This application is a national stage filing under 35 U.S.C. § 371 of international application number PCT/CN2020/117160, filed on Sep. 23, 2020, which claims priority to Chinese patent application No. 201910907176.8 filed on Sep. 24, 2019. The contents of these applications are incorporated herein by reference in their entirety.
The present disclosure relates to the technical field of communication, and in particular, to a Belief Propagation (BP) equalization method and apparatus, a communication device and a non-transitory computer-readable storage medium.
Equalization in the field of communication refers to equalization of characteristics of a channel. That is, a receiver produces characteristics opposite to those of the channel to cancel inter-symbol interference caused by time-varying and multipath effects. In multi-user detection, equalization technologies adopted include Zero Forcing (ZF), Minimum Mean Square Error (MMSE), Interference Rejection Combining (IRC), Sphere Decoding (SD) and BP algorithms. The BP algorithm uses a Factor Graph (FG) idea to update belief information between nodes iteratively. The performance is better than that of a linear equalization algorithm, and the implementation complexity is lower than that of a conventional linear equalization algorithm because no large matrix inverse operation is required. In some cases, the BP equalization algorithm is mainly implemented in two manners, namely Factor Graph based Graphical Model with Gaussian Approximation of Interference (FG-GAI) and Channel Hardening-Exploiting Message Passing (CHEMP). FG-GAI and CHEMP both have problems of high costs and limited application scenarios.
According to some embodiments of the present disclosure, a BP equalization method and apparatus, a communication device and a non-transitory computer-readable storage medium are provided, so as to solve at least to some extent the problems of high overhead and limited application scenarios in the BP equalization algorithm in some cases.
In view of the above, according to an embodiment of the present disclosure, a BP equalization method is provided. The method may include: splitting a received signal Yc, a channel estimation Hc and a symbol estimation Xc into real parts and imaginary parts to obtain a received signal matrix Y, a channel estimation matrix H and a symbol estimation matrix X; performing orthogonal triangular (QR) decomposition on the channel estimation matrix H to obtain an equivalent received signal Ybp, an equivalent channel R and a noise power σ2; and performing iteration based on the equivalent received signal Ybp, the equivalent channel R and the noise power σ2 to obtain a position probability of per stream symbol.
According to another embodiment of the present disclosure, a BP equalization apparatus is further provided. The apparatus may include: a splitting module, a decomposition module and an iteration module. The splitting module is configured to split a received signal Yc, a channel estimation Hc and a symbol estimation Xc into real parts and imaginary parts to obtain a received signal matrix Y, a channel estimation matrix H and a symbol estimation matrix X. The decomposition module is configured to perform QR decomposition on the channel estimation matrix H to obtain an equivalent received signal Ybp, an equivalent channel R and a noise power σ2. The iteration module is configured to perform iteration based on the equivalent received signal Ybp, the equivalent channel R and the noise power σ2 to obtain a position probability of per stream symbol.
According to yet another embodiment of the present disclosure, a communication device is further provided. The device may include a processor, a memory and a communication bus. The communication bus is configured to connect the processor to the memory. The processor is configured to execute a computer program stored in the memory to carry out the BP equalization method as described above.
According to yet another embodiment of the present disclosure, provided is a non-transitory computer-readable storage medium storing one or more computer programs, where the one or more computer programs, when executed by one or more processors, cause the one or more processors to carry out the BP equalization method as described above.
Other features and corresponding beneficial effects of the present disclosure will be set forth in part in the description which follows, and it is to be understood that at least part of the beneficial effects will become apparent from the description of the present disclosure.
In order to make objects, technical schemes and advantages of the present disclosure clear, embodiments of the present disclosure are described in further detail below with reference to specific implementations in conjunction with the drawings. It is to be understood that the embodiments described herein are intended only to illustrate and not to limit the present disclosure.
In view of the problems of high overhead and limited application scenarios in a BP equalization algorithm in some cases, a BP equalization method is provided according to an embodiment. The method involves performing QR decomposition on a channel estimation matrix H, so that an update dimension is the number of streams multiplied by the number of streams, which does not increase with the number of antennas, achieving dimensionality reduction and being more suitable for Massive MIMO multi-user detection scenarios. Thus, the application scenarios of the BP equalization method are expanded. At the same time, since an R matrix is an upper triangular matrix, and only non-zero nodes need to be iterated during iteration, the computation overhead can be further reduced and the accuracy of symbol estimation in the equalization algorithm can be improved. The BP equalization algorithm according to this embodiment is applicable to a variety of communication devices, including at least one of a variety of network-side communication devices and a variety of terminal-side communication devices. Moreover, the BP equalization algorithm according to this embodiment is also applicable to QR-GAI algorithms of any-order QAM. For easy understanding, the BP equalization algorithm according to this embodiment may be called a QR-GAI algorithm.
