Conditional mutual information (CMI) analysis and precoding design for generally correlated wireless multi-hop multi-input multi-output (MIMO) channels are presented in this paper. Although some particular scenarios have been examined in existing publications, this paper investigates a generally correlated transmission system having spatially correlated channel, mutually correlated source symbols, and additive colored Gaussian noise (ACGN). First, without precoding techniques, we derive the optimized source symbol covariances upon mutual information maximization. Secondly, we apply a precoding technique and then design the precoder in two cases: maximizing the mutual information and minimizing the detection error. Since the optimal design for the end-to-end system cannot be analytically obtained in closed form due to the non-monotonic nature, we relax the optimization problem and attain sub-optimal designs in closed form. Simulation results show that without precoding, the average mutual information obtained by the asymptotic design is very close to the one obtained by the optimal design, while saving a huge computational complexity. When having the proposed precoding matrices, the end-to-end mutual information significantly increases while it does not require resources of the system such as transmission power or bandwidth.
Hinweise
Competing interests
The authors declare that they have no competing interests.
1 Introduction
With the fast-paced development of computing technologies, wireless devices have enough computation and communication capabilities to support various multimedia applications. To deliver high-quality multimedia over a wireless channel, multi-input multi-output (MIMO) technology has been emerging as one of the enabling technologies for the next-generation multimedia systems by providing very high-speed data transmission over wireless channels [1]. In the last decade, MIMO has been adopted by almost all new LTE, 3GPP, 3GPP2, and IEEE standards for wireless broadband transmission to support wireless multimedia applications [2-7]. A fundamental assumption of MIMO system design is placing antennas far enough [3] from each other to make fading uncorrelated. It means that different pairs of transmitting and receiving antennas are uncorrelated so that the channel statistical knowledge can be expressed as a diagonal covariance matrix. However, this assumption is no longer held true for compact embedded multimedia system design due to the small form factor. The compact system design will cause a MIMO spatial correlation problem [8-13], leading to a significant deterioration on the system performance. Furthermore, the pervasive use of computing devices such as laptop computers, PDAs, smart phones, automotive computing devices, wearable computers, and video sensors leads to a fast-growing deployment of wireless mesh networks (WMN) [14] to connect these computing devices by a multi-hop wireless channel. Therefore, how to achieve high channel capacity by using multi-hop MIMO transceivers under strict space limitations is the fundamental question targeted in this paper.
In the first part of this paper, we analyze the capacity (or bound on the capacity) of generally correlated wireless multi-hop amplify-and-forward (AF) MIMO channels. For generality, we consider a wireless system, in which the channel at each hop is spatially correlated but independent of that at the other hops, the source symbols are mutually correlated, and the additive Gaussian noises are colored. Although most previous works on wireless channel only consider white noise and uncorrelated data symbols, the assumption of white noise is not always true (see, e.g.,[15-19]). Moreover, in practice, the case of correlated data symbols arises due to various signal processing operations at the baseband in the transmitter.
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For less than three-hop wireless channel, various works have been done on the capacity or bounds on the capacity [1,13,20-24]. For multi-hop relay network, capacity analysis was proposed in [25-27]. In [25], the authors considered rate, diversity, and network size in the analysis. In [26,27], the authors assumed that there is no noise at relay nodes, and the number of antennas is very large. Since these assumptions are not feasible in compact MIMO design with mutual interference, in this paper, we consider a generally correlated system at the wireless fading channel, data symbols, and additive colored Gaussian noises (ACGN). It includes the correlated system assumption in [26,27] as a special case. First, we derive the optimal source symbol covariance to maximize the mutual information between the channel input and the channel output when having the full knowledge of channel at the transmitters. Secondly, the numerical interior point method-based solution and an asymptotic solution in closed form are derived to maximize the average mutual information when having only the channel statistics at the transmitters. Although the asymptotic design is very simple and comes by maximizing an upper bound of the objective function, simulation results show that the asymptotic design performs well as the numerically optimal design.
