\right|}^2& -b_{N_{\mathrm{ap}}1}{a}_{{\mathrm{<figure-callout\; id="1"\; label="N\; ap"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">N</figure-callout>}}_{\mathrm{ap}}1}^{*}& & & 0\\ {-a}_{21}{b}_{21}^{*}& ...& & -a_{N_{\mathrm{ap}}1}{\mathrm{<figure-callout\; id="1"\; label="b\; N\; ap"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">b</figure-callout>}}_{N_{\mathrm{ap}}}^{{}_{}1}& \underset{i=1}{\overset{N_{\mathrm{ap}}}{\mathrm{\&Sigma;}}}{\left|{\mathrm{<figure-callout\; id="1"\; label="b\; i"\; filenames="A20038010456001331.png,A20038010456001371.png"\; state="\{\{state\}\}">b</figure-callout>}}_i\right|}^2& 0& ...& \&CenterDot;\&CenterDot;\&CenterDot;\\ ...& ...& & & 0& \underset{i=1}{\overset{N_{\mathrm{ap}}}{\mathrm{\&Sigma;}}}{\left|{\mathrm{<figure-callout\; id="2"\; label="b\; i"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">b</figure-callout>}}_i\right|}^2& 0& 0\\ {-a}_{{2N}_{\mathrm{ut}}}{b}_{{2N}_{\mathrm{ut}}}^{*}& ...& & {-a}_{N_{\mathrm{ap}}{N}_{\mathrm{ut}}}{b}_{N_{\mathrm{ap}}{N}_{\mathrm{ut}}}^{*}& 0& ...& 0& \underset{i=1}{\overset{N_{\mathrm{ap}}}{\mathrm{\&Sigma;}}}{\left|b_{i{N}_{\mathrm{ut}}}\right|}^2\\ & & & & & & & \end{array}\right]$

$\underset{\&OverBar;}{y}=\left[\begin{array}{c}{u}_2\\ u_3\\ ...\\ u_{N_{\mathrm{ap}}}\\ v_1\\ {\mathrm{<figure-callout\; id="2"\; label="v"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">v</figure-callout>}}_2\\ ...\\ v_{N_{\mathrm{ut}}}\end{array}\right],\underset{\&OverBar;}{z}=\left[\begin{array}{c}0\\ 0\\ ...\\ 0\\ a_{11}{b}_{11}^{*}\\ a_{12}{b}_{12}^{*}\\ ...\\ a_{{1N}_{\mathrm{ut}}}{b}_{1N_{\mathrm{ut}}}^{*}\end{array}\right]$

Matrix AComprise (N _Ap+ N _Ut-1) OK, preceding N _Ap-1 row is corresponding to the N in the formulary (36a) _Ap-1 formula, last N _UtRow is corresponding to the N in the formulary (36b) _UtIndividual formula.Particularly, matrix AFirst row generates from formulary (36a) according to i=2, second is capable of the i=3 generation, the rest may be inferred.Matrix AN _ApRow generates from formulary (36b) according to j=1, and the rest may be inferred, and last column is according to j=N _UtGenerate.As implied above, matrix AEvery and vectorial zEvery can be based on matrix

With

In every and draw.

Correction factor is included in vector yIn, following drawing:

y＝ A ^-1 z (38)

The MMSE result calculated is the correction matrix that makes the down link of calibration and the mean square error minimum in the uplink channel responses

With Shown in formula (34).Because matrix With

Estimate based on down link and uplink channel responses With Obtain, so correction matrix

With Quality depend on channel estimating

With

Quality.The MIMO pilot tone is average so that obtain at the receiver place With Estimation more accurately.

Calculate the correction matrix that obtains based on MMSE With

Generally good than calculating the correction matrix that obtains based on the matrix ratio.Very little and tolerance noise can make under the situation that channel gain demotes greatly especially true at some channel gains.

3. calculate in the back

Can determine a pair of updating vector for each data subband

With

Because adjacent subband may be correlated with, therefore calculate simplification.For example, can carry out calculating for every n subband rather than for each subband, wherein n can be determined by the intended response of transmission/reception chain.If carry out calibration for being less than total data and pilot subbands, then the correction factor of " not calibration " subband can be by obtaining for " calibration " subband interpolation correction factor.

Also can use various other calibration programs to be respectively access point and user terminal derivation updating vector

With Yet such scheme can be that access point is derived " compatible " updating vector when calibration is carried out by different user terminals.

After derivation, user terminal is the updating vector of all data subbands

Beam back access point.If access point is calibrated (for example by other user terminal), then upgrade current updating vector with the updating vector that newly receives.Like this, if access point uses updating vector Send the MIMO pilot tone, user terminal is determined new updating vector from this MIMO pilot tone Updating vector after then upgrading is current and new the amassing of updating vector, promptly ${\underset{\&OverBar;}{\overset{^}{k}}}_{\mathrm{ap}3}\left(k\right)={\underset{\&OverBar;}{\overset{^}{k}}}_{\mathrm{ap}1}\left(k\right)\&CenterDot;{\underset{\&OverBar;}{\overset{^}{k}}}_{\mathrm{ap}2}\left(k\right),$ Wherein multiplication is by element ground execution one by one.Then, the updating vector after the renewal

Can be access in a use, till they are upgraded once more.

Updating vector

With

Can derive by same user terminal or different user terminals.In one embodiment, the updating vector after the renewal is defined as ${\underset{\&OverBar;}{\overset{^}{k}}}_{\mathrm{ap}3}\left(k\right)={\underset{\&OverBar;}{\overset{^}{k}}}_{\mathrm{ap}1}\left(k\right)\&CenterDot;{\underset{\&OverBar;}{\overset{^}{k}}}_{\mathrm{ap}2}\left(k\right),$ Wherein multiplication is by element ground execution one by one.In another embodiment, the updating vector after the renewal can be redefined into ${\underset{\&OverBar;}{\overset{^}{k}}}_{\mathrm{ap}3}\left(k\right)={\underset{\&OverBar;}{\overset{^}{k}}}_{\mathrm{ap}1}\left(k\right)\&CenterDot;{\underset{\&OverBar;}{\overset{^}{k}}}_{\mathrm{<figure-callout\; id="2"\; label="ap"\; filenames="A20038010456001331.png"\; state="\{\{state\}\}">ap</figure-callout>}2}^{\mathrm{\&alpha;}}\left(k\right),$ Wherein α is used to provide average weighted factor (for example 0＜α＜1).If it is not frequent that calibration is upgraded, it is best that then α approaches 1 possibility.If calibration is upgraded frequently but made an uproar, then less α value can be preferable.Then, the updating vector after the renewal

Be access in a use, till they are upgraded once more.

Access point and user terminal use their corresponding updating vectors

With Perhaps corresponding correction matrix With

(for k ∈ K) convergent-divergent modulated symbol before transmission, as described below.Formula (27) illustrates the down link and the uplink channel of the calibration that user terminal and access point observe.

VII. spatial manipulation

After carrying out calibration and remedying difference in transmission/reception chain, can be the spatial manipulation at TDD system simplification access point and user terminal place.As mentioned above, the downlink channel response of calibration is ${\underset{\&OverBar;}{H}}_{\mathrm{cdn}}\left(k\right)={\underset{\&OverBar;}{H}}_{\mathrm{dn}}\left(k\right){\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right).$ The uplink channel responses of calibration is

${\underset{\&OverBar;}{H}}_{\mathrm{cup}}\left(k\right)={\underset{\&OverBar;}{H}}_{\mathrm{up}}\left(k\right){\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right)\&ap;{\left({\underset{\&OverBar;}{H}}_{\mathrm{dn}}\left(k\right){\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right)\right)}^T.$

1. handle in the up link space

The uplink channel responses matrix of calibration H _Cup(k) singular value decomposition can be expressed as:

${\underset{\&OverBar;}{H}}_{\mathrm{cup}}\left(k\right)={\underset{\&OverBar;}{U}}_{\mathrm{ap}}\left(k\right)\underset{\&OverBar;}{\mathrm{\&Sigma;}}\left(k\right){\underset{\&OverBar;}{V}}_{\mathrm{ut}}^H\left(k\right),k\&Element;K,---\left(39\right)$

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

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

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

Correspondingly, the downlink channel response matrix of calibration H _Cdn(k) singular value decomposition can be expressed as:

${\underset{\&OverBar;}{H}}_{\mathrm{cdn}}\left(k\right)={\underset{\&OverBar;}{V}}_{\mathrm{ut}}^{*}\left(k\right)\underset{\&OverBar;}{\mathrm{\&Sigma;}}\left(k\right){\underset{\&OverBar;}{U}}_{\mathrm{ap}}^T\left(k\right),k\&Element;K---\left(40\right)$

Matrix V _Ut ^*(k) and U _Ap ^*(k) be respectively H _CdnThe matrix of the left side (k) and the right eigenvector.Shown in formula (39) and (40) and based on above description, the matrix of the left side of a link and the right eigenvector is respectively the complex conjugate of the matrix of the right of another link and left side eigenvector.Matrix V _Ut(k), V _Ut ^*(k), V _Ut ^T(k) and V _Ut ^H(k) be matrix V _Ut(k) multi-form, matrix U _Ap(k), U _Ap ^*(k), U _Ap ^T(k) and U _Ap ^H(k) also be matrix U _Ap(k) multi-form.For simplicity, the matrix of indication in the following description U _Ap(k) and V _Ut(k) also refer to their various other forms.Matrix U _Ap(k) and V _Ut(k) be used for carrying out spatial manipulation by access point and user terminal respectively, and by their subscript sign.Eigenvector is also referred to as " control " vector usually.

User terminal can be estimated the downlink channel response of calibrating based on the MIMO pilot tone that access point sent.Then, user terminal can be estimated the downlink channel response of calibration

Carry out singular value decomposition (for k ∈ K), to obtain

Diagonal matrix

Matrix with left side eigenvector V _Ut ^*(k).This singular value decomposition can be given: ${\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{cdn}}\left(k\right)={\underset{\&OverBar;}{\overset{^}{V}}}_{\mathrm{ut}}^{*}\left(k\right)\underset{\&OverBar;}{\overset{^}{\mathrm{\&Sigma;}}}\left(k\right){\underset{\&OverBar;}{\overset{^}{U}}}_{\mathrm{ap}}^T\left(k\right),$ Wherein the cap " ^ " on each matrix represents that it is the estimation of actual matrix.

Similarly, access point can be estimated the uplink channel responses calibrated based on the MIMO pilot tone that user terminal sent.Then, access point can be estimated the uplink channel responses of calibration Carry out singular value decomposition (for k ∈ K), to obtain

Diagonal matrix Matrix with left side eigenvector U _Ap ^*(k).This singular value decomposition can be given: ${\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{cup}}\left(k\right)={\underset{\&OverBar;}{\overset{^}{U}}}_{\mathrm{ap}}\left(k\right)\underset{\&OverBar;}{\overset{^}{\mathrm{\&Sigma;}}}\left(k\right){\underset{\&OverBar;}{\overset{^}{V}}}_{\mathrm{ut}}^H\left(k\right).$ One (N _Ut* N _Ut) matrix F _Ut(k) can be defined as:

${\underset{\&OverBar;}{F}}_{\mathrm{ut}}\left(k\right)={\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right){\underset{\&OverBar;}{\overset{^}{V}}}_{\mathrm{ut}}\left(k\right),k\&Element;K---\left(41\right)$

When activity, user terminal is estimated the downlink channel calibrated continuously

And The matrix of left side eigenvector

The latter is used for upgrading matrix F _Ut(k).

User terminal uses matrix F _Ut(k) carry out spatial manipulation for wave beam control and space multiplexing mode.For space multiplexing mode, the transmission vector of each subband x _Up(k) can be expressed as:

${\underset{\&OverBar;}{x}}_{\mathrm{up}}\left(k\right)={\underset{\&OverBar;}{F}}_{\mathrm{ut}}\left(k\right){\underset{\&OverBar;}{s}}_{\mathrm{up}}\left(k\right),k\&Element;K,---\left(42\right)$

Wherein s _Up(k) be a data vector, it has will be at the N of subband k _SThe N that sends on the individual eigenmodes _SIndividual code element;

F _Ut(k) in the replacement formula (15) V(k), for simplicity, in formula (42), omitted for realize the channel counter-rotating by G(k) the signal convergent-divergent that carries out;

x _Up(k) be the transmission vector of the up link of subband k.

At the access point place, the reception vector of ul transmissions r _Up(k) can be expressed as:

r _up(k)＝ H _up(k) x _up(k)+ n _up(k)， k∈K， (43)

$={\underset{\&OverBar;}{H}}_{\mathrm{up}}\left(k\right){\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right){\underset{\&OverBar;}{\overset{^}{V}}}_{\mathrm{ut}}\left(k\right){\underset{\&OverBar;}{s}}_{\mathrm{up}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{up}}\left(k\right)$

$\&ap;{\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{cup}}\left(k\right){\underset{\&OverBar;}{\overset{^}{V}}}_{\mathrm{ut}}\left(k\right){\underset{\&OverBar;}{s}}_{\mathrm{up}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{up}}\left(k\right)$

$={\underset{\&OverBar;}{\overset{^}{U}}}_{\mathrm{ap}}\left(k\right)\underset{\&OverBar;}{\overset{^}{\mathrm{\&Sigma;}}}\left(k\right){\underset{\&OverBar;}{\overset{^}{V}}}_{\mathrm{ut}}^H\left(k\right){\underset{\&OverBar;}{\overset{^}{V}}}_{\mathrm{ut}}\left(k\right){\underset{\&OverBar;}{s}}_{\mathrm{up}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{up}}\left(k\right)$

$={\underset{\&OverBar;}{\overset{^}{U}}}_{\mathrm{ap}}\left(k\right)\underset{\&OverBar;}{\overset{^}{\mathrm{\&Sigma;}}}\left(k\right){\underset{\&OverBar;}{s}}_{\mathrm{up}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{up}}\left(k\right)$

Wherein r _Up(k) be the reception vector of up link subband k; And

n _Up(k) be the Additive White Gaussian Noise (AWGN) of subband k.Formula (43) uses following relational expression: ${\underset{\&OverBar;}{H}}_{\mathrm{up}}\left(k\right){\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right)={\underset{\&OverBar;}{H}}_{\mathrm{cup}}\left(k\right)\&ap;{\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{cup}}\left(k\right)$ With ${\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{cup}}\left(k\right)={\underset{\&OverBar;}{\overset{^}{U}}}_{\mathrm{ap}}\left(k\right)\underset{\&OverBar;}{\overset{^}{\mathrm{\&Sigma;}}}\left(k\right){\underset{\&OverBar;}{\overset{^}{V}}}_{\mathrm{ut}}^H\left(k\right).$ Shown in formula (43), at the access point place, the ul transmissions that receives by

Carry out conversion, the latter is

The matrix of left side eigenvector Diagonal matrix with the singular value composition

Convergent-divergent.

User terminal uses matrix F _Ut(k) on up link, send a controlled benchmark.Controlled benchmark is the pilot transmission on a broadband eigenmodes using wave beam control or beam shaping, describes in detail below.At the access point place, the controlled benchmark of the up link that receives (when not having noise) is approximately Like this, access point can draw unitary matrix based on the controlled benchmark that user terminal sent And diagonal matrix

Estimation.Can use various estimation techniques to draw the estimation of unitary matrix and diagonal matrix.

In one embodiment, in order to draw Estimation, for the subband k of broadband eigenmodes m, the reception vector of controlled benchmark r _m(k) at first with the complex conjugate p that is the pilot tone OFDM code element that sends of controlled benchmark ^*(k) multiply each other.Describe the generation of controlled benchmark and pilot tone OFDM code element below in detail.For each broadband eigenmodes, its result is in a plurality of controlled reference symbol upper integrals that receive, to draw

Estimation,

Be broadband eigenmodes m

Through the left side of convergent-divergent eigenvector.Because eigenvector has unit power, therefore can estimate based on the received power of controlled benchmark

In singular value (or σ _m(k)), the received power of controlled benchmark can be measured for each subband of each broadband eigenmodes.

In another embodiment, use the next reception vector of MMSE technology based on controlled benchmark r _m(k) draw

Estimation.

Controlled benchmark can be sent out in arbitrary given code-element period for a broadband eigenmodes, and is used for drawing for each subband of this broadband eigenmodes the estimation of an eigenvector again.Like this, receive the estimation that draws an eigenvector in the unitary matrix in the given code-element period of function in office.Because the estimation that in different code-element periods, draws a plurality of eigenvectors of unitary matrix, and because the noise in the transfer path and other degradation source, therefore the eigenvector of estimating for unitary matrix may be non-orthogonal.If estimated eigenvector is then used in the spatial manipulation of transfer of data on other link, then any error of the orthogonality of these estimated eigenvectors all can cause the cross-talk between eigenmodes, and this can make performance degradation.

