GENERATING PRECODERS FOR JOINT TRANSMISSION FROM MULTIPLE TRANSMISSION POINTS TO MULTIPLE USER EQUIPMENTS IN A DOWNLINK COORDINATED MULTIPOINT TRANSMISSION/RECEPTION COMMUNICATIONS SYSTEM

Information

  • Patent Application
  • 20160164578
  • Publication Number
    20160164578
  • Date Filed
    August 05, 2014
    10 years ago
  • Date Published
    June 09, 2016
    8 years ago
Abstract
There is provided generating precoders for joint transmission (JT) in a downlink coordinated multi-point transmission/reception (DL COMP) wireless communications system. The system includes a plurality of transmission points (TPs) operable to communicate with a plurality of user equipments (UEs). Each UE has one of the TPs as its serving TP. The method includes transmitting channel state information (CSI) from each UE to its serving TP, wherein the transmitted CSI includes precoder matrix indicators (PMI), and using the PMI to generate precoders for transmission of data from the plurality of TPs to the plurality of UEs.
Description
TECHNICAL FIELD

The present invention relates to generating precoders for joint transmission (JT) from multiple transmission points to multiple user equipments in a Downlink Coordinated Multi-Point transmission/reception (DL CoMP) communications system.


BACKGROUND ART

The following abbreviations are used herein:















CoMP
Coordinated Multi-Point (the abbreviation CoMP often also



means Coordinated Multi-Point transmission/reception, as



will be evident from the context)


CQI
Channel Quality Indicator


CSI
Channel State Information - CSI includes PMI, RI, CQI (see



below)


DL
Downlink


DMRS
Demodulation Reference Signal


eNodeB
Evolved NodeB (i.e. evolved base station)


JT
Joint Transmission


MMSE
Minimum Mean Squared Error


PMI
Precoder Matrix Indicator


SINR
Signal to Interference plus Noise Ratio


RI
Rank Indicator


TP
Transmission Point


UE
User Equipment









Also, the following mathematical notations are adopted herein:

    • |a| denotes the absolute value of a;
    • ∥a∥2=|a(1)|2+ . . . +|a(N)|2 (unless stated otherwise);
    • Ea denotes the expectation (or expected value) of a; and
    • For any matrix A, AH denotes the conjugate transpose of A, and tr(A) represents the operation of taking the trace of A.


Joint Transmission Downlink Coordinated Multi-Point transmission/reception (JT-DL CoMP).



FIG. 1 schematically represents JT in a DL CoMP system. The system includes multiple TPs (these may be eNodeBs), each TP being equipped with multiple antennas, and multiple UEs where each UE is also equipped with multiple antennas. The multiple TPs transmit data to the multiple UEs on the same time-frequency. Generally, to minimise interferences between TPs and between UEs, the transmission is carried out with CoMP precoders which are generated based on (i.e. generated from the knowledge of) the channel state information (CSI).


Each UE feeds back CSI (which includes RI, PMI and CQI) to its serving TP via uplink, as illustrated in FIG. 2.


In CSI measurement, for each UE there are as many CSI configurations as there are TPs involved in JT-DL CoMP. FIGS. 3A and 3B show CSI measurement for a UE involved in JT-DL CoMP with two TPs. The CSI config#0 is for TP#0 (the serving TP) and the CSI config#1 is for TP#1 (the neighbouring TP).


System Description


A JT DL CoMP system having NTP TPs and NUE UEs may be described mathematically as set out below.


Let τn denote the number of antennas at the n-th TP. The total number of transmit antennas NTX used in DL CoMP transmission is:







N
TX

=




n
=
1


N
TP





τ
n

.






Let NRX denote the number of receive antennas at each UE, and let Hin (size NRX×τn) denote the channel between the n-th TP and the i-th UE.


Then the DL CoMP channel of the i-th UE (size NRX×NTX) is:





Hi=└Hi1, Hi2, . . . , HiNTP┘, i=1, . . . , NUE  Equation (1)


Let Vi (size NTX×RIi) denote the precoder for the i-th UE.


The received signal at the i-th UE (yi) is given by:











y
i

=



H
i






j
=
1


N
UE





V
j



x
j




+

n
i



,





i
=
1

,





,

N
UE





Equation






(
2
)








where ni is additive Gaussian noise. Note that, from the DMRS, the i-th UE can find the effective channel HiVi to generate a decoder.


