CN113726376B - 1bit compression superposition CSI feedback method based on feature extraction and mutual-difference fusion - Google Patents

Abstract

The invention discloses a 1bit compression superposition CSI feedback method based on feature extraction and mutual-difference fusion, which comprises the following steps: obtaining the learning amplitude of the corresponding downlink CSI through a first neural network according to the amplitude of the uplink CSI estimation vector; according to the recovery feedback vector obtained by the base station, CSI (channel state information) feature extraction is carried out by using expert knowledge, and the feature amplitude and the feature angle of downlink CSI are recovered; obtaining a fusion amplitude of the downlink CSI through a second neural network according to a downlink CSI splicing amplitude obtained by splicing the characteristic amplitude of the downlink CSI and the learning amplitude of the downlink CSI; and recovering to obtain a downlink CSI reconstruction vector according to the fusion amplitude of the downlink CSI and the characteristic angle. Compared with the single-bit CS superposition CSI feedback, the method can recover the amplitude of the downlink CSI lost by the single-bit CS according to the bidirectional reciprocity of the uplink and downlink channels, greatly improve the reconstruction precision of the CSI, and obviously improve the reconstruction efficiency of the CSI at the same time.

Description

1bit compression superposition CSI feedback method based on feature extraction and mutual-difference fusion

Technical Field

The invention relates to the technical field of superposition feedback of an FDD (frequency division duplex) large-scale MIMO (multiple input multiple output) system, in particular to a 1bit compression superposition Channel State Information (CSI) feedback method based on feature extraction and mutual-anisotropy fusion.

Background

As a key technology for meeting the efficient spectrum efficiency and energy efficiency of a future 5g (radio generation wireless communication) network, an FDD massive MIMO system can provide wireless data services for more users without increasing the transmission power and system bandwidth through hundreds of antennas deployed at a base station end. Meanwhile, many operations (such as multi-user scheduling, rate allocation, transmitting end precoding, and the like) which bring performance improvement in the FDD massive MIMO system depend on the acquisition of accurate downlink Channel State Information (CSI). In Frequency Division Duplex (FDD) massive MIMO systems, there is weak reciprocity between channels, and CSI can only be fed back from the user end to the base station.

Although the traditional Compressed Sensing (CS) feedback technology using signal sparsity can reduce the system feedback overhead to a certain extent, a large amount of calculation overhead is generated in the reconstruction process; the feedback technology based on Deep Learning (DL) draws attention due to its advantages such as simple structure and fast training speed, but still occupies certain spectrum resources in its feedback process.

In recent years, Superposition Coding (SC) technology has been widely used in various fields of wireless communication due to its characteristic of being able to efficiently use spectrum resources, but superposition coding causes mutual interference, which can be reduced by discarding amplitude information of CSI by a single-bit CS. The loss of CSI amplitude information results in a low accuracy of CSI reconstruction.

Disclosure of Invention

Compared with single-bit CS (circuit switched) superposed CSI feedback, the method recovers the downlink CSI amplitude lost by a single-bit CS according to the bidirectional reciprocity of an uplink channel and a downlink channel, greatly improves the CSI reconstruction precision, and improves the CSI reconstruction efficiency by utilizing a shallow neural network and a simplified version CSI reconstruction method to reconstruct the CSI.

The technical scheme of the invention is as follows:

the 1bit compression superposition CSI feedback method based on feature extraction and mutual-difference fusion comprises the following steps:

estimating vectors from uplink CSI

Amplitude of (2)

Obtaining learning amplitude of corresponding downlink CSI through a first neural network

Based on recovered feedback vector

CSI characteristic extraction is carried out by utilizing expert knowledge, and the characteristic amplitude of downlink CSI is recovered

Angle to characteristic

Wherein the recovery feedback vector

The feedback vector is a corresponding feedback vector obtained by a base station receiving end after recovery according to a feedback vector w sent by a transmitting end;

according to the characteristic amplitude of the downlink CSI

Learning amplitude with downlink CSI

Splicing amplitude of downlink CSI (channel state information) obtained by splicing

