CN1868147A - System and method for channel-adaptive antenna selection - Google Patents

Abstract

Systems and methods that provide channel-adaptive antenna selection in multi-antenna-element communication systems are provided. In one embodiment, a method that selects a subset of receive antennas of a receiver to receive a transmitted RF signal may include, for example, one or more of the following: establishing possible subsets of the receive antennas; determining sets of channel parameter statistics corresponding to the possible subsets of the receive antennas; computing output bit error rates of the receiver, each output bit error rate being computed based on at least one set of channel parameter statistics; selecting a particular possible subset of the receive antennas based upon a criterion predicated on the computed output bit error rates; and connecting one or more RF chains of the receiver to the receive antennas of the selected particular possible subset.

Description

The method and system of channel self-adapting sky line options

Technical field

The present invention relates to communication system, more specifically, relate to a kind of method and system that in many antenna elements communication system, carries out day line options.

Background technology

Current most wireless communication system is all formed by being furnished with the single node that transmits and receives antenna.It is predicted that by using a plurality of emissions and/or a plurality of reception antenna, the performance of a lot of communication systems comprises that capacity will be promoted fully.This antenna configurations has formed the basis of " intelligence " antenna technology.Intelligent antenna technology in conjunction with the space-time signal processing can be used for reducing the adverse effect of input signal multipath fading and suppresses interference signal.Like this, the existing or digital radio system disposed (for example, based on the system of CDMA, based on TDMA system, wlan system and based on system such as the IEEE 802.11a/g of OFDM) performance and capacity will get a promotion.

The introducing diversity gain disturbs the multiple antenna system that designs with suppressing in the processing procedure in order to receive at signal by using, and at least some performance compromise of the wireless system of the above-mentioned type can partly be improved.Such as people such as J.H.Winters in No. 2/3/4 1740-1751 page or leaf of volume in February, 1994 " ieee communication journal " the 42nd " The Impact of Antenna Diversity On the Capacity ofWireless Communication Systems " introduction.By alleviating multipath obtaining more balanced covering, to increase received signal to noise ratio obtaining bigger distance or to reduce required transmitting power, provide better robustness with anti-interference or allow more frequency reuse to obtain bigger capacity, this diversity gain has promoted systematic function.

In combining the communication system of multiple antenna receiver, one group of M reception antenna can be eliminated M-1 interference.Therefore, can launch N signal simultaneously on same bandwidth with N transmitting antenna, then, this N one group of N the antenna that is received device that transmits is divided into N independent signal.This system is commonly referred to multiple-input, multiple-output (MIMO) system, and has obtained broad research.For example, referring to the paper " Optimum combiningfor indoor radio systems with multiple users " of J.H Winters at No. 11, COM-35 volume " ieee communication journal " in November, 1987; People such as C.Chuan are in " Global Communications System association ' 98 in November, 1998, Australia, Sydney, IEEE 1998 " paper " Capacity of Multi-Antenna Array Systems In Indoor WirelessEnvironment " of 1894-1899 page or leaf; People such as D.Shiu are at the paper " Fading Correlation and Its Effect on the Capacity ofMulti-Element Antenna Systems " of No. 3 502-513 pages or leaves of " ieee communication journal " 48 volumes March in 2000.

Some multi-antenna arrays (as MIMO) are for system has increased capacity, and this can realize by using configuration above-mentioned.In the mimo system, under the hypothesis that the ideal of receiver applicable channel is estimated, received signal decomposes the independent channel of M " spatial reuse ".Capacity is increased, is equivalent to M times of a single aerial system.Under the prerequisite that total transmitting power is fixed, capacity that MIMO provides and the linear ratio of the number of antenna element.Particularly, confirm: in total bandwidth with under the situation that always transmitting power does not increase, the data rate with N emission and N reception antenna can be N a times of a single aerial system.For example, referring to people such as G.J.Foschini on No. 3 311-335 page or leaf of " wireless personal communications " the 6th volume in the March, 1998 that Kluwer Academic Publishers publishes " On Limits ofWireless Communications in a Fading Environment When Using MultipleAntennas ".In experimental mimo system, on given reflector or receiver, use usually to surpass N antenna based on N times of spatial reuse.Because each extra antenna all increases diversity gain and antenna gain, suppress to be applicable to all N spatial reuse signal and disturb.Referring to " the Simplified processing for highspectral efficiency wireless communication employing multi-elementarrays " of people such as G.J.Foschini at IEEE Journal on Selected Areas in Communications 11 phase, 17 volume 1841-1852 pages or leaves November in 1999.

Though the number that increases emission and/or reception antenna has strengthened many-sided performance of mimo system,, each provides independently that the RF link makes the cost increase for transmitting and receiving antenna.Usually each RF link comprises low noise amplifier, filter, low-converter and analog-digital converter (A/D), and wherein, back three has occupied the major part of RF link cost.In some existing single-antenna wireless receivers, the cost of required single RF link surpasses 30% of receiver total cost.Obviously, increase along with transmitting and receiving antenna, total system cost and power consumption will increase significantly.

The method that has at present found some to handle above-mentioned defective, as U.S. Patent Publication No. be 20020102950, name is called " Method and apparatus for selection and use ofoptimal antennas in wireless systems "; People such as A.Molisch are in IEEE ICC association in June calendar year 2001, Finland, Helsinki, " the Capacity of MIMOSystems with antenna selection " of 2 volume 570-574 pages or leaves; And people such as R.S.Blum is at " the Onoptimum MIMO with antenna selection " of the 6th volume the 8th phase 322-324 page or leaf in " IEEECommunications Letters " August in 2002, wherein, from numerous antennas, select the subclass of transmit/receive antenna.Because have N spatial reuse doubly, thus N RF link will be used at least, typically, N antenna of selection and/or from reflector n altogether M antenna altogether from receiver _TSelect N antenna, wherein M＞N and n in the individual antenna _T＞N.

Performance with system of day line options depends on the standard of using in the selection course.The standard difference of using even also may cause the antenna subset difference selected under identical channel condition, thereby causes the performance difference.Part document above-mentioned advocates to use the Standard Selection antenna subset of maximum capacity.But capacity is a desired quantity, and this desired quantity may be to be beyond one's reach, because she needs perfectly coding and/or balanced and/or continuous modulation.In fact, being limited coding (perhaps even not coding) and quantizing to modulate of use, and equalizer is not desirable.

Summary of the invention

The system and method that provides channel-adaptive antenna to select in many antenna elements communication system is provided in aspects more of the present invention.

According to the present invention among some aspects embodiment, from reflector with M antenna element or receiver, select the system of N antenna with M antenna element, wherein N is less than M, this system comprises: for example, M antenna element, the N RF link in M antenna element reflector or M the antenna element receiver, be connected in the switch of this N RF link.Described M antenna element receiver is that each possible N antenna element subclass is calculated output error rate in this M antenna element.Each output error rate all calculates based at least one group of channel parameter statistics.This M antenna element receiver is according to the specific N antenna element subclass of Standard Selection based on the output error rate that calculated.As to the response based on the specific N antenna element subclass of described Standard Selection, described switch is connected to N RF link on the N antenna element of this specific N antenna element subclass.

According to the present invention among another embodiment of some aspects, the method that the subclass of the reception antenna of selective reception device receives institute's RF signals transmitted comprises, for example, and with the next item down or multinomial: the possible subclass of setting up reception antenna; Determine possible subclass channel parameter corresponding statistics with described reception antenna; Calculate the output error rate of receiver, each output error rate all calculates based at least one group of channel parameter statistics; According to specific possible subclass based on the Standard Selection reception antenna of the output error rate that calculated; One or more RF links of receiver are connected on the reception antenna of selected specific possible subclass.

According to the present invention among another embodiment of some aspects, the subclass of the transmitting antenna of selection reflector is with the method for transmitting RF input signal, the RF input signal of wherein being launched is as a plurality of output RF signals that are received by the receiver subsequently, described method comprises, for example, with the next item down or multinomial: the possible subclass of setting up transmitting antenna; Determine possible subclass channel parameter corresponding statistics group with described transmitting antenna; Select to add up corresponding emission mode with each group channel parameter respectively; Calculate the output error rate of receiver, each output error rate all calculates based at least one group of channel parameter statistics and at least a selected emission mode; According at least based on the specific possible subclass of the Standard Selection transmitting antenna of the output error rate that calculated; One or more RF links of reflector are connected on the transmitting antenna of selected specific possible subclass.

According to the present invention among another embodiment of some aspects, a kind of method of selecting antenna in the communication system that comprises reflector and receiver is provided, described reflector comprises transmitting antenna, and this transmitting antenna uses the RF output signal of two or more RF transmitting chains by one group of spatial reuse of channels transmit.Described receiver comprises reception antenna, and this reception antenna is used to receive the RF output signal of this group spatial reuse and correspondingly generates one group through the reception RF of the spatial reuse of two or more RF link processing signal.Described method comprises with the next item down or multinomial: set up the possible subclass of this transmitting antenna and the possible subclass of this reception antenna; Determine that the channel parameter of the various combinations of one of one of possible subclass corresponding to this transmitting antenna and possible subclass of this reception antenna adds up; Select to add up corresponding emission mode with various channel parameters respectively; Calculate the output error rate of receiver, each output error rate all calculates based at least one group of channel parameter statistics and selected corresponding emission mode; According at least based on the specific possible subclass of the Standard Selection transmitting antenna of the output error rate that calculated and the specific possible subclass of reception antenna; Described two or more RF transmitting chains are connected on the possible subclass of selected specific transmitting antenna; Two or more RF are received on the possible subclass that links are connected to selected specific reception antenna.

