WO2019041470A1 - 大规模mimo鲁棒预编码传输方法 - Google Patents
大规模mimo鲁棒预编码传输方法 Download PDFInfo
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- WO2019041470A1 WO2019041470A1 PCT/CN2017/106351 CN2017106351W WO2019041470A1 WO 2019041470 A1 WO2019041470 A1 WO 2019041470A1 CN 2017106351 W CN2017106351 W CN 2017106351W WO 2019041470 A1 WO2019041470 A1 WO 2019041470A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B7/00—Radio transmission systems, i.e. using radiation field
- H04B7/02—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
- H04B7/04—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
- H04B7/0413—MIMO systems
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B7/00—Radio transmission systems, i.e. using radiation field
- H04B7/02—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
- H04B7/04—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
- H04B7/0413—MIMO systems
- H04B7/0456—Selection of precoding matrices or codebooks, e.g. using matrices antenna weighting
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B17/00—Monitoring; Testing
- H04B17/30—Monitoring; Testing of propagation channels
- H04B17/391—Modelling the propagation channel
- H04B17/3912—Simulation models, e.g. distribution of spectral power density or received signal strength indicator [RSSI] for a given geographic region
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B7/00—Radio transmission systems, i.e. using radiation field
- H04B7/02—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
- H04B7/04—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
- H04B7/0413—MIMO systems
- H04B7/0417—Feedback systems
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- the invention belongs to the field of communication technologies and relates to a massive MIMO robust precoding transmission method.
- MIMO multiple-input multiple-output
- the large-scale MIMO precoding transmission method is related to the performance gain that can be achieved by large-scale MIMO.
- Precoding can be divided into linear precoding and nonlinear precoding.
- Nonlinear precoding can achieve approximate optimal performance, but its complexity is too high.
- the basic research in the large-scale MIMO related literature is linear precoding, and most of them are downlink linear precoding for single antenna users. For a single-antenna user massive MIMO downlink, linear precoding can achieve approximately optimal performance when the number of transmit antennas is much larger than the number of receive antennas.
- the linear precoding commonly used in the literature is matched filter (MF, Match Filter) precoding and regularized zero forcing (RZF) precoding.
- the user terminal in the mobile communication system has adopted a multi-antenna device.
- multi-antenna users will continue to exist. Therefore, the research on large-scale MIMO precoding design for multi-antenna users cannot be avoided.
- Nonlinear precoding has a very high complexity and is currently not applicable to massive MIMO.
- simple linear precoding such as MF precoding and RZF precoding, cannot achieve approximate optimal performance when the number of transmitting antennas is limited.
- linear precoding to maximize weighted traversal and rate is considered.
- the precoding design depends on the channel state information (CSI, Channel State Information) that the base station can obtain.
- CSI Channel State Information
- the widely used iterative weighted minimum mean square error (WMMSE, Weighted MMSE) precoding method in the traditional multi-user MIMO system can be directly extended to the massive MIMO system.
- the method can converge to a local optimal solution that maximizes the weighting and rate optimization problem.
- WMMSE weighted minimum mean square error
- WMMSE weighted minimum mean square error
- BDMA Wavelength Division Multiple Access
- JSDM Joint Spatial Division and Multiplexing
- each user channel information available at the base station needs to be modeled as a joint correlation model of known channel mean and variance. Since the CSI obtained by the base station has both channel mean and variance information, neither the BDMA transmission method nor the JSDM method can be applied.
- the present invention discloses a large-scale MIMO robust precoding transmission method, which can solve the adaptability problem of large-scale MIMO technology in various typical scenarios.
- the present invention provides the following technical solutions:
- a massive MIMO robust precoding transmission method under imperfect channel state information comprising: based on a pilot signal and a priori statistical channel model, a base station or a transmitting device obtains a posteriori statistical channel model of a mobile terminal or a receiving device channel, including a channel mean Or expected value, and variance information; the base station or transmitting device performs robust precoding transmission using a posteriori statistical channel model including channel mean or expected value, and variance information.