Obtaining fusion amplitude of downlink CSI through second neural network

According to the fusion amplitude of the downlink CSI

Angle to said characteristic

Recovering to obtain downlink CSI reconstruction vector

In some embodiments, the uplink CSI estimation vector magnitude

Obtained by the following model:

wherein the content of the first and second substances,

an estimation vector representing the uplink CSI

The nth element of (1), i.e., | represents the modulo operation of the complex number, and superscript T represents the transposition operation;

in some embodiments, the uplink CSI estimation vector

Receiving sequences by base station for channel estimation

And performing uplink CSI estimation, wherein the estimation method is selected from one or more of LS estimation, MMSE estimation, ML estimation, MAP estimation and pilot auxiliary estimation.

Preferably, the estimation method is selected from an LS estimation method, and the estimation vector of the uplink CSI

Satisfies the following conditions:

wherein s represents a base station known signal sequence transmitted by the user terminal,

shows that Moore-Penrose pseudo-inverse operation is taken,

represents a base station receiving sequence used for channel estimation, and satisfies the following conditions:

where N denotes channel noise, and g denotes an actual uplink CSI vector, i.e., an estimated vector of uplink CSI

Is an estimate of the vector g.

In some preferred embodiments, the first neural network comprises:

an input layer containing a linear activation function, a hidden layer containing a LeakyReLU activation function, and an output layer containing a linear activation function; the number of nodes of the input layer, the hidden layer and the output layer is N, mN and N respectively, and m represents a hidden layer node coefficient determined according to engineering presetting.

In a specific application, the input of the first neural network is the vector magnitude of the uplink CSI estimation

Outputting the learning amplitude of the downlink CSI with the length of N

More preferably, the training loss function of the first neural network is a mean square error loss function.

In a specific application, the expert knowledge is an existing reconstruction method based on compressed sensing.

In some embodiments, the existing compressed sensing-based reconstruction methods include, for example, minimization based on the norm of L1, basis pursuit algorithm, matching pursuit algorithm, orthogonal matching pursuit algorithm, BIHT algorithm, SCA-BIHT algorithm, and the like.

In some embodiments, the recovery feedback vector

Compress the feedback vector in the superposition vector x for the 1bit recovered at the base station, and:

the 1-bit compressed superposition vector

Obtained at the transmitting end by the following model:

wherein d represents an uplink user data sequence with the length of P, E represents user transmission power, and rho belongs to [0,1 ]]The representation superposition factor can be set according to engineering experience, Q represents a spreading matrix with dimension of P multiplied by L, and Q is satisfied^TQ＝P·I_LWherein the superscript "T" denotes the transposition operation, L denotes the modulation signal length, I_LRepresents an L-dimensional identity matrix, r represents a modulated signal sequence of length L, and:

r＝f_mode(w)；

wherein w represents a feedback vector of a transmitting end with length K, and the recovered feedback vector

For the estimate of the feedback vector w at the base station, K is 2L, and:

w＝[p_real,p_imag,z]；

wherein z ∈ {0,1}^1×NRepresenting a length N support set vector, p, of a downlink CSI vector h_realAnd p_imagRespectively representing the real part and the imaginary part of the downlink CSI with the vector length of M after being compressed and quantized by adopting a 1-bit compressed sensing technology.

Preferably, p is_realAnd p_imagSatisfies the following conditions:

wherein h represents a downlink CSI vector, and the downlink CSI reconstructed vector

The method comprises the steps of representing downlink CSI reconstructed at a base station, phi representing a compression matrix adopting a 1-bit compressed sensing technology, and sign (·), Re (·) and Im (·) respectively representing a sign taking operation, a real part taking operation and an imaginary part taking operation.