Among another embodiment of some aspects, provide a kind of method of in the communication system that comprises reflector and receiver, selecting antenna according to the present invention.Described reflector comprises transmitting antenna, and this transmitting antenna uses one or more RF transmitting chains by one group of RF output signal of channels transmit.Described receiver comprises reception antenna, and this reception antenna is used to receive this group RF output signal and correspondingly generates one group of reception RF signal that receives link processing through one or more RF.Described method comprises with the next item down or multinomial: set up the possible subclass of this transmitting antenna and the possible subclass of this reception antenna; Determine to add up corresponding to the channel parameter of the various combinations of the possible subclass of possible the subclass of this transmitting antenna and this reception antenna; Select to add up corresponding emission mode with various channel parameters respectively; Calculate the output error rate of receiver, each output error rate all calculates based at least one group of channel parameter statistics and selected corresponding emission mode; According at least based on the specific possible subclass of the Standard Selection transmitting antenna of the output error rate that calculated and the specific possible subclass of reception antenna; Described one or more RF transmitting chains are connected on the possible subclass of selected specific transmitting antenna; Described one or more RF are received on the possible subclass that links are connected to selected specific reception antenna.

By following description and accompanying drawing, can more in depth understand the details of various advantage of the present invention, various characteristics various aspects and embodiment.Wherein, same Reference numeral is used to represent identical or similar parts in each width of cloth accompanying drawing.

Description of drawings

Figure 1A and Figure 1B are the schematic diagrames of the mimo system of routine;

Fig. 2 A and Fig. 2 B are the schematic diagrames of the mimo system of some aspects according to the present invention;

Fig. 3 is the schematic diagram of the SM-MIMO-OFDM system of some aspects according to the present invention;

Fig. 4 A and Fig. 4 B are the flow charts that day line options is carried out in some aspects according to the present invention;

Fig. 5 is the schematic diagram of the performance change that some aspects cause according to the present invention;

Fig. 6 is the schematic diagram of the SC-MIMO-OFDM system of some aspects according to the present invention;

Fig. 7 is the schematic diagram of the receiver in the DS-SS SIMO system of some aspects according to the present invention.

Embodiment

One, general introduction

Some embodiment of some aspects of the present invention relate to the communication system of using reflector and/or receiver with a plurality of antenna elements.

The method and system that provides channel-adaptive antenna to select in many antenna elements communication system is provided some embodiment of some aspects of the present invention.

Implement some embodiment of some aspects of the present invention, help in one or more multi-antenna wireless communication equipment, to select the antenna element subclass according to the standard based on the output error rate that calculated at least in part.

Implement some embodiment of some aspects of the present invention, help in one or more multi-antenna wireless communication equipment, to select the subclass of antenna element, thereby the error rate (BER) is minimized or optimization.

Implement some embodiment of some aspects of the present invention, help according at least in part based on the standard of the output error rate that calculated channel-select adaptively antenna element subclass in one or more multi-antenna wireless communication equipment.

Implement some embodiment of some aspects of the present invention, can use than the more antenna element of radio frequency (RF) link number.Some embodiment of some aspects of the present invention have improved systematic function to have cost-benefit mode.

Can use subclass that some embodiment of some aspects of the present invention select antenna element in many antenna emitters with the subclass that transmits and/or select antenna element in the multiple antenna receiver with received signal.

Among some embodiment of some aspects of the present invention, at least in part according to the subclass of selecting antenna element at least in part based on the standard of the output error rate that calculated.

Among some embodiment of some aspects of the present invention, select the subclass of antenna element at least in part based on minimum bit-error rate.

Some embodiment of some aspects of the present invention are applicable to use, for example, and the communication system of CDMA signals, spread-spectrum signal, single-carrier signal, multi-carrier signal, orthogonal frequency-division multiplex singal and ultra-broadband signal, space-time diversity signal and spatial reuse signal.

Among some embodiment of some aspects of the present invention, at least in part according to the subclass of selecting antenna element based on the minimum bit-error rate of the parameter relevant (for example statistical parameter) with one or more communication channels.Among some embodiment of some aspects of the present invention, the minimum bit-error rate that calculates based on the parametric statistics according to one or more suitable communication channels is selected the subclass of antenna element at least in part.

Some embodiment of some aspects of the present invention are used in multiple-input, multiple-output (MIMO) communication system and select antenna.For example, the MIMO communication system provides reflector, and this reflector is by N transmission antenna unit broadcasting a plurality of (N) spatial reuse signal, and this N antenna element is from one group of n _TChoose in the individual antenna element, wherein n _T＞N.For example, the MIMO communication system provides receiver, M antenna element altogether in this receiver, and from wherein selecting N reception antenna unit, M＞N wherein, the output signal number of this N reception antenna unit generation equals the number of spatial reuse signal.This output signal is provided for corresponding RF link to handle in base band then.Like this, some embodiment of some aspects of the present invention help making BER to minimize (for example, channel-adaptive BER minimizes) and/or reduce RF Signal Processing cost in the multiaerial system.

Some embodiment of some aspects provide a kind of reflector according to the present invention, and this reflector comprises the transmitting antenna of one or more RF links and specific quantity, and wherein, the quantity of RF link is equal to or less than the quantity of transmitting antenna.Some embodiment of some aspects provide a kind of system and/or method according to the present invention, for example, select the subclass of specific a plurality of transmitting antennas, selecteed antenna subset transmitting RF input signal, institute's RF signals transmitted is received by receiver as a plurality of RF output signals subsequently.Set up specific a plurality of transmitting antennas a plurality of may subclass (for example, its number is equal to or less than the number of the possible subclass of the transmitting antenna that comprises specific quantity or other types combined characteristic).Determine many groups channel parameter statistics or other parameters corresponding to the possible subclass of these specific a plurality of transmitting antennas.Select the emission mode corresponding or the pattern of other types with corresponding channel parameter statistics.Described emission mode comprises, for example, and modulation level and/or encoding rate.For example, calculate a plurality of BER (as output BER) of receiver.Wherein, each output BER calculates based on one group of channel parameter statistics and/or corresponding selected emission mode at least in part.For example, the possible subclass of specific a plurality of transmitting antennas can be based on fixed standard is selected according to exporting BER and/or selected emission mode at least in part.Then, one or more RF links are connected on the described transmitting antenna or in specific a plurality of transmitting antenna on the selecteed transmitting antenna that may subclass.

Some embodiment of some aspects provide channel parameter statistics according to the present invention, and it comprises, first-order statistics, second-order statistics and higher order statistical more.Channel parameter statistics comprises following one or multinomial: for example, and the Euclidean distance (Euclidean distance) of the output signal-to-noise ratio of receiver, output signal and interference and noise ratio, likelihood ratio (for example log-likelihood), ensemble.For example, the channel parameter statistics can be calculated on frequency domain or time domain.

Some embodiment of the antenna selecting method of some aspects can be used in the dissimilar multiple antenna communications according to the present invention.In certain embodiments, some embodiment of the antenna selecting method of some aspects according to the present invention can be applied to single channel (SC) system (as, the system that does not have spatial reuse) in the multiple antenna receiver, is applied in many antenna emitters of single-channel system or is applied in the reflector and/or receiver of multiplexing (SM) of usage space or single-channel mimo system.

For example, some embodiment of some aspects according to the present invention, (wherein M＞N), for example, when considering that multiple channel parameter is added up, the subclass of selected antenna element minimizes BER to choose N reception antenna unit from one group of M available antenna element.Implementation procedure is as follows: at first set up the possible subclass of a plurality of transmitting antennas and the possible subclass of M reception antenna.This method comprises that also many groups channel parameter of the various combinations of one of possible subclass of one of possible the subclass determined corresponding to transmitting antenna and reception antenna adds up.Select to add up corresponding a plurality of emission modes with described many group channel parameters respectively.In addition, calculate a plurality of output error rates of receiver at least in part based on a pattern in one group of parametric statistics in described many group channel parameters statistics and the corresponding a plurality of emission modes.Then, select a possibility subclass of a plurality of transmitting antennas and a possibility subclass of a plurality of reception antennas based on certain standard, wherein, this standard is determined according to described a plurality of output error rates and a plurality of emission mode at least in part.This method also comprises: with one or more RF transmitting chains be connected to a plurality of transmitting antennas described one may subclass and with one or more RF receive links be connected to a plurality of reception antennas described one may subclass on.

Some embodiment of some aspects provide a kind of standard according to the present invention, for example, this standard is based on the next item down or multinomial: the maximum of the data rate on the minimum value of output error rate, emission mode, output error rate, the maximum of data rate, the receiver first order and the minimum value of the output error rate on the receiver second level.

When single channel or spatial multiplexing MIMO system use under the situation of a plurality of RF links at transmitting terminal and/or receiving terminal, the base band weighted sum assembled scheme of determining can be combined with antenna selecting method, be applied to together in reflector (as precoding) and/or the receiver.For example, base band weighted sum sky line options is designed so that all BER minimizes.In another embodiment, for example, make the minimized while of BER, the base band weighting can be designed so that output signal-to-noise ratio (SNR), signal and interference and noise ratio (SINR) or maximum capacity by suitable sky line options.