- a priori statistical correlation channel model is obtained by the following steps:
- the base station or the transmitting device obtains through uplink channel sounding
- the a priori statistical correlation channel model adopts one of the following models: a joint correlation channel model, a separation correlation model and a full correlation model.
- the posterior statistical channel model is obtained by the following steps:
- the base station or the transmitting device obtains channel information by channel estimation and prediction by using an uplink pilot signal and a priori joint correlation channel model;
- Channel information is obtained based on channel estimation, prediction, and feedback by the mobile terminal or the receiving device using the downlink pilot signal and the a priori joint correlation channel model.
- the channel mean or expected value and the variance information in the a posteriori statistical channel model include a channel posterior mean or a posteriori expectation value, and a posteriori variance information.
- channel posterior mean or expected value, and the posterior variance information include:
- conditional mean or conditional expectation value and conditional variance information of the mobile terminal or the receiving device under the condition of the received downlink pilot signal are provided.
- the a posteriori statistical channel model is a posteriori statistical channel model including channel estimation error, channel aging, and spatial correlation effects.
- the posterior statistical correlation channel model and the prior statistical channel model adopt one of the following models: a joint correlation channel model, a separation correlation model and a full correlation model.
- the base station or the transmitting device performs a linear precoding matrix design of each mobile terminal or receiving device according to the weighted traversal and rate maximization criteria, and the weighted traversal and rate are based on the established posterior The weighted sum rate conditional mean calculated by the statistical channel model.
- the weighted traversal is performed by the MM algorithm.
- the rate maximization precoding design problem is transformed into an iterative solution quadratic optimization problem.
- the random matrix expectation required for solving the quadratic optimization problem is calculated by using the deterministic equivalent.
- a method for acquiring a large-scale MIMO downlink robust precoding domain pilot multiplex channel information under the imperfect channel state information includes: obtaining, by the base station or the transmitting device, a posterior statistical channel model of the mobile terminal or the receiving device channel, including a channel mean or an expected value, And the variance information; the base station or the transmitting device performs robust precoding transmission using a posteriori statistical channel model including channel mean or expected value and variance information; in the robust precoding transmission, the downlink is implemented in the precoding domain
- the pilot multiplex channel information is acquired, and the base station or the transmitting device sends a downlink pilot signal to each mobile terminal or the receiving device in the precoding domain, and the mobile terminal or the receiving device uses the received pilot signal to perform the precoding domain equivalent channel.
- Channel estimation, the precoding domain equivalent channel is the actual transmission channel multiplied by the robust precoding matrix.
- the precoding domain pilot signals transmitted by the base station or the transmitting device to each mobile terminal or the receiving device are transmitted on the same time-frequency resource, and the pilots of the mobile terminals or the receiving devices are not required to be orthogonal.
- the precoding domain pilot signal transmitted by the base station or the transmitting device to each mobile terminal or the receiving device is a frequency domain signal modulated by the ZC sequence or the ZC sequence group.
- a receiving method for massive MIMO robust precoding transmission includes: a transmitting signal transmitted by robust precoding is received by a mobile terminal or a receiving device after passing through a transmission channel, and the mobile terminal or the receiving device uses the received transmitting signal to receive a signal. deal with.
- the received transmission signal includes a downlink full pilot frequency signal, and/or a robust precoding domain pilot signal, and/or a robust precoding domain data signal.
- the pilot signal is a frequency domain signal generated by modulation of a ZC sequence or a ZC sequence group.
- the mobile terminal or the receiving device performs channel estimation, prediction, and feedback using the received downlink full pilot frequency signal.
- the mobile terminal or the receiving device performs channel estimation of the precoding domain equivalent channel by using the received robust precoding domain pilot signal.
- the mobile terminal or the receiving device performs demodulation or detection of the precoding domain signal by using the received robust precoding domain data signal.