Precoding


Precoding is dependent on PMI which is part of the CSI. (Recall that CSI is fed back by a UE to its serving TP via uplink.) Let pin denote the PMI corresponding to Hin. Note that in a 2-stage PMI codebook system, pin is a pair PMI#1 and PMI#2.


According to the 3GPP standard (TS 36.211), the precoder Win (of size τn×RIi) associated with the reported PMI pin is used for precoding data to send from the n-th TP to the i-th UE. The total DL CoMP precoder is therefore given by:











V
i

=

[




W

i





1







W

i





2












W

iN
TP





]


,





i
=
1

,





,

N
UE





Equation






(
3
)








Note that, in a 2-stage PMI codebook system, Win=Win(1)×Win(2) associated with PMI#1 and PMI#2.


Precoding in this way is not optimal and it may be desirable to provide an improved or at least an alternative way of generating precoders.


It is to be clearly understood that mere reference herein to previous or existing systems, methods, models, processes, procedures, practices, publications or other information, or to any problems or issues, does not constitute an acknowledgement or admission that any of those things individually or in any combination formed part of the common general knowledge of those skilled in the field, or that they are admissible prior art.


SUMMARY OF INVENTION

In one broad form, the invention provides a method for generating precoders for joint transmission (JT) in a downlink coordinated multi-point (DL CoMP) wireless communications system, the system including a plurality of transmission points (TPs) operable to communicate with a plurality of user equipments (UEs) wherein each UE has one of the TPs as its serving TP, and the method comprises:


transmitting channel state information (CSI) from each UE to its serving TP, wherein the transmitted CSI includes precoder matrix indicators (PMI), and


using the PMI to generate precoders for transmission of data from the plurality of TPs to the plurality of UEs.


The use of the PMI to generate precoders may involve using the PMI to find a representative matrix (Ĥin) representing the channel (Hin) between an n-th TP and an i-th UE. In some embodiments, a fixed codebook (ΩRI) of representative matrices may be generated from PMI codebook(s), the CSI transmitted from each UE to its serving TP may include a rank indicator (RI), and ΩRI may be different for different RI. In such embodiments, if the RI for the i-th UE (RIi) is equal to the number of receive antennas of the UE (NRX) (i.e. if RIi=NRX) then ΩRI may contain matrices Ĥ(m), m=1, . . . of size NRX×τn, where τn is the number of antennas at the n-th TP. Alternatively, if RIi is less than NRX (i.e. if RIi<NRX) then ΩRI may contain vectors ĥ(m), m=1, . . . of size τn×1. Proposals for the way in which Ĥin may be calculated in specific embodiments of the invention, both for the case where RIi=NRX, and also the case where RIi<RRX, are discussed below.


It is envisaged that non-coherent precoding may be used in some embodiments (or some embodiments may operate or be used in systems where non-coherent precoding is used), and where this is so the method for generating precoders may further comprise using the representative matrix Ĥin, a Lagrange multiplier νn and a noise variance estimate σi2 to compute the precoders (Vin). The precoders Vin may be computed using an iterative procedure. Proposals for the way in which the precoders Vin and the Lagrange multiplier νn may be calculated for the case of non-coherent precoding in specific embodiments of the invention are discussed below.


Whilst non-coherent precoding may be used in some embodiments of the invention, in other embodiments coherent precoding may be used (or embodiments may operate or be used in systems where coherent precoding is used). Where coherent precoding is used, the method for generating precoders may involve finding the representative matrix (Ĥin) in the manner described for the case of non-coherent precoding (as discussed above and also in further detail below), and then further finding a representative matrix Ĥi representing the total channel as follows:





Ĥi=└Ĥi1, Ĥi2, . . . , ĤiNTP┘, i=1, . . . , NUE


In the case of coherent precoding, the method for generating precoders may further comprise using the said representative matrix Ĥi, a Lagrange multiplier ν and a noise variance estimate σi2 to compute the precoders (Vi). Like in the case of non-coherent precoding, for the case of coherent precoding the precoders Vi may be computed using an iterative procedure. Proposals for the way in which the precoders Vi and the Lagrange multiplier ν may be calculated for the case of coherent precoding in specific embodiments of the invention are discussed below.