In one embodiment, the eigenvector of estimating for each unitary matrix is forced orthogonal.The quadrature of eigenvector can be realized with various technology, such as the decomposition of the QR factor, least mean-square error calculating, polarization decomposing or the like.The QR factor is decomposed a matrix M ^T(having non-orthogonal row) resolves into an orthogonal matrix Q _FWith a upper triangular matrix R _FMatrix Q _FFor M ^TRow form positive three and hand over the basis. R _FDiagonal element exist Q _FProvide on the direction of respective column M ^TThe length of the component of each row.Matrix Q _FCan be used for the spatial manipulation on the down link.Matrix Q _FWith R _FCan be used for deriving the matched filter matrix that strengthens for up link.The QR factor is decomposed and can be carried out by the whole bag of tricks, comprises Gram-Schmidt process, householder transformation or the like.

Also can use other to estimate the technology of unitary matrix and diagonal matrix based on controlled benchmark, this within the scope of the invention.

Therefore, access point can be estimated based on the controlled benchmark that user terminal sent

With Both, and need not right

Carry out singular value decomposition.

Standardization matched filter matrix from the ul transmissions of user terminal M _Ap(k) can be expressed as:

${\underset{\&OverBar;}{M}}_{\mathrm{ap}}\left(k\right)={\underset{\&OverBar;}{\overset{^}{\mathrm{\&Sigma;}}}}^{-1}\left(k\right){\underset{\&OverBar;}{\overset{^}{U}}}_{\mathrm{ap}}^H\left(k\right),k\&Element;K---\left(44\right)$

The access point place can be expressed as for the matched filtering of ul transmissions:

${\underset{\&OverBar;}{\overset{^}{s}}}_{\mathrm{up}}\left(k\right)={\underset{\&OverBar;}{M}}_{\mathrm{ap}}\left(k\right){\underset{\&OverBar;}{r}}_{\mathrm{up}}\left(k\right)$

$={\underset{\&OverBar;}{\overset{^}{\mathrm{\&Sigma;}}}}^{-1}\left(k\right){\underset{\&OverBar;}{\overset{^}{U}}}_{\mathrm{ap}}^H\left(k\right)({\underset{\&OverBar;}{\overset{^}{U}}}_{\mathrm{ap}}\left(k\right)\underset{\&OverBar;}{\overset{^}{\mathrm{\&Sigma;}}}\left(k\right){\underset{\&OverBar;}{s}}_{\mathrm{up}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{up}}\left(k\right)),k\&Element;K---\left(45\right)$

$={\underset{\&OverBar;}{s}}_{\mathrm{up}}\left(k\right)+{\underset{\&OverBar;}{\overset{~}{n}}}_{\mathrm{up}}\left(k\right)$

Wherein

It is the modulation symbol vector that sends by user terminal for space multiplexing mode s _Up(k) estimation.For the wave beam control model, only use matrix M _Ap(k) delegation comes to provide a symbol estimation for the used eigenmodes of transfer of data

2. down link spatial manipulation

For down link, access point uses (a N _Ap* N _Ap) matrix F _Ap(k) carry out spatial manipulation.This matrix can be expressed as:

${\underset{\&OverBar;}{F}}_{\mathrm{ap}}\left(k\right)={\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right){\underset{\&OverBar;}{\overset{^}{U}}}_{\mathrm{ap}}^{*}\left(k\right),k\&Element;K.---\left(46\right)$

Correction matrix

Derive and between alignment epoch, beamed back access point by user terminal.Matrix Can draw based on the controlled benchmark that user terminal sends on up link.

For space multiplexing mode, the transmission vector of the down link of each data subband x _Dn(k) can be expressed as:

x _dn(k)＝ F _ap(k) s _dn(k)， k∈K， (47)

Wherein x _Dn(k) be to send vector, s _Dn(k) be the data vector of down link, omit equally for simplicity by G(k) the signal convergent-divergent for realizing that the channel counter-rotating is carried out.

At the user terminal place, the reception vector of downlink transmission r _Dn(k) can be expressed as:

r _dn(k)＝ H _dn(k) x _dn(k)+ n _dn(k)

$={\underset{\&OverBar;}{H}}_{\mathrm{dn}}\left(k\right){\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right){\underset{\&OverBar;}{\overset{^}{U}}}_{\mathrm{ap}}\left(k\right){\underset{\&OverBar;}{s}}_{\mathrm{dn}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{dn}}\left(k\right)$

$={\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{cdn}}\left(k\right){\underset{\&OverBar;}{\overset{^}{U}}}_{\mathrm{ap}}^{*}\left(k\right){\underset{\&OverBar;}{s}}_{\mathrm{dn}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{dn}}\left(k\right)$

$={\underset{\&OverBar;}{\overset{^}{V}}}_{\mathrm{ut}}^{*}\left(k\right)\underset{\&OverBar;}{\overset{^}{\mathrm{\&Sigma;}}}\left(k\right){\underset{\&OverBar;}{\overset{^}{U}}}_{\mathrm{ap}}^T\left(k\right){\underset{\&OverBar;}{\overset{^}{U}}}_{\mathrm{ap}}^{*}\left(k\right){\underset{\&OverBar;}{s}}_{\mathrm{dn}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{dn}}\left(k\right))$

$={\underset{\&OverBar;}{\overset{^}{V}}}_{\mathrm{ut}}^{*}\left(k\right)\underset{\&OverBar;}{\overset{^}{\mathrm{\&Sigma;}}}\left(k\right){\underset{\&OverBar;}{s}}_{\mathrm{dn}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{dn}}\left(k\right),k\&Element;K---\left(48\right)$

Shown in formula (48), at the user terminal place, the downlink transmission warp that receives Conversion, Be

The matrix of left side eigenvector Diagonal matrix with the singular value composition Come convergent-divergent.

${\underset{\&OverBar;}{M}}_{\mathrm{ut}}\left(k\right)={\underset{\&OverBar;}{\overset{^}{\mathrm{\&Sigma;}}}}^{-1}\left(k\right){\underset{\&OverBar;}{\overset{^}{V}}}_{\mathrm{ut}}^T\left(k\right),k\&Element;K---\left(49\right)$

As mentioned above, estimate by downlink channel response calibration

Carry out singular value decomposition, user terminal can be derived diagonal matrix

Matrix with left side eigenvector

So the matched filtering that the user terminal place is a downlink transmission to carry out can be expressed as:

${\underset{\&OverBar;}{\overset{^}{s}}}_{\mathrm{dn}}\left(k\right)={\underset{\&OverBar;}{M}}_{\mathrm{ut}}\left(k\right){\underset{\&OverBar;}{r}}_{\mathrm{dn}}\left(k\right)$

$={\underset{\&OverBar;}{\overset{^}{\mathrm{\&Sigma;}}}}^{-1}\left(k\right){\underset{\&OverBar;}{\overset{^}{V}}}_{\mathrm{ut}}^T\left(k\right)({\underset{\&OverBar;}{\overset{^}{V}}}_{\mathrm{ut}}^{*}\left(k\right)\underset{\&OverBar;}{\overset{^}{\mathrm{\&Sigma;}}}\left(k\right){\underset{\&OverBar;}{s}}_{\mathrm{dn}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{dn}}\left(k\right)),k\&Element;K---\left(50\right)$

$={\underset{\&OverBar;}{s}}_{\mathrm{dn}}\left(k\right)+{\underset{\&OverBar;}{\overset{~}{n}}}_{\mathrm{dn}}\left(k\right)$

3. the spatial manipulation of access point and user terminal

Because the reciprocal channel and the calibration of TDD system, so the spatial manipulation at access point and user terminal place is all simplified.Access point summed up by table 32 and the user terminal place is that data send and receive the spatial manipulation of carrying out.

Table 32

The spatial manipulation of Data Receiving is also referred to as matched filtering.

Since the existence of reciprocal channel, therefore

It is user terminal The right eigenvector of (be used for send) and

Both matrixes of left side eigenvector of (being used for receiving).Similarly,

It is access point The right eigenvector of (be used for send) and

Both matrixes of left side eigenvector of (being used for receiving).Singular value decomposition need be the downlink channel response estimation of calibration by user terminal only

Carry out, to draw With

Access point can be derived based on the controlled benchmark that user terminal sent

With

And need not uplink channel responses is estimated

Carry out singular value decomposition.Access point and user terminal may be because for deriving

And used different means therefore to have multi-form matrix

In addition, access point is based on the matrix of controlled benchmark derivation

The matrix general and user terminal is derived with singular value decomposition

Different.For simplicity, in above-mentioned derivation, do not demonstrate these differences.

4. wave beam control

For specific channel condition, it is preferable only sending data on a broadband eigenmodes, and this broadband eigenmodes generally is best or main broadband eigenmodes.This situation may be: the reception SNR of all other broadband eigenmodes is enough poor, thereby available transmitted power can realize improved performance by using all on the eigenmodes of main broadband.

Transfer of data on broadband eigenmodes can be controlled with beam shaping or wave beam and realize.For beam shaping, generally use the eigenvector of main broadband eigenmodes Or (promptly after ordering,

Or First row) modulated symbol is carried out spatial manipulation, k ∈ K wherein.For wave beam control, generally use one group of " standardized " (or saturated) eigenvector of main broadband eigenmodes Or

Modulated symbol is carried out spatial manipulation, wherein k ∈ K.For clear, the wave beam control of up link is described below.

For up link, each eigenvector of main broadband eigenmodes

Element have different sizes, k ∈ K wherein.Like this, each subband also have different sizes through preregulated code element, described through preregulated code element by the eigenvector of the modulated symbol of subband k and subband k

Element multiply each other and draw.Thereby every day, the transmission vector of line all had different sizes, described each send vector all comprise a given transmitting antenna the total data subband through preregulated code element.If the transmitted power of every transmit antennas is restricted (for example because the restriction of power amplifier), then beam shaping uses the gross power that every antenna can be used by halves.

The eigenvector of main broadband eigenmodes is only used in wave beam control

Phase information, k ∈ K, and each eigenvector carried out standardization makes that all elements in the eigenvector all has equal size.The standardization eigenvector of subband k

Can be expressed as:

${\underset{\&OverBar;}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)={\left[\begin{array}{cccc}{\mathrm{Ae}}^{j{\mathrm{\&theta;}}_1\left(k\right)}& {\mathrm{Ae}}^{j{\mathrm{\&theta;}}_2\left(k\right)}& \&CenterDot;\&CenterDot;\&CenterDot;& {\mathrm{Ae}}^{j{\mathrm{\&theta;}}_{N_{\mathrm{ut}}}\left(k\right)}\end{array}\right]}^T,---\left(51\right)$

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

θ _i(k) be the phase place of the subband k of antenna i, provide as follows:

${\mathrm{\&theta;}}_i\left(k\right)=\&angle;{\hat{v}}_{\mathrm{ut},1,i}\left(k\right)={\tan }^{-1}\left(\frac{\mathrm{Im}\left\{{\hat{v}}_{\mathrm{ut},1,i}\left(k\right)\right\}}{\mathrm{Re}\left\{{\hat{v}}_{\mathrm{ut},1,i}\left(k\right)\right\}}\right)---\left(52\right)$

Shown in formula (52), vector

In the phase place of each element all from eigenvector Respective element in to draw (be θ _i(k) from

Draw, wherein ${\underset{\&OverBar;}{\overset{^}{v}}}_{\mathrm{ut},1}\left(k\right)={\left[\begin{array}{cccc}{\underset{\&OverBar;}{\overset{^}{v}}}_{\mathrm{ut},\mathrm{1,1}}\left(k\right)& {\underset{\&OverBar;}{\overset{^}{v}}}_{\mathrm{ut},\mathrm{1,2}}\left(k\right)& \&CenterDot;\&CenterDot;\&CenterDot;& {\underset{\&OverBar;}{\overset{^}{v}}}_{\mathrm{ut},1,N_{\mathrm{ut}}}\end{array}\left(k\right)\right]}^T).$

5. uplink beam control

User terminal is controlled the spatial manipulation of carrying out for wave beam and can be expressed as on up link:

${\underset{\&OverBar;}{\overset{~}{x}}}_{\mathrm{up}}\left(k\right)={\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ut}}{\underset{\&OverBar;}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)s_{\mathrm{up}}\left(k\right),k\&Element;K,---\left(53\right)$

Wherein s _Up(k) be the modulated symbol that will on subband k, send; And

Be for wave beam control, the transmission vector of subband k.Shown in formula (53), the standardization dominant vector of each subband

N _UtIndividual element has equal size but has different phase places.

The access point place is that the ul transmissions that wave beam control receives can be expressed as:

${\underset{\&OverBar;}{\overset{~}{r}}}_{\mathrm{up}}\left(k\right)={\underset{\&OverBar;}{H}}_{\mathrm{up}}\left(k\right){\underset{\&OverBar;}{\overset{~}{x}}}_{\mathrm{up}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{up}}\left(k\right),k\&Element;K,---\left(54\right)$

$={\underset{\&OverBar;}{H}}_{\mathrm{up}}\left(k\right){\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right){\underset{\&OverBar;}{\overset{~}{v}}}_{\mathrm{up}}\left(k\right)+s_{\mathrm{up}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{up}}\left(k\right)$

$={\underset{\&OverBar;}{H}}_{\mathrm{cup}}\left(k\right){\underset{\&OverBar;}{\overset{~}{v}}}_{\mathrm{up}}\left(k\right)+s_{\mathrm{up}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{up}}\left(k\right)$

Wherein Be for wave beam control, the reception vector of the up link of subband k.

Use the capable vector of matched filter of the ul transmissions of wave beam control

Can be expressed as:

${\underset{\&OverBar;}{\overset{~}{m}}}_{\mathrm{ap}}\left(k\right)={\left({\underset{\&OverBar;}{H}}_{\mathrm{cup}}\left(k\right){\underset{\&OverBar;}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)\right)}^H,k\&Element;K---\left(55\right)$

The matched filter vector

Can draw as described below.The spatial manipulation (being matched filtering) that the access point place carries out for the receiving uplink transmission of using wave beam control can be expressed as:

${\hat{s}}_{\mathrm{up}}\left(k\right)={\widetilde{\mathrm{\&lambda;}}}_{\mathrm{up}}^{-1}\left(k\right){\underset{\&OverBar;}{\overset{~}{m}}}_{\mathrm{up}}\left(k\right){\underset{\&OverBar;}{\overset{~}{r}}}_{\mathrm{up}}\left(k\right)$

$={\widetilde{\mathrm{\&lambda;}}}_{\mathrm{up}}^{-1}\left(k\right){\left({\underset{\&OverBar;}{H}}_{\mathrm{cup}}\left(k\right){\underset{\&OverBar;}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)\right)}^H({\underset{\&OverBar;}{H}}_{\mathrm{cup}}\left(k\right){\underset{\&OverBar;}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)s_{\mathrm{up}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{up}}\left(k\right)),k\&Element;K,---\left(56\right)$

$=s_{\mathrm{up}}\left(k\right)+{\tilde{n}}_{\mathrm{up}}\left(k\right)$

Wherein ${\widetilde{\mathrm{\&lambda;}}}_{\mathrm{up}}\left(k\right)={\left({\underset{\&OverBar;}{H}}_{\mathrm{cup}}\left(k\right){\underset{\&OverBar;}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)\right)}^H\left({\underset{\&OverBar;}{H}}_{\mathrm{cup}}\left(k\right){\underset{\&OverBar;}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)\right)$ (promptly Be

Inner product with its conjugate transpose),

Be the modulated symbol s that on up link, sends by user terminal _Up(k) estimation, and

It is the noise of reprocessing.

6. downlink beamforming control

Access point is controlled the spatial manipulation of carrying out for wave beam and can be expressed as on down link:

${\underset{\&OverBar;}{\overset{~}{x}}}_{\mathrm{dn}}\left(k\right){=\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ap}}{\underset{\&OverBar;}{\overset{~}{u}}}_{\mathrm{ap}}\left(k\right)s_{\mathrm{dn}}\left(k\right),k\&Element;K,---\left(57\right)$

Wherein Be the standardization eigenvector of subband k, it is based on the eigenvector of main broadband eigenmodes

And generate, as above described for up link.

Use the capable vector of matched filter of the downlink transmission of wave beam control Can be expressed as:

${\underset{\&OverBar;}{\overset{~}{m}}}_{\mathrm{ut}}\left(k\right)={\left({\underset{\&OverBar;}{H}}_{\mathrm{cdn}}\left(k\right){\underset{\&OverBar;}{\overset{~}{u}}}_{\mathrm{ap}}\left(k\right)\right)}^H,k\&Element;K,---\left(58\right)$

The spatial manipulation that the user terminal place carries out the downlink transmission that receives (being matched filtering) can be expressed as:

${\hat{s}}_{\mathrm{dn}}\left(k\right)={\widetilde{\mathrm{\&lambda;}}}_{\mathrm{dn}}^{-1}\left(k\right){\underset{\&OverBar;}{\overset{~}{m}}}_{\mathrm{ut}}\left(k\right){\underset{\&OverBar;}{\overset{~}{r}}}_{\mathrm{dn}}\left(k\right)$

$={\widetilde{\mathrm{\&lambda;}}}_{\mathrm{dn}}^{-1}\left(k\right){\left({\underset{\&OverBar;}{H}}_{\mathrm{cdn}}\left(k\right){\underset{\&OverBar;}{\overset{~}{u}}}_{\mathrm{ap}}\left(k\right)\right)}^H({\underset{\&OverBar;}{H}}_{\mathrm{cdn}}\left(k\right){\underset{\&OverBar;}{\overset{~}{u}}}_{\mathrm{ap}}\left(k\right)s_{\mathrm{up}}\left(k\right)+{\underset{\&OverBar;}{n}}_{\mathrm{dn}}\left(k\right)),k\&Element;K,---\left(59\right)$

$=s_{\mathrm{dn}}\left(k\right)+{\tilde{n}}_{\mathrm{dn}}\left(k\right)$

Wherein ${\widetilde{\mathrm{\&lambda;}}}_{\mathrm{dn}}\left(k\right)={\left({\underset{\&OverBar;}{H}}_{\mathrm{cdn}}\left(k\right){\underset{\&OverBar;}{\overset{~}{u}}}_{\mathrm{ap}}\left(k\right)\right)}^H\left({\underset{\&OverBar;}{H}}_{\mathrm{cdn}}\left(k\right){\underset{\&OverBar;}{\overset{~}{u}}}_{\mathrm{ap}}\left(k\right)\right)$ (promptly Be Inner product with its conjugate transpose).