- the present invention has the following advantages and benefits:
- the large-scale MIMO robust transmission method proposed by the present invention can solve the universality problem of large-scale MIMO for various typical mobile scenarios and achieve high spectral efficiency.
- the invention utilizes a posteriori statistical channel model including channel mean and variance information for robust precoding transmission, and the statistical channel model used is more complete and accurate; the robust precoding method can realize dimensionality reduction transmission, which can reduce the data transmission required
- the pilot overhead reduces the complexity of demodulation or detection and improves the overall efficiency of the transmission.
- 1 is a flowchart of a massive MIMO downlink robust precoding transmission method
- 2 is a flowchart of another method for massive MIMO downlink robust precoding transmission
- FIG. 3 is a flowchart of a method for acquiring channel information of a massive MIMO downlink robust precoding domain
- FIG. 4 is a flowchart of a receiving method for massive MIMO downlink robust precoding transmission
- 5 is a flow chart of another receiving method for massive MIMO downlink robust precoding transmission
- FIG. 6 is a flowchart of a massive MIMO downlink robust linear precoding design method
- FIG. 7 is a schematic diagram of comparison of traversal and rate results of the robust precoding transmission method and the BDMA method in the present embodiment under the downlink of the massive MIMO system;
- FIG. 8 is a schematic diagram of a robust precoding transmission method in this embodiment under the downlink of a massive MIMO system under consideration. A comparison of the traversal and rate results of the rod RZF method in three different mobile scenarios.
- a method for transmitting a large-scale MIMO downlink robust precoding includes: a base station obtains a prior channel joint correlation channel model of each user channel by using an uplink channel sounding; and the base station uses an uplink pilot signal and a first A joint correlation channel model is obtained, and a posteriori joint correlation channel model of each user channel is obtained through channel estimation and prediction, including channel mean and variance information; the base station performs robust precoding using a posteriori joint correlation channel model including channel mean and variance information. transmission.
- the base station referred to in the present invention may also employ other transmitting devices capable of transmitting and transmitting information.
- the channel mean is also often referred to as the expected value.
- another large-scale MIMO downlink robust precoding transmission method disclosed in the embodiment of the present invention includes a mobile terminal obtaining a channel prior a joint correlation channel model through downlink channel sounding; and a mobile terminal using a downlink pilot signal. And a priori joint channel model, obtaining a posteriori joint correlation channel model of each channel through channel estimation and prediction and feeding back to the base station, the posterior joint correlation model including channel mean and variance information; the base station utilizing channel mean and variance information The posterior joint correlation model performs robust precoding transmission.
- the mobile device referred to in the present invention may also employ other receiving devices capable of receiving information.
- a method for acquiring a large-scale MIMO downlink robust precoding domain pilot multiplexed channel information includes a base station using a pilot signal and a prior statistical channel model to obtain a posterior of a mobile terminal.
- the statistical channel model includes channel mean and variance information; the base station performs robust precoding design using a posteriori statistical channel model including channel mean and variance information; the base station transmits robust precoding domain pilots to each user on the same time-frequency resource
- the signal, the robust precoding domain pilot signal used is a ZC sequence; the mobile terminal uses the received robust precoding domain pilot signal to perform channel estimation of the robust precoding domain equivalent channel, and the robust precoding domain equivalent
- the channel is the actual transmission channel multiplied by the robust precoding matrix.
- a receiving method for massive MIMO downlink robust precoding transmission disclosed in the embodiment of the present invention includes: using a pilot signal and a prior statistical channel model to obtain a posteriori statistical channel model of a mobile terminal, including Channel mean and variance information; the base station or the transmitting device performs robust precoding design using a posteriori joint correlation channel model including channel mean and variance information; the base station transmits the robust precoded signal, including the robust precoding domain guide Frequency signals and data signals; mobile terminals use the received robust precoding domain pilot signals for robustness Channel estimation of the precoding domain equivalent channel; the mobile terminal performs precoding domain signal demodulation or detection using the received data signal and the channel estimation of the precoding domain equivalent channel.