Some embodiment of some aspects relate to and are used for multiaerial system according to the present invention, comprise in the multiaerial system as N times of spatial reuse, based on the channel-adaptive approach and/or the system that minimize BER selection antenna.In order to make some embodiment easy to understand of some aspects according to the present invention, be provided in multiaerial system, realizing the overview of the typical framework of day line options below.Subsequently, also provide and carry out other relevant details of system and method for channel-adaptive day line options based on minimizing BER.

Two, the framework that is used for day line options

Some embodiment of some aspects can be used in the wireless communication system according to the present invention, and in this wireless communication system, the RF link number that reflector and/or receiver use is less than the number of the transmit/receive antenna of use.In the embodiment of some aspect some, from selecting N reception antenna unit, wherein M＞N M reception antenna unit altogether according to the present invention.Generate N RF output signal like this, then, this N RF output signal is by N RF link.In a typical embodiment, each RF link comprises, for example filter, down-converter and A/D converter.Then, the output signal of the A/D converter of each RF link generation is by the output signal of digital processing with N spatial reuse of generation.By carry out the selection of essential antenna subset at RF, have reception antenna, but have only the cost of realization cost and system of N times of space multiplexing system of N RF link to be similar to N reception antenna more than N.Therefore, under relatively low cost by using extra antenna can promote the receiver performance.

N RF link and n can be had _TUse similar techniques on the reflector of individual transmitting antenna, wherein n _T＞N.In one embodiment, switch and then behind this N the RF link, this switch is connected to each RF link from n _TOn the subclass of the N that chooses in an individual transmitting antenna transmitting antenna.With the same in receiver, by carry out the selection of the subclass of essential antenna at RF, have transmitting antenna, but have only the cost of realization cost and system of system of N times of spatial reuse of N RF link to be similar to N transmitting antenna and N RF link more than N.Therefore, under relatively low cost by using extra antenna can promote transmitter performance.

A, spatial reuse

Some embodiment of some aspects according to the present invention, it is a kind of based on the signal emission mode that all uses a plurality of antennas on reflector and receiver that spatial reuse (SM) provides, under this pattern, can increase the bit rate of Radio Link and do not need to increase corresponding power or bandwidth consumption.When receiver and reflector all use under the situation of N antenna, the inlet flow that offers the information symbol of reflector is divided into N independently subcode stream.Spatial reuse attempt to allow each subcode stream all occupy " channel " identical in the multiple access protocol applicatory (as, time slot, frequency or coding/key sequence).In reflector, each subcode stream is added to respectively on this N transmitting antenna and propagates to receiver by multipath communication channel between two parties.Then, the receiving array of N reception antenna of receiver configuration receives compound multipath signal.On receiver, to estimating from receiving antenna array with respect to N the phase place of given subcode stream and " spatial signature " of N amplitude definition.Then, use the signal that signal processing technology receives with separation, this signal processing technology is reduced original subcode stream and is synthesized in the original incoming symbol stream.J.H.Winters is at the paper of No. 11, COM-35 volume " ieee communication journal " in November, 1987 " Optimum combining for indoor radiosystems with multiple users " in further set forth spatial reuse communication principle and exemplary systems realize.The present invention is comprehensively with reference to this paper.

The mimo system of B, routine

By considering conventional mimo system shown in Figure 1, can set forth aspects more of the present invention fully.As shown in Figure 1, mimo system 100 comprises the receiver 130 shown in the reflector 110 shown in Figure 1A and Figure 1B among Fig. 1.Reflector 110 and receiver 130 comprise that respectively number is that one group of RF transmitting chain of T and one group of RF that number is R receive link, and these RF links are configured to and transmit and receive one group of spatial reuse signal that number is N.One of in the system 100, below supposing: (i) T is greater than N, and R equals N; (ii) T equals N, and R is greater than N; Perhaps (iii) T and R all greater than N.

With reference to Figure 1A, the input signal S that will launch, this signal typically comprises the numerical chracter code stream, is separated into N independently subcode stream S by demodulation multiplexer 102 _{1,2 ..., N}Then, subcode stream S _{1,2 ..., N}Be sent to digital signal processor (DSP) 105, DSP 105 generates T output signal T _{1,2 ..., T}This T output signal T _{1,2 ..., T}Usually by with N subcode stream S _{1,2 ..., N}Generate by weighting, promptly by using T different weighted factor this N subcode stream S _{1,2 ..., N}In each subcode stream power be weighted (as, with a complex multiplication) and NT code stream of formation.Then, this NT code stream made up to form T output signal T _{1,2 ..., T}Then, use T digital-to-analog (D/A) transducer 108 with this T output signal T _{1,2 ..., T}Convert T analog signal A to _{1,2 ..., T}By signal and this T the analog signal A that in frequency mixer 112, local oscillator 114 is produced _{1,2 ..., T}Mixing is with this T analog signal A _{1,2 ..., T}Upconvert to suitable emission carrier wave RF frequency.Then, this T RF signal is (as RF _{1,2 ..., T}) by corresponding amplifier 116 amplifications and by corresponding antenna 118 emissions.

With reference now to Figure 1B,, R the reception antenna 131 that reflector 100 RF signals transmitted are installed on the receiver 130 receives.Each signal in R the signal that reception antenna 131 receives is all amplified and passes through filter 135 filtering by corresponding low noise amplifier 133.Then, utilize frequency mixer 137 that resulting filtering signal is down-converted to base band from RF, each frequency mixer all provides a local oscillation signal by local oscillator 138.Though the receiver among Figure 1B all is configured to the homostrobe device, also can use with the heterodyne receiver of intermediate frequency (IF) frequency as feature.Then, use R analog to digital (A/D) transducer 140 of one group of correspondence to convert R the baseband signal that frequency mixer 137 produces to digital signal.Then, digital signal processor 142 is with this R digital signal D _{1,2 ..., R}The weighted sum combination is to form N spatial reuse output signal S ' _{1,2 ..., N}, this N spatial reuse output signal S ' _{1,2 ..., N}Comprise the S that transmits _{1,2 ..., N}Estimation.Then, multiplexer 155 is with this N output signal S ' _{1,2 ..., N}Carry out multiplexed to produce the estimation 160 (S ') of original input signal S.

The sky line options of RF in C, the spatial reuse communication system

Referring now to Fig. 2,, Figure 2 shows that MIMO communication system 200 with reflector 210 and receiver 250, reflector 210 and receiver 250 can only use N emission/RF to receive link in configuration and realize N spatial reuse doubly, even be respectively fitted with the transmit/receive antenna more than N on reflector 210 and the receiver 250.Particularly, reflector 210 comprises one group of MT transmitting antenna 240, and receiver comprises one group of MR reception antenna 260, and in the present invention some embodiment aspect some, MT and/or MR are more than or equal to N.For example, (i) MT is greater than N, and MR equals N; (ii) MT equals N, and MR is greater than N; Or (iii) MT and MR all greater than N.

Shown in Fig. 2 A, the input signal S that will launch is separated into N independently subcode stream SS by demodulation multiplexer 202 _{1,2 ..., N}Then, Dui Ying D/A converter group 206 is with the individual independently subcode stream SS of this N _{1,2 ..., N}Convert N analog submodule code stream AS to _{1,2 ..., N}Then, local oscillator 214 provides signal for frequency mixer 212, and frequency mixer 212 is with this N analog submodule code stream AS _{1,2 ..., N}Upconvert to suitable emission carrier wave RF frequency.Then, switch 218 with N RF signal generating (as RF _{1,2 ..., N}) in each RF signal be connected on the subclass of a selected N transmission antenna unit.Switch 218 with this N RF signal (as RF _{1,2 ..., N}) be connected to N the transmitting antenna of from MT available transmission antenna 240, selecting, thus one group of N output signal obtained.Then, corresponding N amplifier 234 amplifies this N output signal, launches through N the transmitting antenna 240 that amplified output signal is selected.In another embodiment, amplifier 234 is positioned at before the switch 218.Under this configuration, only need N amplifier rather than MT; And if amplifier of each antenna configurations in this MT transmitting antenna just needs MT amplifier.Selecting N antenna is BER for the output signal that minimizes receiver.

With reference to figure 2B, MR the reception antenna 260 that N RF signal of reflector 210 emissions is set on the receiver 250 receives.Each received signal is all amplified by the low noise amplifier of correspondence (LNA) 264 in this MR received signal, and then, switch 276 is connected to N RF link to form N RF signal with the subclass of N received signal, and this N RF signal is by N corresponding filter 280.In another embodiment, low noise amplifier 264 can be positioned at after the switch 276, and like this, the sum of the LNA of use is N rather than MR; If each reception antenna all is provided with a LNA in this MR reception antenna, then need MR LNA.Then, use N frequency mixer 282 that N the overanxious signal that generates is down-converted to base band, wherein, local oscillator 284 provides carrier signal to each frequency mixer.In the embodiment of Fig. 2 B, though receiver 250 realizes that with the homostrobe device receiver 250 can realize that also described heterodyne receiver is a feature with intermediate frequency (IF) frequency with heterodyne receiver.(in fact, some any embodiment of some aspects can dispose in conjunction with homodyne configuration or heterodyne according to the present invention).One group of corresponding N A/D converter 286 converts N the baseband signal that frequency mixer 282 produces to digital signal.Digital signal processor 288 is further handled this N digital signal to form the output signal SS ' of N spatial reuse _{1,2 ..., N}, this N spatial reuse output signal SS ' _{1,2 ..., N}Be N independent subcode stream SS _{1,2 ..., N}Estimation.Then, 292 couples of these N of multiplexer output signal SS ' _{1,2 ..., N}Carry out multiplexedly to produce output signal S ', S ' is the estimation of input signal S.