7. the spatial manipulation of carrying out with channel counter-rotating

For up link, the transmission vector of space multiplexing mode x _Up(k) can export as by user terminal:

${\underset{\&OverBar;}{x}}_{\mathrm{up}}\left(k\right)={\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right){\underset{\&OverBar;}{\overset{^}{V}}}_{\mathrm{ut}}\left(k\right)\underset{\&OverBar;}{G}\left(k\right){\underset{\&OverBar;}{s}}_{\mathrm{up}}\left(k\right),k\&Element;K,---\left(60\right)$

Wherein G(k) be the diagonal matrix of the gain of above-mentioned channel counter-rotating.Formula (60) is similar to formula (15), except using Replace V(k) in addition.

Element be provided for multiplier 952 in the beam-shaper 950 of Fig. 9 B.

For up link, the transmission vector of wave beam control model

Can export as by user terminal:

${\underset{\&OverBar;}{\overset{~}{x}}}_{\mathrm{up}}\left(k\right)={\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right){\underset{\&OverBar;}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)\tilde{g}\left(k\right)s_{\mathrm{up}}\left(k\right),k\&Element;K,---\left(61\right)$

Wherein

Be a vector, it has four elements to have identical size, but phase place is based on the eigenvector of main eigenmodes

And draw.Vector Can be similar to top such derivation the described in formula (16) and (17).Gain

Realization channel counter-rotating, and above can being similar to such derivation the described in the formula (18) to (20), except being formula (20) use ${\widetilde{\mathrm{\&lambda;}}}_1\left(k\right)={\underset{\&OverBar;}{\overset{~}{v}}}_{\mathrm{ut}}^H\left(k\right){\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{cup}}^H\left(k\right){\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{ut}}\left(k\right){\underset{\&OverBar;}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)$ In addition. Element be provided for multiplier 1052 in the wave beam control unit 1050 of Figure 10 B.

For down link, the transmission vector of space multiplexing mode x _Dn(k) can export as by access point:

${\underset{\&OverBar;}{x}}_{\mathrm{dn}}\left(k\right)={\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right){\underset{\&OverBar;}{\overset{^}{U}}}_{\mathrm{ap}}^{*}\left(k\right)\underset{\&OverBar;}{G}\left(k\right){\underset{\&OverBar;}{s}}_{\mathrm{dn}}\left(k\right),k\&Element;K,---\left(62\right)$

Formula (62) is similar to formula (15), except replacing V(k) use

In addition.

Element can be provided for multiplier 952 in the beam-shaper among Fig. 9 B 950.

For down link, the transmission vector of wave beam control model Can export as by access point:

${\underset{\&OverBar;}{\overset{~}{x}}}_{\mathrm{dn}}\left(k\right)={\underset{\&OverBar;}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right){\underset{\&OverBar;}{\overset{~}{u}}}_{\mathrm{ap}}\left(k\right)\tilde{g}\left(k\right)s_{\mathrm{dn}}\left(k\right),k\&Element;K,---\left(63\right)$

Wherein Be a vector, it has four elements, and they have equal size, but their phase place is based on main eigenmodes

Draw.Gain

Realized the channel counter-rotating, and can be with top such derivation the described in the formula (18) to (20), except being formula (20) use ${\widetilde{\mathrm{\&lambda;}}}_1\left(k\right)={\underset{\&OverBar;}{\overset{~}{u}}}_{\mathrm{ap}}^H\left(k\right){\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{cdn}}^H\left(k\right){\underset{\&OverBar;}{\overset{^}{H}}}_{\mathrm{cdn}}\left(k\right){\underset{\&OverBar;}{\overset{~}{u}}}_{\mathrm{ap}}\left(k\right)$ In addition.

Element be provided for multiplier 1052 in Figure 10 B medium wave beam control system unit 1050.

VIII. pilot configuration

For the MIMO wlan system provides a pilot configuration, access point and user terminal can be carried out regularly and frequency acquisition, channel estimating and correct other required function of System Operation.Table 33 is listed the four class pilot tones and their Short Description of an exemplary pilot structure.

Table 33-pilot type

Pilot type	Describe
		Beacon pilot frequency	Send and be used for the pilot tone of timing and frequency acquisition from all transmitting antennas.
The MIMO pilot tone	Send and be used for the pilot tone of channel estimating from all transmitting antennas with different orthogonal codes.
		Controlled benchmark or controlled pilot tone	On the specific eigenmodes of the mimo channel of a specific user terminal, send and be used for the pilot tone of channel estimating and possible rate controlled.
Carrier pilot	Be used for carrier signal is carried out the pilot tone of Phase Tracking.

Controlled benchmark and controlled pilot tone are synonyms.

In one embodiment, pilot configuration comprises: (1) for down link-beacon pilot frequency, MIMO pilot tone, carrier pilot that controlled benchmark and access point sent, and (2) are for up link-MIMO pilot tone, controlled benchmark and the carrier signal that sent by user terminal.

Downlink beacon pilot tone and MIMO pilot tone are sending (shown in Fig. 5 A) on BCH in each tdd frame.User terminal can use beacon pilot frequency to carry out timing and frequency acquisition and Doppler's estimation.User terminal can use the MIMO pilot tone: (1) draws the estimation of downlink mimo channel, (2) for ul transmissions derives controlled vector (if supporting wave beam control or space multiplexing mode), and (3) derive matched filter for downlink transmission.The controlled benchmark of down link can be used for carrying out channel estimating by specific user terminal.

The controlled benchmark of up link is sent by each active user terminals of supporting wave beam control or space multiplexing mode, and can be used for by access point: (1) derives dominant vector for downlink transmission, and (2) derive matched filter for ul transmissions.Usually, controlled benchmark is only sent by the user terminal of supporting wave beam control and/or space multiplexing mode.Benchmark sends object, and no matter whether it is correctly controlled (for example because the channel estimating of difference).Just, because gating matrix is the diagonal angle, so benchmark is also by every transmit antennas quadrature that becomes.

If user terminal is calibrated, then it can use vector (for k ∈ K) sends a controlled benchmark on the main eigenmodes on the RACH, wherein For main eigenmodes Row.If user terminal is not calibrated, then it can be with vectorial ${\underset{\_}{v}}_{\mathrm{ut},p}\left(k\right)={\left[e^{j{\mathrm{\&theta;}}_1\left(k\right)},\begin{array}{cccc}& e^{j{\mathrm{\&theta;}}_2\left(k\right)}& e^{j{\mathrm{\&theta;}}_3\left(k\right)}& e^{j{\mathrm{\&theta;}}_{N_{\mathrm{ut}}}\left(k\right)}\end{array}\right]}^T$ (for k ∈ K) sends a pilot tone on RACH.The vector of each subband v _{Ut, p}(k) comprise N _UtIndividual STOCHASTIC CONTROL coefficient, their phase theta _i(k) may select according to a pseudo-random process, wherein i ∈ 1,2 ... N _Ut.Owing to have only N _UtRelative phase between individual control coefrficient just has relation, and therefore can be made as zero to the phase place of first control coefrficient (is θ ₁(k)=0).Other N _UtThe phase place of-1 control coefrficient may change when each access attempts, makes each control coefrficient with 360 °/N _{θ i}The interval covered whole 360 degree, N wherein _{θ i}Be N _UtFunction.When before calibration, in beam modes, using RACH, when each RACH attempts to dominant vector v _{Ut, p}(k) N _UtThe phase perturbation of individual element makes user terminal not make the dominant vector of damaging for all access attempts.Can send MIMO for the user terminal of not supporting wave beam control and/or space multiplexing mode, or send MIMO by these user terminals.

Directly with before access point is communicated by letter, access point is not known the channel of arbitrary user terminal at user terminal.When the user wished to send data, it at first estimated channel based on the MIMO pilot tone that access point sent.()

$\underset{\_}{x}\left(k\right)={\underset{\_}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right)\&CenterDot;{\underset{\_}{\overset{^}{v}}}_{\mathrm{ut},1}\left(k\right)\&CenterDot;p\left(k\right),k\&Element;K^{\&prime;},---\left(64\right)$

Dominant vector

Be to estimate through the uplink channel responses of calibration The matrix of the right eigenvector First row, wherein ${\underset{\_}{\overset{^}{V}}}_{\mathrm{ut}}\left(k\right)=\left[\begin{array}{cccc}{\underset{\_}{\overset{^}{v}}}_{\mathrm{ut},1}\left(k\right)& {\underset{\_}{\overset{^}{v}}}_{\mathrm{ut},2}\left(k\right)& {\underset{\_}{\overset{^}{v}}}_{\mathrm{ut},3}\left(k\right)& {\underset{\_}{\overset{^}{v}}}_{\mathrm{ut},4}\left(k\right)\end{array}\right],$ Be I row.More than supposition In singular value and

Row with above-mentioned sequence arrangement.

Second code element of the controlled benchmark that user terminal sends in the leader of RACH comprises the data rate indicator (DRI) of RACH PDU.As shown in Table 15, by DRI being mapped to a specific QPSK code element s _DriDRI is embedded in the second controlled reference symbol, then, s _DriCode element multiplies each other with pilot frequency code element p (k) before spatial manipulation.Second code element of the controlled benchmark of RACH can be expressed as:

$\underset{\_}{x}\left(k\right)={\underset{\_}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right)\&CenterDot;{\underset{\_}{\overset{^}{v}}}_{\mathrm{ut},1}\left(k\right)\&CenterDot;s_{\mathrm{dri}}\&CenterDot;p\left(k\right),k\&Element;K^{\&prime;},---\left(65\right)$

Shown in formula (64) and (65), the eigenvector of only main eigenmodes The controlled benchmark that just is used for RACH.

The code element of the controlled benchmark that user terminal sends in the leader of RCH can be expressed as:

${\underset{\_}{x}}_{\mathrm{up},\mathrm{sr},m}\left(k\right)={\underset{\_}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right)\&CenterDot;{\underset{\_}{\overset{^}{v}}}_{\mathrm{ut},m}\left(k\right)\&CenterDot;p\left(k\right),k\&Element;K^{\&prime;},---\left(66\right)$

Wherein x _{Up, sr, m}(m) be the transmission vector of the subband k of broadband eigenmodes m; And Be broadband eigenmodes m subband k dominant vector (promptly M row).The code element of the controlled benchmark that access point sends in the leader of RCH can be expressed as:

${\underset{\_}{x}}_{\mathrm{dn},\mathrm{sr},m}\left(k\right)={\underset{\_}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right)\&CenterDot;{\underset{\_}{\overset{^}{u}}}_{\mathrm{ap},m}^{*}\left(k\right)p\left(k\right),k\&Element;K^{\&prime;},---\left(67\right)$

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

It is the correction matrix of the subband k of access point; And

It is the dominant vector of the subband k of broadband eigenmodes m.

Dominant vector

Be to estimate through the downlink channel response of calibration The right eigenvector matrix

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

Controlled benchmark can send in every way.In one embodiment, one or more eigenvectors are used for the controlled benchmark of each tdd frame, and depend on the duration of controlled benchmark, and the latter is represented by the FCH/RCH leader type field in the FCCH information element.Table 36 is listed for an exemplary design, for the employed eigenmodes of leader of the RCH and the RCH of various leader sizes.

Table 36

Type	The leader size	Employed eigenmodes
			0	0 OFDM code element	No leader
1	1 OFDM code element	Eigenmodes m, wherein m=frame counter mould 4
			2	4 OFDM code elements	Whole	4 eigenmodes circulations in leader
3	8 OFDM code elements	In leader twice of whole 4 eigenmodes cocycle

Shown in table 36, when guide's sequence size is 4 or 8 OFDM code elements, for whole four eigenmodes in the single tdd frame send controlled benchmark.User terminal is that the controlled benchmark that n OFDM code element sends in the leader of RCH can be expressed as:

${\underset{\_}{x}}_{\mathrm{up},\mathrm{sr},n}\left(k\right)={\underset{\_}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right)\&CenterDot;{\underset{\_}{\overset{^}{v}}}_{\mathrm{ut},n\mathrm{mod}4}\left(k\right)\&CenterDot;p\left(k\right),k\&Element;K^{\&prime;},n=\{1,...,L\},---\left(68\right)$

Wherein L is the leader size, and promptly for type 2, L=4 is for type 3, L=8.

Similarly, access point is that the controlled benchmark that n OFDM code element sends in the leader of FCH can be expressed as:

${\underset{\_}{x}}_{\mathrm{dn},\mathrm{sr},n}\left(k\right)={\underset{\_}{\overset{^}{K}}}_{\mathrm{ap}}\left(k\right)\&CenterDot;{\underset{\_}{\overset{^}{u}}}_{\mathrm{ap},\mathrm{<figure-callout\; id="4"\; label="n\; mod"\; filenames="A20038010456001411.png"\; state="\{\{state\}\}">n</figure-callout>}\mathrm{mod}4}^{*}\left(k\right)p\left(k\right),k\&Element;K^{\&prime;},n=\{1,...,L\}---\left(69\right)$

Shown in formula (68) and (69), in each 4-code-element period, circulate through four eigenmodes by (the n mod 4) computing of dominant vector.This scheme can when the quicker change of channel, use and/or in the time need obtaining good channels so for correct system operation and estimate in an early stage use that connects.

In another embodiment, a broadband eigenmodes for each tdd frame sends controlled benchmark.For example, in four tdd frames, can circulate through the controlled benchmark of four broadband eigenmodes.For example, user terminal can be respectively the first, second, third and the 4th tdd frame and use dominant vector

With

The specific dominant vector that uses can be specified by 2 LSB of frame counter value in the BCH message.This scheme can use short leader partly in PDU, but may require the long time period to obtain the good estimation of channel.

For above-mentioned two embodiment, can on used whole four eigenmodes of transfer of data, send controlled benchmark, be less than four eigenmodes (for example because untapped eigenmodes is very poor and abandon by water filling) even used at present.Controlled benchmark at present do not use transmission on the eigenmodes to make to receive function to determine when eigenmodes is improved to can be selected.

B. the controlled benchmark of wave beam control

For the wave beam control model, the spatial manipulation of transmitting terminal is carried out with one group of standardization eigenvector of main broadband eigenmodes.Overall transfer function with standardization eigenvector be different from have the nonstandardized technique eigenvector overall transfer function (promptly ${\underset{\_}{H}}_{\mathrm{cup}}\left(k\right){\underset{\_}{\overset{^}{v}}}_{\mathrm{ut},1}\left(k\right)\&NotEqual;{\underset{\_}{H}}_{\mathrm{cup}}\left(k\right){\underset{\_}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)).$ Then, the controlled benchmark that generates with one group of standardization eigenvector of whole subbands can be sent by transmitter, and is used for deriving matched filter vectors into these subbands of wave beam control model by receiver.

For up link, the controlled benchmark of wave beam control model can be expressed as:

${\underset{\_}{\overset{~}{x}}}_{\mathrm{up},\mathrm{sr}}\left(k\right)={\underset{\_}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right){\underset{\_}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)p\left(k\right),k\&Element;K.---\left(70\right)$

At the access point place, the controlled benchmark of the receiving uplink of wave beam control model can be expressed as:

${\underset{\_}{\overset{~}{r}}}_{\mathrm{up},\mathrm{sr}}\left(k\right)={\underset{\_}{H}}_{\mathrm{up}}\left(k\right){\underset{\_}{x}}_{\mathrm{up},\mathrm{sr}}\left(k\right)+{\underset{\_}{n}}_{\mathrm{up}}\left(k\right),k\&Element;K---\left(71\right)$

$={\underset{\_}{H}}_{\mathrm{up}}\left(k\right){\underset{\_}{\overset{^}{K}}}_{\mathrm{ut}}\left(k\right){\underset{\_}{\overset{~}{v}}}_{\mathrm{ut}}\left(k\right)p\left(k\right)+{\underset{\_}{n}}_{\mathrm{up}}\left(k\right)$

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

In order to obtain the capable vector of matched filter for the ul transmissions of using wave beam control The reception vector of controlled benchmark

At first with p ^*(k) multiply each other.So on the controlled reference symbol of a plurality of receptions to integration as a result to form Estimation.So vector It is exactly the conjugate transpose of this estimation.