Regardless of whether coherent precoding or non-coherent precoding is used, the CSI transmitted from each UE to its serving TP may include (in addition to the PMI) a channel quality indicator (CQI), and the above-mentioned noise variance estimate σi2 may be found using the CQI by i) finding the signal to interference plus noise ratio (SINRi1) based on thresholds in the CQI table; and ii) calculating σi2 using the SINRi1 and the serving TP's transmit power Ps. A specific proposal for the way in which this might be done is discussed below.


As mentioned above, the CSI transmitted from each UE to its serving TP may include a rank indicator (RI). Suitably, from the up to NTP reported RIin, the majority may be selected as a single common RIi for the i-th UE. In this case, it may be that only CQIi{circumflex over (n)}(l) associated with the selected RIi are candidates for CQI selection. The selection may be carried out per codeword independently, and the majority among the candidates may be selected as a common CQI for l-th codeword CQIi(l).


In another broad form, the invention provides a downlink coordinated multi-point (DL CoMP) wireless communications system in which joint transmission (JT) is performed between a plurality of transmission points (TPs) and a plurality of user equipments (UEs), wherein each UE has one of the TPs as its serving TP, channel state information (CSI) is transmitted from each UE to its serving TP, the transmitted CSI includes precoder matrix indicators (PMI), and the PMI is used to generate precoders for transmission of data from the plurality of TPs to the plurality of UEs.


Aspects and features described herein with reference to one form of the invention (e.g. the method form) may also form part of, or be used (in any combination) in any other form of the invention (e.g. the system form). In fact, more generally, any of features or aspects described herein can be combined in any combination with any one or more other features or aspects described herein within the scope of the invention.





BRIEF DESCRIPTION OF DRAWINGS

Preferred features, embodiments and variations of the invention may be discerned from the following Detailed Description which provides sufficient information for those skilled in the art to perform the invention. The Detailed Description is not to be regarded as limiting the scope of the preceding Summary of the Invention in any way. The Detailed Description will make reference to a number of drawings as follows:



FIG. 1 is schematically represents a JT-DL CoMP system.



FIG. 2 is schematically represents the way each UE feeds back CSI to its serving TP via uplink.



FIG. 3A schematically illustrates CSI measurement for JT-DL CoMP.



FIG. 3B schematically illustrates CSI measurement for JT-DL CoMP.



FIG. 4 is a flowchart illustrating, for the case of non-coherent precoding, a method for generating j-MMSE precoders in accordance with the embodiment of the invention discussed below.



FIG. 5 is a flowchart illustrating, for the case of non-coherent precoding, a method for computing the Lagrange multiplier for the n-th TP.



FIG. 6 is a flowchart illustrating, for the case of coherent precoding, a method for generating j-MMSE precoders in accordance with the embodiment of the invention discussed below.



FIG. 7 is a flowchart illustrating, for the case of coherent precoding, a method for computing the Lagrange multiplier for all TPs.



FIG. 8 schematically illustrates the estimation of a UE's noise variance based on the reported CQI of the serving TP.



FIG. 9 schematically illustrates RI and CQI collection from the reported RI and CQI for transmission to the i-th UE.





DESCRIPTION OF EMBODIMENTS

Joint transmit & receive optimisation methods have previously been proposed. See, for example, Sampath H. and Paulraj A., “Joint Transmit and Receive Optimization for High Data Rate Wireless Communication Using Multiple Antennas”, Thirty-Third Asilomar Conference on Signals, Systems, and Computers, 1999, and Zhang J., et. al., “Joint Linear Transmitter and Receiver Design for Downlink of Multiuser MIMO Systems”, IEEE Communications Letters, Vol. 9, No. 11, November 2005.


Embodiments of the present invention provide MMSE precoders based (at least somewhat) on the joint transmit & receive optimization methods discussed in the above academic papers. However, unlike the methods in these academic papers, the present invention does not require knowledge of the channel to generate MMSE precoders. Instead (and in contrast), embodiments of the invention require only the PMI, which is fed back by UEs to serving TPs, as shown in FIG. 2. The precoder according to the particular embodiments of the invention discussed below will be referred to as the j-MMSE precoder.