In the present invention some embodiment aspect some, increase base band weighted sum combination (as " precoding ") scheme at transmitting terminal, be used in combination with following antenna selecting method.In this case, the DSP module is arranged between demodulation multiplexer 202 and the D/A converter 206, like this N independent subcode stream SS _{1,2 ..., N}Be combined to form one group of N output signal by the complex factor weighted sum.Then, Dui Ying one group of D/A converter 206 converts this N output signal to analog signal AS _{1,2 ..., N}

In the embodiment of the present invention aspect some, can be used in combination typical antenna selecting method, increase space-time code at transmitting terminal.In this case, replace demodulation multiplexer 202 with the DSP module, it handles input signal S to form one group of N output signal in the room and time territory.Then, Dui Ying one group of D/A converter 206 converts this N output signal to analog signal AS _{1,2 ..., N}Two kinds of space-time technology commonly used are: 1) introduce time delay (or being equivalent to phase deviation) in the one or more output signals in N output signal; 2) use transmit diversity techniques, this technology has relevant the elaboration at the 8th phase the 16th volume 1451-1458 page or leaf in " IEEE Journal on Selected Areasin Communications " October in 1998 in the paper that S.M.Alamouti writes " A Simple transmit diversity technique for wirelesscommunications ".The present invention is in full with reference to this paper.

For example, the space-time code technology is applicable to the SC mimo system and/or for obtaining the diversity gain designed system.Precoding technique is applicable to based on SC or based on the mimo system of spatial reuse or for obtaining data rate and diversity gain designed system.

Three, carry out in RF band based on minimum bit-error rate

The method and/or the system of channel self-adapting sky line options

A, general introduction

Some embodiment of some aspects relate to the method and/or the channel-adaptive antenna selective system of carrying out channel-adaptively selected antenna in multiple antenna communication based on minimum error rates according to the present invention.For example, some embodiment of some aspects according to the present invention in the communication system of many antennas, select the subclass of antenna element to launch and/or received signal, so that minimum bit-error rate.For example, some embodiment of some aspects according to the present invention in the communication system of many antennas, select the subclass of antenna element to launch and/or received signal, exist under the situation of variation with the one or more suitable communication channels of box lunch, the error rate was minimized in the whole time period.When using a plurality of antennas to launch, can use some embodiment of some aspects according to the present invention to select the antenna of reflector.When using a plurality of antennas to receive, can use some embodiment of some aspects according to the present invention to come the antenna of selective reception device.

For example, some embodiment of some aspects are applicable to according to the present invention: the receiver that (i) uses a plurality of antennas in being called single-channel system (as not adopting the system of spatial reuse); (ii) in single-channel system, use the reflector of a plurality of antennas; (iii) the RF link that reflector and/or receiver use in spatial reuse or single-channel mimo system is less than the system of emission and/or reception antenna.

Below with reference to Fig. 3 to Fig. 7, in following typical range the present invention some embodiment aspect some are set forth: 1) have the mimo system of spatial reuse, wherein the RF quantity of links used of reflector and receiver is less than the number of emitter/receiver antenna; 2) do not have the single channel mimo system of spatial reuse, wherein the RF quantity of links used of reflector and receiver is less than the number of emitter/receiver antenna; With 3) do not have the single channel SIMO system of spatial reuse, comprising the receiver that uses a plurality of antenna elements.The single channel (SC) that some embodiment of some aspects also can be used for not having spatial reuse according to the present invention goes into singly (MISO) system more, and wherein reflector uses a plurality of antenna elements.

As example, the following examples are to set forth to the system that uses OFDM modulation (OFDM) (as following the 802.1-1a wlan standard) or based on the system of direct sequence spread spectrum (DS-SS) (as following the WCDMA standard).Some embodiment of some aspects according to the present invention, by in conjunction with space-time Rake receiver, the processing capacity of DS-SS receiver can expand to spatial domain, and space-time Rake (rake formula) receiver can make up the multipath " tap (taps) " corresponding to time-domain and spatial domain effectively.This expansion shows that technology described here can be generalized to the system that any service time under the frequency selective fading environment in the reality and/or frequency domain are handled.

Sky line options in B, the SM-MIMO-OFDM system

Some embodiment of some aspects according to the present invention that shown in Figure 3 is use the reflector and the receiver architecture of the SM-MIMOOFDM system 300 of day line options.As shown in the figure, two independently subcode stream 304 (as the spatial reuse signal) OFDM be modulated on Nt the frequency subcarriers, and by two RF links 308, for emission is prepared.In this, switch module 312 is selected two antenna elements and these two antenna elements is connected on two RF links 308 from 4 transmission antenna unit 316.Because 4 antenna elements 316 of reflector 302 have only two selected, so the number of RF transmitting chain reduces to the number of spatial reuse signal easily.

In the embodiment shown in fig. 3, at any given time, switch module 312 all comprises antenna element that identification will be used to launch to 316 information.Switch module 312 itself can be according to calculate this information (as being under the situation of interchangeable (reciprocal) at channel 318) based on the algorithm of minimum BER standard.In another embodiment, module 312 can be by the information of feedback path (not shown) reception from receiver 330.At channel 318 is not under the situation of interchangeable (reciprocal), for example can use a kind of method in back under the limit interferences environment.

In the receiver 330, switch module 334 selects two antenna elements to be used to receive the incoming signal of reflector 302 emissions from 4 antenna elements 338.2 antennas 338 that switch module 334 will be selected are connected to two RF links 342, and these two RR links 342 are used for becoming numeric field to carry out Base-Band Processing these two conversion of signals.Then, go up at each accent (at each tone) weighting matrix 346 is applied on the signal that is received to separate and to reduce each spatial reuse signal that is launched.

In typical embodiment, deploy switch module 334 makes it calculate and select in the antenna element 338 which that antenna element is received by carrying out algorithm oneself based on minimum BER standard.When channel is not under the interchangeable situation, can further dispose module 334, which should use antenna element 316 to calculate reflector 302, and this information is offered reflector 302.Below in conjunction with Fig. 4 A and Fig. 4 B two kinds of possible sky line options algorithms being carried out by switch module 312,334 are described.

Forward among Fig. 4 A, Fig. 4 A is depicted as day flow chart of line options algorithm 400, and wherein, coded/modulated pattern (as data speed or throughput) is fixing or is adapted to long-term principle (long-termbasis) (as be applicable to SNR wide variation).The task of it line options algorithm is to determine reflector 302 for each packet should use in the antenna element 316 which should use in the antenna element 338 which to antenna element to antenna element and definite reflector 330 under given pattern.For example, in this selection course, suppose that channel 318 is accurate fixing (for example, channel 318 is constant in during the packet emission, changes independently) between two adjacent packets.Though channel 318 shows some frequency selectivities, a day line options is common for whole frequency bandwidth.

With reference to figure 4A, when reflector 302 has just started state the unknown still of (step 401) and channel 318, use the subclass emission wireless signal of one group of two antenna element of acquiescence in the antenna element 316.Similarly, receiver 330 uses the subclass of one group of two antenna element of acquiescence in the antenna element 338 to obtain synchronously.Then, obtain channel condition information (CSI) (step 402) .In the embodiment of some aspect some, obtain the operation of CSI and carry out by receiver 330 according to the present invention.The training sequence of being made up of known symbol sends to receiver 330 from reflector 302.In the receiver 330, based on signal that is received and known symbol sebolic addressing estimation channel 318.Whenever channel 318 changes, all carry out this estimation operation as when each packet realizes.For this system of selection of successful execution, should in whole frequency bandwidth, the people such as carry out completely the channel matrix estimation (as, all antenna elements 338 (across all tones) on all are transferred from all antenna elements 316 of reflector 302 to receiver 330 are carried out channel path gain estimation) .J.J.Van de Beek IEEE the 45th " Vehicular TechnologyConference " 25-28 day July nineteen ninety-five the 2nd volume 815-819 page or leaf paper " On ChannelEstimation in OFDM Systems " and A.N.Mody and the paper " Synchronization for MIMO OFDM Systems " of G.L.Stuber at IEEE Globecom2001 first volume 509-513 page or leaf in set forth the channel estimating techniques based on training sequence that are applicable to mimo system. The present invention is in full with reference to these papers.

Again with reference to figure 4, by carrying out link circuit self-adapting algorithm obtaining mode information (step 404).In the embodiment shown in Fig. 4 A, patterns of change occurs slowly.Therefore can use the link circuit self-adapting algorithm to determine from long-term average SNR, which kind of possible candidate pattern is best suited for using.Under given model selection standard (as, maximum data rate and minimum transmitting power), from the channel/SNR condition of long-term change, what use that link circuit self-adapting computing standard can guarantee to use is effective patterns.The typical link circuit self-adapting algorithm that can be used in the frequency selectivity mimo system is described at No. 6 people's such as 108-115 page or leaf S.Catreux of ieee communication magazine the 40th volume June in 2002 paper " Adaptive Modulation and MIMO Coding for Broadband Wireless DataNetworks ", and the present invention is comprehensively with reference to this paper.Usually, model selection is independent of the method for selecting the emitter/receiver antenna element.The selection of pattern can be exclusively based on long-term SNR statistics.Therefore, the speed of the speed ratio sky line options of patterns of change wants slow a lot.In other words, select algorithm may realize selecting new antenna subset corresponding to each packet, the function that patterns of change then changes as long-term SNR.