For easy understanding, this embodiment is illustrated below by taking the schematic flowchart of the BP equalization method shown in
At S101, a received signal Yc, a channel estimation Hc and a symbol estimation Xc are split into real parts and imaginary parts to obtain a received signal matrix Y, a channel estimation matrix H and a symbol estimation matrix X.
The received signal Yc in this embodiment may be a received signal of a communication device. The communication device may be a network-side communication device, which, for example, may include, but is not limited to, a variety of base stations. Certainly, in some examples, the communication device may also include a variety of terminal-side communication devices. In this embodiment, after receiving the received signal Yc, the communication device may perform the BP equalization method shown in
In this embodiment, S101 is intended to split a complex field QAM constellation point into two real number field PAM constellation points to allow for a real number field operation in subsequent steps.
In this embodiment, a receiving model may be flexibly arranged according to a specific application scenario. In an example, for the received signal Yc, the channel estimation Hc and the symbol estimation Xc, the receiving model (it is to be understood that the receiving model is not limited to the following example model, and may be flexibly adjusted as required) may be arranged as follows:
Yc=HcXc+Nc;
where the received signal satisfies Yc∈Cante×1; the channel estimation satisfies Hc∈Cante×flow; the symbol estimation satisfies Xc∈Cflow×1; the white Gaussian noise satisfies Nc∈Cante×1, with a mean of 0 and a variance of 2·σ2; C denotes a complex field; ante denotes the number of antennas; flow denotes the number of streams; and σ2 denotes a noise power.
Correspondingly, a received signal matrix Y, a channel estimation matrix H and a symbol estimation matrix Sσ
Y=HX+N;
where the received signal matrix satisfies
the channel estimation matrix satisfies
the symbol estimation matrix satisfies
denotes taking a real part, and Im{.} denotes taking an imaginary part.
At S102, QR decomposition is performed on the channel estimation matrix H to obtain an equivalent received signal Ybp, an equivalent channel R and a noise power σ2; so as to serve as input in a next step.
In an example of this embodiment, QR decomposition is performed on the channel estimation matrix H to obtain:
Y=HX+N=QRX+N;
and according to Y=HX+N=QRX+N, the following is obtained:
YbpQTY=RX+QTN∈R2·flow×1;
where the equivalent noise QTN has a mean of 0, and the noise power is σ2.
The QR decomposition performed on the channel estimate H=QR∈R2·ante×2·flow in this step has at least the following advantages. 1) The equivalent channel R has a dimension of R∈R2·flow×2·flow, which under Massive MIMO, is much smaller than an original channel dimension H∈R2·ante×2·flow, thereby greatly reducing the complexity of subsequent iterative algorithms. 2) According to characteristics of a unitary matrix, var(QTN)=var(N), that is, the noise power is constant, where var(.) denotes a variance. 3) Since R denotes an upper triangular matrix, only non-zero elements need to be updated in subsequent iteration, which can further reduce the computation overhead.
At S103, iteration is performed based on the equivalent received signal Ybp, the equivalent channel R and the noise power σ2 to obtain a position probability of per stream symbol.
For example, to be continued with the above example, the performing iteration based on the equivalent received signal Ybp, the equivalent channel R and the noise power σ2 to obtain a position probability of per stream symbol may include:
After the equivalent received signal mean Su,ONI and the equivalent received signal variance estimate Sσ
In order to further improve the accuracy of symbol estimation in the equalization algorithm, before the per stream symbol likelihood probability llr∈RM×1 and the per stream belief probability proT∈RM×1 are calculated according to Su,ONI and Sσ
μ and s obtained above are obtained by removing a mean and a variance of the equivalent received signal of the ONI stream from Observation Node ONI.
In the above step, since R is an upper triangular matrix, only ONI={2·flow, . . . , 1} and SNI={ONI, . . . , 2·flow} need to be traversed. In this way, iteration overhead of the QR-GAI algorithm can be further reduced. In addition, GAI white noise estimation (GAI estimation performance deteriorates significantly under high channel correlation) is not required for nodes of ONI=2·flow due to the absence of inter-stream interference. Therefore, a Log Likelihood Ratio (LLR) belief probability is high, which makes the iterative algorithm have dominant nodes in the iteration, thereby improving the estimation performance of the overall iterative algorithm.