A) Non-Coherent Precoding

In the case of non-coherent precoding, the individual j-MMSE precoder Vin is computed using the joint transmit and receive MMSE optimization as follows.


Finding Representative Channels


Let ΩRI denote the fixed codebook of representative channel matrices which is generated from the PMI codebook(s). There are different ΩRI for different RI.

    • For RIi=NRX, the ΩRI contains matrices Ĥ(m), m=1, . . . of size NRX×τn
    • For RIi<NRX, the ΩRI contains vectors ĥ(m), m=1, . . . of size τn×1


Let Ĥin be the representative for the channel Hin. The representative channel is obtained as follows:


If RIi=NRX, then






Ĥ
in
(m*)εΩRI, i=1, . . . , NUE, n=1, . . . , NTP


with











m
*

=



arg





max

m


tr


{



[



H
^



(
m
)




W
in


]

H



[



H
^



(
m
)




W
in


]


}



,







H
^



(
m
)




Ω
RI






Eqaution






(
4
)








If RIi<NRX, then


1) Calculate correlation values:






C
in(m)=tr{[ĥH(m)Win]HH(m)Win]}, m=1, . . .  Equation (5)


and


2) Sort to find the NRX correlation values Cin(m1)>Cin(m2) > . . . >Cin(mNRX) and the NRX corresponding ĥ(m1), ĥ(m2), . . . , ĥ(mNRX) to form the channel matrix






Ĥ
in
=[ĥ(m1),ĥ(m2), . . . ,ĥ(mNRX)]H  Equation (6)


Here Win (of size τn×RIi) is the precoder in the 3GPP standard (TS 36.211) associated with the PMI pin. Note that, if the PMI consists of PMI#1 and PMI#2, then Win=Win(1)×Win(2).


Generating the j-MMSE Precoder Vin (see FIG. 4)


Let (m) denote the m-th iteration of the procedure. The precoder is generated as follows:

    • 1) (401) Initialize Gin (m=0)=Jin, i=1, . . . , NUE. Here Jin is a RIi×τn matrix with the (a,b)-th element being zero for a≠b and being 1 for a=b.
    • 2) (402) Compute Vin(m+1) using Gin(m) and the Lagrange multiplier νn for i=1, . . . , NUE as follows.











V

i





n




(

m
+
1

)


=



[





j
=
1


N
UE










H
^

jn
H




G
jn
H



(
m
)





G
jn



(
m
)





H
^

jn



+


υ
n


I


]


-
1





H
^


i





n

H




G

i





n

H



(
m
)







Equation






(
7
)










    • 3) (403) Compute Gin(m+1) using Vin(m+1) and the given noise variance estimate σi2 for i=1, . . . , NUE as follows.














G

i





n




(

m
+
1

)


=



V

i





n

H



(

m
+
1

)







H
^


i





n

H



[





j
=
1


N
UE










H
^


i





n





V
jn



(

m
+
1

)





V
jn
H



(

m
+
1

)





H
^


i





n

H



+


σ
i
2


I


]



-
1







Equation






(
8
)










    • 4) (404) Compute









E
=




i
=
1


N
UE













G

i





n




(

m
+
1

)


-


G

i





n




(
m
)





F
2








    • 5) (405) increment m and repeat step 2), step 3) and step 4) until













i
=
1


N
UE













G

i





n




(

m
+
1

)


-


G

i





n




(
m
)





F
2


<

ɛ
.





Here ∥·∥2F denotes Frobenius norm and ε is the convergent threshold.

    • 6) (406) Output Vin(m+1), i=1, . . . NUE.


Computing the Lagrange multiplier νn (see FIG. 5)


For each of the n-th TP, the Lagrange multiplier νn is computed as follows.

    • 1) (501) Compute λk as










U





Λ






U
H


=




i
=
1


N
UE










H
^


i





n

H




G

i





n

H



(
m
)





G

i





n




(
m
)





H
^


i





n








Equation






(
9
)










    • 2) (502) Set νmin and νmax

    • 3) (503) Set νn=(νmaxmin)/2 .

    • 4) (504) Compute the following quantity











P
^

n

=




k
=
1


τ
n










λ
k



(


λ
k

+

υ
n


)

2


.