Step 406,408 and 410 repeats in a looping fashion, up to the combination of the subclass of all possible transmit/receive antenna unit estimated intact (step 411).For example, consider type shown in Figure 3 the MIMO-OFDM system (as, dispose 4 transmission antenna unit 316 and 4 reception antenna unit 338), complete channel matrix can transfer k (tone k) to go up matrix notation with 4 * 4, this 4 * 4 matrix H in frequency domain _kExpression.All selected the subclass of two antennas at each end after, the size of subchannel matrix is reduced to 2 * 2 matrix, uses

Expression.From selecting the combination of 2 unit to have 4 antenna elements altogether $\left(\begin{array}{c}4\\ 2\end{array}\right)=6$ Plant the possible method of selecting.Because it line options is applied to reflector 302 and receiver 330 among both, so

The sum of possible combination be 36.Usually, the mimo system that is reduced to n * n in the size of the mimo system of M * M (under the situation of M＞n), is selected may having made up of n antenna element from M possible antenna element $\left(\begin{array}{c}M\\ n\end{array}\right)=\frac{M!}{n!(M-n)!}$ Kind.When all carrying out day line options on reflector and the receiver,

The sum of possible combination be This is corresponding to the number of times that comprises that step 406,408 and 410 circulation repeat.This repetitive process can serial mode be carried out (as reusing shared processing resource) or carry out (as spending extra processing resource) with parallel mode.In typical embodiment, can handle all possible combination of antennas simultaneously, wherein each possible combination of antennas is used and is independently handled resource.

Comprise the processing that at every turn repeats all to influence an antenna subsystem of step 406,408 and 410 circulation.At first, schedule to last the shop sign in the form of a streamer system obtain all accent (tone) go up (k=1 ..., 2 * 2 matrixes Nt)

(step 406).Then, each transfer on k and the spatial reuse calculated signals that is launched for each processing after signal and interference and noise ratio (SINR) (step 408).The signal processing technology of using based on reflector 302 and/or receiver 330 (as, maximum ratio is synthesized (MRC), Minimum Mean Square Error (MMSE), intrinsic beam forming and maximum likelihood (ML)), usually find the solution SINR with the closed form solution.For example, if reflector 302 is not carried out spatial manipulation and receiver 330 uses MMSE, SINR can followingly determine so:

Calculate $B_k={\tilde{H}}_k^H{\tilde{H}}_k+\frac{{\mathrm{\σ}}^2}{{\mathrm{\σ}}_s^2}{I}_2$ Wherein, $I_2=\left[\begin{array}{c}10\\ 01\end{array}\right],$ σ ²With σ _s ²Represent noise and signal power respectively, k=1 ..., Nt (step 408-1).

Calculate $C_k=1/\mathrm{diag}\left(B_k^{-1}\right),$ To each k=1 ..., Nt, C _KIt is the vector (step 408-2) of N * 1.

Calculate ${\mathrm{SINR}}_k=\frac{{\mathrm{\σ}}_s^2}{{\mathrm{\σ}}^2}{C}_k-1,$ To each k=1 ..., Nt, SINR _kIt is the vector of N * 1

(step 408-3).

In the step 410, consider present mode, SINR information is converted into BER information (as step 404).Because BER may be the complicated function of channel 318 and employed coded/modulated and combination of antennas technology, so adopt the approximate expression of BER.This approximate expression also can be channel 318 and the coded/modulated that is suitable for and the function of combination of antennas technology.BER in the packet of emission subcode stream i (for example, if used coding, the output of Viterbi decoder) can be expressed as one group of SINR _k, K=1 ..., the nonlinear unknown function f of Nt, as:

$\stackrel{\‾}{{\mathrm{BER}}_i}=f\left(\right\{{\mathrm{SINR}}_k^i\left\}\right),i=1,...,N;k=i,...,N_t$

Then, with some known function approximate representation function f.Particularly, with the average error rate approximate representation output BER of channel, as:

$\stackrel{\‾}{{\mathrm{BER}}_t}\≈1/N_t\underset{k=1}{\overset{N_t}{\mathrm{\Σ}}}{\mathrm{BER}}_k^i---\left(1\right)$

BER wherein _k ⁱBe that spatial reuse subcode stream i is transferring the error rate under the given SINR on the k.In another embodiment, BER _kBe to transfer the error rate under the given signal to noise ratio (snr) on the k.Work as BER _kBe on channel time sampling k, during the error rate under the given SINR, also can in time-domain, average.BER _kIt can be the error rate corresponding to given signal component (transferring or control lag) as channel.

In addition, also can represent BER with some simple closed form approximations to function _kThe pattern 1 (as BPSK, R1/2) of finding to simulate 802.1-1a by emulation down and SINR or SNR (in certain embodiments, can ignore BER normalization factor 1/Nt, because this factor does not influence a day line options) behavior of relevant average error rate BER, for example: by

$\stackrel{\‾}{\mathrm{BER}}\≈-\underset{k=1}{\overset{N_t}{\mathrm{\Σ}}}\tanh \left({\mathrm{SINR}}_k^i\right);i=1,...,N---\left(2\right)$

Available-tanh (SINR _k) BER of approximate representation signal component k.

Function tanh always can not represent BER by sufficient approximation, particularly for different modulation techniques.When using specific technology, available following function is approximate representation BER better:

1) under the awgn channel BER of uncoded BPSK modulation be (for example referring to J.G.Proakis, Digital Communications, 3 ^RdED.McGraw-Hill Series, 1995):

${\mathrm{BER}}_{\mathrm{BPSK}}=Q\left(\sqrt{\frac{{2E}_b}{N_o}}\right)=Q\left(\sqrt{{2\mathrm{\γ}}_b}\right)=\frac{1}{2}\mathrm{erfc}\left(\sqrt{{\mathrm{\γ}}_b}\right)=\frac{1}{2}\mathrm{erfc}\left(\sqrt{{\mathrm{\γ}}_s}\right)$

Function below available (comparing with y=-tanh (x)) is the form of approximate representation Function e rfc moderately:

$y=-[(1-e^{-2\sqrt{x}})+(1-e^{-1.8x})]$

2) under the awgn channel BER of uncoded QPSK modulation be (for example referring to J.G.Proakis, Digital Communications, 3 ^RdED.McGraw-Hill Series, 1995)

${\mathrm{BER}}_{\mathrm{QPSK}}=Q\left(\sqrt{\frac{{2E}_b}{N_o}}\right)=Q\left(\sqrt{2{\mathrm{\γ}}_b}\right)=\frac{1}{2}\mathrm{erfc}\left(\sqrt{{\mathrm{\γ}}_b}\right)=\frac{1}{2}\mathrm{erfc}\left(\sqrt{\frac{{\mathrm{\γ}}_s}{2}}\right).$

Function below available comes the approximate representation better than y=-tanh (x) Form:

$y=-[(1-e^{-1.3\sqrt{x}})+(1-e^{-x})]$

3) BER of uncoded 16QAM modulation can derive from given symbol error rate under the awgn channel, for example from J.G.Proakis, and Digital Communications, 3 ^RdED.McGraw-Hill Series, symbol error rate given in 1995 is derived:

${\mathrm{BER}}_{16\mathrm{QAM}}=1-\sqrt{1-\frac{3}{2}Q\left(\sqrt{\frac{{3E}_s}{15N_o}}\right)}=1-\sqrt{1-\frac{3}{4}\mathrm{erfc}\left(\frac{{\mathrm{\γ}}_s}{10}\right)}$

A suitable fitting function is y=-(1-e ^-02x).

4) BER of uncoded 64QAM modulation can derive from given symbol error rate under the awgn channel, for example from J.G.Proakis, and Digital Communications, 3 ^RdED.McGraw-Hill Series, symbol error rate given in 1995 is derived:

${\mathrm{BER}}_{64\mathrm{QAM}}=1-{(1-\frac{7}{4}Q\left(\sqrt{\frac{{\mathrm{\γ}}_s}{21}}\right))}^{1/3}=1-{(1-\frac{7}{8}\mathrm{erfc}\left(\sqrt{\frac{{\mathrm{\γ}}_s}{42}}\right))}^{1/3}$

A suitable fitting function is $y=-(1-e^{-0.35\sqrt{x}}).$

Be appreciated that any fitting function that can reasonably simulate BER and SINR relation all can be used in the equation (2).The number of the fitting function that this is suitable is not limited to above-named example.

As implied above, step 406 to step 410 repeats, up to the combination (step 411) of having considered all possible antenna subset.The result of repetitive process is to have obtained all

(or

Plant one group N the estimation (each spatial reuse signal is corresponding to an estimation) of the BER value of possible combination of antennas.Then, the back is exactly that select can be with the maximum (max) of the average (mean) of this group BER, this group BER minimized antenna subset (step 412) of minimum value (min) of this group BER maybe.