- another method for receiving massive MIMO downlink robust precoding transmission includes: the base station sends a downlink full pilot frequency; and the mobile terminal uses the received full pilot frequency for channel estimation and prediction. And a posteriori statistical channel model of the feedback mobile terminal, including channel mean and variance information; the base station or the transmitting device performs robust precoding design using a posteriori joint correlation channel model including channel mean and variance information; the base station transmits the robust precoding
- the processed signal includes a robust precoding domain pilot signal and a data signal; the mobile terminal utilizes the received robust precoding domain pilot signal to perform channel estimation of the robust precoding domain equivalent channel; and the mobile terminal utilizes the receiving The pre-coded domain signal demodulation or detection is performed on the received data signal and the channel estimate of the precoding domain equivalent channel.
- a method for designing a massive MIMO downlink robust precoding includes a base station establishing a weighted traversal and a rate maximization problem according to a posterior statistical channel model; and a weighted traversal and rate by an MM algorithm.
- the maximization problem is transformed into an iterative solution to the quadratic problem; the random matrix expectation of the closed-type optimal solution of the quadratic problem is used, and its deterministic equivalence is used for fast calculation.
- the method of the present invention is mainly applicable to a large-scale MIMO system equipped with a large-scale antenna array on the base station side to simultaneously serve multiple users.
- the specific implementation process of the robust precoding transmission method of the present invention is described in detail below with reference to a specific communication system example. It should be noted that the method of the present invention is applicable not only to the specific system model cited in the following examples, but also to other configurations. System model.
- the MIMO system consists of one base station and K mobile terminals.
- the number of antennas configured by the base station is M t .
- the number of antennas configured by the kth user is M k , and
- the system time resource is divided into a number of time slots, each of which includes N b time blocks (T symbol intervals).
- the large-scale MIMO system considered in this embodiment operates in a Time Division Duplexing (TDD) mode.
- TDD Time Division Duplexing
- the uplink pilot signal is transmitted only in the first block.
- the second to N b blocks are used for downlink precoding domain pilot signals and data signal transmission.
- the length of the uplink training sequence is the length of the block, that is, T symbol intervals.
- mutually orthogonal training sequences (M r ⁇ T) are used for different uplink transmit antennas.
- FDD Frequency Division Duplexing
- the uplink channel training phase can be replaced with the downlink channel feedback phase, and the downlink transmission phase remains unchanged. Specifically, the downlink full pilot signal is transmitted in the first block, and the mobile terminal feedback is received.
- the large-scale MIMO system channel is considered to be a stationary channel, and the statistical channel model of each user channel can be represented as a joint correlation model.
- the channel from the base station to the kth user on the nth block of the mth slot has the following structure
- U k and V k are deterministic ⁇ matrices
- M k is a deterministic matrix composed of non-negative elements
- W k,m,n is a matrix consisting of zero mean, unit variance, independent and identically distributed complex Gaussian random variables .
- M t can become very large.
- all users have the same V k .
- the base station side is equipped with a uniform linear antenna array and the number of antennas M t is very large.
- all users' V k can be approximated as a DFT matrix.
- the channel model in equation (1) can be rewritten as
- Equation (2) Represents an M t ⁇ M t -dimensional DFT matrix.
- the channel model described in equation (2) can be regarded as a priori model of the channel before channel estimation.
- the time evolution of the channel between blocks and blocks is represented by a first-order Gauss-Markov stochastic model as
- ⁇ k is a time correlation factor related to the user's moving speed.
- J 0 ( ⁇ ) represents the first-order zero-order Bessel function
- vk represents the kth User speed
- f c represents the carrier frequency
- c is the speed of light.
- the model in equation (3) is used for channel prediction.
- the base station obtains a priori joint correlation channel model of each user through channel sounding, that is, obtains U k and ⁇ k .