Be operated in wave beam control model following time, user terminal can send a plurality of code elements of controlled benchmark, for example uses the standardization eigenvector One or more code elements, use the eigenvector of main broadband eigenmodes

One or more code elements and the one or more code elements that may use the eigenvector of other broadband eigenmodes.With The controlled reference symbol that generates can be used for deriving the matched filter vector by access point With

The controlled reference symbol that generates can be used to obtain Then be used for deriving on the down link wave beam and control employed standardization eigenvector Eigenvector with other eigenmodes Arrive The controlled reference symbol that generates can be used for drawing by access point

Arrive

And the singular value of these other eigenmodes.It still is the wave beam control model that this information then is used for being defined as transfer of data usage space multiplexer mode by access point.

For down link, user terminal can be estimated based on the downlink channel response through calibration For the wave beam control model derives the matched filter vector

Particularly, user terminal from Singular value decomposition draw

And can derive the standardization eigenvector Then, user terminal can

With

Multiply by mutually and draw

Then based on Derive Perhaps, controlled benchmark can use the standardization eigenvector by access point

Send, this controlled benchmark can be handled to draw in the above described manner by user terminal

4. carrier pilot-up link

OFDM sub band structure described here comprises that index is four pilot subbands of-21 ,-7,7 and 21.In one embodiment, a carrier pilot is not to send on four pilot subbands of a leader part in whole OFDM code elements.Carrier pilot can be used for following the tracks of the phase change that the drift owing to transmitter and receiver place oscillator causes by receiver.This may provide improved data demodulates performance.

Carrier pilot comprises four pilot frequency sequence P _C1(n), P _C2(n), P _C3(n) and P _C4(n), they are sent out on four pilot subbands.Pilot frequency sequence can be defined as:

P _c1(n)＝P _c2(n)＝P _c3(n)＝-P _c4(n)，n＝{1，2...127}， (72)

Wherein n is the index of OFDM code-element period.

Pilot frequency sequence can define based on various data sequences.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 as complete one, the following signal value that is mapped as of output bit: 1 -1 and 0  1.So, for n={1,2 ... 127}, pilot frequency sequence P _C1(n) can be expressed 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) pilot frequency code element can be arrived with a specific modulation in the value in " 1 " and " 1 ".For example, by using BPSK, " 1 " is mapped as " 1+j ", and " 1 " is mapped as " (1+j) ".If have more than 127 OFDM code elements, then repeat pilot frequency sequence, make for n＞127, P _C1(n)=P _C1(n mod 127)

In one embodiment, be four pilot frequency sequences of each transmission channel replacement.Like this, on down link, being an OFDM code element replacement pilot frequency sequence of BCH message, is that an OFDM code element of FCCH message is reset once more, and resets for FCH goes up an OFDM code element that sends.In another embodiment, pilot frequency sequence is reset at the place that begins of each tdd frame, and repeats as required.For this embodiment, pilot frequency sequence can be stopped during the leader part of BCH and RCH.

Under diversity mode, shown in table 29, it is right that four pilot frequency sequences are mapped as four subband/antennas.Particularly, P _C1(n) be used for the subband-21 of antenna 1, P _C2(n) be used for the subband-7 of antenna 2, P _C3(n) be used for the subband 7 of antenna 3, P _C4(n) be used for the subband 21 of antenna 4.Each pilot frequency sequence is sent out on relevant subband and antenna then.

Under space multiplexing mode, four pilot frequency sequences are sent out on the main eigenmodes of their corresponding subbands.The spatial manipulation of carrier pilot code element is similar to the processing of carrying out into modulated symbol, as mentioned above.Under the wave beam control model, four pilot frequency sequences use wave beam to be controlled on their corresponding subbands and are sent out.The wave beam control of carrier pilot code element also is similar to the processing of carrying out into modulated symbol.

For the MIMO wlan system one specific pilot configuration has been described above.Also can be for this system use other pilot configuration, this is within the scope of the invention.

IX. system operation

Figure 12 A illustrates a specific embodiments of the state diagram 1200 of user terminal operations.This state diagram comprises one of four states-initial (Init) state 1210, dormancy (Dormant) state 1220, inserts (Access) state 1230 and be connected (Connected) state 1240.Each state 1210,1220,1230 and 1240 all is associated with a plurality of sub-states (not shown in Figure 12 A for simplicity).

In initial condition, user terminal capture systems frequency and timing, and obtain the system parameters that BCH goes up transmission.In initial condition, user terminal can be carried out following function:

● system determines-user terminal determines which carrier frequency to come capture systems with.

● frequency/timing acquisition-user terminal is caught beacon pilot frequency and is correspondingly regulated its frequency and timing.

● parameter catches-and user terminal processes BCH to be to obtain and the access point system associated parameter of receiving downlink signal therefrom.

After finishing the required function of initial condition, user terminal changes resting state into.

In resting state, user terminal periodically monitor the system parameters that whether has among the BCH after the renewal, to the indication of the paging that sends on the down link and broadcast, or the like.Do not distribute any Radio Resource under this state to user terminal.In resting state, user terminal can be carried out following function:

● if registration is guaranteed that user terminal just enters access state according to register requirement.

● if the calibration of emittor/receiver is guaranteed that user terminal just enters according to calibration request and accesses terminal.

● user terminal monitors whether BCH has couple FCH to go up the paging of transmission and the indication of broadcast.

● if user terminal has the data that will send on up link, it just enters access state according to resource request.

● user terminal is carried out such as the update system parameter and is followed the tracks of the such maintenance process of channel.

● user terminal can enter the operator scheme of branch time slot with conserver power source, if this pattern is supported by user terminal.

If user terminal is all expected Radio Resource from access point for any task, it just changes into and accesses terminal.For example, user terminal can change access state in response to the paging that sends in the BCH message or DST designator, is used for registration or request calibration, perhaps the special-purpose resource of request.

In access state, user terminal is in the process of connecting system.User terminal can send SMS message and/or to the request of FCH/RCH resource with RAHC.Operation on the RACH is following to be described in further detail.If user terminal is access in a release, it just transforms back into resting state.If user terminal is assigned to the resource of down link and/or up link, it just changes connection status into.

In connection status, user terminal is assigned to the FCH/RCH resource, although be not all necessary for each tdd frame.User terminal can use the resource of being distributed versatilely or can be idle (still keeping connecting) in connection status.User terminal remains under the connection status, till it is access in a release or till it did not have movable back overtime in a specific timeout period, it transformed back into resting state under this situation.

In dormancy, access or connection status following time, if if user terminal is closed power supply or connects to be lost, user terminal just transforms back into initial condition.

Figure 12 B illustrates a specific embodiments of the state diagram of connection status 1240.In this embodiment, connection status comprises the sub-state 1260 of three sub-states-set up, opens sub-state 1270 and idle sub-state 1280.User terminal enters the sub-state of setting up after receiving distribution on the FCCH.

In setting up sub-state, user terminal is in the process of setting up connection, as yet swap data not.Connect set up can comprise to access point, speed determine, the channel estimating of service negotiation or the like.Enter set up sub-state after, user terminal is provided with a timer in a specific time quantum.If timer expired before user terminal leaves this sub-state, it just changes resting state into.User terminal changes the sub-state of opening into after setting up finishing to connect.

In opening sub-state, user terminal and access point be swap data on down link and/or up link.In the time of in opening sub-state, user terminal monitors whether BCH has the indication of system parameters and paging/broadcast.If be correctly decoded BCH message in the tdd frame of a specific quantity, then user terminal transforms back into initial condition.

User terminal monitors also whether FCCH has channel allocation, rate controlled, RCH timing controlled and power control information.User terminal uses BCH beacon pilot frequency and FCH leader to estimate the SNR that receives, and the definite maximum rate that can reliably keep on FCH.

The FCH of the user terminal of each tdd frame and RCH distribution are provided by the information element among the FCCH PDU that sends in current (perhaps may be previous) tdd frame.For arbitrary given tdd frame, for the distributing user terminal not of the transfer of data on FCH and/or the RCH.For wherein not being each tdd frame of data transmission scheduling user terminal, it does not receive FCH PDU on down link, and does not send on up link.

For each tdd frame of dispatched users terminal wherein, the transfer of data on down link and/or the up link uses FCCH to distribute speed, transmission mode and the RCH timing slip (for up link) of expression in (promptly being addressed to the FCCH information element of user terminal) to carry out.User terminal receives the FCH PDU that sends to it, and it is carried out the demodulation sign indicating number.User terminal also sends RCH PDU, and it comprises leader and RCH data rate indicator.The rate control information that user terminal comprises in distributing according to FCCH is regulated RCH and is gone up the speed of using.If be the control of ul transmissions applied power, then the user regulates its transmitted power based on the power control command that comprises among the FCCH.Exchanges data can happen suddenly, and user terminal enters idle sub-state under this situation when not having data commutative.User terminal enters idle sub-state according to the indication of access point.If access point is not distributed to user terminal to FCH or RCH in the tdd frame of a specific quantity, then user terminal transforms back into resting state and keeps its MAC ID.

In idle sub-state, up link and down link all are idle.On either direction, do not send data.Yet link is kept with controlled benchmark and control messages.Under this sub-state, access point is at RCH and may periodically distribute to user terminal (unnecessary while) to idle PDU on the FCH.Perhaps, user terminal can remain under the connection status indefinitely, as long as access point periodically distributes idle PDU to keep this link on FCH and RCH.

In idle sub-state following time, user terminal monitors BCH.If BCH message is not correctly decoded in the tdd frame of a specific quantity, then user terminal just transforms back into initial condition.User terminal monitors also whether FCCH has channel allocation, rate controlled, RCH timing controlled and power control information.User terminal can also estimate to receive the maximum rate that SNR and definite FCH support.User terminal go up to send idle PDU at RCH (when being assigned with), and if its RCH request bit of having data to send just to be provided with among the idle PDU.If access point is not distributed to user terminal to FCH or RCH in the tdd frame of a specific quantity, user terminal just transforms back into resting state, and keeps its MAC ID.

Enter three sub-states any one after, overtime timer can be set as a particular value.If there is not activity in the time of in sub-state, then this timer countdown.Set up, in activity or the idle sub-state time, if the expiration of overtime timer, terminal can transform back into resting state, loses if connect, terminal can transform back into initial condition.In activity or idle sub-state following time, be released if connect, terminal also can transform back into resting state.

Figure 12 A and 12B illustrate a specific embodiment of the state diagram that can be used for user terminal.Also can be for system definition have less, additional and/or different states and various other state diagrams of sub-state, this is within the scope of the invention.

X. insert at random

In one embodiment, adopt a kind of random access scheme to make user terminal can insert the MIMO wlan system.In one embodiment, random access scheme is based on the Aloha scheme of one fen time slot, and user terminal sends so that can insert this system in the RACH time slot of selecting at random whereby.User terminal can send a plurality of transmission on RACH, till inserting licensed or having reached maximum access attempts number of times.Each parameter that can change each RACH transmission is to improve the probability of success, and is as described below.

Figure 13 has illustrated the timeline of RACH, and it is divided into the RACH time slot.In each tdd frame and the RACH time slot duration can with the RACH number of time slot be configurable parameter.Can use maximum 32 RACH time slots in each tdd frame.Protection between the BCH PDU of the ending of a last RACH time slot and next tdd frame begins also is configurable parameter at interval.Three parameters of this of RACH can change along with the change of frame, and indicated by RACH length field, RACH time slot size field and the RACH protection interval field of BCH message.

When user terminal was wished connecting system, it is the system parameters of treatments B CH to obtain to be correlated with at first.Then, user terminal sends a RACH PDU on RACH.This RACH PDU comprises a RACH message, and it comprises access point for handling from the required information of the access request of user terminal.For example, RACH message comprises the MAC ID that user terminal is assigned to, and it makes access point energy identifying subscriber terminal.Registration MAC ID (being specific MAC ID value) can keep for unregistered user terminal.Under this situation, the long ID of user terminal can be included in the load field of RACH message together with registration MAC ID.

As described below, RCH PDU can be sent out with one of four speed, and is listed as table 15.Selected speed is embedded in the leader of RACH PDU (shown in Fig. 5 C).RACH PDU also has 1,2,4 or 8 OFDM code elements of variable-length (also listing as table 15), and this length is represented in the message duration of RACH message field.

In order to send RACH PDU, user terminal is at first determined the RACH number of time slot (i.e. " available " RACH number of time slot) that can be used for transmitting.This determines to make based on following: available RACH number of time slot in (1) current tdd frame, the duration of (2) each RACH time slot, (3) protection at interval, and the length of (4) the RACH PDU that will send.RACH PDU can not extend beyond the ending of the RACH segmentation of tdd frame.Like this, if RACH PDU adds that than a RACH time slot protection is long at interval, then this PDU can not be sent out on one or more available after a while RACH time slots.Based on above-named factor, the RACH timeslot number that can be used for sending RACH PDU may lack than the number of available RACH time slot.The RACH segmentation comprises a protection at interval, and the latter is used to prevent that the ul transmissions from user terminal from can disturb with next BCH segmentation, and this is possible for the user terminal that does not compensate its round-trip delay.

Then, user terminal selects one of available RACH time slot to send RACH PDU randomly.Then, user terminal begins to send RACH PDU from selected RACH time slot.If user terminal is known the round-trip delay of access point, then it can regularly remedy this delay by correspondingly regulating it.

When access point received a RACH PDU, it used the CRC that comprises in the reception RACH message to check this message.If the CRC failure, access point just abandons this RACH message.If CRC passes through, access point just is provided with the RACH acknowledgement bit on the BCH in follow-up tdd frame, and sends RACH affirmation in 2 tdd frames on FCCH.Acknowledgement bit is being set on the BCH and may having delay in transmission on the FCCH between confirming, it is used to remedy dispatch delay or the like.For example, if access point receives message on RACH, it can be provided with acknowledgement bit on BCH, and has delayed response on FCCH.Acknowledgement bit stops user terminal to carry out retry, and makes unsuccessful user terminal retry fast, except at busy RACH in the cycle.

If user terminal is being carried out registration, it just uses registration MAC ID (for example 0x0001).Access point responds by send a MAC ID assignment messages on FCH.All other RACH transport-type comprises the user terminal MAC ID that system distributes.The MAC ID that access point is distributed to user terminal by use sends affirmation on FCCH, thereby has clearly confirmed the RACH message that all correctly receive.

After user terminal sent RACH PDU, it monitored that BCH and FCCH are to determine whether its RACH PDU has been access in a reception and processing.User terminal monitors that BCH is to determine whether to be provided with the RACH acknowledgement bit in the BCH message.If this bit is established, this affirmation that shows this and/or other user terminal sends on FCCH, so user terminal is further handled FCCH to obtain to comprise IE type 3 information elements of affirmation.Otherwise if the RACH acknowledgement bit is not established, user terminal just continues to monitor BCH or continue its access procedure on RACH.

FCCH IE type 3 is used to transmit the quick affirmation to successful access attempts.Each confirmation element comprises and the MAC ID that is associated for its user terminal that sends affirmation.Confirm fast to be used for its access request of informing user terminal has been received but unconnected with the distribution of FCH/RCH resource.On the contrary, be associated with FCH/RCH distribution based on the affirmation that distributes.If receiving one on FCCH, user terminal confirms that fast it just changes resting state into.If user terminal receives one based on the affirmation that distributes, its schedule information with regard to obtaining to send with this affirmation, and bring into use the FCH/RCH that distributes in the current tdd frame.(

If user terminal receives an affirmation on FCCH in the tdd frame of a specific quantity after sending RACH PDU, it just continues the access procedure on the RACH.Under this situation, user terminal can suppose that access point does not correctly receive RACH PDU.User terminal is kept a counter and is counted inserting number of attempt.This counter the first time access attempts be initialized as zero, increase one for each access request subsequently then.If Counter Value reaches maximum attempts, user terminal just stops access procedure.

For each follow-up access attempts, user terminal is at first determined each parameter of this access attempts, comprise that (1) is sending the time quantum that will wait for before the RACH PDU, the RACH time slot that use for RACH PDU transmission (2), and the speed of (3) RACH PDU.For the time quantum of determining to wait for, the maximum time amount that the at first definite access attempts next time of user terminal will be waited for, this is called contention window (CW).In one embodiment, contention window (is that unit provides with the tdd frame) may the growth of index ground (be CW=2 for each access attempts ^{Access_attempt}).Contention window also can be determined based on some other function (for example linear function) of access attempts number of times.The time quantum of between zero-sum CW, selecting next access attempts to wait at random then.User terminal can be waited for this time quantum before sending RACH PDU for next access attempts.

For next access attempts, if be not that a last access attempts uses minimum speed limit, user terminal reduces the speed of RACH PDU.The initial rate of first access attempts can be selected based on the reception SNR of the last pilot tone that sends of BCH.Access point is failed correctly to receive RACH PDU and may be caused and fail to receive the confirmation.Like this, the speed of RACH PDU is lowered in next access attempts, to improve the correct probability that receives of access point.