In the second part of this paper, we apply the precoding technique and then design the precoding matrix to either maximizing the mutual information or minimizing the detection error. It has been shown in [20] that beamforming, which can be considered as a particular case of precoding, increases the mutual information of single-hop MIMO channel. In [28], the outage capacity of multi-hop MIMO networks is investigated, and the performance of several relaying configurations and signaling algorithms is discussed. In [25], the authors considered rate, diversity, and network size in the analysis. The multi-hop capacity of OFDM-based MIMO-multiplexing relaying systems is derived in [29,30] for frequency-selective fading channels. Apparently, in the literature, only references [26,27] actually study the asymptotic capacity and precoding design for wireless correlated multi-hop MIMO relay networks. Under a special case of wireless channels having only white noise at the destination, no noise at all relay levels, and the number of antennas is very large (to infinity); references [26,27] provide the precoding strategy and asymptotic capacity. Since the special wireless channel assumption in [26,27] is not always feasible for compact MIMO design with space limitation and mutual interference at various signal-to-noise ratio (SNR) levels, in this paper, we design precoders for the generally correlated AF system. Obviously, the optimal capacity and precoding design cannot be analytically obtained in closed form as the design problem is very complicated and neither convex nor concave. Similarly to [26,27], for generally correlated multi-hop MIMO channels, we propose asymptotic designs in closed form.
First, instead of designing the optimal precoding strategy to maximize the end-to-end mutual information, we derive the sub-optimal precoding strategy by optimally maximizing the mutual information between the input and output signals at each hop. Since the mutual information and detection error have a very close relationship, we further propose the other sub-optimal precoding strategy by optimally minimizing the mean square error (MSE) of the soft detection of the transmitted signal at each hop. Simulation results show that the asymptotic precoding designs are efficient. They significantly increase the end-to-end mutual information, while do not require any resource of the system such as transmission power or bandwidth.
The paper is organized as follows. Section 2 first describes the correlated wireless multi-hop MIMO model without any precoding techniques and then designs the source signal covariance to maximize the mutual information in two cases: having full knowledge of channel state information at the transmitters and having only the channel statistics at the transmitters. Section 3 first proposes the precoding design to maximize the mutual information and then proposes the precoding design to minimize the soft detection error. Simulation results are provided in Section 4 and Section 5 concludes the paper.
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Notation: Boldface upper and lower cases denote matrices and column vectors. Superscript ∗ and H depict the complex conjugate and the Hermitian adjoint operator, while ⊗ stands for the Kronecker product. IN is the N×N identity matrix. Sometimes, the index N are omitted when the size of the identity matrix is clear in the context. E{z} is the expectation of the random variable z and tr{A} is the trace of the matrix A. \(\mathcal {I}(.)\) and \(\mathcal {H}(.)\) denote the mutual information and the entropy, respectively. Rxy depicts the covariance matrix of two random variables x and y. A≤B (A<B, respectively) for symmetric matrices A and B means that B−A is a positive semi-definite (definite, respectively) Hermitian matrix.
2 The correlated channel and mutual information maximization
2.1 Spatially correlated wireless multi-hop MIMO channel
Consider an N-hop wireless MIMO channel as presented in Figure 1. The MIMO system has a0 antennas at the source, ai antennas at the i-th relay, and aN antennas at the destination. Then, the channel gain matrix at the i-th hop is represented by the Kronecker model [11,12,31-35] as:
and Σti and Σri are ai−1×ai−1 and ai×ai known covariance matrices that capture the correlations of the transmitting and receiving antenna arrays, respectively. The matrix Hwi is an ai×ai−1 matrix whose entries are independent and identically distributed (i.i.d.) circularly symmetric complex Gaussian random variables of variance \(\sigma _{\textit {hi}}^{2}\), i.e., \(\mathcal {CN}(0,\sigma _{\textit {hi}}^{2})\). The known matrices Σri and Σti are assumed to be invertible and have the following forms:
where tij (rnm, respectively) with i≠j (n≠m, respectively) reflects the correlated fading between the i-th and the j-th (n-th and m-th, respectively) elements of the transmitting (receiving, respectively) antenna array. The channel at each hop undergoes correlated MIMO Rayleigh flat fading. However, the fading channels of any two different hops are independent. Moreover, the channel at each hop is quasi-static block fading with a suitable coherence time for the system to be in the non-ergodic regime.