In some preferred embodiments, based on the above application, the recovery feedback vector

Further comprising: de-spreading the receiving sequence Y, and obtaining the recovery feedback vector by MMSE detection and interference elimination

Such as, it includes:

obtaining the received sequence by following an over-channel model

Y＝gx+N；

Wherein, Y represents the receiving sequence of the base station end, x represents the 1-bit compressed superposition vector sent by the user end, N represents the channel noise, and g represents the uplink channel vector.

Despread signal obtained by despreading processing model

Obtaining a detection signal by the following MMSE detection model

Where dec (-) denotes a hard decision operation (-)^-1Representing the inverse operation of the matrix, (-)^HRepresents the conjugate transpose operation of the matrix,

representing the variance of the uplink channel;

obtaining a de-interfered data sequence by the following interference elimination model

Obtaining a recovered feedback vector by the following feedback vector recovery model

Wherein f is_demoDenotes demodulation processing, and a recovery feedback vector is obtained

Comprises the following steps:

wherein the content of the first and second substances,

a support set with length N representing the recovered downlink CSI vector h,

and

and respectively representing the real part and the imaginary part of the length M of the recovered downlink CSI vector h compressed and quantized by adopting the 1-bit compressed sensing technology.

In some preferred embodiments, the feedback vector is recovered according to the obtained base station side

Performing characteristic amplitude of downlink CSI

Angle of the characteristic

The process of recovering (1) comprises:

the obtained parameters

The method comprises the following steps of (1) taking the SCA-BIHT algorithm as an input, wherein the SCA-BIHT algorithm is expert knowledge;

outputting the characteristic value of the downlink CSI after circulating n times through an SCA-BIHT algorithm

Wherein n can be preset according to engineering experience;

according to the characteristic value of downlink CSI

Obtaining the downlink CSI characteristic amplitude by the following formula

Angle of the characteristic

Wherein f is_ampDenotes the amplitude operation on a complex number, f_ang(. cndot.) denotes performing an angle operation on a complex number.

In some preferred embodiments, the second neural network comprises:

an input layer containing a linear activation function, a hidden layer containing a LeakyReLU activation function, and an output layer containing a linear activation function; the number of nodes of the input layer, the hidden layer and the output layer is 2N, kN and N respectively, and k represents a hidden layer node coefficient determined according to engineering presetting.

In a specific application, the input of the second neural network is the downlink CSI splicing amplitude

Outputting the fusion amplitude of the downlink CSI with the length of N

Wherein the downlink CSI splicing amplitude

Obtained by the following model:

wherein [ · ] denotes the splicing operation of the vectors.

More preferably, the training loss function of the second neural network is a mean square error loss function.

At one endIn some preferred embodiments, the downlink CSI reconstruction vector

Recovery of (c) is obtained by the following model:

wherein, e represents a Hadamard product, e represents a natural index, and j represents an imaginary number unit.

The invention utilizes the bidirectional reciprocity of the uplink and downlink channels, recovers the amplitude of the downlink CSI through a shallow amplitude learning network, combines the technical advantages of single-bit CS, SC and DL, superimposes the downlink CSI processed by the single-bit CS to the uplink user sequence to be fed back to the base station, recovers the downlink CSI at the base station end by using the traditional UL-US detection and the simplified version of the traditional downlink CSI reconstruction method, and then fuses the amplitude of the downlink CSI obtained by the traditional method and the amplitude learning network through the shallow amplitude fusion network, improves the accuracy of the amplitude of the downlink CSI, and can effectively reduce the mutual interference caused by superposition coding to ensure the reconstruction accuracy of the CSI under the condition of not increasing the frequency spectrum overhead.

Compared with the single-bit CS overlapped CSI feedback, the method recovers the downlink CSI amplitude lost by the single-bit CS according to the bidirectional reciprocity of the uplink and downlink channels, greatly improves the CSI reconstruction precision, and improves the CSI reconstruction efficiency by utilizing a shallow neural network and a simplified version of the traditional downlink CSI reconstruction method.