Fig. 4 B is day flow chart of line options algorithm 500, wherein, the respective change of responsive channels 318, the number of times that the coded/modulated pattern changes is identical with the number of times that every packet realizes.In this embodiment, the frequency of coded/modulated mode adjustment is identical with the frequency that day line options realizes.

With reference to figure 4B, step 501 is similar with 402 to step 401 respectively with 502.As shown in the figure, step 504 comprises a circulation to step 510, and this circulation repeats have been estimated up to the combination of all possible antenna subsets and to finish.The number of times that this circulation repeats equals (end at link is selected) or

(two ends at link are all selected).Relevant this point, step 504 is similar with 408 to step 406 respectively with 506.Based on the understanding of the instantaneous SINR that all are transferred, link adaptation module (as data rate and minimum transmitting power of maximum) under given model selection standard be the definite effective patterns (step 508) of each spatial reuse signal.This step is similar to step 404, and pattern that different is is determined to be based on instantaneous SNR (or SINR) statistics rather than added up based on long-term SNR (or SINR).Therefore, the combination of different antenna subsets may obtain different patterns and determines.At last, under given instantaneous SINR and pattern information, the BER of correspondence is calculated or determined to step 510 in the mode described in the step 410.

Again, execution in step 504 to step 510 has been considered finish (step 511) up to all possible combination of antennas.In case repeat finish after, obtain all (or Plant one group N the estimation (as the corresponding estimation of each spatial reuse signal) of the BER value of possible combination of antennas.Select the algorithm 500 and the difference of algorithm 400 to be

(or Plant possible combination of antennas and need not to use identical coded/modulated pattern.Therefore, select which antenna subset not only to depend on minimizing of BER, also depend on pattern (as data speed or throughput).According to the step of selecting in the algorithm 500 512, in that to select the antenna element subclass to make final when determining, following several exemplary options is arranged:

Option one

1) will use all combinations of the antenna subset of model identical to be grouped into public storage pool (common pool).

2) select and the corresponding storage pool (pool) of height mode (obtaining maximum fast) according to speed.

3) in this storage pool, use to the fully similar mode of step 412 and select combination the minimized antenna subset of BER.

Option 2

Do not consider the pattern that each is used in combination, use to the fully similar mode of step 412 and select combination the minimized antenna subset of BER.

Option 3

Carry out the mixing version of option one and option 2, for example:

1) will use all combinations of the antenna subset of model identical to be grouped into public storage pool.

2) select and X X corresponding storage pool of height mode (obtaining maximum fast according to speed), wherein, X is an integer, equals 1 or 2 or 3, etc.

3) in these storage pools, use to the fully similar mode of step 412 and select combination the minimized antenna subset of BER.

Figure 5 shows that in the SM-MIMO-OFDM system under the noise limit environment adopt typical day line options technology after, as the schematic diagram of the packet-error-rate (PER) of SNR function.For example, the result of Fig. 5 can be applied to exemplary approach shown in Figure 3 and use in 4 systems that transmit and receive antenna.The result has only reflected the packet of 1000 byte-sized in some examples and the situation of the coded/modulated pattern of fixing.This result has reflected that also reflector applicatory and receiver all combine two typical R F links.In addition, to use BPSK modulation, encoding rate be that 1/2 (as the pattern 1 of 802.11a), channel model are characterized as " channel A " (as the delay expansion of 50ns rms, Antenna Correlation of 0.5) and fitting function is tanh to the result of Fig. 5.

The legend of the curve among Fig. 5 is as follows:

2 * 22SM-MIMO MMSE: this system is corresponding to using 2 transmitting antennas and 2 reception antennas, the SM-MIMO-OFDM system of 2 spatial reuses (SM) signal being arranged.Because the number of antenna equals the number of SM signal, so do not use a day line options.Use the baseband bank scheme to separate 2 subcode streams in the receiver, as MMSE.

4 * 42SM-MIMO sel mcap MMSE: this system is corresponding to using 4 transmission antenna unit and 4 reception antenna unit, the SM-MIMO-OFDM system of 2 spatial reuses (SM) signal being arranged.All use conventional system of selection on reflector and the receiver in 4 antenna elements, to select the subclass of 2 antenna elements according to the heap(ed) capacity standard.After selecting antenna subset on the receiver, MMSE is applied in the base band to separate 2 subcode streams.

2 * 42SM-MIMO sel mber MMSE (bound): this system is corresponding to using 2 transmission antenna unit and 4 reception antenna unit, the SM-MIMO-OFDM system of 2 spatial reuses (SM) signal being arranged.Only at selective method for application on the receiving terminal in 4 antenna elements, to select the subclass of 2 antenna elements according to minimum BER standard.In this case, use the plan total function to come approximate representation BER.As an alternative, suppose and know BER fully.This situation is not easy to realize, but the scope of the performance that some embodiment of some aspects of the application of the invention can reach is provided.

4 * 4 2SM-MIMO sel mber MMSE (bound): this system is corresponding to using 4 transmission antenna unit and 4 reception antenna unit, the SM-MIMO-OFDM system of 2 spatial reuses (SM) signal being arranged.On transmitting terminal and the receiving terminal all selective method for application in 4 antenna elements, to select the subclass of 2 antenna elements according to minimum BER standard.In this case, do not use fitting function to come approximate representation BER.As an alternative, suppose and know BER fully.This situation is not easy to realize, but the scope of the performance that some embodiment of some aspects of the application of the invention can reach is provided.

4 * 42SM-MIMO sel mber MMSE (implementation tanh): this system is corresponding to using 4 transmission antenna unit and 4 reception antenna unit, the SM-MIMO-OFDM system of 2 spatial reuses (SM) signal being arranged.On transmitting terminal and receiving terminal, all use system of selection according to some embodiments of the invention, in 4 antenna elements, to select the subclass of 2 antenna elements according to minimum BER standard.Use the fitting function of tanh as approximate representation BER.

The result of Fig. 5 shows, with respect to the system that does not use day line options, the system of the sky line options of all some types of use provides gain, has shown that also the sky line options based on minimum BER standard can provide bigger gain than the sky line options based on the heap(ed) capacity standard.Particularly, with respect to the system that does not use day line options, all used the gain that on the PER of 10e-2 level, obtains 7.6dB according to the system of of the present invention day line options at reflector and receiver; With respect to the system that uses based on the sky line options of heap(ed) capacity standard, all used the gain that on the PER of 10e-2 level, obtains 4.2dB according to the system of of the present invention day line options at reflector and receiver.Can observe, only on receiver, use the gain that the system of selection of the embodiment of some aspect some according to the present invention obtains, less than in reflector and the receiver gain that all selective method for application obtained, but greater than the gain of not using system of selection.At last, the very approaching theoretic performance range shown in Figure 5 of the performance of the system of some embodiment of some aspects according to the present invention.

The sky line options of C, SC-MIMO-OFDM system

Shown in Figure 6 is SC-MIMO-OFDM system 600, and this system also uses precoding technique except that the antenna selecting method that uses according to some embodiments of the invention.In the embodiment of Fig. 6, precoding relates to the various base band weighted sum assembled schemes of carrying out on the reflector 602.With reference to figure 6, to generate one group of N output signal, wherein the number of the RF link 612 of use is relevant in N and the reflector 602 by the combination of one group of composite factor 608 weighted sum for single bit stream symbol 604.Then, this N output signal is passed through N RF link 612 to produce N RF signal.Then, this N RF signal is connected in M the transmission antenna unit 616 corresponding one group of N transmission antenna unit by switch 620 and by channel 624 emissions.

In the receiver 622, the signal that switch 630 selects N reception antenna unit to come in by channel 624 with reception from M reception antenna unit 626.Then, this N RF received signal handled by N RF link 634, and converts numeric field to the reduction original transmitted signal for carrying out Base-Band Processing.

For example, some embodiment of some aspects according to the present invention are designed into base band weighting 608 and antenna selecting method together, jointly BER is minimized.For example, among some embodiment of some aspects, select base band weighting 608 to maximize output SNR (or SINR) or capacity, implement day line options simultaneously to minimize BER according to the present invention.With the corresponding subchannel matrix of maximum singular value (singular value) Right singular vector and the subclass of the left singular vector subclass that can be used for selecting best transmitting antenna 616, reception antenna 626 and suitable transmitting baseband weighting 608 and receive base band weighting 640.J.B.Andersen is in No. 2 13-16 page or leaf of " IEEE Antennas and Propagation Magazine " the 42nd volume April in 2000, to do not adopt base band weighted value in day line options mimo system scope determine be described, the present invention is in full with reference to this article.

Embodiment shown in Figure 6 is revised in the base band weighting 608 that available space-time code module replaces in the reflector 602.In this case, according to some embodiments of the invention, all use antenna selecting method to select antenna subset on reflector and the receiver.In addition, the input code flow of space-time code resume module symbol is rolled up described in " the A simple transmit diversitytechnique for wireless communications " of 1451-1458 page or leaf in the 8th phase the 16th of " IEEE Journal on Selected Areas in Communications " October in 1998 as S.M.Alamouti.