In an example of this embodiment, a per stream symbol likelihood probability llr∈RM×1 and a per stream belief probability proT∈RM×1 are calculated according to the equivalent received signal mean Su,ONI and the equivalent received signal variance estimate Sσ
The process of calculating the per stream symbol likelihood probability llr∈RM×1 includes: defining a symbol index vector
and for an index i=1, 2, . . . , M, calculating the per stream symbol likelihood probability llr∈RM×1 according to the following formulas:
where llr(i) denotes a likelihood ratio of . . . s2, . . . ool X(ONI) being si(0)/β to being si(i)β at an ith symbol position, i=1, 2, . . . , M.
Then, the per stream belief probability proT∈RM×1 is calculated according to the following formulas:
proT(i)=exp(llr(i))/Σi exp(llr(i));
where proT(i) denotes a probability that an ONIth stream symbol X(ONI) is si(i)/β.
In some examples of this embodiment, in order to prevent probability jumps in adjacent iteration cycles, the performing iteration based on the equivalent received signal Ybp, the equivalent channel R and the noise power σ2 to obtain a position probability of per stream symbol may further include updating the ONIth stream symbol with the following damping algorithm:
pro(:,ONI)=df·pro(:,ONI)+(1−df·proT);
where pro(:,ONI) denotes all rows and ONI columns, and df denotes a damping factor. The value of df in this embodiment may be flexibly determined. In an example, the value may be any value from 0.2 to 0.3.
In this embodiment, after the per stream symbol position probability is obtained through S103, the obtained per stream symbol position probability may be applied flexibly as required.
In an example of this embodiment, a complex QAM constellation point of per stream symbol SNI={1, . . . , flow} may be calculated by utilizing the obtained per stream symbol position probability, so as to output a per stream symbol bit-level LLR probability.
The calculating a complex QAM constellation point of per stream symbol SNI={1, . . . , flow} includes:
where pro(rp,SNI) and pro (ip,SNI+flow) denote probabilities of real-value symbol positions of a real part and an imaginary part of an SNIth stream.
In some examples, pro(rp,SNI) and pro(ip,SNI+flow) may be directly used as decoding module input. In some examples, the BP equalization method in this embodiment further includes calculating a symbol hard decision, including:
where {circumflex over (X)}(SNI) denotes a hard decision value of a per stream 2M QAM complex symbol, and j denotes the imaginary part.
The QR-GAI algorithm according to this embodiment has at least the following advantages over the FG-GAI algorithm in some cases. 1) Dimensionality reduction is realized, and computation overhead in Massive MIMO scenarios is greatly reduced. 2) A high belief probability of a last stream is guaranteed by a Successive Interference Cancellation (SIC) principle, and the accuracy of multi-user detection is improved. 3) Only non-zero elements of an R matrix are updated during the iteration, which further reduces the computation overhead. In addition, the QR-GAI algorithm according to this embodiment has at least the following advantages over the CHEMP algorithm. 1) The dimensionality reduction operation does not increase the noise power, and improves the accuracy of symbol estimation. 2) A high belief probability of a last stream is guaranteed by the SIC principle. 3) The equivalent channel R matrix is sparser than a covariance matrix of H, which makes the algorithm still applicable under high channel correlation. In addition, the QR-GAI algorithm according to this embodiment may be extended to QAM of any order. The application scenarios can be further expanded.
For easy understanding, the QR-GAI algorithm shown in example embodiment one of this embodiment is illustrated in combination with two application scenarios based on 4QAM and 16QAM.
Example one: Refer to
At S201, a two-dimensional QAM complex field constellation point is split into two PAM constellation points. A received signal Yc=HcXc+Nc is split into a real part and an imaginary part to obtain:
where Y=HX+N is satisfied.
At S202, QR decomposition is performed on a channel estimation matrix H=QR∈R2·ante×2·flow to obtain YbpQTY=RX+QTN∈R2·flow×1. In this example, equivalent noise QTN has a mean of 0 and a variance of σ2. Input Ybp∈R2·flow×1, R∈R2·flow×2·flow and σ2 at S203 is obtained.