The ACGN at i-th hop is definied as ni with zero-mean and covariance matrix \({\sf E}\{\mathbf {n}_{i} \mathbf {n}_{i}^{H}\}=\mathbf {R}_{i}\), i=1,…,N. Additionally, n1,…,nN are all independent of each other, i.e., the colored noise at each hop is statistically uncorrelated with the colored noise at the other hops.
The vector x0 that contain the data symbols at the source is modeled as complex random variables with covariance matrix \(\mathbf {R}_{x_{0}}=\mathsf {E}\left \{\mathbf {x_{0}} \mathbf {x_{0}}^{H}\right \}\) under the power constraint \(\mathsf {tr}\{\mathbf {R}_{x_{0}}\}=P_{0}\). For the general case of correlated data symbols, \(\mathbf {R}_{x_{0}} \neq \beta \mathbf {I}_{a_{0}}, \beta >0\), while \(\mathbf {R}_{x_{0}}={\sf E}\left \{\mathbf {x_{0}} \mathbf {x_{0}}^{H}\right \}= \beta \mathbf {I}_{a_{0}}\) for the case of uncorrelated data symbols.
Accordingly, the received signal at the destination can be expressed as:
2.2 Mutual information maximization and channel capacity when having channel state information at the transmitters
The conditional mutual information (CMI) [36] between the transmitted signal x0 and the received signal \(\dot {\mathbf {y}}_{N}\) in Equation 4 is given by:
where p(x) is the probability mass function (PMF) of the random variable x0. The maximum is taken over all possible input distributions p(x).
Note that we have the fundamental condition [37] det(I+XY)= det(I+YX). By Theorem 3 and Theorem 4 in the Appendix, the CMI in Equation 6 can be expressed as:
under the allowed transmitted signal power P0. For simple cases of channel characteristics, the solution of Equation 10 can be derived from the Hadamard inequality argument [36]. We now give a direct solution method based on spectral optimization for the general case.
Let \(\mathbf {Q}=\mathbf {R}_{x_{0}} \geq 0\) and \(\mathbf {P}=\mathbf {G}_{N}^{H}\mathbf {R}_{\dot {n}}^{-1}\mathbf {G}_{N}>0\). Equation 10 can be written as:
is \(\mathbf {Q}=\mathbf {U}^{H}\mathbf {D}_{P}^{-1}\mathbf {XU}\). Here, U is the unitary matrix obtained from the singular value decomposition (SVD) of P=UHDPU, and X is the diagonal matrix having its diagonal elements X(i,i) satisfy:
2.3 Average mutual information maximization and channel capacity with only the channel statistics at the transmitters
The end-to-end mutual information between the transmitted signal x0 and received signal \(\dot {\mathbf {y}}_{N}\) in Equation 4 is given by Equation 6. When considering the mutual information for a long time period, the average end-to-end mutual information between channel input x0 and channel output \((\dot {\mathbf {y}}_{N},\mathbf {G}_{N})\) can be expressed as:
to obtain the capacity in the non-ergodic regime of the system. Since the objective function is the expectation of a concave function with respect to the to-be-designed variable, obtaining the optimal solution in closed form to this problem is very difficult or almost impossible. We propose to use ‘SeDuMi’ [38] or ‘SDPT 3’ [39] solver for a numerically optimal solution. To reduce the computational complexity, an asymptotic solution in closed form is also derived by relaxing the objective function.