    • 5) (505) Check if {circumflex over (P)}n>Pn and if so set νminn otherwise set νmaxn. Here Pn is the transmit power of the n-th TP.

    • 6) (506) Repeat step 3), step 4) and step 5) until |{circumflex over (P)}n−Pn|<ε. Here ε is the convergent threshold.

    • 7) (507) Output νn.





B) Coherent Precoding

In the case of coherent precoding, the total j-MMSE precoder V, is computed using the joint transmit and receive MMSE optimization as follows:


Finding Representative Channels


First the individual representative channel Ĥin is found as in the non-coherent case discussed above. Then the total channel is generated by:





Ĥi=└Ĥi1, Ĥi2, . . . , ĤiNTP┘, i=1, . . . , NUE  Equation (10)


Generating the j-MMSE Precoder Vi (see FIG. 6)


Let (m) denote the m-th iteration of the procedure. The precoder is generated as follows:

    • a) (601) Initialize Gi(m=0)=Ji, i=1, . . . , NUE . Here Ji is a RIi×NTX matrix with the (a,b)-th element being zero for a≠b and being 1 for a=b.
    • b) (602) Compute Vi(m+1) using Gi(m) and the Lagrange multiplier ν for i=1, . . . , NUE as follows.











V
i



(

m
+
1

)


=



[





j
=
1


N
UE










H
^

j
H




G
j
H



(
m
)





G
j



(
m
)





H
^

j



+

υ





I


]


-
1





H
^

i
H




G
i
H



(
m
)







Equation






(
11
)










    • c) (603) Compute Gi(m+1) using Vi(m+1) and the given noise variance estimate σi2 for i=1, . . . , NUE as follows.














G
i



(

m
+
1

)


=



V
i
H



(

m
+
1

)







H
^

i
H



[





j
=
1


N
UE










H
^

i




V
j



(

m
+
1

)





V
j
H



(

m
+
1

)





H
^

i
H



+


σ
i
2


I


]



-
1







Equation






(
12
)










    • d) (604) Compute









E
=




i
=
1


N
UE













G

i








(

m
+
1

)


-


G

i








(
m
)





F
2








    • e) (605) increment m and repeat step b), step c) and step d) until













i
=
1


N
UE













G

i








(

m
+
1

)


-


G

i








(
m
)





F
2


<

ɛ
.







    • f) (606) Output Vi(m+1), i−1, . . . NUE





Computing the Lagrange Multiplier ν (see FIG. 7)


The Lagrange multiplier ν is obtained as follows.

    • 1) (701) Compute λk as










U





Λ






U
H


=




i
=
1


N
UE










H
^


i





H




G

i





H



(
m
)





G

i








(
m
)





H
^


i












Equation






(
13
)










    • 2) (702) Set νmin and νmax

    • 3) (703) Set ν=(νmaxmin)/2.

    • 4) (704) Compute the following quantity










P
^

=




k
=
1


N
TX










λ
k



(


λ
k

+
υ

)

2


.








    • 5) (705) Check if {circumflex over (P)}>P and if so set νmin=ν otherwise set νmax=ν. Here P is the total transmit power,









P
=




n
=
1


N
TP









P
n

.








    • 6) (706) Repeat step 3), step 4) and step 5) until |{circumflex over (P)}−P|<ε. Here ε is the convergent threshold.

    • 7) (707) Output the Lagrange multiplier ν.





C) Noise Variance Estimating (see FIG. 8)

The following noise variance estimation may be used for both non-coherent and coherent precoding. The method estimates the UE's noise variance from the reported CQI for the serving TP is as follows:

    • 1) (801) Find SINRi1 based on the SINR thresholds in the CQI table.
    • 2) (802) Calculate σi2 using SINRi1 and the serving TP's transmit power Ps as follows.