At S203, a main iteration process of a QR-GAI algorithm is performed. In this example, a fully connected BP network is constructed, with an Observation Node of Ybp∈R2·flow×1 and an Information Node of X∈R2·flow×1. Per stream position probability
is initialized, where M denotes an order of QAM, and for 4QAM, Pro=0.5·I2×2·flow. In this example, referring to
At S2031, GAI interference estimation is performed, and for each Observation Node the following processing is performed:
Su,ONI=ΣSNI=ONI2·flowR(ONI,SNI)·(2·Pro(1,SNI)−1)√{square root over (2)}; and
Sσ
where SNI={ONI, . . . , 2·flow} denotes a Symbol Node index, (2·Pro(1, SNI)−1)/√{square root over (2)} denotes per stream symbol estimate, Su,ONI denotes an equivalent received signal mean on Observation Node ONI, 2·Pro(1,SNI)·(1−Pro(1,SNI)) denotes per stream variance estimate, Sσ
According to a principle of Extrinsic Information, a mean and a variance of a stream ONI are removed to obtain:
μ=Su,ONI−R(ONI,ONI)·(2·Pro(1,ONI)−1)/√{square root over (2)}; and
s=Sσ
where μ and s obtained above are obtained by removing a mean and a variance of the equivalent received signal of the stream ONI from Observation Node ONI.
At S2032, a likelihood probability llr∈R2×1 is calculated first, and then a belief probability pro∈R2×2·flow is calculated. Criteria for calculating likelihood probability llr∈R2×1 are:
llr(1)=0; and
llr(2)=2/s·R(ONI,ONI)·(Ybp(ONI)−μ);
where llr(1) denotes a likelihood ratio of an ONIth stream symbol being +√{square root over (2)}/2 to being +√{square root over (2)}/2, with the value being 0. llr(2) denotes a likelihood ratio of an ONIth stream symbol being +√{square root over (2)}/2 to being −√{square root over (2)}/2.
The belief probability pro∈R2×2·flow is calculated, and update criteria of a temporary belief probability proT∈R2×1 are defined as:
proT(1)=exp(llr(1))/(exp(llr(1))+exp(llr(2))); and
proT(2)=exp(llr(2))/(exp(llr(1))+exp(llr(2)));
where proT(1) and proT(2) denote probabilities of the ONIth stream symbol being +√{square root over (2)}/2 and −√{square root over (2)}/2, respectively.
At S2033, the ONIth stream is updated with a damping algorithm to obtain:
pro(:,ONI)=df·pro(:,ONI)+(1−df·proT);
where df denotes a damping factor, and the value of df in this example may be any value from 0.2 to 0.3.
At S204, per stream symbol position decision is outputted. A symbol vector si={1,−1} is defined, and for a complex QAM constellation point of each stream SNI={1, . . . , flow},
where pro(rp,SNI) and pro(ip,SNI+flow) denote probabilities of real value symbol positions of a real part and an imaginary part of an SNI stream, which may be directly used as decoding module input.
In this example, for a symbol hard decision,
where {circumflex over (X)}(SNI) denotes a hard decision value of a 4QAM symbol of an SNIth stream.
Example two: Refer to
At S401, a two-dimensional 16QAM complex field constellation point is split into two 4QAM constellation points. A received signal Yc=HcXc+Nc is split into a real part and an imaginary part to obtain:
where Y=HX+N is satisfied.
At S402, QR decomposition is performed on a channel estimation matrix H=QR∈R2·ante×2·flow to obtain YbpQTY=RX+QTN∈R2·flow×1. In this example, equivalent noise QTN has a mean of 0 and a variance of σ2. Input Ybp∈R2·flow×1, R∈R2·flow×2·flow and σ2 at S203 is obtained.
At S403, a main iteration process of a QR-GAI algorithm is performed. A fully connected BP network is constructed, with an Observation Node of Ybp∈R2·flow×1 and an Information Node of X∈R2·flow×1. A belief probability Pro=¼·I4×2·flow is initialized. The process includes sub-steps a) to c).
At sub-step a), GAI interference estimation is performed. For each Observation Node ONI={2·flow, . . . , 1}, a symbol vector si={3,1,−1,−3} is defined to obtain:
where Su,ONI denotes an equivalent received signal mean on Observation Node ONI, Sσ
A mean and a variance of the stream ONI are removed to obtain:
where μ and s are obtained by removing a mean and a variance of the equivalent received signal of the stream ONI from Observation Node ONI.