Since the function \(\mathbf {R}_{x_{0}}\rightarrow \log \det \left (\mathbf {I}+\mathbf {R}_{x_{0}}\mathbf {G}_{N}^{H}\mathbf {R}_{\dot {n}}^{-1}\mathbf {G}_{N}\right)\) is concave, it is obvious that:
Therefore, instead of maximizing the average end-to-end mutual information between the channel input and channel output, we now maximize an upper bound of the mutual information. Simulation results will show that this upper bound is closed to the true mutual information value. The relaxed optimization problem is now expressed as:
Again, let \(\mathbf {Q}=\mathbf {R}_{x_{0}} \geq 0\) and \(\mathbf {P}=\mathsf {E}_{\mathbf {G}_{N}}\left \{\mathbf {G}_{N}^{H}\mathbf {R}_{\dot {n}}^{-1}\mathbf {G}_{N}\right \}>0\), it can be seen that Problem (15) is now in the form of (11), and hereby, the solution to (15) can be optimally obtained.
3 Precoding design for spatially correlated wireless multi-hop MIMO channel
3.1 Precoded N-hop wireless MIMO channel formulation
By applying the precoding technique to the wireless system, a precoded N-hop wireless MIMO channel is presented in Figure 2. Before transmitting over the wireless channel, the source signal x0 is linearly precoded by a linear precoder P0 such that the transmitted signal at the source is:
For the sake of saving transmission bandwidth, all precoding matrices considered in this paper are square, i.e., non-redundancy precoder. The purpose of precoding technique here is to re-form the transmitted signal and re-allocate the transmitted power such that the transmitted signal can effectively combat the spatial correlation and colored noise in the eigen-mode. For single-hop wireless channels, the non-redundancy precoders to cope with spatial correlations and colored noises have been successfully proposed in [35,40] and in [19], respectively.
The received signal at the first hop can be expressed as:
Since the AF strategy is considered, the received signal xi at the i-th hop is also the source signal at the next hop. Before transmitting over the wireless channel, the source signal xi is also linearly precoded by a linear precoder Pi such that the transmitted signal at the i-th transmitter is:
By Theorem 3 and Theorem 4 in the Appendix, the instantaneous end-to-end mutual information between the system input x0 and the system output \(\bar {\mathbf {y}}_{N}\) is given by:
The maximum is taken over all possible precoding matrices Pi−1, i=1,…,N. The design problem is how to obtain the optimal set of precoding matrices Pi−1 to maximize the mutual information and consequently attain the channel capacity (Equation 23) of the correlated MIMO multi-hop wireless channel.
3.2 Asymptotic capacity and precoder design to maximize the individual mutual information
Since the objective function in Equation 23 is very complicated and neither a convex nor a concave function with respect to the to-be-designed variables Pi−1, generally obtaining the optimal solution in closed form to this problem is impossible. In this section, we propose to relax the objective function to obtain an asymptotic solution in closed form.
Instead of maximizing only the end-to-end mutual information between the source and the destination, we propose to maximize the individual mutual information between the transmitted signal and received signal at all hops. Based on each maximization problem at each hop, one after the others, each precoding matrix is designed.
Similarly to single-hop wireless models, it can be seen that the input-output relationship at each hop can be expressed as:
Note that we have the fundamental condition [37] det(I+XY)= det(I+YX). By Theorem 3 and Theorem 4 in the Appendix, the mutual information between the system input xi−1 and the system output xi at the i-th hop is given by:
As \(\mathbf {R}_{1}^{-1}\) is definite and \(\mathbf {R}_{x_{0}}\) is semi-definite, let \(\mathbf {P}=\mathbf {H}_{1}^{H} \mathbf {R}_{1}^{-1}\mathbf {H}_{1} > 0\) and make the variable change \(\mathbf {Q}=\mathbf {P}_{0}\mathbf {R}_{x_{0}} \mathbf {P}_{0}^{H} \geq 0\), Equation 27 can be written as:
where its optimal solution Q can be obtained in closed form by Theorem 1. It can be be seen that the variable change \(\mathbf {Q}=\mathbf {P}_{0}\mathbf {R}_{x_{0}} \mathbf {P}_{0}^{H} \geq 0\) is legal as for every known matrix Q, one can easily find out a corresponding matrix \(\mathbf {P}_{0}=\mathbf {Q}^{1/2} \mathbf {R}_{x_{0}}^{-1/2}\).