Drawings

FIG. 1 is a schematic overall flow diagram of the present invention;

FIG. 2 is a schematic diagram of a first neural network structure according to the present invention;

FIG. 3 is a structural diagram of a second neural network according to the present invention.

Detailed Description

The present invention is described in detail below with reference to the following embodiments and the attached drawings, but it should be understood that the embodiments and the attached drawings are only used for the illustrative description of the present invention and do not limit the protection scope of the present invention in any way. All reasonable variations and combinations that fall within the spirit of the invention are intended to be within the scope of the invention.

Referring to fig. 1, a specific 1-bit compression superposition CSI feedback method based on feature extraction and mutual-difference fusion includes:

a1) estimating vectors from uplink CSI

Amplitude of (2)

Obtaining learning amplitude of corresponding downlink CSI through first neural network

More specific embodiments are as follows:

the uplink CSI estimation vector

Receiving sequences by base station for channel estimation

And performing uplink CSI estimation.

The estimation of the uplink CSI may be further implemented by using an uplink CSI estimation method in the prior art, such as LS estimation, MMSE estimation, ML estimation, MAP estimation, pilot-assisted estimation, and the like, for example, in a specific embodiment, the uplink CSI estimation performed by using LS estimation is as follows:

wherein the content of the first and second substances,

indicating the received estimation sequence at the base station end, s indicating the base station known signal transmitted by the user end,

represents the Moore-Penrose pseudo-inverse operation.

Referring to fig. 2, the first neural network includes the following neural network structure:

the device comprises an input layer, a hidden layer and an output layer, wherein the input layer adopts a linear activation function, the hidden layer adopts an activation function LeakyReLU, and the output layer adopts a linear activation function.

The number of nodes of an input layer, a hidden layer and an output layer of the first neural network is N, mN and N respectively, m represents a node coefficient of the hidden layer and can be obtained according to engineering presetting.

Obtaining a learning amplitude of downlink CSI through the first neural network

The process comprises the following steps:

estimating a vector according to the uplink CSI

Obtaining uplink CSI amplitude by

Wherein the content of the first and second substances,

representing vectors

The nth element of (a), i |, represents a modulo operation of a complex number;

estimating vector magnitude of the obtained uplink CSI

Self-transfusionInputting the first neural network in the layer, and outputting the learning amplitude of the downlink CSI with the length of N

The training loss function of the first neural network adopts a mean square error loss function.

a2) Recovering feedback vector obtained from base station

CSI characteristic extraction is carried out by utilizing expert knowledge, and the characteristic amplitude of downlink CSI is recovered

Angle of the characteristic

a3) According to the characteristic amplitude of the downlink CSI

Learning amplitude with downlink CSI

Splicing amplitude of downlink CSI (channel state information) obtained by splicing

Obtaining a fusion amplitude of downlink CSI through a second neural network

More specific embodiments are as follows:

referring to fig. 3, the second neural network is a neural network structure including:

the device comprises an input layer, a hidden layer and an output layer, wherein the input layer adopts a linear activation function, the hidden layer adopts a LeakyReLU activation function, and the output layer adopts a linear activation function.

The number of nodes of an input layer, a hidden layer and an output layer of the second neural network is 2N, kN and N respectively, k represents a node coefficient of the hidden layer and can be obtained according to engineering presetting.

Obtaining a fusion amplitude of downlink CSI through the second neural network

The process of (2) comprises:

by the characteristic amplitude of the downlink CSI

Learning range with the downlink CSI

Obtaining downlink CSI splicing amplitude

Wherein [ ·]A stitching operation that represents a vector is performed,

a real number set with dimension of 1 × 2N is represented;

splicing the obtained downlink CSI

Inputting the second neural network from the input layer, and outputting the fusion amplitude of the downlink CSI with the length of N

The training loss function of the amplitude fusion network adopts a mean square error loss function.

a4) According to the fusion amplitude of the downlink CSI

Angle to said characteristic

Recovering to obtain downlink CSI reconstruction vector

More specific embodiments are as follows:

the recovery obtains a downlink CSI reconstruction vector

The method of (1) is as follows:

wherein, e represents a Hadamard product, e represents a natural index, and j represents an imaginary number unit.