At sub-step b), a likelihood probability llr∈R4×1 and a belief probability Pro∈R4×2-flow are calculated. For a symbol position index i={1,2,3,4},
where llr(i) denotes a likelihood ratio of an ONIth stream symbol being 3/√{square root over (10)} to being
si(i)/√{square root over (10)}.
A temporary belief probability is then calculated. For a symbol position index i={1,2,3,4},
proT(i)=exp(llr(i))/Σi exp(llr(i));
where proT(i) denote a probability of the ONIth stream symbol being si(i)/√{square root over (10)}.
At sub-step c), the ONIth stream is updated with a damping algorithm to obtain:
pro(:,ONI)=df·pro(:,ONI)+(1−df·proT);
where df denotes a damping factor, and df may be set to 0.2 to 0.3.
At S404, a bit-level LLR decision or symbol hard decision is outputted. For a symbol index vector si={3,1,−1,−3}, for a complex constellation point of each stream SNI={1, . . . , flow},
where pro(rp,SNI) and pro(ip,SNI+flow) denote LLR probabilities of the SNIth stream real value symbol, which may be used as decoding module input or used for other purposes as required.
For a symbol hard decision,
where {circumflex over (X)}(SNI) denotes a hard decision value of per stream 16QAM symbol.
It is to be understood that, in this embodiment, the BP equalization method according to this embodiment is illustrated with only two application scenarios based on 4QAM and 16QAM. Application scenarios based on 64QAM and 256QAM may be deduced by analogy with reference to the above embodiments, which are not described in detail herein. Besides, it is to be understood that the BP equalization method according to this embodiment is applicable to QAM of any order.
This embodiment provides a BP equalization apparatus. The BP equalization apparatus may be arranged in a communication device. The communication device may include at least one of a user-side communication device and a network-side communication device. Refer to
The splitting module 501 is configured to split a received signal Yc, a channel estimation Hc and a symbol estimation Xc into real parts and imaginary parts to obtain a received signal matrix Y, a channel estimation matrix H and a symbol estimation matrix X.
In this embodiment, the splitting module 501 splits a complex field QAM constellation point into two real number field PAM constellation points to allow for a real number field operation in subsequent steps.
In this embodiment, the splitting module 501 may flexibly arrange a receiving model according to a specific application scenario. In an example, for the received signal Yc, the channel estimation Hc and the symbol estimation Xc, the receiving model may be arranged as follows:
Yc=HcXc+Nc;
where the received signal satisfies Yc∈Cante×1; the channel estimation satisfies Hc∈Cante×flow; the symbol estimation satisfies Xc∈Cflow×1; the white Gaussian noise satisfies Nc∈Cante×1, with a mean of 0 and a variance of 2·σ2; C denotes a complex field; ante denotes the number of antennas; flow denotes the number of streams; and σ2 denotes a noise power.
Correspondingly, a received signal matrix Y, a channel estimation matrix H and a symbol estimation matrix X obtained through splitting into real parts and imaginary parts by the splitting module 501 satisfy:
Y=HX+N;
the received signal matrix is
the channel estimation matrix is
the symbol estimation matrix is
Re{.} denotes taking a real part, and Im{.} denotes taking an imaginary part.
The decomposition module 502 is configured to perform QR decomposition on the channel estimation matrix H to obtain an equivalent received signal Ybp, an equivalent channel R and a noise power σ2.
In an example of this embodiment, the decomposition module 502 performs QR decomposition on the channel estimation matrix H to obtain:
Y=HX+N=QRX+N;
and according to Y=HX+N=QRX+N, the decomposition module 502 obtains:
YbpQTY=RX+QTN∈R2·flow×1;
where the equivalent noise QTN has a mean of 0, and the noise power is σ2.
The QR decomposition performed by the decomposition module 502 on the channel estimate H=QR∈R2·ante×2·flow has at least the following advantages. 1) The equivalent channel R has a dimension of R∈R2·flow×2·flow, which under Massive MIMO, is much smaller than an original channel dimension H∈R2·ante×2·flow, thereby greatly reducing the complexity of subsequent iterative algorithms. 2) According to characteristics of a unitary matrix, var(QTN)=var(N), that is, the noise power is constant, where var(.) denotes a variance. 3) Since R denotes an upper triangular matrix, only non-zero elements need to be updated in subsequent iteration, which can further reduce the computation overhead.
The iteration module 503 is configured to perform iteration based on the equivalent received signal Ybp, the equivalent channel R and the noise power σ2 to obtain a position probability of per stream symbol.