σ
i
2

=



P
s

/

N
UE






l
=
1


L
i









SINR
il

/

L
i





,





i
=
1

,





,

N
UE





Equation






(
14
)








where Li the number of codewords used for the i-th UE. For less complexity, the noise variance can be fixed to zero as:





σi2=0, i=1 , . . . , NUE  Equation (15)


D) Rank and CQI selection (see FIG. 9)


Because, for a given UE, all TPs have common transmission rank and common CQI, it follows that rank and CQI selection is necessary. From the as many as NTP reported RIin, the majority is selected as the single common RIi for the i-th UE. The selection can be done using the histogram. Then only CQIi{circumflex over (n)} (l) associated with the selected RIi are the candidates for CQI selection. The selection is carried out per codeword independently. The majority among the candidates is selected as the common CQI for the l-th codeword CQIi(l). The selection can be done using the histogram.


Advantages


As discussed above, embodiments of the present invention do not require knowledge of the channel to generate the j-MMSE precoder. Rather, they require only the PMI which is fed back by UEs. This may provide a number of advantages. For instance, it may provide improved performance in comparison with methods which directly use reported PMI. Also, as is made evident above, the invention is applicable to both coherent and non-coherent precoding.


In the present specification and claims (if any), the word ‘comprising’ and its derivatives including ‘comprises’ and ‘comprise’ include each of the stated integers but does not exclude the inclusion of one or more further integers.


Reference throughout this specification to ‘one embodiment’ or ‘an embodiment’ means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, the appearance of the phrases ‘in one embodiment’ or ‘in an embodiment’ in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more combinations.


In compliance with the statute, the invention has been described in language more or less specific to structural, systems or methodical features. It is to be understood that the invention is not limited to specific features shown or described since the means herein described comprises preferred forms of putting the invention into effect. The invention is, therefore, claimed in any of its forms or modifications within the proper scope of the appended claims (if any) appropriately interpreted by those skilled in the art.


This application is based upon and claims the benefit of priority from Australia Patent Application No. 2013902955, filed on Aug. 7, 2013, the disclosure of which is incorporated herein in its entirety by reference.