- a priori joint correlation channel model of each user can be obtained through user downlink channel sounding.
- the CSI of the downlink transmission channel is obtained by channel estimation using the uplink pilot signal received by the base station through channel reciprocity.
- Uplink pilot matrix of the kth user in the first block on the time slot m Indicates an uplink received random noise matrix whose elements have a mean of zero and a variance of And independent and identically distributed complex Gaussian random variables.
- W k,m,n is a matrix consisting of independent and identically distributed, zero mean, unit variance complex Gaussian random variable elements, Medium element is
- Equation (7) indicates that the imperfect CSI of each UE available at the base station side can be modeled as a joint correlation model including channel mean (or expected value) and variance information, and the model includes channel estimation error, channel variation, and Spatially related impacts.
- the channel information obtained by the base station in the equation (7) is a conditional mean value (or conditional expectation value) and conditional variance information of the base station under the condition that the uplink pilot signal is received.
- the a posteriori model described in the equation (7) is a general model of the imperfect CSI available at the base station side of the massive MIMO system in different mobile scenarios. When ⁇ k is very close to 1, it is suitable for a communication scenario when the user is quasi-stationary.
- ⁇ k becomes very small, it is suitable for a communication scenario in which the user moves very fast. Further, in this case It becomes close to zero, and the difference between the a posteriori model in the equation (7) and the a priori model in the equation (2) becomes very small.
- the ⁇ k is set to different values according to different moving speeds of the user, and the established a posteriori model can be used to describe the channel model in a plurality of typical mobile communication scenarios of massive MIMO.
- the channel estimation, prediction and feedback of the mobile terminal can also obtain the posterior joint correlation model in equation (7).
- the base station transmits a downlink full pilot frequency; the mobile terminal performs channel estimation, prediction, and feedback using the received full pilot frequency.
- the channel information obtained in the equation (7) becomes a conditional mean value (or conditional expectation value) and conditional variance information of the mobile terminal under the condition of the received downlink pilot signal.
- P k,m,n are the M k ⁇ d k -dimensional precoding matrices of the kth UE
- z k,m,n is a distribution Complex Gaussian random noise vector
- the transmitted robust precoding domain pilot signals are on the same time-frequency resource, and each user pilot does not require orthogonality, that is, pilot multiplexing can be performed.
- the precoding domain pilot signal transmitted by the base station to each user is a frequency domain signal generated by modulation of a ZC sequence or a ZC sequence group.
- the mobile terminal After receiving the pilot signal, the mobile terminal performs channel estimation of the robust precoding domain equivalent channel, and the robust precoding domain equivalent channel is H k,m,n P k,m,n .
- the UE side can obtain a perfect CSI with an equivalent channel matrix of the respective robust precoding domain.
- each user can perform robust precoding domain signal detection by using the received data signal. Total interference noise per UE
- R k,m,n denote the covariance matrix of z' k,m,n .
- Expectation function ⁇ represents the expected function of H k,m,n based on the user side length statistics. According to the channel reciprocity, the long-term statistical channel information of the user side is consistent with the long-term statistical channel information of the base station end given in the formula (2). Therefore, the expectation function ⁇ can be calculated according to equation (2). Suppose the kth UE knows R k,m,n , and the kth user traversal rate can be expressed as
- a conditional expectation function for H k,m,n derived from the posterior model in equation (7) is represented.
- Defining function represents the weighted traversal and rate, which is the weighted sum rate conditional mean calculated from the established posterior statistical channel model.
- the purpose of this embodiment is to design the precoding matrix P 1,m,n ,P 2,m,n ,...,P K,m,n to maximize the weighted traversal and rate, ie to solve the optimization problem.
- w k is the weighting factor of the kth user and P is the total power constraint.
- the objective function in the optimization problem (13) is a very complex function about the precoding matrix, so the problem is difficult to solve directly.