After having waited for this stand-by period of selecting at random, user terminal selects a RACH time slot to be used for the transmission of RACH PDU once more at random.The selection of the RACH time slot of this access attempts can be carried out with the similar fashion of above-mentioned first access attempts, except the RACH parameter of (in BCH message, transmitting) current tdd frame (be RACH timeslot number, time slot duration and protection at interval) with current RACH PDU length is used.RACHPDU is sent out in the RACH time slot of selecting at random then.

Above-mentioned access procedure continues up to following any point takes place: (1) user terminal receives an affirmation from access point, or (2) have reached the maximum number of attempt that allows.For each access attempts, can be chosen in as described above and send the time quantum that to wait for before the RACH PDU, RACH time slot that RACH PDU transmission will be used and the speed of RACH PDU.If receive the confirmation, user terminal just as indicated in confirming work (be that it is waited for when receiving quick affirmation in resting state, perhaps use FCH/RCH begins when receiving based on the affirmation that distributes).If reached the maximum access attempts number of times that allows, user terminal just transforms back into initial condition.

XI. speed, power and timing controlled

Access point is dispatched down link and the ul transmissions on FCH and the RCH, and further controls the speed of all active user terminals.In addition, access point is in the transmitted power of up link adjusted specific activities user terminal.Various control loops be can keep and each active user terminals regulations speed, transmitted power and timing come to be.

1. fix and variable rate services

Access point can be supported the service of the fixing and variable bit rate on FCH and the RCH.The fixed rate service can be used for voice, video or the like.Variable rate services can be used for grouped data (for example web browsing).

For the fixed rate service on the FCH/RCH, fixed rate is used for whole connection.The transmission of best achievement is used for FCH and RCH (promptly not retransmitting).The FCH/RCH PDU of access point scheduling constant number in each fixed time interval is to satisfy the Qos requirement of service.According to postponing requirement, access point may need not each tdd frame and all dispatch a FCH/RCH PDU.For the fixed rate service, on RCH rather than FCH, realize power control.

For the variable rate services on the FCH/RCH, the employed speed of FCH/RCH can change along with channel condition.For some synchronous service (for example video, audio frequency), qos requirement can be utilized minimum-rate constraints.For these services, the scheduler at access point place is regulated FCH/RCH and is distributed, thereby constant rate of speed can be provided.For asynchronous data service (for example web browses, file transfer or the like), optimum efficiency transmits and has the re-transmission option.For these services, speed be channel condition the maximum that can reliably bear.Scheduling to the FCH/RCH PDU of user terminal generally is the function of their qos requirement.When on downlink/uplink, not having data to send, on FCH/RCH, send idle PDU to keep link.For variable rate services, on FCH rather than RCH, realize the control of closed-loop power.

2. rate controlled

Rate controlled can be used for FCH and RCH goes up the variable rate services of work, so that the channel condition that makes the speed of FCH/RCH be suitable for changing.The employed speed of FCH and RCH can be controlled independently.In addition, in space multiplexing mode, the speed of each broadband eigenmodes of each dedicated transmission channel can independently be controlled.Rate controlled is carried out based on the feedback that each active user terminals provided by access point.Scheduler schedules transfer of data in the access point, and the rate-allocation of definite active user terminals.

The maximum rate that can support on arbitrary link all is following function: the channel response matrix of (1) total data subchannel, and the viewed noise level of (2) receiver, the quality of (3) channel estimating, and may other factors.For the TDD system, channel for down link and up link can be considered to be reciprocal (carry out calibration with any difference that remedies access point and user terminal place after).Yet this reciprocal channel does not also mean that noise floor is identical with the user terminal place at access point.Therefore, for given user terminal, the speed on FCH and the RCH can be controlled independently.

The closed-loop rate controlled can be used for the transfer of data on one or more space channels.The closed-loop rate controlled can realize with one or more loops.Inner ring road is estimated channel condition and is that each used space channel of transfer of data is selected a suitable speed.Channel estimating and rate selection can be carried out as described above.Outer ring can be used for estimating the quality of the transfer of data that receives on each space channel, and regulates the operation of inner ring road.Data transmission quality can quantize with packet error rate (PER), decoder metric or the like or their combination.For example, outer ring can be regulated the SNR skew of each space channel so that be this space channel realization target P ER.If for space channel detects excessive grouping mistake, it is that a space channel selects one than low rate that outer ring also can be indicated inner ring road.

Downlink rate control

Each active user terminals can be come estimating down-ward link channel based on the MIMO pilot tone that sends in each tdd frame on BCH.Access point also can send a controlled benchmark in sending to the FCH PDU of specific user terminal.By MIMO pilot tone on the use BCH and/or the controlled benchmark on the FCH, user terminal can estimate to receive the maximum rate that can support on SNR and the definite FCH.If user terminal is operated under the space multiplexing mode, just can determine maximum rate for each broadband eigenmodes.Each user terminal can be in the FCH of RCH PDU rate indicator field be beamed back the maximum rate (for diversity mode) that maximum rate (for space multiplexing mode) that each broadband eigenmodes supported, maximum rate (for the wave beam control model) that main broadband eigenmodes is supported or mimo channel are supported to access point.These speed can be mapped as and receive SNR, and the latter then is used for carrying out above-mentioned the injecting process.Perhaps, user terminal can be beamed back sufficient information (for example receiving SNR) so that make access point can determine the maximum rate that down link is supported.

For using diversity, wave beam control still is that the feedback that is based on from user terminal of determining of space multiplexing mode is made.Along with the separation between dominant vector improves, the number of the broadband eigenmodes of selecting for use also can increase.

Figure 14 A has illustrated the process for the speed of user terminal control downlink transmission.One BCH PDU sends in first segmentation of each tdd frame, and comprises the beacon and the MIMO pilot tone that can be used for estimating and following the tracks of this channel by user terminal.Controlled benchmark also can be sent out in the leader of the FCH PDU that sends to user terminal.User terminal is estimated this channel based on MIMO and/or controlled benchmark, and the maximum rate that can support of definite down link.If under space multiplexing mode, then being each broadband eigenmodes, user job supports a speed.Then, user terminal sends the rate indicator of FCH at it in the FCH rate indicator field of the RCH PDU that access point sends.

Scheduler uses down link to dispatch downlink transmission in the follow-up tdd frame for the maximum rate of each active user terminals support.Reflect in the information element that the speed of user terminal and other channel allocation information send on FCCH.The speed of distributing to a user terminal can influence the scheduling of other user terminal.The user determines that the minimum delay between speed and the use thereof is about single tdd frame.

By using the Gram-Schmidt sequencer procedure, access point can directly be determined the maximum rate that FCH supports from the RCH leader exactly.So this can simplify rate controlled greatly.

Uplink rate control

Each user terminal sends a controlled benchmark on RACH between system's access periods, and send controlled benchmark after being assigned to the FCH/RCH resource on RCH.Access point can be that each broadband eigenmodes estimates to receive SNR based on the controlled benchmark on the RCH, and determines the maximum rate that each broadband eigenmodes is supported.At first, access point may not have good channel estimating so that allow at maximum rate place that each broadband eigenmodes is supported or near the reliable operation that carries out it.In order to improve reliability, the initial rate of the last use of FCH/RCH can be significantly less than the maximum speed of supporting.Access point can be on a plurality of tdd frames to controlled benchmark integration so that obtain improved channel estimating.Along with the raising of channel estimating, speed also can be enhanced.

Figure 14 B has illustrated the process of the speed that is used to user terminal control ul transmissions.When being uplink transmission scheduling, user terminal sends a RCH PDU, and it comprises that access point is used for determining the benchmark of the maximum rate on the up link.Then, scheduler uses up link to dispatch uplink data transmission in the follow-up tdd frame for the maximum rate of each active user terminals support.The speed of user terminal and other channel allocation information are reflected in FCCH and go up in the information element that sends.Access point determines that the minimum delay between speed and the use thereof is about single tdd frame.

3. power control

For the fixed rate service, power control can be used for the ul transmissions (but not rate controlled) on the RCH.For the fixed rate service, speed is consulted when call setup, and is maintained fixed during connecting.Some fixed rate services may require with limited mobility to be associated.Yet in one embodiment,, but down link is not used power control for up link has realized power control with the interference between the antagonism user terminal.

One power control mechanism is used for controlling the up-link transmit power of each active user terminals, and the SNR that makes the access point place receive is maintained at a rank that can realize the desired service quality.This rank is commonly referred to target and receives SNR, working point or set point.For the user terminal that moves, propagation loss changes along with moving of user terminal probably.Power control mechanism is followed the tracks of the variation in the channel so that remain near the set point receiving SNR.

Power control mechanism can be with two power control loop road realization-inner ring roads and outer ring.The transmitted power of inner loop adjustment user terminal makes the reception SNR at access point place be maintained near the set point.Outer ring is regulated set point realizing other performance of a specific order, and performance measures quantification by specific FER (Floating Error Rate) (FER) (for example 1%FER), packet error rate (PER), BLER (block error rate) (BLER), message error rate (MER) or some.

Figure 15 has illustrated the operation of the internal power control of user terminal.After user terminal was assigned to FCH/RCH, access point was estimated the reception SNR on the RCH and it is compared with set point.The initial power that user terminal will use can determine when call setup, and generally near its maximum transmit power level.For each frame period, exceed a specific positive surplus δ if receive SNR, access point just can reduce a specified quantitative (for example 1dB) with its transmitted power by indicating user terminal in sending to the FCCH information element of this user terminal.On the contrary, if receive SNR than the low surplus δ of threshold value, access point just can improve described specified quantitative with its transmitted power by indicating user terminal.If receive SNR in acceptable set point restriction, access point just can not ask the transmitted power of user terminal is changed.Up-link transmit power is given the initial transmission power level and adds all power adjustments sums that receive from access point.

The initial setting point that the use of access point place is set is to realize other performance of a specific order.This set point is regulated by the FER or the PER of outer ring based on RCH.For example, if frame error/grouping mistake does not take place on a special time period, then set point can reduce by first amount (for example 0.1dB).If exceed mean F ER owing to one or more frame errors/grouping mistake occurring, then set point can improve second amount (for example 1dB).Set point, hysteresis margin and outer ring operation are specific for the employed power controlling Design of system.

4. timing controlled

Timing controlled is preferably used in the frame structure based on TDD, and wherein down link and up link are shared identical frequency band in the mode of time division duplex.Therefore user terminal can spread in the system, and is associated with different propagation delays to access point.In order to make the efficient maximum on the up link, can regulate timing from the RCH of each user terminal and the ul transmissions on the RACH to remedy its propagation delay.So this can guarantee to arrive the access point place from the ul transmissions of different user terminals in a special time window, and can be not interfering with each other on up link, and is perhaps like this for downlink transmission.

Figure 16 has illustrated the process of the uplink timing that is used to regulate user terminal.At first, user terminal sends a RACH PDU so that can connecting system on up link.Access point is derived the initial estimation of the round-trip delay (TDD) that is associated with user terminal.Round-trip delay can be based on following estimation: (1) access point is used for determining the sliding correlation detector of transmission starting point, and the time slot ID that comprises among (2) RACH PDU that user terminal sent.Then, access point is estimated as user terminal based on Initial R TD and calculates an initial Timing Advance.Initial Timing Advance was sent to user terminal at it before the transmission on the RCH.Initial Timing Advance can be sent out in the message on FCH, be sent out in a field of FCCH information element, perhaps is sent out by some other means.

User terminal receives initial Timing Advance from access point, uses this Timing Advance then in all the subsequent uplink transmission on RCH and the RACH.If user terminal is assigned to the FCH/RCH resource, the order that access point sent that its Timing Advance just can regularly be regulated in the field by the RCH of FCCH information element is regulated.So user terminal can be regulated its ul transmissions on RCH based on present Timing Advance, current Timing Advance equals initial Timing Advance and adds that access point sends to whole timings adjustings of user terminal.

Each part and the various technology of MIMO wlan system described herein can be come time slot by various means.For example, the processing at access point and user terminal place can realize with hardware, software or their combination.For hardware was realized, processing can realize in following components and parts: one or more application-specific integrated circuit (ASIC)s (ASIC), digital signal processor (DSP), digital signal processing appts (DSPD), programmable logic device (PLD), field programmable gate array (FPGA), processor, controller, microcontroller, microprocessor, other is designed to carry out the electronic unit of function described here or their combination.

For software was realized, processing can realize with the module (for example process, function or the like) of carrying out function described here.Software code can be stored in the memory cell (for example memory among Fig. 7 732 or 782), and is carried out by processor (for example controller 730 or 780).Memory cell can realize in processor or outside the processor that it is by being coupled on various means well known in the art and the processor communication under one situation of back.

Here the title that comprises makes things convenient for index, and helps the specific chapters and sections in location.These titles are not in order to limit its down scope of described notion, and these notions can be applied in other chapters and sections of 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 deviate from the spirit or scope of the present invention 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 (216)

1. method that sends data in wireless multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Select at least one user terminal to be used for the interior at interval transfer of data of current scheduling from a plurality of user terminals, wherein said at least one user terminal comprises the user terminal with many antennas;

For each of described at least one user terminal is selected at least one speed, each of wherein said at least one speed is to select a plurality of speed of supporting from system, and wherein each of a plurality of speed all is associated with a specific code rate and a specific modulation scheme;

Select a transmission mode for each of described at least one user terminal, wherein said each transmission mode of user is to select a plurality of transmission modes of supporting from system; And

Dispatch described at least one user terminal and think that at least one speed of each user terminal selecting and transmission mode carry out transfer of data in current scheduling at interval.

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

For each of described at least one user terminal is selected a transmitting continuous phase, wherein said at least one user terminal is scheduled in to inherent current scheduling of the transmitting continuous phase of each user terminal selecting and carries out transfer of data at interval.

3. the method for claim 1 is characterized in that, each of described at least one user terminal is scheduled in the inherent down link of current scheduling interval, up link or its both enterprising line data transmission.

4. method as claimed in claim 3, it is characterized in that, for each user terminal that is scheduled in the transmission of the enterprising line data of down link and up link, select at least one speed and the transmission mode of user terminal independently for down link and up link.

5. method as claimed in claim 2 is characterized in that, for each user terminal that is scheduled in the transmission of the enterprising line data of down link and up link, selects the transmitting continuous phase of user terminal independently for down link and up link.

6. the method for claim 1, it is characterized in that, described a plurality of transmission mode comprises a diversity mode and a space multiplexing mode, described diversity mode support is from the redundant data transmission that has of many transmit antennas, and described space multiplexing mode is supported the transfer of data on a plurality of space channels.

7. method as claimed in claim 6, it is characterized in that, described a plurality of transmission mode also comprises a wave beam control model, and it supports the transfer of data on the single space channel, and described single space channel is associated with the flank speed of described a plurality of space channels centre.

8. method as claimed in claim 6 is characterized in that, described a plurality of transmission modes also comprise the support many output of single input (SIMO) pattern from single transmit antenna to many reception antennas.

9. the method for claim 1 is characterized in that, for the transmission mode of each user terminal selecting depends on the number of antennas that the user terminal place is available.

10. the method for claim 1 is characterized in that, described MIMO communication system is used OFDM (0FDM).

11. method as claimed in claim 10 is characterized in that also comprising:

Selecting a unit for each of described at least one user terminal is the transmitting continuous phase of an integer OFDM code element, and wherein said at least one user terminal is scheduled in to inherent current scheduling of the transmitting continuous phase of each user terminal selecting and carries out transfer of data at interval.

12. a kind of device in wireless multiple access multiple-input and multiple-output (MIMO) communication system comprises:

One controller is used for:

Select at least one user terminal to be used for carrying out transfer of data in the current scheduling interval from a plurality of user terminals, wherein said at least one user terminal comprises the user terminal with many antennas,

For each of described at least one user terminal is selected at least one speed, each of wherein said at least one speed is to select a plurality of speed of supporting from system, and each of wherein said a plurality of speed all is associated with a specific code rate and a specific modulation scheme; And

Select a transmission mode for each of described at least one user terminal, wherein said each transmission mode of user is to select a plurality of transmission modes of supporting from system; And

One scheduler is used to dispatch described at least one user terminal and thinks that at least one speed of each user terminal selecting and transmission mode carry out transfer of data in current scheduling at interval.

13. device as claimed in claim 12, it is characterized in that, described controller also be used to described at least one user terminal each select a transmitting continuous phase, wherein said at least one user terminal is scheduled in to inherent current scheduling of the transmitting continuous phase of each user terminal selecting and carries out transfer of data at interval.

14. device as claimed in claim 12, it is characterized in that, described a plurality of transmission mode comprises a diversity mode and a space multiplexing mode, described diversity mode support is from the redundant data transmission that has of many transmit antennas, and described space multiplexing mode is supported the transfer of data on a plurality of space channels.

15. device as claimed in claim 14, it is characterized in that, described a plurality of transmission mode also comprises a wave beam control model, and it supports the transfer of data on the single space channel, and described single space channel is associated with the flank speed of described a plurality of space channels centre.

16. device as claimed in claim 12 is characterized in that, described MIMO communication system is used OFDM (OFDM).