For example, to be continued with the above example, the performing, by the iteration module 503, iteration based on the equivalent received signal Ybp, the equivalent channel R and the noise power σ2 to obtain a position probability of per stream symbol may include: constructing, by the iteration module 503, a fully connected BP network by taking the equivalent received signal Ybp as an Observation Node and the symbol estimation matrix X as a Symbol Node, and initializing a per stream symbol position probability as
M being an order of QAM, that is, 2M QAM; and then performing the following calculation: calculating, by the iteration module 503, an equivalent received signal mean Su,ONI and an equivalent received signal variance estimate Sσ
where
denotes a per stream estimate,
denotes a per symbol variance estimate, SNI denotes a stream index, and β denotes a symbol energy normalization factor. For example, for 4QAM, 16QAM, 64QAM and 256QAM, values of β are √{square root over (2)}, √{square root over (10)}, √{square root over (42)}, √{square root over (150)}, respectively. QAM of other orders may be deduced by analogy, which are not described in detail herein.
After the equivalent received signal mean Su,ONI and the equivalent received signal variance estimate Sσ
In this embodiment, in order to further improve the accuracy of symbol estimation in the equalization algorithm, before the iteration module 503 calculates the per stream symbol likelihood probability llr∈RM×1 and the per stream belief probability proT∈RM×1 according to Su,ONI and Sσ
where μ and s obtained above are obtained by removing a mean and a variance of the equivalent received signal of the ONI stream from Observation Node ONI.
In the above step, since R is an upper triangular matrix, only ONI={2·flow, . . . , 1} and SNI={ONI, . . . , 2·flow} need to be traversed. In this way, iteration overhead of the QR-GAI algorithm can be further reduced. In addition, GAI white noise estimation (GAI estimation performance deteriorates significantly under high channel correlation) is not required for nodes of ONI=2·flow due to the absence of inter-stream interference. Therefore, a Log Likelihood Ratio (LLR) belief probability is high, which makes the iterative algorithm have dominant nodes in the iteration, thereby improving the estimation performance of the overall iterative algorithm.
In an example of this embodiment, the iteration module 503 calculates a per stream symbol likelihood probability and a per stream belief probability proT∈RM×1 according to the equivalent received signal mean Su,ONI and the equivalent received signal variance estimate Sσ
The process of calculating, by the iteration module 503, the per stream symbol likelihood probability llr∈RM×1 includes:
Then, the iteration module 503 calculates the per stream belief probability proT∈RM×1 according to the following formulas:
proT(i)=exp(llr(i))/Σi exp(llr(i));
where proT(i) denotes a probability that an ONIth stream symbol X(ONI) is si(i)/β.
In some examples of this embodiment, in order to prevent probability jumps in adjacent iteration cycles, the performing, by the iteration module 503, iteration based on the equivalent received signal Ybp, the equivalent channel R and the noise power σ2 to obtain a position probability of per stream symbol may further include updating the ONIth stream symbol with the following damping algorithm:
pro(:,ONI)=df·pro(:,ONI)+(1−df·proT);
where pro(:,ONI) denotes all rows and ONI columns, and df denotes a damping factor. The value of df in this embodiment may be flexibly determined. In an example, the value may be any value from 0.2 to 0.3.
In this embodiment, after the iteration module 503 obtains the per stream symbol position probability, the obtained per stream symbol position probability may be applied flexibly as required. For example, referring to
In an example of this embodiment, the application processing module 504 may calculate a complex QAM constellation point of per stream symbol SNI={1, . . . , flow} by utilizing the obtained per stream symbol position probability, so as to output a per stream symbol bit-level LLR probability.
The calculating, by the application processing module 504, a complex QAM constellation point of per stream symbol SNI={1, . . . , flow} includes:
where pro(rp,SNI) and pro(ip,SNI+flow) denote probabilities of real-value symbol positions of a real part and an imaginary part of an SNIth stream.
In some examples, pro(rp,SNI) and pro(ip,SNI+flow) may be directly used as decoding module input. In some examples, the application processing module 504 in this embodiment may be further configured to calculate a symbol hard decision, including:
where {circumflex over (X)}(SNI) denotes a hard decision value of a per stream 2M QAM complex symbol, and j denotes the imaginary part.