- the MM (Minorize Maximization or Majorize Minimization) algorithm can be used to transform the weighted traversal and rate maximization precoding design problem into an iterative solution quadratic optimization problem.
- the key to the MM algorithm is to find a simple minorizing function for the objective function. For simplicity, define a single-sided correlation matrix with for
- the limit point of the precoding matrix sequence given in equation (26) is a local maximum point of the original optimization problem (13). Further, the optimization problem in the equation (26) is a concave quadratic function of the precoding matrix P 1, m, n , P 2, m, n , ..., P K, m, n .
- the optimal solution can be obtained directly by the Lagrange multiplier method.
- ⁇ * is the optimal Lagrangian factor corresponding to the energy constraint.
- the channel model given in equation (7) is a joint correlation model with a non-zero mean.
- the deterministic equivalent of R k,m,n is
- Step 3 Calculate ⁇ k, m, n and according to equations (34)-(35)
- Step 4 Calculate according to equations (22), (38), (39) with
- a comparison of the results of the robust precoding transmission method and the BDMA method in the present embodiment is given.
- Figure 7 shows the traversal and rate results comparison of the robust precoding transmission method and the BDMA method in the present embodiment under the downlink of the massive MIMO system under consideration.
- the robust precoding transmission method in this embodiment is significantly superior to the BDMA method. This is because in the robust precoding transmission method, the base station performs robust precoding transmission using a posteriori joint correlation model including channel mean (or expected value) and variance information, and the BDMA method utilizes prior joint correlation including only channel variance information. The model transmits and fails to make full use of the statistical channel information available to the base station.
- the robust RZF method is an extension of the RZF precoding method widely used in single-antenna user massive MIMO systems under imperfect channel state information.
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- 非完美信道状态信息下大规模MIMO鲁棒预编码传输方法,其特征在于,包括:基于导频信号和先验统计信道模型,基站或发送装置获得移动终端或接收装置信道的后验统计信道模型,包含信道均值或期望值、以及方差信息;基站或发送装置利用包含信道均值或期望值、以及方差信息的后验统计信道模型进行鲁棒预编码传输。