Example 1

In step a1), obtaining an uplink CSI estimation vector through LS estimation

One specific example of (a) is as follows:

suppose that: n-2, P-4, base station-side received sequence for channel estimation

Comprises the following steps:

the base station known signal s sent by the user side is:

s＝[0.7528-0.6083i -0.1666-0.1308i 0.9869+0.4514i 0.4556+0.2695i]；

pseudo inverse matrix of base station known signal s transmitted by user terminal

Comprises the following steps:

according to LS estimation processing formula

Can calculate the uplink CSI estimation vector

Comprises the following steps:

example 2

In the step a2), the lengths of the recovered downlink CSI vectors h compressed and quantized by adopting the 1-bit compressed sensing technology are all the real parts of M

And imaginary part

And recovering the feedback vector

Obtaining a support set with the length of N of the recovered downlink CSI vector h

One specific example of (a) is as follows:

suppose that: n2 and M3, recovering the feedback vector

Comprises the following steps:

according to the formula

The recovered real part of the length M of the downlink CSI vector h compressed and quantized by the 1-bit compressed sensing technology can be obtained

Comprises the following steps:

the lengths of the recovered downlink CSI vectors h compressed and quantized by the 1-bit compressed sensing technology are M imaginary parts

Comprises the following steps:

support set with length N of recovered downlink CSI vector h

Comprises the following steps:

example 3

In step a1), the vector is estimated by uplink CSI

Obtaining uplink CSI estimation vector magnitude

One specific example of (a) is as follows:

estimating the CSI obtained in example 1Vector

According to the formula

Computing inputs in an amplitude learning network

Comprises the following steps:

example 4

In step a3), obtaining downlink CSI splicing amplitude

One specific example of (a) is as follows:

suppose that: n2, characteristic amplitude of downlink CSI

Learning amplitude of downlink CSI

According to the model

The input namely downlink CSI splicing amplitude in the amplitude fusion network can be obtained

Comprises the following steps:

example 5

In the step a4), recovering to obtain the downlink CSI reconstruction vector

One specific example of (a) is as follows:

suppose that: n2, fusion amplitude of downlink CSI

Characteristic angle of downlink CSI

According to the model

The recovered downlink CSI reconstruction vector can be calculated

Comprises the following steps:

the above examples are merely preferred embodiments of the present invention, and the scope of the present invention is not limited to the above examples. All technical schemes belonging to the idea of the invention belong to the protection scope of the invention. It should be noted that modifications and embellishments within the scope of the invention may be made by those skilled in the art without departing from the principle of the invention, and such modifications and embellishments should also be considered as within the scope of the invention.

Claims (7)

1. The 1bit compression superposition CSI feedback method based on feature extraction and mutual-difference fusion is characterized by comprising the following steps:

estimation vector based on uplink CSI

Amplitude of (2)

Obtaining correspondences via a first neural networkLearning range of downlink CSI

Based on recovered feedback vector

CSI characteristic extraction is carried out by utilizing expert knowledge, and the characteristic amplitude of downlink CSI is recovered

Angle of the characteristic

Wherein the recovery feedback vector

The feedback vector is a corresponding feedback vector obtained by a base station receiving end after recovery according to a feedback vector w sent by a transmitting end;

according to the characteristic amplitude of the downlink CSI

Learning range with downlink CSI

Splicing amplitude of downlink CSI (channel state information) obtained by splicing