REFERENCE SIGNS LIST



  • TP0 SERVING TP

  • TP1 NEIGHBOURING TP


Claims
  • 1. A method for generating precoders for joint transmission (JT) in a downlink coordinated multi-point transmission/reception (DL CoMP) wireless communications system, the system including a plurality of transmission points (TPs) operable to communicate with a plurality of user equipments (UEs) wherein each UE has one of the TPs as its serving TP, and the method comprises: transmitting channel state information (CSI) from each UE to its serving TP, wherein the transmitted CSI includes precoder matrix indicators (PMI), andusing the PMI to generate precoders for transmission of data from the plurality of TPs to the plurality of UEs.
  • 2. The method as claimed in claim 1, wherein using the PMI to generate precoders involves using the PMI to find a representative matrix (Ĥin) representing the channel (Hin) between an n-th TP and an i-th UE.
  • 3. The method as claimed in claim 2, wherein a fixed codebook (ΩRI) of representative matrices is generated from PMI codebook(s), the CSI transmitted from each UE to its serving TP includes a rank indicator (RI), and ΩRI is different for different RI.
  • 4. The method as claimed in claim 3 wherein, if the RI for the i-th UE (RIi) is equal to the number of receive antennas of the UE (NRX) (i.e. if RIi=NRX) then ΩRI contains matrices Ĥ(m), m=1, . . . of size NRX×τn, where τn is the number of antennas at the n-th TP.
  • 5. The method as claimed in claim 4 wherein, if RIi is less than NRX (i.e. if RIi<NRX) then ΩR, contains vectors ĥ(m), m=1, . . . of size τn×1.
  • 6. The method as claimed in claim 5 wherein, for RIi=NRX, the representative matrix Hin is found by: Ĥin=Ĥ(m*)εΩRI, i=1, . . . , NUE, n=1, . . . , NTP with
  • 7. The method as claimed in claim 6 wherein, for RIi<NRX, the representative matrix Ĥin is found by: a) calculating correlation values as: Cin(m)=tr{[ĥH(m)Win]H[ĥH(m)Win]}, m=1, . . .andb) sorting to find the N correlation values Cin(m1)>Cin(m2)> . . . >Cin(mNRX) and the corresponding vectors ĥ(m1), ĥ(m2), . . . , ĥ(mNRX,) to form the channel matrix Ĥin=[ĥ(m1),ĥ(m2), . . . ,ĥ(mNRX)]H
  • 8. The method as claimed in claim 7, wherein non-coherent precoding is used and the method further comprises using the representative matrix Ĥin, a Lagrange multiplier νn and a noise variance estimate σi2 to compute the precoders (Vin).
  • 9. The method as claimed in claim 8, wherein precoders Vin are computed using an iterative procedure.
  • 10. The method as claimed in claim 9, wherein precoders Vin are computed using the following iterative procedure where (m) denotes the m-th iteration: a) initialize a quantity Gin (m=0)=Jin, i=1, . . . , NUE, where Jin is a RIi×τn matrix with the (a,b)-th element being zero for a≠b and 1 for a=b;b) compute Vin(m+1) using Gin(m) and the Lagrange multiplier τn for i=1, . . . , NUE as follows:
  • 11. The method as claimed in claim 10, wherein the Lagrange multiplier νn for the n-th TP is computed using the following procedure: a) compute λk as
  • 12. The method as claimed in claim 8, wherein the CSI transmitted from each UE to its serving TP includes a channel quality indicator (CQI) and the noise variance estimate 6,2 is found using the CQI as follows: a) find the signal to interference plus noise ratio (SINR) based on thresholds in the CQI table; andb) calculate σi2 using the SINRi1 and the serving TP's transmit power Ps as follows.
  • 13. The method as claimed in claim 12 wherein, from up to NTP reported RIin, the majority is selected as a single common RIi for the i-th UE.
  • 14. The method as claimed in claim 13, wherein only CQIi{circumflex over (n)}(l) associated with the selected RIi are candidates for CQI selection, the selection is carried out per codeword independently, and the majority among the candidates is selected as a common CQI for the l-th codeword CQIi(l).
  • 15. The method as claimed in claim 7, wherein coherent precoding is used and the method further comprises finding a representative matrix Ĥi representing the total channel as follows: Ĥi=└Ĥi1, Ĥi2, . . . , ĤiNTP┘, i=1, . . . , NUE
  • 16. The method as claimed in claim 15, wherein the method further comprises using the representative matrix Ĥi, a Lagrange multiplier τ and a noise variance estimate σi2 to compute the precoders (Vi).
  • 17. The method as claimed in claim 16, wherein precoders Vi are computed using an iterative procedure.
  • 18. The method as claimed in claim 17, wherein precoders Vi are computed using the following iterative procedure where (m) denotes the m-th iteration: a) initialize Gi(m=0)=Ji, i=1, . . . , NUE, where Ji is a RIi×NTX matrix with the (a,b)-th element being zero for a≠b and 1 for a≠b, and NTX is the total number of transmit antennas of all TPs;b) compute Vi(m+1) using Gi(m) and the Lagrange multiplier ν for i=1, . . . , NUE as follows:
  • 19. The method as claimed in claim 18, wherein the Lagrange multiplier ν is computed using the following procedure: a) compute λk as
  • 20. The method as claimed in claim 16, wherein the CSI transmitted from each UE to its serving TP includes a channel quality indicator (CQI) and the noise variance estimate σi2 is found using the CQI as follows: a) find the signal to interference plus noise ratio (SINRi1) based on the SINR thresholds in the CQI table; andb) calculate σi2 using the SINR,, and the serving TP's transmit power Ps as follows.
  • 21. The method as claimed in claim 20 wherein, from as many as NTP reported RIin, the majority is selected as a single common RIi for the i-th UE.
  • 22. The method as claimed in claim 21, wherein only CQIi{circumflex over (n)} (l) associated with the selected RIi are candidates for CQI selection, the selection is carried out per codeword independently, and the majority among the candidates is selected as the common CQI for the l-th codeword CQIi(l).
  • 23. A downlink coordinated multi-point transmission/reception (DL COMP) wireless communications system in which joint transmission (JT) is performed between a plurality of transmission points (TPs) and a plurality of user equipments (UEs), wherein each UE has one of the TPs as its serving TP, channel state information (CSI) is transmitted from each UE to its serving TP, the transmitted CSI includes precoder matrix indicators (PMI), and the PMI is used to generate precoders for transmission of data from the plurality of TPs to the plurality of UEs.
Priority Claims (1)
Number Date Country Kind
2013902955 Aug 2013 AU national
PCT Information
Filing Document Filing Date Country Kind
PCT/JP2014/071349 8/5/2014 WO 00