This embodiment further provides a communication device. The communication device may be a user-side device, for example, a variety of user-side user equipment (e.g., user terminals), or a network-side communication device, such as various AAUs (e.g., base station devices). Referring to
The communication bus 603 is configured to realize communication connection between the processor 601 and the memory 602.
In an example, the processor 601 may be configured to execute one or more computer programs stored in the memory 602, so as to carry out the BP equalization method in the above embodiment.
For easy understanding, a description is given in an example of this embodiment by taking a base station as the communication device. Moreover, it is to be understood that the base station of this embodiment may be a cabinet macro base station, a distributed base station or a multi-mode base station. Referring to
The BBU 71 is configured to perform centralized control and management of the entire base station system and uplink and downlink baseband processing and provide physical interfaces for information interaction with the radio remote unit and a transport network. According to different logic functions, as shown in
The RRU 72 is configured to communicate with the BBU through a baseband radio frequency (RF) interface to complete conversion between a baseband signal and an RF signal. Referring to
Additionally, it is to be understood that the base station of this embodiment may also use a Central Unit-Distributed Unit (CU-DU) architecture. The DU is a distributed access point responsible for underlying baseband protocol and RF processing. The CU is responsible for higher-layer protocol processing and centralized management of DUs. The CU and the DU jointly perform baseband and RF processing of the base station.
In this embodiment, the base station may further include a storage unit for storing various data. For example, the storage unit may store the one or more computer programs. The main control unit or the CU may be used as a processor to execute the one or more computer programs stored in the storage unit to carry out the BP equalization method of the above embodiments.
In this example, when the BP equalization apparatus is disposed in the base station, the functions of at least one module of the BP equalization apparatus may also be implemented by the main control unit or the central unit.
For easy understanding, a description is given in another example of this embodiment by taking a communication terminal as the communication device. Referring to
The RF unit 801 may be configured for communication, that is, receiving and sending signals. For example, the RF unit 801 receives downlink information from the base station and sends the received downlink information to the processor 810 for processing. Moreover, the RF unit 801 sends uplink data to the base station. Generally, the RF unit 801 includes, but not limited to, an antenna, at least one amplifier, a transceiver, a coupler, a low-noise amplifier and a duplexer. Moreover, the RF unit 801 may also communicate with a network and other devices by way of wireless communication. The sensor 805 may be, for example, a light sensor, a motion sensor or other sensors. In an embodiment, the light sensor includes an ambient light sensor or a proximity sensor. The ambient light sensor may adjust the brightness of a display panel 8061 according to the brightness of the ambient light.
The display unit 806 is configured to display information inputted by or provided for a user. The display unit 806 may include a display panel 8061, for example, an organic light-emitting diode (OLED) display panel or an active-matrix organic light-emitting diode (AMOLED) display panel.
The user input unit 807 may be configured to receive input digital or character information and generate key signal input related to user settings and function control of the mobile terminal. The user input unit 807 may include a touch panel 8071 and another input device 8072.
The interface unit 808 serves as an interface through which at least one external device can be connected to the communication terminal. For example, the external device may include an external power supply (or battery charger) port, a wired or wireless data port, a memory card port, a port for connecting an apparatus having an identification module, an audio input/output (I/O) port and the like.
The memory 809 may be configured to store software programs and various data. The memory 809 may include a high-speed random-access memory and may also include a non-volatile memory such as at least one disk memory, a flash memory device or another volatile solid-state memory.
As the control center of the communication terminal, the processor 810 is configured to connect various parts of the communication terminal by various interfaces and lines and perform various functions and data processing of the communication terminal by executing software programs and/or modules stored in the memory 809 and invoking data stored in the memory 809. For example, the processor 810 may be configured to invoke the one or more computer programs stored in the memory 809 to carry out the BP equalization method as described above.
The processor 810 may include one or more processing units. In an embodiment, an application processor and a modem processor may be integrated into the processor 810. The application processor is configured to process an operating system, a user interface and an application program. The modem processor is configured to process wireless communication. It is to be understood that the modem processor may not be integrated into the processor 810.
The power supply 811 (for example, a battery) may be logically connected to the processor 810 through a power management system to perform functions such as charging management, discharging management and power consumption management through the power management system.
In this example, when the BP equalization apparatus is disposed in the communication terminal, the functions of at least one module of the BP equalization apparatus may also be implemented by the processor 810.