17. a kind of device in wireless multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Be used for selecting at least one user terminal to be used for carrying out the device of transfer of data in the current scheduling interval from a plurality of user terminals, wherein said at least one user terminal comprises the user terminal with many antennas,

Each that is used to described at least one user terminal is selected the device of at least one speed, each of wherein said at least one speed is to select a plurality of speed of supporting from system, and each of wherein said a plurality of speed all is associated with a specific code rate and a specific modulation scheme;

Each that is used to described at least one user terminal is selected the device of a transmission mode, and wherein said each transmission mode of user is to select a plurality of transmission modes of supporting from system; And

Be used to dispatch described at least one user terminal and think at least one speed of each user terminal selecting and transmission mode is carried out transfer of data in the current scheduling interval device.

18. device as claimed in claim 17 is characterized in that also comprising:

Each that is used to described at least one user terminal is selected the device of a transmitting continuous phase, and wherein said at least one user terminal is scheduled in to inherent current scheduling of the transmitting continuous phase of each user terminal selecting and carries out transfer of data at interval.

19. device as claimed in claim 17, it is characterized in that, described a plurality of transmission mode comprises a diversity mode and a space multiplexing mode, described diversity mode support is from the redundant data transmission that has of many transmit antennas, and described space multiplexing mode is supported the transfer of data on a plurality of space channels.

20. device as claimed in claim 19, it is characterized in that, described a plurality of transmission mode also comprises a wave beam control model, and it supports the transfer of data on the single space channel, and described single space channel is associated with the flank speed of described a plurality of space channels centre.

21. device as claimed in claim 17 is characterized in that, described MIMO communication system is used OFDM (OFDM).

22. a method that sends data in wireless multiple access multiple-input and multiple-output (MIMO) communication system comprises:

From a plurality of user terminals, select based on first user terminal that has single reception antenna;

Based on first transmission mode, data are sent to single reception antenna from many transmit antennas of first user terminal at interval in the very first time;

From described a plurality of user terminals, select to have second user terminal of many reception antennas;

Based on second transmission mode, in second time interval, data are sent to many reception antennas from many transmit antennas of second user terminal, wherein said first and second transmission modes are to select a plurality of transmission modes of supporting from system.

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

From described a plurality of user terminals, select to have the 3rd user terminal of many reception antennas;

Based on the 3rd transmission mode, in the 3rd time interval, data are sent to many reception antennas from many transmit antennas of the 3rd user terminal, wherein said the 3rd transmission mode is selected from described a plurality of transmission modes.

24. method as claimed in claim 22 is characterized in that, described a plurality of transmission modes comprise a space multiplexing mode, and it is supported in the transfer of data on a plurality of space channels that formed by many transmit antennas and Duo Gen reception antenna.

25. method as claimed in claim 24 is characterized in that, each of described a plurality of space channels all is associated with a corresponding speed.

26. method as claimed in claim 24 is characterized in that, the employed number of spatial channels of the transfer of data in the space multiplexing mode is selectable.

27. method as claimed in claim 22, it is characterized in that, described a plurality of transmission mode comprises the wave beam control model of supporting the transfer of data on the single space channel, and described single space channel has flank speed in a plurality of space channels of many transmit antennas and the formation of Duo Gen reception antenna.

28. method as claimed in claim 22 is characterized in that, described a plurality of transmission modes comprise a diversity mode, and it supports the redundant data transmission that has from many transmit antennas.

29. method as claimed in claim 28 is characterized in that, described diversity mode has been realized space time transmit diversity (STTD), and it is supported in interior each transmission to modulated symbol from a pair of antenna of two code-element periods.

30. method as claimed in claim 28 is characterized in that, described diversity mode realized that sky takes place frequently and sent diversity (SFTD), and it is supported in two subbands each transmission to modulated symbol from a pair of antenna.

31. a kind of device in wireless multiple access multiple-input and multiple-output (MIMO) system comprises:

One controller, it is used for selecting second user terminal that has first user terminal of single reception antenna and have many reception antennas from a plurality of user terminals; And

One sends spatial processor, is used for:

Based on the first transmission mode deal with data, be used for the very first time at interval in transmission from many transmit antennas of first user terminal to single reception antenna, and

Based on the second transmission mode deal with data, be used in second time interval transmission from many transmit antennas of second user terminal to many reception antennas, wherein said first and second transmission modes are to select a plurality of transmission modes of supporting from system.

32. device as claimed in claim 31, it is characterized in that, described controller also is used for having from described a plurality of user terminals selections the 3rd user terminal of many reception antennas, wherein said transmission spatial processor also is used for based on the 3rd transmission mode deal with data, be used in the 3rd time interval transmission from many transmit antennas of the 3rd user terminal to many reception antennas, wherein said the 3rd transmission mode is selected from described a plurality of transmission modes.

33. device as claimed in claim 31 is characterized in that, described a plurality of transmission modes comprise a space multiplexing mode, and it is supported in the transfer of data on a plurality of space channels that formed by many transmit antennas and Duo Gen reception antenna.

34. device as claimed in claim 31, it is characterized in that, described a plurality of transmission mode comprises the wave beam control model of supporting the transfer of data on the single space channel, and described single space channel has flank speed in a plurality of space channels of many transmit antennas and the formation of Duo Gen reception antenna.

35. device as claimed in claim 31 is characterized in that, described a plurality of transmission modes comprise a diversity mode, and it supports the redundant data transmission that has from many transmit antennas.

36. a kind of device in wireless multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Be used for having the device of first user terminal of single reception antenna from a plurality of user terminals selections;

Based on first transmission mode, in very first time interval, data are sent to the device of single reception antenna from many transmit antennas of first user terminal;

Be used for having the device of second user terminal of many reception antennas from a plurality of user terminals selections; And

Based on second transmission mode, in second time interval, data are sent to the device of many reception antennas from many transmit antennas of second user terminal.

37. device as claimed in claim 36 is characterized in that also comprising:

Be used for having the device of the 3rd user terminal of many reception antennas from described a plurality of user terminals selections; And

Based on the 3rd transmission mode, in the 3rd time interval, data are sent to the device of many reception antennas from many transmit antennas of the 3rd user terminal, wherein said the 3rd transmission mode is selected from described a plurality of transmission modes.

38. device as claimed in claim 36 is characterized in that, described a plurality of transmission modes comprise a space multiplexing mode, and it is supported in the transfer of data on a plurality of space channels that formed by many transmit antennas and Duo Gen reception antenna.

39. device as claimed in claim 36, it is characterized in that, described a plurality of transmission mode comprises the wave beam control model of supporting the transfer of data on the single space channel, and described single space channel has flank speed in a plurality of space channels of many transmit antennas and the formation of Duo Gen reception antenna.

40. device as claimed in claim 36 is characterized in that, described a plurality of transmission modes comprise a diversity mode, and it supports the redundant data transmission that has from many transmit antennas.

41. the method for a swap data in wireless time division duplex (TDD) multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Select first group of at least one user terminal to be used in the current scheduling interval in the enterprising line data transmission of down link;

Select second group of at least one user terminal to be used in the current scheduling interval in the enterprising line data transmission of up link;

In current scheduling very first time segmentation at interval, on down link, data are sent to first group of described at least one user terminal; And

In current scheduling second time slice at interval on up link from the second group of received transfer of data of described at least one user terminal, wherein said first and second time slices are time division duplex in current scheduling at interval.

42. method as claimed in claim 41 is characterized in that also comprising:

Select a transmission mode for each user terminal in described first group from a plurality of transmission modes that system supported, the transmission mode that wherein is based upon each user terminal selecting sends to each user terminal in described first group to data.

43. method as claimed in claim 41 is characterized in that also comprising:

The pilot tone that sends on up link based on user terminal is that each user terminal in described first group draws channel estimating, wherein is based upon channel estimating that each user terminal draws data are sent to each user terminal in described first group.

44. method as claimed in claim 41 is characterized in that also comprising:

Select a transmission mode for each user terminal in described second group from a plurality of transmission modes that system supported, the transmission mode that wherein is based upon each user terminal selecting sends to each user terminal in described second group to data.

45. method as claimed in claim 41 is characterized in that also comprising:

Determine the timing of each user terminal in described second group; And

Each user terminal that is based upon timing that user terminal determines and is in described second group is regulated the timing of transfer of data on up link.

46. method as claimed in claim 41 is characterized in that also comprising:

For each user terminal in described second group is determined received power; And

Be based upon received power that user terminal determines and be each user terminal in described second group and regulate the transmitted power of transfer of data on up link.

47. a kind of device in wireless time division duplex (TDD) multiple access multiple-input and multiple-output (MIMO) communication system comprises:

One controller, be used to select first group and second group of at least one user terminal, described first group is used for transmitting at the enterprising line data of down link in the current scheduling interval, and described second group is used in the current scheduling interval in the enterprising line data transmission of up link;

Send spatial processor, be used for deal with data, be used on down link, data being sent to first group of described at least one user terminal in current scheduling very first time segmentation at interval; And

Receive spatial processor, be used in current scheduling second time slice at interval second group of received transfer of data from described at least one user terminal on up link, wherein said first and second time slices are time division duplexs in the current scheduling interval.

48. device as claimed in claim 47, it is characterized in that, described controller also is used to each user terminal in described first group to select a transmission mode from a plurality of transmission modes that system supported, the transmission mode that wherein is based upon each user terminal selecting sends to each user terminal in described first group to data.

49. device as claimed in claim 47, it is characterized in that, the pilot tone that described controller also is used for sending on up link based on user terminal is that each described first group user terminal draws channel estimating, wherein is based upon channel estimating that user terminal draws data are sent to each user terminal in described first group.

50. device as claimed in claim 47, it is characterized in that, described controller also is used to each user terminal in described second group to select a transmission mode from a plurality of transmission modes that system supported, the transfer of data that wherein comes from each user terminal in described second group is based on to the transmission mode of user terminal selecting carries out.

51. device as claimed in claim 47, it is characterized in that described controller also is used for determining the timing of described second group of each user terminal and is based upon timing that user terminal determines is that each user terminal in described second group is regulated the timing of transfer of data on up link.

52. device as claimed in claim 47, it is characterized in that described controller also is used for determining the received power of described second group of each user terminal and is the transmitted power that each user terminal in described second group is regulated transfer of data on up link based on the received power of user terminal.

53. a kind of device in wireless time division duplex (TDD) multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Be used to select first group of at least one user terminal to be used for the device that transmits at the enterprising line data of down link at interval in current scheduling;

Be used to select second group of at least one user terminal to be used for the device that transmits at the enterprising line data of up link at interval in current scheduling;

Be used on down link, data being sent to first group device of described at least one user terminal in current scheduling very first time segmentation at interval; And

Be used at current scheduling second time slice at interval device from the second group of received transfer of data of described at least one user terminal on up link, wherein said first and second time slices are time division duplex in current scheduling at interval.

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

Be used to each user terminal in described first group to select the device of a transmission mode from a plurality of transmission modes that system supported, the transmission mode that wherein is based upon each user terminal selecting sends to each user terminal in described first group to data.

55. device as claimed in claim 53 is characterized in that also comprising:

The pilot tone that is used for sending on up link based on user terminal is the device that each described first group user terminal draws channel estimating, wherein is based upon channel estimating that user terminal draws data are sent to each user terminal in described first group.

56. device as claimed in claim 53 is characterized in that also comprising:

Be used to each user terminal in described second group to select the device of a transmission mode from a plurality of transmission modes that system supported, the transfer of data that wherein comes from each user terminal in described second group is based on to the transmission mode of user terminal selecting carries out.

57. device as claimed in claim 53 is characterized in that also comprising:

The device that is used for the timing of definite described second group of each user terminal; And

Be based upon timing that user terminal determines and be each user terminal in described second group and regulate the device of the timing of transfer of data on up link.

58. device as claimed in claim 53 is characterized in that also comprising:

The device that is used for the received power of definite described second group of each user terminal; And

Based on the received power of user terminal is that each user terminal in described second group is regulated the device of the transmitted power of transfer of data on up link.

59. the method for a swap data in wireless time division duplex (TDD) multiple-input and multiple-output (MIMO) communication system comprises:

On up link, receive a pilot tone from user terminal;

Derive at least one dominant vector based on the down link that described reception pilot tone is a user terminal; And

Carry out spatial manipulation with described at least one dominant vector for first transfer of data that on down link, is sent to user terminal.

60. method as claimed in claim 59, it is characterized in that, for the down link of user terminal is derived single dominant vector, wherein first transfer of data is carried out the spatial manipulation of wave beam control so that send first transfer of data via the single space channel of down link with described single dominant vector.

61. method as claimed in claim 59, it is characterized in that, for the down link of user terminal is derived a plurality of dominant vectors, wherein first transfer of data is carried out the spatial manipulation of spatial reuse so that send first transfer of data via a plurality of space channels of down link with described a plurality of dominant vectors.

62. method as claimed in claim 59 is characterized in that also comprising:

Based on receiving pilot tone is that the up link of user terminal derives a matched filter; And

Carry out matched filtering with described matched filter for second transfer of data that on up link, receives from user terminal.

63. method as claimed in claim 62, it is characterized in that, described matched filter comprises at least one eigenvector of at least one eigenmodes of up link, and wherein at least one eigenvector of up link is equal at least one dominant vector of down link.

64. a kind of device in wireless time division duplex (TDD) multiple-input and multiple-output (MIMO) communication system comprises:

Receive spatial processor, be used on up link, receiving a pilot tone from user terminal;

Controller is used for deriving at least one dominant vector based on the down link that described reception pilot tone is a user terminal; And

Send spatial processor, be used for carrying out spatial manipulation for first transfer of data that on down link, is sent to user terminal with described at least one dominant vector.

65. as the described method of claim 64, it is characterized in that, described controller is used to the down link of user terminal to derive single dominant vector, the spatial manipulation that wherein said transmission spatial processor carries out wave beam control with described single dominant vector to first transfer of data is so that send first transfer of data via the single space channel of down link.

66. as the described method of claim 64, it is characterized in that, described controller is used to the down link of user terminal to derive a plurality of dominant vectors, wherein said transmission spatial processor carries out the spatial manipulation of spatial reuse with described a plurality of dominant vectors to first transfer of data, so that send first transfer of data via a plurality of space channels of down link.

67. as the described method of claim 64, it is characterized in that, it is that the up link of user terminal derives a matched filter that described controller also is used for based on receiving pilot tone, and wherein said reception spatial processor also carries out matched filtering with matched filter for second transfer of data that receives from user terminal on up link.

68. as the described method of claim 67, it is characterized in that, described matched filter comprises at least one eigenvector of at least one eigenmodes of up link, and wherein at least one eigenvector of up link is equal at least one dominant vector of down link.

69. a kind of device in wireless time division duplex (TDD) multiple-input and multiple-output (MIMO) communication system comprises:

Be used on up link, receiving the device of a pilot tone from user terminal;

Derive the device of at least one dominant vector based on the described reception pilot tone down link that is user terminal; And

Carry out the device of spatial manipulation for first transfer of data that on down link, is sent to user terminal with described at least one dominant vector.

70. as the described device of claim 69, it is characterized in that, for the down link of user terminal is derived single dominant vector, wherein first transfer of data is carried out the spatial manipulation of wave beam control so that send first transfer of data via the single space channel of down link with described single dominant vector.

71. as the described device of claim 69, it is characterized in that, for the down link of user terminal is derived a plurality of dominant vectors, wherein first transfer of data is carried out the spatial manipulation of spatial reuse so that send first transfer of data via a plurality of space channels of down link with described a plurality of dominant vectors.

72., it is characterized in that also comprising as the described device of claim 69:

Based on receiving pilot tone is the device that the up link of user terminal derives a matched filter; And

Carry out matched filtering with described matched filter for second transfer of data that on up link, receives from user terminal.

73. as the described device of claim 72, it is characterized in that, described matched filter comprises at least one eigenvector of at least one eigenmodes of up link, and wherein at least one eigenvector of up link is equal at least one dominant vector of down link.

74. a method that sends and receive pilot tone in wireless multiple-input and multiple-output (MIMO) communication system comprises:

Send the MIMO pilot tone from many antennas and at first communication link, wherein said MIMO pilot tone comprises a plurality of pilot transmission of sending from many antennas, wherein all can be by the communication entity sign that receives the MIMO pilot tone from the pilot transmission of every antenna; And

At least one eigenmodes via the second communication link receives a controlled pilot tone from described communication entity, and wherein said controlled pilot tone generates based on described MIMO pilot tone.

75., it is characterized in that described first communication link is a up link as the described method of claim 74, described second communication link is a down link, described communication entity is a user terminal.

76., it is characterized in that described first communication link is a down link as the described method of claim 74, described second communication link is a up link, described communication entity is an access point.

77., it is characterized in that the orthogonal codes all different with from the pilot transmission of every antenna are associated as the described method of claim 74.

78., it is characterized in that described controlled pilot tone receives from the single eigenmodes of second communication link as the described method of claim 74, and be issued with the many antennas of full transmitted power from communication entity.

79., it is characterized in that described controlled pilot tone is received via a plurality of eigenmodes of second communication link as the described method of claim 74.