Obtaining a fusion amplitude of downlink CSI through a second neural network

According to the fusion amplitude of the downlink CSI

Angle to said characteristic

Recovering to obtain downlink CSI reconstruction vector

Wherein the recovery feedback vector

The feedback vector in the superposition vector x is compressed for 1bit recovered at the base station, and:

the 1-bit compressed superposition vector

Obtained at the transmitting end by the following model:

wherein d represents an uplink user data sequence with the length of P, E represents user transmission power, and rho belongs to [0,1 ]]The superposition factor is expressed and can be set according to engineering experience, Q represents a spreading matrix with dimension of P multiplied by L and satisfies Q^TQ＝P·I_LWhere the superscript T denotes the transposition operation, L denotes the modulation signal length, I_LExpressing an L-dimensional identity matrix, and r expressing a modulation signal sequence with the length of L;

obtaining the recovery feedback vector

The process of (2) comprises:

despread signal obtained by despreading processing model

Wherein, Y represents a receiving sequence of NxP dimension at the base station end;

obtaining a detection signal by the following MMSE detection model

Where dec (-) denotes a hard decision operation and g denotes an upstream channel vector, (.)^-1Representing the inverse operation of the matrix, (-)^HRepresents the conjugate transpose operation of the matrix,

representing the variance of the uplink channel;

obtaining a de-interfered data sequence by the following interference elimination model

Obtaining a recovered feedback vector by the following feedback vector recovery model

Wherein f is_demoDenotes demodulation processing, and a recovery feedback vector is obtained

Comprises the following steps:

wherein the content of the first and second substances,

a support set with length N representing the recovered downlink CSI vector h,

and

respectively representing the real part and the imaginary part of the length M of the recovered downlink CSI vector h compressed and quantized by adopting a 1-bit compressed sensing technology;

characteristic amplitude of the downlink CSI

Angle of the characteristic

The process of recovering (1) comprises:

the obtained parameters

The SCA-BIHT algorithm is used as the input of the SCA-BIHT algorithm, wherein the SCA-BIHT algorithm is expert knowledge;

outputting the characteristic value of the downlink CSI after circulating n times through an SCA-BIHT algorithm

Wherein n can be preset according to engineering experience;

according to the characteristic value of downlink CSI

Obtaining the downlink CSI characteristic amplitude by the following formula

Angle of the characteristic

Wherein f is_ampDenotes the amplitude operation on a complex number, f_ang(. cndot.) denotes performing an angle operation on a complex number.

2. The method of claim 1, wherein the uplink CSI estimation vector magnitude

Obtained by the following model:

wherein the content of the first and second substances,

an estimation vector representing the uplink CSI

The nth element, |, represents the modulo operation of the complex number, and the superscript T represents the transpose operation.

3. The method of claim 2, wherein the estimation vector of the uplink CSI is estimated based on a Channel State Information (CSI)

Obtained by the following model:

wherein s represents a base station known signal sequence transmitted by the user terminal,

showing that Moore-Penrose pseudo-inverse operation is taken,

represents a base station receiving sequence used for channel estimation, and satisfies the following conditions:

where N denotes channel noise and g denotes an actual uplink CSI vector.

4. The method of claim 2, wherein the first neural network comprises:

an input layer containing a linear activation function, a hidden layer containing a Leaky ReLU activation function, and an output layer containing a linear activation function; the number of nodes of the input layer, the hidden layer and the output layer is N, mN and N respectively, and m represents a hidden layer node coefficient determined according to engineering presetting.

5. The method of claim 2, wherein the second neural network comprises:

an input layer containing a linear activation function, a hidden layer containing a Leaky ReLU activation function, and an output layer containing a linear activation function; the number of nodes of the input layer, the hidden layer and the output layer is 2N, kN and N respectively, and k represents a hidden layer node coefficient determined according to engineering presetting.

6. The method of claim 1, wherein the neural network is trained by a mean square error loss function.

7. The method of claim 1, wherein the downlink CSI reconstruction vector

Recovery of (c) is obtained by the following model:

wherein, e represents a Hadamard product, e represents a natural index, and j represents an imaginary number unit.

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