The sky line options of D, DS-SS-SIMO system

Fig. 7 is 2 the reception antenna unit 704 (n that have of DS-SS SIMO system _RThe schematic diagram of receiver 700=2).Receiver 700 combines RAKE receiver function and typical day line options is handled.As shown in the figure, receiver 700 only is provided with single RF link 708, and at any time down, switch 712 is connected to a antenna element in two reception antenna unit 704 with this RF link 708.Determine to select which antenna element in two antenna elements 704 to be connected based on minimum BER standard with RF link 708.According to the present invention among some embodiment of some aspects, calculate the BER value of the received signal corresponding, the antenna element 704 of the minimum BER value of selection acquisition with each reception antenna unit 704.Because the function of the coded/modulated of BER channel normally applicatory and use and the complexity of combination of antennas technology, given channel and combination of antennas technology are given regularly, approximate representation BER, the variation that makes BER is the function of employed coded/modulated method.

In case select the optimal antenna in the antenna element 704, the RAKE receiver moves in identical mode in singly going into singly (SISO) system (the every end as link has an antenna).The RAKE receiver uses J correlator 720 (as J=2 among Fig. 7), and each correlator is all corresponding with an one of J independent multipath components.Each such assembly all respectively with time delay τ _JRelevant, j=1 ..., J.Then, the output of each correlator 720 (as pointer) be weighted 730 and combination 740 to form the single outputs 750 of received signal, this output 750 comprises the estimation that has transmitted.

In one embodiment, at the input of RAKE receiver, can be expressed as corresponding to the received signal of i antenna element 704:

$r_i\left(t\right)=\underset{l=1}{\overset{L_i}{\mathrm{\Σ}}}{h}_{i,l}\sqrt{2P}d(t-{\mathrm{\τ}}_{i,l})p(t-{\mathrm{\τ}}_{i,l})\cos (w_0(t-{\mathrm{\τ}}_{i,l})-{\mathrm{\θ}}_{i,l})+n_i\left(t\right)---\left(3\right)$

Wherein, L _iBe the number of the tap (tap) in the channel that receives of i antenna element 704, h _{I, l}Be antenna i and tap

Compound channel gain, P is a signal transmission power, d is the data sequence that comprises the symbol of period T, p is a sequence spreading, this sequence spreading comprises the chip of period T c=T/G, wherein G is a spreading factor.In addition, τ _{I, l}Corresponding to tap

With the path delay of antenna i, w _oCorresponding to carrier frequency, w _o=2 π f ₀, θ _{I, l}Corresponding to tap Phase shift with antenna i.The noise n that on i antenna element 704, records _iModel be N for the two ends spectral density ₀/ 2 AWGN handles.In order to be concise in expression with clear equation

(3) phantom order user environment.But the present invention is not limited to this supposition, and the present invention can be applied in the multi-user environment.

At the output of the correlator 720 of j pointer, the following expression of received signal:

$r_{i,j}=\sqrt{\frac{2}{T}}{\∫}_{{\mathrm{\τ}}_j}^{{\mathrm{\τ}}_j}{r}_i\left(t\right)p(t-{\mathrm{\τ}}_j)\cos (w_0(t-{\mathrm{\τ}}_j)-{\mathrm{\θ}}_j)\mathrm{dt}=\sqrt{\mathrm{PT}}{h}_{i,j}{d}_0+n_{i,j}---(4.)$

D wherein ₀Be the expectation symbol that will modulate, n _{I, l}Be to have 0 average and the two ends spectral density is N ₀/ 2 AWGN noise contribution.Do not have in the equation (4) in order to be concise in expression with clear, to suppose to disturb in the path equally (IPI).But the present invention also can be used for existing the environment of IPI.

After the diversity combination, the final output of the RAKE receiver corresponding with i antenna element 704 is:

$r_i=\underset{j=1}{\overset{J}{\mathrm{\Σ}}}{w}_{i,j}{r}_{i,j}---(5.)$

Wherein J is the pointer number of RAKE receiver, selects optimum combined weighted with match channels usually, as:

$w_{i,j}=h_{i,j}^{*}---(6.)$

Under this environment, RAKE carries out the combination of maximum ratio, and the SNR of corresponding with i antenna element 704 RAKE output is:

${\mathrm{\γ}}_i=\underset{j=1}{\overset{J}{\mathrm{\Σ}}}{\mathrm{\γ}}_{i,j}---(7.)$

Wherein, γ _{I, j}Be the SNR after the combination on j the path related with i antenna element 704.Based on equation (4), can represent with following formula:

${\mathrm{\γ}}_{i,j}=\frac{{\left|h_{i,j}\right|}^{2}P}{{\mathrm{\σ}}^2}---(8.)$

Wherein, ${\mathrm{\σ}}^2=\frac{N_0}{2}\·\frac{2}{T}$ It is noise power.

Can be to γ _iThe cognition of likelihood density function (PDF) in obtain the BER of the output of the RAKE receiver corresponding with i antenna element 704.For example,, used the BPSK modulation if data sequence is not used coding, as J.G.Proakis, nineteen ninety-five McGraw-Hill series, the method described in the 3rd edition " DigitalCommunications " will be by being expressed as The condition error probability be attached to γ _iLikelihood density function (PDF) in can obtain BER, as:

${\mathrm{BER}}_i={\∫}_0^{\∞}Q\left(\sqrt{{2\mathrm{\γ}}_i}\right)p_r\left({\mathrm{\γ}}_i\right)d{\mathrm{\γ}}_i---(9.)$

In case estimated the BER of all reception antennas, just selected to obtain the antenna element 704 of minimum BER:

$\underset{i=1,...n_R}{\min }\left\{{\mathrm{BER}}_i\right\}---\left(10\right)$

Wherein, n _RThe sum of expression reception antenna unit.

Obviously, when adding coding (as turbo coding, convolutional encoding) and use other modulating stages in system, being used to of using in the equation (9) estimates that the analog function of BER will need change.Among some embodiment of some aspects, typical day line options algorithm can be used the fitting function of BER behavior in any accurately simulate given system according to the present invention.Usually, fitting function depends on the next item down or multiple parameters, for example: the coding of channel, use and/signal processing, receiver SNR and other parameters of modulation, transmitting terminal and/or receiving terminal.

Typical embodiment shown in Figure 7 can expand to two-dimentional RAKE receiver, carries out the processing of spatial domain and time-domain in the two-dimentional RAKE receiver.In this scope, (M＞N), selected subclass minimizes the BER of two-dimentional RAKE output can to come to select the subclass of the individual antenna of N (N＞1) from M antenna altogether in conjunction with typical day line options algorithm.

The present invention is described by some embodiment, and those skilled in the art know, under the situation that does not break away from the spirit and scope of the present invention, can carry out various changes or equivalence replacement to these features and embodiment.In addition, under instruction of the present invention, can make amendment to these features and embodiment can not break away from the spirit and scope of the present invention to adapt to concrete situation and material.Therefore, the present invention is not subjected to the restriction of specific embodiment disclosed herein, and all interior embodiment of claim scope that fall into the application belong to protection scope of the present invention.

Claims (56)

1, the method for the RF signal that is launched with reception of a kind of subclass of reception antenna of selective reception device comprises:

Set up the possible subclass of described reception antenna;

Determine possible subclass channel parameter corresponding statistics group with described reception antenna;

Calculate the output error rate of receiver, each output error rate all calculates based at least one group of channel parameter statistics;

According to specific possible subclass based on the Standard Selection reception antenna of the output error rate that calculated;

One or more RF links of receiver are connected on the reception antenna of selected specific possible subclass.

2, method according to claim 1 also comprises:

Select emission mode, wherein, the selection of every kind of emission mode is all based at least one group of channel parameter statistics; With

Make described standard at least based on selected emission mode.

3, method according to claim 1, wherein, every group of channel parameter statistics comprises at least a in the Euclidean distance of output signal-to-noise ratio, output signal and the interference of receiver and noise ratio, log-likelihood, ensemble.

4, method according to claim 1, wherein, every group of channel parameter statistics comprises first-order statistics, second-order statistics and at least a in the higher order statistical more.

5, method according to claim 1, wherein, every group of channel parameter statistics all calculated on frequency domain.

6, method according to claim 1, wherein, every group of channel parameter statistics all calculated on time domain.

7, method according to claim 2, wherein, each selected emission mode comprises modulation level and encoding rate.

8, method according to claim 1, wherein, described standard is based on minimum output error rate.

9, method according to claim 1, wherein, described standard is based on the maximum data rate of the receiver first order and at least one in the partial minimum output error rate of receiver.

10, method according to claim 1, wherein, at least one described output error rate closed form expression formula approximate representation.

11, method according to claim 10, wherein, each output error rate closed form expression formula approximate representation.

12, method according to claim 10, wherein, it is one of following that described closed form expression formula comprises at least:

a)y＝-tanh(x)，

$b)---y=-[(1-e^{-2\sqrt{x}})+(1-e^{-1.8x})],$

$c)---y=-[(1-e^{-1.3\sqrt{x}})+(1-e^{-x})],$

D) y=-(1-e ^-0.2x), or

$e)---y=-(1-e^{-0.35\sqrt{x}}).$

13, method according to claim 10, wherein, described closed form expression formula depends on the coding of RF signals transmitted and at least one in the modulation.

14, method according to claim 10, wherein, the function of output signal-to-noise ratio that described closed form expression formula is a receiver or output signal and noise and interference ratio.

15, method according to claim 1, wherein:

The number of described reception antenna greater than the RF quantity of links and

The number of reception antenna equals the RF quantity of links in each possible subclass.