- 根据权利要求1所述的非完美信道状态信息下大规模MIMO鲁棒预编码传输方法,其特征在于,所述先验统计相关信道模型通过以下步骤获得:基站或发送装置通过上行信道探测获得;或通过移动终端或接收装置基于下行信道探测获得。
- 根据权利要求1所述的非完美信道状态信息下大规模MIMO鲁棒预编码传输方法,其特征在于,所述先验统计相关信道模型采用以下模型中的一种:联合相关信道模型,分离相关模型和全相关模型。
- 根据权利要求1所述的非完美信道状态信息下大规模MIMO鲁棒预编码传输方法,其特征在于,所述后验统计信道模型通过以下步骤获得:基站或发送装置利用上行导频信号和先验联合相关信道模型,通过信道估计和预测获得信道信息;或通过移动终端或接收装置利用下行导频信号和先验联合相关信道模型,基于信道估计、预测、反馈获得信道信息。
- 根据权利要求1所述的非完美信道状态信息下大规模MIMO鲁棒预编码传输方法,其特征在于,所述后验统计信道模型中信道均值或期望值、以及方差信息包括信道后验均值或后验期望值、以及后验方差信息。
- 根据权利要求5所述的非完美信道状态信息下大规模MIMO鲁棒预编码传输方法,其特征在于,所述信道后验均值或期望值、以及后验方差信息包括:基站或发送装置在接收到的上行导频信号条件下的条件均值或条件期望值、以及条件方差信息;或移动终端或接收装置在接收到的下行导频信号条件下的条件均值或条件期望值、以及条件方差信息。
- 根据权利要求1所述的非完美信道状态信息下大规模MIMO鲁棒预编码传输方法,其特征在于,所述后验统计信道模型为包含信道估计误差、信道老化和空间相关影响的后验统计信道模型。
- 根据权利要求1所述的非完美信道状态信息下大规模MIMO鲁棒预编码传输方法,其特征在于,所述后验统计相关信道模型采用以下模型中的一种:联合相关信道模型,分离相关模型和全相关模型。
- 根据权利要求1所述的非完美信道状态信息下大规模MIMO鲁棒预编码传输方法,其特征在于,在所述的鲁棒预编码传输中,基站或发送装置根据加权遍历和速率最大化准则,进行各移动终端或接收装置的线性预编码矩阵设计,加权遍历和速率为根据所建立后验统计信道模型计算出的加权和速率条件均值。
- 根据权利要求1所述的非完美信道状态信息下大规模MIMO鲁棒预编码传输方法,其特征在于,在所述的鲁棒预编码传输过程中,基站或发送装置根据加权遍历和速率最大化准则进行各移动终端或接收装置的线性预编码设计时,通过MM算法将所述将加权遍历和速率最大化预编码设计问题转化为迭代求解二次型优化问题进行求解。
- 根据权利要求10所述的非完美信道状态信息下大规模MIMO鲁棒预编码传输方法,其特征在于,所述二次型优化问题求解时所需的随机矩阵期望,利用其确定性等同进行快速计算。
- 非完美信道状态信息下大规模MIMO下行鲁棒预编码域导频复用信道信息获取方法,其特征在于,包括:基站或发送装置获得移动终端或接收装置信道的后验统计信道模型,包含信道均值或期望值、以及方差信息;基站或发送装置利用包含信道均值或期望值、以及方差信息的后验统计信道模型进行鲁棒预编码传输;在所述的鲁棒预编码传输中,下行链路在预编码域实施导频复用信道信息获取,基站或发送装置在预编码域向各移动终端或接收装置发送下行导频信号,移动终端或接收装置利用接收到的导频信号,进行预编码域等效信道的信道估计,预编码域等效信道为实际的传输信道乘以鲁棒预编码矩阵。
- 根据权利要求12所述的非完美信道状态信息下大规模MIMO下行鲁棒预编码域导频复用信道信息获取方法,其特征在于,基站或发送装置向各移动终端或接收装置发送的预编码域导频信号在同一时频资源上发送,各移动终端或接收装置的导 频不要求正交。
- 根据权利要求12所述的非完美信道状态信息下大规模MIMO下行鲁棒预编码域导频复用信道信息获取方法,其特征在于,基站或发送装置向各移动终端或接收装置发送的预编码域导频信号为ZC序列或ZC序列组经过调制生成的频域信号。
- 大规模MIMO鲁棒预编码传输的接收方法,其特征在于,包括:通过鲁棒预编码传输的发送信号经过传输信道后由移动终端或接收装置进行接收,移动终端或者接收装置利用接收到的发送信号进行接收信号处理。
- 根据权利要求15所述的大规模MIMO鲁棒预编码传输的接收方法,其特征在于,所述的接收到的发送信号包括下行全向导频信号,和/或鲁棒预编码域导频信号,和/或鲁棒预编码域数据信号。
- 根据权利要求16所述的大规模MIMO鲁棒预编码传输的接收方法,其特征在于,所述导频信号为ZC序列或ZC序列组经过调制生成的频域信号。
- 根据权利要求15所述的大规模MIMO鲁棒预编码传输的接收方法,其特征在于,在所述的接收信号处理中,移动终端或接收装置利用接收到的下行全向导频信号进行信道估计、预测和反馈。
- 根据权利要求15所述的大规模MIMO鲁棒预编码传输的接收方法,其特征在于,在所述的接收信号处理中,移动终端或接收装置利用接收到的鲁棒预编码域导频信号进行预编码域等效信道的信道估计。
- 根据权利要求15所述的大规模MIMO鲁棒预编码传输的接收方法,其特征在于,在所述的接收信号处理中,移动终端或接收装置利用接收到的鲁棒预编码域数据信号进行预编码域信号的解调或检测。
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