80., it is characterized in that described controlled pilot tone is sent by communication entity as the described method of claim 74 in the configurable time remaining of the system phase.

81. a kind of device in wireless multiple-input and multiple-output (MIMO) communication system comprises:

Send spatial processor, being used to generate a MIMO pilot tone is used for transmitting from many antennas with at first communication link, wherein said MIMO pilot tone comprises a plurality of pilot transmission from many antenna transmission, and wherein the pilot transmission from every antenna can be identified by the communication entity that receives the MIMO pilot tone; And

Receive spatial processor, be used to handle a controlled pilot tone, described controlled pilot tone is received from communication entity via at least one eigenmodes of second communication link, and described controlled pilot tone generates based on the MIMO pilot tone.

82., it is characterized in that the orthogonal codes all different with from the pilot transmission of every antenna are associated as the described device of claim 81.

83., it is characterized in that described controlled pilot tone is received via the single eigenmodes of second communication link as the described device of claim 81, and be sent out with the many antennas of full transmitted power from communication entity.

84., it is characterized in that described controlled pilot tone is received via a plurality of eigenmodes of second communication link as the described device of claim 81.

85. a kind of device in wireless multiple-input and multiple-output (MIMO) communication system comprises:

Be used for from many antennas and send the device of MIMO pilot tone at first communication link, wherein said MIMO pilot tone comprises a plurality of pilot transmission from many antenna transmission, and wherein the pilot transmission from every antenna can be identified by the communication entity that receives the MIMO pilot tone; And

Be used for via at least one eigenmodes of second communication link device from communication entity receiving slave pilot tone, described controlled pilot tone generates based on the MIMO pilot tone.

86., it is characterized in that the orthogonal codes all different with from the pilot transmission of every antenna are associated as the described device of claim 85.

87., it is characterized in that described controlled pilot tone is received via the single eigenmodes of second communication link as the described device of claim 85, and be sent out with the many antennas of full transmitted power from communication entity.

88., it is characterized in that described controlled pilot tone is received via a plurality of eigenmodes of second communication link as the described device of claim 85.

89. a method of carrying out channel estimating in wireless multiple-input and multiple-output (MIMO) communication system comprises:

Via at least one eigenmodes of up link from user terminal receiving slave pilot tone; And

Based on the controlled pilot tone that is received is at least one eigenmodes estimation channel response of the up link of user terminal.

90., it is characterized in that also comprising as the described method of claim 89:

Derive a matched filter based on the estimated channel response of at least one eigenmodes of described up link, wherein said matched filter is used at least one eigenmodes via up link is carried out matched filtering from the transfer of data that user terminal receives.

91., it is characterized in that also comprising as the described method of claim 89:

Based on the controlled pilot tone that is received is at least one eigenmodes estimation channel response of the down link of user terminal.

92., it is characterized in that also comprising as the described method of claim 91:

At least one the eigenmodes estimated channel that is based upon down link responds and derives at least one dominant vector, and described at least one dominant vector is used for arriving the transfer of data of user terminal at least one eigenmodes of described down link.

93. as the described method of claim 92, it is characterized in that, described controlled pilot tone is received via a plurality of eigenmodes of up link, the channel response of a plurality of eigenmodes of described user terminal down link is based on that the controlled pilot tone that received estimates, a plurality of eigenmodes estimated channel that wherein are based upon described down link respond and derive a plurality of dominant vectors.

94., it is characterized in that described a plurality of dominant vectors are to derive as the described method of claim 93 orthogonally.

95. a kind of device in wireless multiple-input and multiple-output (MIMO) communication system comprises:

Receive spatial processor, it is used for receiving a controlled pilot tone via at least one eigenmodes of up link from user terminal; And

Controller, being used for based on the controlled pilot tone that is received is at least one eigenmodes estimation channel response of the up link of user terminal.

96. as the described device of claim 95, it is characterized in that, at least one eigenmodes estimated channel that described controller also is used to be based upon up link responds and derives a matched filter, and wherein said matched filter is used at least one eigenmodes via up link is carried out matched filtering from the transfer of data that user terminal receives.

97., it is characterized in that it is at least one eigenmodes estimation channel response of the down link of user terminal that described controller also is used for based on the controlled pilot tone that is received as the described device of claim 95.

98. as the described device of claim 97, it is characterized in that, at least one eigenmodes estimated channel that described controller also is used to be based upon down link responds and derives at least one dominant vector, and wherein said at least one dominant vector is used at least one eigenmodes of down link the transfer of data to user terminal.

99. a kind of device in wireless multiple-input and multiple-output (MIMO) communication system comprises:

Be used for receiving from user terminal the device of a controlled pilot tone via at least one eigenmodes of up link; And

It based on the controlled pilot tone that is received the device that at least one eigenmodes of the up link of user terminal is estimated channel response.

100., it is characterized in that also comprising as the described device of claim 99:

At least one the eigenmodes estimated channel that is based upon described up link responds the device of deriving a matched filter, and wherein said matched filter is used at least one eigenmodes via up link is carried out matched filtering from the transfer of data that user terminal receives.

101., it is characterized in that also comprising as the described device of claim 99:

It based on the controlled pilot tone that is received the device that at least one eigenmodes of the down link of user terminal is estimated channel response.

102., it is characterized in that also comprising as the described device of claim 101:

At least one the eigenmodes estimated channel that is based upon down link responds the device of deriving at least one dominant vector, and wherein said at least one dominant vector is used for arriving the transfer of data of user terminal at least one eigenmodes of down link.

103. the channel architecture of a wireless multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Be used on down link, sending the broadcast channel of employed system parameters of Downlink channel estimation and pilot tone;

Be used for sending the forward control channel that is used for the scheduling of transfer of data on down link and the up link on the down link;

Be used on down link, sending the forward channel of traffic data;

Be used for sending the Random Access Channel of the request that is used for connecting system in up link; And

Be used on up link, sending the backward channel of traffic data.

104., it is characterized in that broadcast channel, forward control channel, forward channel, Random Access Channel and backward channel are time-multiplexed as the described channel architecture of claim 103 in having the frame of the duration scheduled time.

105., it is characterized in that in described frame, at first send broadcast channel, next sends forward control channel as the described channel architecture of claim 104.

106., it is characterized in that described broadcast channel and forward control channel send with a diversity mode as the described channel architecture of claim 103, described diversity mode support is from the redundant data transmission that has of many transmit antennas.

107. as the described channel architecture of claim 103, it is characterized in that, described forward channel and backward channel are supported a diversity mode and a space multiplexing mode, described diversity mode support is from the redundant data transmission that has of many transmit antennas, and described space multiplexing mode is supported the transfer of data on a plurality of space channels.

108. as the described channel architecture of claim 103, it is characterized in that, described Random Access Channel is supported single input many output (SIMO) pattern and a wave beam control model, described SIMO pattern is supported the transfer of data from single transmit antenna to many reception antennas, and described wave beam control model is supported in the transfer of data on the single space channel relevant with flank speed in a plurality of space channels.

109., it is characterized in that described forward channel and backward channel respectively have a variable time remaining phase as the described channel architecture of claim 103.

110., it is characterized in that described forward control channel and Random Access Channel respectively have a variable time remaining phase as the described channel architecture of claim 103.

111., it is characterized in that described scheduling is included as the sign of the user terminal that transmits on down link and the up link and dispatch as the described channel architecture of claim 103.

112. as the described channel architecture of claim 103, it is characterized in that, described scheduling comprises a transmission mode and at least one speed of each user terminal of dispatching for the transfer of data on down link and the up link, described transmission mode is to select a plurality of transmission modes of supporting from system, and each of described at least one speed is to select a plurality of speed of supporting from system.

113., it is characterized in that described forward channel also is used for sending a controlled pilot tone as the described channel architecture of claim 103 at least one eigenmodes of user terminal down link.

114., it is characterized in that described backward channel also is used for sending on the up link employed second pilot tone of uplink channel estimation as the described channel architecture of claim 103.

115., it is characterized in that described backward channel also is used for sending a controlled pilot tone from user terminal at least one eigenmodes of up link as the described channel architecture of claim 103.

116. a kind of device in wireless multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Send data processor, be used for:

Processing is used for system parameters and the pilot tone sent via broadcast channel, and wherein said pilot tone is used for the channel estimating of down link,

Processing is used for the schedule information sent via forward control channel, and wherein said schedule information is used for the transfer of data on down link and the up link, and

Processing is used for the traffic data sent via forward channel; And

Receive data processor, be used for:

User's request that processing receives via Random Access Channel, and

The traffic data that processing receives via backward channel.

117., it is characterized in that broadcast channel, forward control channel, forward channel, Random Access Channel and backward channel are time-multiplexed as the described device of claim 116 in having the frame of the duration scheduled time.

118., it is characterized in that described broadcast channel and forward control channel send with a diversity mode as the described device of claim 116, described diversity mode support is from the redundant data transmission that has of many transmit antennas.

119. as the described device of claim 116, it is characterized in that, described forward channel and backward channel are supported a diversity mode and a space multiplexing mode, described diversity mode support is from the redundant data transmission that has of many transmit antennas, and described space multiplexing mode is supported the transfer of data on a plurality of space channels.

120. as the described device of claim 116, it is characterized in that, described Random Access Channel is supported single input many output (SIMO) pattern and a wave beam control model, described SIMO pattern is supported the transfer of data from single transmit antenna to many reception antennas, and described wave beam control model is supported in the transfer of data on the single space channel relevant with flank speed in a plurality of space channels.

121. a kind of device in wireless multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Processing is used for the system parameters sent via broadcast channel and the device of pilot tone, and wherein said pilot tone is used for the channel estimating of down link,

Processing is used for the device of the schedule information sent via forward control channel, and wherein said schedule information is used for the transfer of data on down link and the up link;

Processing is used for the device of the traffic data sent via forward channel;

Be used to handle the device of the user's request that receives via Random Access Channel; And

Be used to handle the device of the traffic data that receives via backward channel.

122., it is characterized in that broadcast channel, forward control channel, forward channel, Random Access Channel and backward channel are time-multiplexed as the described channel architecture of claim 121 in having the frame of the duration scheduled time.

123., it is characterized in that described broadcast channel and forward control channel send with a diversity mode as the described channel architecture of claim 121, described diversity mode support is from the redundant data transmission that has of many transmit antennas.

124. as the described channel architecture of claim 121, it is characterized in that, described forward channel and backward channel are supported a diversity mode and a space multiplexing mode, described diversity mode support is from the redundant data transmission that has of many transmit antennas, and described space multiplexing mode is supported the transfer of data on a plurality of space channels.

125. as the described channel architecture of claim 121, it is characterized in that, described Random Access Channel is supported single input many output (SIMO) pattern and a wave beam control model, described SIMO pattern is supported the transfer of data from single transmit antenna to many reception antennas, and described wave beam control model is supported in the transfer of data on the single space channel relevant with flank speed in a plurality of space channels.

126. a method that sends signaling information in wireless multiple-input and multiple-output (MIMO) communication system comprises:

On first subchannel of forward control channel, send first group signaling information of at least one user terminal with first rate; And

Send second group signaling information of at least one user terminal on second subchannel of forward control channel with second speed, wherein said second speed is higher than described first rate, and described second subchannel is sent out after first subchannel.

127., it is characterized in that also comprising as the described method of claim 126:

Send the 3rd group signaling information of at least one user terminal on the 3rd subchannel of forward control channel with third speed, wherein said third speed is higher than described second speed, and described the 3rd subchannel is sent out after second subchannel.

128., it is characterized in that described first subchannel shows whether second subchannel is sent out as the described method of claim 126 in present frame.

129. a kind of device in wireless multiple-input and multiple-output (MIMO) communication system comprises:

Send data processor, be used for:

Handle first group signaling information of at least one user terminal based on first rate, and

Handle second group signaling information of at least one user terminal based on second speed higher than first rate; And

Transmitter unit is used for:

On first subchannel of forward control channel, send the treated schedule information of the described first user terminal group, and

Send the treated schedule information of the described second user terminal group on second subchannel of forward control channel, wherein said second subchannel is sent out after first subchannel.

130. as the described device of claim 129, it is characterized in that, described transmission data processor also is used for handling based on the third speed higher than second speed the 3rd group signaling information of at least one user terminal, wherein said transmitter unit also is used for sending the treated signaling information of the 3rd user terminal group on the 3rd subchannel of forward control channel, wherein said the 3rd subchannel is sent out after second subchannel.

131., it is characterized in that described first subchannel shows whether second subchannel is sent out as the described device of claim 129 in present frame.

132. a kind of device in wireless multiple-input and multiple-output (MIMO) communication system comprises:

Be used on first subchannel of forward control channel, sending the device of first group signaling information of at least one user terminal with first rate; And

Be used for sending with second speed on second subchannel of forward control channel the device of second group signaling information of at least one user terminal, wherein said second speed is higher than described first rate, and described second subchannel is sent out after first subchannel.

133., it is characterized in that also comprising as the described device of claim 132:

Be used for sending with third speed on the 3rd subchannel of forward control channel the device of the 3rd group signaling information of at least one user terminal, wherein said third speed is higher than described second speed, and described the 3rd subchannel is sent out after second subchannel.

134., it is characterized in that described first subchannel shows whether second subchannel is sent out as the described device of claim 132 in present frame.

135. a method that receives signaling information in multiple-input and multiple-output (MIMO) communication system at the user terminal place comprises:

The signaling information that reception sends on first subchannel of forward control channel with first rate; And

If do not obtain the signaling information of user terminal from first subchannel, then receive the signaling information that on second subchannel of forward control channel, sends with second speed, wherein said second speed is higher than described first rate, and described second subchannel is sent out after first subchannel.

136., it is characterized in that also comprising as the described method of claim 126:

If do not obtain the signaling information of user terminal from second subchannel, then receive the signaling information that on the 3rd subchannel of forward control channel, sends with third speed, wherein said third speed is higher than described second speed, and described the 3rd subchannel is sent out after second subchannel.

137., it is characterized in that also comprising as the described method of claim 126:

Stop the processing of forward control channel in the decoding failure back that runs into forward control channel one subchannel.

138. a kind of device in wireless multiple-input and multiple-output (MIMO) communication system comprises:

Receive data processor, be used for:

The signaling information that reception sends on first subchannel of forward control channel with first rate, and

If do not obtain the signaling information of described device from first subchannel, then receive the signaling information that on second subchannel of forward control channel, sends with second speed, wherein said second speed is higher than described first rate, and described second subchannel is sent out after first subchannel; And

Be used to indicate the controller of the processing of first and second subchannels.

139. as the described device of claim 138, it is characterized in that, described reception data processor also is used for: if do not obtain the signaling information of described device from second subchannel, then receive the signaling information that on the 3rd subchannel of forward control channel, sends with third speed, wherein said third speed is higher than described second speed, and described the 3rd subchannel is sent out after second subchannel.

140., it is characterized in that described controller also is used for stopping in the decoding failure back that runs into forward control channel one subchannel the processing of forward control channel as the described device of claim 138.

141. a kind of device in wireless multiple-input and multiple-output (MIMO) communication system comprises:

Be used to receive the device of the signaling information that on first subchannel of forward control channel, sends with first rate; And

If not from first subchannel obtain described device signaling information, then receive the device of the signaling information that sends at second subchannel of forward control channel with second speed, wherein said second speed is higher than described first rate, and described second subchannel is sent out after first subchannel.

142., it is characterized in that also comprising as the described device of claim 141:

If not from second subchannel obtain described device signaling information, then receive the device of the signaling information that sends at the 3rd subchannel of forward control channel with third speed, wherein said third speed is higher than described second speed, and described the 3rd subchannel is sent out after second subchannel.

143., it is characterized in that also comprising as the described device of claim 141:

Be used for stopping the device of the processing of forward control channel in the decoding failure back that runs into forward control channel one subchannel.

144. a kind of method that is used to handle for the data of transmission in wireless multiple-input and multiple-output (MIMO) communication system comprises:

According to an encoding scheme Frame is encoded to obtain encoded Frame;

Encoded Frame is divided into a plurality of encoded data bursts, an encoded data burst is arranged for each of a plurality of space channels;

According to an interleaving scheme each encoded data burst is interweaved to obtain corresponding data burst through interweaving, wherein obtain a plurality of data bursts through interweaving for described a plurality of space channels; And

Modulate each data burst to obtain a corresponding modulation, symbol streams, wherein obtain a plurality of modulation, symbol streams for described a plurality of space channels through interweaving.

145. as the described method of claim 144, it is characterized in that, cut apart encoded Frame by once filling up an encoded data burst fully.

146. as the described method of claim 144, it is characterized in that, by iterative cycles repeatedly through a plurality of encoded data bursts and the coded-bit of the specific quantity of the coded frame data that in each iteration, is used for hanging oneself come partly to fill each encoded data burst, thereby cut apart encoded Frame.

147. as the described method of claim 144, it is characterized in that, each of described a plurality of space channels all is associated with a corresponding speed, wherein the speed of each space channel all shows a certain modulation schemes and the specific coding speed that described space channel will use, wherein said certain modulation schemes is to select a plurality of modulation schemes of supporting from system, and described specific coding speed is to select a plurality of code rates of supporting from system.