This embodiment further provides a computer-readable storage medium. The computer-readable storage medium includes a volatile or non-volatile medium, removable or non-removable medium implemented in any method or technology for storing information (such as computer-readable instructions, data structures, computer program modules or other data). The computer-readable storage medium includes, but is not limited to, a random-access memory (RAM), a read-only memory (ROM), an electrically erasable programmable read-only memory (EEPROM), a flash memory or another memory technology, a compact disc read-only memory (CD-ROM), a digital versatile disc (DVD) or another optical storage, a magnetic cassette, a magnetic tape, a magnetic disk or another magnetic storage device, or any other medium that can be used for storing desired information and accessed by a computer.
In an example, the computer-readable storage medium of the embodiment may be configured to store one or more computer programs which, when executed by one or more processors, cause the one or more processors to carry out the BP equalization method of the above embodiments.
This embodiment further provides a computer program (or computer software) that may be distributed in a computer-readable medium and executed by a computing device to cause the computing device to perform at least one step of the BP equalization method of the above embodiments. Moreover, in some cases, the illustrated or described at least one step may be performed in a sequence different from the sequence described in the above embodiments.
This embodiment further provides a computer program product. The computer program product includes a computer-readable apparatus having stored thereon the computer programs as illustrated above. In this embodiment, the computer-readable apparatus may include the computer-readable storage medium as illustrated above.
In the BP equalization method and apparatus, the communication device and the storage medium according to the embodiments of the present disclosure, firstly, a received signal Yc, a channel estimation Hc and a symbol estimation Xc are split into real parts and imaginary parts to obtain a received signal matrix Y, a channel estimation matrix H and a symbol estimation matrix X; then, QR decomposition is performed on the channel estimation matrix H to obtain an equivalent received signal Ybp, an equivalent channel R and a noise power σ2, and iteration is performed based on the equivalent received signal Ybp, the equivalent channel R and the noise power σ2 to obtain a position probability of per stream symbol. Due to the QR decomposition, an update dimension is the number of streams multiplied by the number of streams, which does not increase with the number of antennas, achieving dimensionality reduction and being more suitable for Massive MIMO multi-user detection scenarios of large-scale array antennas. That is, application scenarios of the BP equalization method are improved. At the same time, an R matrix is an upper triangular matrix, and only non-zero nodes need to be iterated during iteration, so the computation overhead can be further reduced and the accuracy of symbol estimation in the equalization algorithm can be improved.
In the embodiments of the present disclosure, the noise power can also be ensured to be constant during dimensionality reduction by utilizing characteristics of a unitary matrix.
During information iterative update, according to the SIC principle, the use of the principle of canceling inter-stream interference of a last stream without a GAI algorithm and the optimal use of a damping filtering method can ensure the high belief probability of nodes, thereby improving the accuracy of the overall multi-user detection and accelerating the convergence speed.
As can be seen, it is to be understood by those having ordinary skills in the art that some or all steps of the method and function modules/units in the system or apparatus may be implemented as software (which may be implemented by computer program codes executable by a computing device), firmware, hardware and suitable combinations thereof. In the hardware implementation, the division of the function modules/units mentioned in the above description may not correspond to the division of physical components. For example, one physical component may have multiple functions, or one function or step may be performed jointly by several physical components. Some or all physical components may be implemented as software executed by a processor such as a central processing unit, a digital signal processor or a microprocessor, may be implemented as hardware, or may be implemented as integrated circuits such as application-specific integrated circuits.
Additionally, as is known to those having ordinary skills in the art, communication media generally include computer-readable instructions, data structures, computer program modules, or other data in carriers or in modulated data signals transported in other transport mechanisms and may include any information delivery medium. Therefore, the present disclosure is not limited to any particular combination of hardware and software.
The above is a detailed description of embodiments of the present disclosure in conjunction with specific implementations and is not to be construed as limiting the scope of the present disclosure. For those having ordinary skills in the art to which the present disclosure pertains, simple deductions or substitutions may be made without departing from the concept of the present disclosure and are considered to fall within the scope of the present disclosure.
Number | Date | Country | Kind |
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201910907176.8 | Sep 2019 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2020/117160 | 9/23/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2021/057798 | 4/1/2021 | WO | A |
Number | Name | Date | Kind |
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20090257530 | Shim | Oct 2009 | A1 |
Number | Date | Country |
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101841375 | Sep 2010 | CN |
101909028 | Dec 2010 | CN |
107005504 | Aug 2017 | CN |
2011106571 | Sep 2011 | WO |
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Number | Date | Country | |
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20220353111 A1 | Nov 2022 | US |