16, a kind of subclass of the transmitting antenna of selecting reflector is with the method for transmitting RF input signal, and the RF input signal of wherein being launched is as a plurality of output RF signals that received by receiver subsequently, and described method comprises:

Set up the possible subclass of transmitting antenna;

Determine possible subclass channel parameter corresponding statistics group with described transmitting antenna;

Select to add up corresponding emission mode with each group channel parameter respectively;

Calculate the output error rate of receiver, each output error rate all calculates based at least one group of channel parameter statistics and at least a selected emission mode;

According at least based on the specific possible subclass of the Standard Selection transmitting antenna of the output error rate that calculated;

One or more RF links of reflector are connected on the transmitting antenna of selected specific possible subclass.

17, method according to claim 16, wherein, every group of channel parameter statistics comprises at least a in the Euclidean distance of output signal-to-noise ratio, output signal and the interference of receiver and noise ratio, log-likelihood, ensemble.

18, method according to claim 16, wherein, every group of channel parameter statistics comprises first-order statistics, second-order statistics and at least a in the higher order statistical more.

19, method according to claim 16, wherein, every group of channel parameter statistics all calculated on frequency domain.

20, method according to claim 16, wherein, every group of channel parameter statistics all calculated on time domain.

21, method according to claim 16, wherein, each selected emission mode comprises modulation level and encoding rate.

22, method according to claim 16, wherein, described standard minimizes the output error rate of receiver.

23, method according to claim 16, wherein, described standard is based on output error rate that is calculated and selected emission mode.

24, method according to claim 16, wherein, described standard is based on the maximum data rate of the receiver first order and at least one in the partial minimum output error rate of receiver.

25, method according to claim 16, wherein, each output error rate closed form expression formula approximate representation.

26, method according to claim 25, wherein, described closed form expression formula is one of following at least:

a)y＝-tanh(x)，

$b)---y=-[(1-e^{-2\sqrt{x}})+(1-e^{-1.8x})],$

$c)---y=-[(1-e^{-1.3\sqrt{x}})+(1-e^{-x})],$

D) y=-(1-e ^-0.2x), or

$e)---y=-(1-e^{-0.35\sqrt{x}}).$

27, method according to claim 25, wherein, described closed form expression formula depends on the coding of RF output signal and at least one in the modulation.

28, method according to claim 25, wherein, the function of at least one in output signal-to-noise ratio that described closed form expression formula is a receiver or output signal and noise and the interference ratio.

29, method according to claim 1, wherein, it is one of following that the described RF signal that is launched comprises at least: CDMA signals, single-carrier signal, OFDM coding and ultra-broadband signal.

30, method according to claim 16, wherein, it is one of following that described a plurality of RF output signals comprise at least: CDMA signals, single-carrier signal, orthogonal frequency-division multiplex singal and ultra-broadband signal.

31, method according to claim 16, wherein:

The number of described transmitting antenna greater than the number of RF chain and

The number of transmitting antenna equals the number of RF chain in each possible subclass.

32, a kind of method of in the communication system that comprises reflector and receiver, selecting antenna, described reflector comprises transmitting antenna, this transmitting antenna uses the RF output signal of two or more RF transmitting chains by one group of spatial reuse of channels transmit, described receiver comprises reception antenna, this reception antenna is used to receive the RF output signal of this group spatial reuse and correspondingly generates one group through the reception RF of the spatial reuse of two or more RF link processing signal, and described method comprises:

Set up the possible subclass of described transmitting antenna and the possible subclass of described reception antenna;

Determine to add up corresponding to the channel parameter of the various combinations of the possible subclass of possible the subclass of described transmitting antenna and described reception antenna;

Select to add up corresponding emission mode with various channel parameters respectively;

Calculate the output error rate of receiver, each output error rate all calculates based at least one group of channel parameter statistics and selected corresponding emission mode;

According at least based on the specific possible subclass of the Standard Selection transmitting antenna of the output error rate that calculated and the specific possible subclass of reception antenna;

Described two or more RF transmitting chains are connected on the possible subclass of selected specific transmitting antenna;

Described two or more RF are received on the possible subclass that links are connected to selected specific reception antenna.

33, method according to claim 32, wherein, each group channel parameter statistics comprises at least a in the Euclidean distance of output signal-to-noise ratio, output signal and the interference of receiver and noise ratio, log-likelihood, ensemble.

34, method according to claim 32, wherein, every group of channel parameter statistics comprises first-order statistics, second-order statistics and at least a in the higher order statistical more.

35, method according to claim 32, wherein, every group of channel parameter statistics all calculated on frequency domain.

36, method according to claim 32, wherein, every group of channel parameter statistics all calculated on time domain.

37, method according to claim 32, wherein, each selected emission mode comprises modulation level and encoding rate.

38, method according to claim 32, wherein, described standard is based on the minimum output error rate of receiver.

39, method according to claim 32, wherein, described standard is based on output error rate that is calculated and selected emission mode.

40, method according to claim 32, wherein, described standard is based on the maximum data rate of the receiver first order and at least one in the partial minimum output error rate of receiver.

41, method according to claim 32, wherein, described output error rate is with one or more closed form expression formula approximate representations.

42, according to the described method of claim 41, wherein, it is one of following that described one or more closed form expression formulas comprise at least:

a)y＝-tanh(x)，

$b)---y=-[(1-e^{-2\sqrt{x}})+(1-e^{-1.8x})],$

$c)---y=-[(1-e^{-1.3\sqrt{x}})+(1-e^{-x})],$

D) y=-(1-e ^-0.2x), or

$e)---y=-(1-e^{-0.35\sqrt{x}}).$

43, according to the described method of claim 41, wherein, described one or more closed form expression formulas depend on the coding of this group spatial reuse RF output signal and/or at least one in the modulation.

44, according to the described method of claim 41, wherein, the function of at least one in the output signal-to-noise ratio that described one or more closed form expression formulas are receivers or output signal and noise and the interference ratio.

45, method according to claim 32, wherein, this method also comprises:

Use one group of base band weighted value that input signal execution separation and weighting are operated to form first group of baseband signal; With

At least produce described spatial reuse RF output signal group based on this first group of baseband signal.

46, method according to claim 32, wherein, this method also comprises:

With the spatial reuse RF signal down that receives to form first group of baseband signal; With

Use first group of base band weighted value that this first group of baseband signal implemented base band weighted sum synthetic operation.

47, method according to claim 32, wherein, it is one of following that described spatial reuse RF output signal comprises at least: CDMA signals, single-carrier signal, orthogonal frequency-division multiplex singal and ultra-broadband signal.

48, method according to claim 32, wherein:

The number of described transmitting antenna greater than the number of described two or more RF chains and

The number of described reception antenna is greater than the number of described two or more RF chains.

49, a kind of method of in the communication system that comprises reflector and receiver, selecting antenna, described reflector comprises transmitting antenna, this transmitting antenna uses one or more RF transmitting chains by one group of RF output signal of channels transmit, described receiver comprises reception antenna, this reception antenna is used to receive this group RF output signal and correspondingly generates one group of reception RF signal through one or more RF reception link processing, and this method comprises:

Set up the possible subclass of described transmitting antenna and the possible subclass of described reception antenna;

Determine to add up corresponding to the channel parameter of the various combinations of the possible subclass of possible the subclass of described transmitting antenna and described reception antenna;

Select to add up corresponding emission mode with various channel parameters respectively;

Calculate the output error rate of receiver, each output error rate all calculates based at least one group of channel parameter statistics and selected corresponding emission mode;

According at least based on the specific possible subclass of the Standard Selection transmitting antenna of the output error rate that calculated and the specific possible subclass of reception antenna;

Described one or more RF transmitting chains are connected on the possible subclass of selected specific transmitting antenna;

Described one or more RF are received on the possible subclass that links are connected to selected specific reception antenna.

50, according to the described method of claim 49, wherein, described standard is based on output error rate that is calculated and selected emission mode.

51, according to the described method of claim 49, wherein, this method also comprises:

Use one group of transmitting baseband weighted value that execution separation of input baseband signal and weighting are operated to form first group of baseband signal; With

At least produce described RF output signal based on this first group of baseband signal.

52, according to the described method of claim 51, wherein, described transmitting baseband weighted value is to use precoding or space-time code technology to produce.

53, according to the described method of claim 49, wherein, this method also comprises:

With the RF sets of signals down-conversion that receives to form first group of baseband signal; With

Use a group of received base band weighted value that this first group of baseband signal carried out base band weighting and synthetic operation.

54, according to the described method of claim 51, wherein, described transmitting baseband weighted value obtains from the single vector corresponding to the channel matrix of the possible subclass of selected transmitting antenna.

55, according to the described method of claim 53, wherein, described reception base band weighted value obtains from the single vector corresponding to the channel matrix of the possible subclass of selected reception antenna.

56, a kind of from M antenna element reflector or the receiver of M antenna element select the system of N antenna element, wherein N comprises less than M:

M antenna element in the receiver of the reflector of a M antenna element or M antenna element;

N RF link; With

Be connected to the switch of this N RF chain,

Wherein, the receiver of this M antenna element calculates the output error rate of each possible N antenna element subclass in this M antenna element, and each output error rate all calculates based on one group of channel parameter statistics at least,

The receiver of a described M antenna element is based on the specific N antenna element subclass of Standard Selection based on the output error rate that calculated; With

As to the response based on the specific N antenna element subclass of described Standard Selection, described switch is connected to described N RF link on N the antenna element of this specific N antenna element subclass.

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