148., it is characterized in that described a plurality of code rates are based on single base sign indicating number and the acquisition of a plurality of brachymemma pattern as the described method of claim 147.

149., it is characterized in that also comprising as the described method of claim 144:

Each encoded data burst of brachymemma is so that the code rate that acquisition is selected for the space channel of encoded data burst.

150., it is characterized in that described mimo system uses OFDM (OFDM) as the described method of claim 144.

151. as the described method of claim 150, it is characterized in that, for one group in each iteration M subband, by circulation in iteration repeatedly through a plurality of encoded data bursts and the coded-bit of the coded frame data that is used for hanging oneself fill each encoded data burst partially, thereby cut apart encoded Frame, wherein M is greater than 1 and less than the employed sub-band sum of transfer of data.

152., it is characterized in that described iteration is for the coded-bit of every group of M subband and carry out as the described method of claim 151.

153., it is characterized in that also comprising as the described method of claim 150:

Handle a plurality of modulation, symbol streams to obtain a plurality of OFDM code element stream, wherein said OFDM code element has a circulating prefix-length of selecting at least two cyclic-redundancy prefix length supporting from system.

154., it is characterized in that also comprising as the described method of claim 150:

Handle a plurality of modulation, symbol streams to obtain a plurality of OFDM code element stream, the size of wherein said OFDM code element is to select at least two OFDM code element sizes supporting from system.

155. a kind of device in wireless multiple-input and multiple-output (MIMO) communication system comprises:

Encoder, it is encoded to obtain encoded Frame to Frame according to an encoding scheme;

Demultiplexer is used for encoded Frame is divided into a plurality of encoded data bursts, for each of a plurality of space channels an encoded data burst is arranged;

Interleaver, it interweaves to obtain corresponding data burst through interweaving to each encoded data burst according to an interleaving scheme, wherein obtains a plurality of data bursts through interweaving for described a plurality of space channels; And

The symbol mapped unit, it is used to modulate each data burst through interweaving to obtain corresponding modulation, symbol streams, wherein obtains a plurality of modulation, symbol streams for described a plurality of space channels.

156. as the described device of claim 155, it is characterized in that, each of described a plurality of space channels all is associated with a corresponding speed, wherein the speed of each space channel shows a certain modulation schemes and the specific coding speed that described space channel will use, wherein said certain modulation schemes is to select a plurality of modulation schemes of supporting from system, and described specific coding speed is to select a plurality of code rates of supporting from system.

157., it is characterized in that described mimo system uses OFDM (OFDM) as the described device of claim 155.

158. as the described device of claim 157, it is characterized in that, described demultiplexer is used for: for one group of M subband of each iteration, by circulation in iteration repeatedly through a plurality of encoded data bursts and the coded-bit of the coded frame data that is used for hanging oneself come partly to fill each encoded data burst, thereby cut apart encoded Frame, wherein M is greater than 1 and less than the employed sub-band sum of transfer of data.

159., it is characterized in that also comprising as the described device of claim 157:

Be used to handle described a plurality of modulation, symbol streams to obtain a plurality of OFDM modulators of a plurality of OFDM code element stream, wherein said OFDM code element has a circulating prefix-length of selecting at least two circulating prefix-lengths supporting from system.

160., it is characterized in that also comprising as the described device of claim 157:

Be used to handle described a plurality of modulation, symbol streams to obtain a plurality of OFDM modulators of a plurality of OFDM code element stream, the size of wherein said OFDM code element is to select at least two OFDM code element sizes supporting from system.

161. a kind of device in wireless multiple-input and multiple-output (MIMO) communication system comprises:

Be used for Frame being encoded to obtain the device of encoded Frame according to an encoding scheme;

Be used for encoded Frame is divided into the device of a plurality of encoded data bursts, an encoded data burst arranged for each of a plurality of space channels;

Be used for each encoded data burst being interweaved to obtain the device of corresponding data burst through interweaving, wherein obtain a plurality of data bursts through interweaving for described a plurality of space channels according to an interleaving scheme; And

Be used to modulate each data burst to obtain the device of corresponding modulation, symbol streams, wherein obtain a plurality of modulation, symbol streams for described a plurality of space channels through interweaving.

162. as the described device of claim 161, it is characterized in that, each of described a plurality of space channels all is associated with a corresponding speed, wherein the speed of each space channel shows a certain modulation schemes and the specific coding speed that described space channel will use, wherein said certain modulation schemes is to select a plurality of modulation schemes of supporting from system, and described specific coding speed is to select a plurality of code rates of supporting from system.

163., it is characterized in that described mimo system uses OFDM (OFDM) as the described device of claim 161.

164. as the described device of claim 163, it is characterized in that, for one group in each iteration M subband, by circulation in iteration repeatedly through a plurality of encoded data bursts and the coded-bit of the coded frame data that is used for hanging oneself come partly to fill each encoded data burst, thereby cut apart encoded Frame, wherein M is greater than 1 and less than the employed sub-band sum of transfer of data.

165., it is characterized in that also comprising as the described device of claim 163:

Be used to handle described a plurality of modulation, symbol streams to obtain the device of a plurality of OFDM code element stream, wherein said OFDM code element has a circulating prefix-length of selecting at least two circulating prefix-lengths supporting from system.

166., it is characterized in that also comprising as the described device of claim 163:

Be used to handle described a plurality of modulation, symbol streams to obtain the device of a plurality of OFDM code element stream, the size of wherein said OFDM code element is to select at least two OFDM code element sizes supporting from system.

167. a method that inserts wireless multiple access multiple-input and multiple-output (MIMO) communication system comprises:

On down link via the first transmission channel receiving system information;

Send one via second transmission channel and insert request on up link, wherein said access request is sent out based on the system information that is received;

Monitor whether the 3rd transmission channel on the down link sends the affirmation of the request of access to some extent; And

If in the preset time section, do not receive described affirmation then repeat described reception, transmission and monitoring step.

168. as the described method of claim 167, it is characterized in that, monitor that the 3rd transmission channel comprises:

Monitor the affirmation bit in described first transmission channel, and

If be provided with acknowledgement bit then handle described the 3rd transmission channel for described affirmation.

169. as the described method of claim 167, it is characterized in that, sent a plurality of access requests.

170. as the described method of claim 169, it is characterized in that, send described a plurality of access request with the speed that reduces one by one.

171., it is characterized in that also comprising as the described method of claim 169:

Before sending next access request in the middle of described a plurality of access requests, wait for a pseudorandom time period.

172., it is characterized in that also comprising as the described method of claim 169:

Send a controlled pilot tone together with the request that inserts on described second transmission channel, described controlled pilot tone is sent out at least one eigenmodes of the mimo channel of up link.

173., it is characterized in that described system information shows the time interval that wherein allows to send the request of access as the described method of claim 167, wherein said access request was sent out in the described time interval.

174., it is characterized in that described system information shows wherein the time slot of the specific quantity that allows to send the request of access as the described method of claim 167, wherein inserted request mark and wherein sent the particular time-slot that this accesss is asked.

175., it is characterized in that described time slot has can be by duration time of system configuration as the described method of claim 174.

176. a kind of device in wireless multiple access multiple-input and multiple-output (MIMO) communication system comprises:

On down link via the reception data processor of the first transmission channel receiving system information;

Processing is used on up link the transmission data processor of the access request that sends via second transmission channel, and wherein said access request is sent out based on the system information that is received;

Monitor whether the 3rd transmission channel on the down link sends the controller of the affirmation of the request of access to some extent, and

Wherein said reception data processor is used to receive the system information after the renewal, send data processor and be used to handle another and insert request, and controller monitors described the 3rd transmission channel when not receiving the confirmation in the section at the fixed time.

177., it is characterized in that described controller is used for monitoring the affirmation bit of described first transmission channel as the described device of claim 176, and indication reception data processor is that described the 3rd transmission channel is handled in described affirmation when being provided with acknowledgement bit.

178. as the described device of claim 176, it is characterized in that, sent a plurality of access requests.

179. as the described device of claim 178, it is characterized in that, send described a plurality of access request with the speed that reduces one by one.

180., it is characterized in that described controller was waited for a pseudorandom time period as the described device of claim 178 before beginning to send next access request in the middle of described a plurality of access requests.

181., it is characterized in that also comprising as the described device of claim 178:

Send spatial processor, be used for sending a controlled pilot tone together with the request that inserts on described second transmission channel, described controlled pilot tone is sent out at least one eigenmodes of the mimo channel of up link.

182. a kind of device in wireless multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Be used on down link device via the first transmission channel receiving system information;

Be used for sending via second transmission channel on up link the device of the request of access, wherein said access request is sent out based on the system information that is received;

Be used to monitor whether the 3rd transmission channel on the down link sends the device of the affirmation of the request of access to some extent; And

If described affirmation does not receive in the section at the fixed time then repeats the device of described reception, transmission and monitoring step.

183. as the described device of claim 182, it is characterized in that, describedly be used to monitor that the device of the 3rd transmission channel comprises:

Be used for monitoring the device of the affirmation bit of described first transmission channel, and

If be provided with acknowledgement bit then handle the device of described the 3rd transmission channel for described affirmation.

184. as the described device of claim 182, it is characterized in that, sent a plurality of access requests.

185. as the described device of claim 184, it is characterized in that, send described a plurality of access request with the speed that reduces one by one.

186., it is characterized in that also comprising as the described device of claim 184:

Before sending next access request in the middle of described a plurality of access requests, wait for a pseudorandom time period.

187., it is characterized in that also comprising as the described device of claim 184:

Be used for sending together with the access request on described second transmission channel device of a controlled pilot tone, described controlled pilot tone is sent out at least one eigenmodes of the mimo channel of up link.

188. a method that sends data in wireless time division duplex (TDD) multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Estimate the channel response of first communication link;

Based on the estimated channel response of first communication link is that at least one space channel of second communication link is determined at least one speed, for each space channel a speed is arranged; And

On at least one space channel of second communication link, send data with described at least one speed.

189., it is characterized in that in described mimo system, described first communication link is a up link as the described method of claim 188, described second communication link is a down link.

190., it is characterized in that also comprising as the described method of claim 188:

The signal of a plurality of space channels of estimating the second communication link based on the Noise Estimation and the estimated channel response of described first communication link of described first communication link is to noise and interference ratio (SNR).

191., it is characterized in that described at least one space channel is also selected based on the injecting process as the described method of claim 190, wherein said at least one speed is based on the SNR of described at least one space channel and described the injecting process and is definite.

192., it is characterized in that described mimo system uses OFDM (OFDM) as the described method of claim 188.

193. as the described method of claim 192, it is characterized in that, for each of a plurality of subbands obtains a plurality of space channels, wherein a plurality of broadbands space channel is formed by a plurality of space channels of described a plurality of subbands, and each broadband space channel all comprises each a space channel of described a plurality of subbands.

194. as the described method of claim 193, it is characterized in that, based on the SNR of a plurality of space channels of described a plurality of subbands and select at least one broadband space channel to carry out transfer of data.

195. as the described method of claim 194, it is characterized in that, further reverse and select at least one broadband space channel so that in a plurality of subbands of each broadband space channel, realize similar SNR based on channel.

196. as the described method of claim 188, it is characterized in that, the channel response of first communication link is based on the controlled pilot tone that a plurality of eigenmodes via first communication link receive and estimates that each of wherein said at least one space channel is all corresponding to one of a plurality of eigenmodes.

197. a kind of device in wireless time division duplex (TDD) multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Controller is used to estimate the channel response of first communication link, and is that at least one space channel of second communication link is determined at least one speed based on the estimated channel response of first communication link, and each space channel has a speed; And

Send data processor, be used for coming deal with data, be used at least one space channel of second communication link, transmitting based on described at least one speed.

198. as the described device of claim 197, it is characterized in that, described controller also is used for: the signal of a plurality of space channels of estimating the second communication link based on the Noise Estimation and the estimated channel response of described first communication link of described first communication link is to noise and interference ratio (SNR), and selects at least one space channel based on the SNR of described a plurality of space channels in a plurality of space channels.

199. as the described device of claim 198, it is characterized in that described controller also is used for selecting described at least one space channel and determining described at least one speed based on the SNR and the described the injecting process of described at least one space channel based on a injecting process.

200., it is characterized in that described mimo system uses OFDM (OFDM) as the described device of claim 197.

201. as the described device of claim 200, it is characterized in that, for each of a plurality of subbands obtains a plurality of space channels, wherein a plurality of broadbands space channel is formed by a plurality of space channels of described a plurality of subbands, and each broadband space channel all comprises each a space channel of a plurality of subbands.

202. a kind of device in wireless time division duplex (TDD) multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Be used to estimate the device of the channel response of first communication link;

Based on the estimated channel response of first communication link is the device that at least one space channel of second communication link is determined at least one speed, and each space channel has a speed; And

On at least one space channel of second communication link, send the device of data with described at least one speed.

203., it is characterized in that also comprising as the described device of claim 202:

The signal of a plurality of space channels of estimating the second communication link based on the Noise Estimation and the estimated channel response of described first communication link of described first communication link is to the device of noise and interference ratio (SNR);

In a plurality of space channels, select the device of at least one space channel based on the SNR of described a plurality of space channels.

204., it is characterized in that described at least one space channel is also selected based on a injecting process as the described device of claim 203, wherein said at least one speed is based on that the SNR of described at least one space channel and described the injecting process determine.

205., it is characterized in that described mimo system uses OFDM (OFDM) as the described device of claim 202.

206. as the described device of claim 205, it is characterized in that, for each of a plurality of subbands obtains a plurality of space channels, wherein a plurality of broadbands space channel is formed by a plurality of space channels of described a plurality of subbands, and each broadband space channel all comprises each a space channel of a plurality of subbands.

207. a method that sends data in wireless multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Estimate the channel response of first communication link;

Based on estimated channel response is that at least one space channel of first communication link is determined the speed that at least one is supported, for each space channel a speed of being supported is arranged, each speed of supporting all shows the maximum rate of being supported by corresponding space channel on the pre-determined characteristics rank;

Via the second communication link described at least one speed of being supported is sent to a transmitting entity;

Receive at least one selected speed of described at least one space channel, each space channel has a selected speed, and each selected speed all is equal to or less than the speed that space channel is supported; And

On at least one space channel of first communication link, receive transfer of data with described at least one selected speed.

208., it is characterized in that in described mimo system, described first communication link is a up link as the described method of claim 207, described second communication link is a down link.

209. as the described method of claim 207, it is characterized in that, the estimated channel response of first communication link comprises the signal of a plurality of space channels of first communication link to noise and interference ratio (SNR), and wherein said at least one space channel is based on that the SNR of a plurality of space channels selects from described a plurality of space channels.

210., it is characterized in that described at least one space channel is also selected based on the injecting process as the described method of claim 209, wherein said at least one speed is based on the SNR of described at least one space channel and described the injecting process and is definite.

211. a kind of device in wireless multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Controller, be used to estimate the channel response of first communication link, and based on estimated channel response is that at least one space channel of first communication link is determined the speed that at least one is supported, for each space channel a speed of being supported is arranged, each speed of supporting all shows the maximum rate of being supported by corresponding space channel on the pre-determined characteristics rank;

Send data processor, it sends to a transmitting entity to described at least one speed of being supported via the second communication link;

Receive data processor, be used for:

Receive at least one selected speed of described at least one space channel, each space channel has a selected speed, and each selected speed all is equal to or less than the speed that space channel is supported; And

Handle the transfer of data that at least one space channel of first communication link, receives with described at least one selected speed.

212. as the described device of claim 211, it is characterized in that, the estimated channel response of first communication link comprises the signal of a plurality of space channels of first communication link to noise and interference ratio (SNR), and wherein said controller is selected at least one space channel based on the SNR of a plurality of space channels from described a plurality of space channels.

213. as the described device of claim 212, it is characterized in that, described controller is also selected at least one space channel based on the injecting process, and determines the speed that at least one is supported based on the SNR and the described the injecting process of described at least one space channel.

214. a kind of device in wireless multiple access multiple-input and multiple-output (MIMO) communication system comprises:

Be used to estimate the device of the channel response of first communication link;

Based on estimated channel response is the device that at least one space channel of first communication link is determined the speed that at least one is supported, for each space channel a speed of being supported is arranged, each speed of supporting all shows the maximum rate of being supported by corresponding space channel on the pre-determined characteristics rank;

Be used for described at least one speed of being supported being sent to the device of a transmitting entity via the second communication link;

Be used to receive the device of at least one selected speed of described at least one space channel, each space channel has a selected speed, and each selected speed all is equal to or less than the speed that space channel is supported; And

On at least one space channel of first communication link, receive the device of transfer of data with described at least one selected speed.

215. as the described device of claim 214, it is characterized in that, the estimated channel response of first communication link comprises the signal of a plurality of space channels of first communication link to noise and interference ratio (SNR), and wherein said at least one space channel is based on that the SNR of a plurality of space channels selects from described a plurality of space channels.

216., it is characterized in that described at least one space channel is also selected based on the injecting process as the described device of claim 215, wherein at least one speed of supporting is based on that the SNR of described at least one space channel and described the injecting process determine.

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