From the optimal value of Q, it is obvious to have the optimal value of P0 since \(\mathbf {R}_{x_{0}}\) is semi-definite. After having the optimal value of P0, from Equation 24, the covariance matrix \(\mathbf {R}_{x_{1}}\) can be calculated easily. It is also obvious to see that \(\mathbf {R}_{x_{1}}\) is semi-definite. Consequently, by using the optimal precoding matrices in the previous hops, the precoding matrix Pi−1, i=2,…,N in the current i-th hop can be optimally obtained by solving the maximization problems:
3.3 Precoding design to minimize the detection error
When designing a wireless system, one criterion which is usually used for this purpose is the minimization of the detection error. To detect the source signal x0 from the received signal in Equation 18, the minimum mean square error (MMSE) estimator of x0 is [41]:
In essence, \(\widetilde {\mathbf {x}}_{0}\) is a soft estimate of the data vector x0. The final hard decision \(\widehat {\mathbf {x}}_{0}\) is obtained by appropriately rounding up each element of \(\widetilde {\mathbf {x}}_{0}\) to the nearest signal point in the constellation. The mean square error (MSE) in the MMSE estimation of the source symbols from the received signal at the destination is given by [41]:
In order to improve the detection performance, instead of designing the precoding matrices Pi−1, i=1…,N to maximize the end-to-end mutual information as shown in the above sections, we now design the precoding matrices Pi−1 to minimize the MSE (Equation 30) under the power constraint in Equation 16.
Similar to the design for mutual information maximization, it can be seen that the objective function in Equation 31 is very complicated and neither a convex nor a concave function with respect to the to-be-designed variables Pi−1. Since it is impossible to obtain the optimal solution in closed form for Problem (31), we relax the optimization problem (31) for an asymptotic solution in closed form.
Instead of globally minimizing the MSE of the source symbol detection at the destination only, we minimize the MSE of the soft estimate at each hop. Based on each minimization problem at each hop, each precoding matrix is obtained, one after the others. The input-output relationship (Equation 24) at each hop is again used for the asymptotic design. The MSE in the MMSE estimation of the transmitted signal xi−1 from the received signal xi in Equation 24 is:
This optimization problem has the same form and solution as those in [19], Equation 12. The optimal solution is summarized in the following.
Let M be the rank of Qi. Make the following SVDs of \(\mathbf {Q}_{i}=\mathbf {U}_{Q}^{H} \mathbf {\Sigma }_{Q} \mathbf {U}_{Q}\) and \(\mathbf {R}_{x_{i-1}}=\mathbf {U}_{x_{i-1}}^{H} \mathbf {\Sigma }_{x_{i-1}} \mathbf {U}_{x_{i-1}}\). Here, \(\mathbf {\Sigma }_{Q} = {\sf diag} \left [\mathbf {\Sigma }_{\textit {MQ}}^{2} \;\; \mathbf {0}\right ]\), with ΣMQ>0, is a diagonal matrix having the eigenvalues of Qi on its main diagonal in decreasing order and UQ is the unitary matrix whose columns are the corresponding eigenvectors of Qi. Analogously, \(\mathbf {\Sigma }_{x_{i-1}}>0\) is the diagonal matrix having the eigenvalues of \(\mathbf {R}_{x_{i-1}}\) in decreasing order on its main diagonal, and \(\mathbf {U}_{x_{i-1}}\) is the unitary matrix whose columns are the corresponding eigenvectors.
Theorem 2.
The optimal precoder matrices Pi−1 to be used with the MMSE detection at each hop are:
where \(\gamma (j)=\boldsymbol {\Sigma }_{x_{i-1}}^{1/2}(j,j)\boldsymbol {\Sigma }_{\textit {MQ}}(j,j), \widehat {\mathbf {U}}_{Q}\) and \(\widehat {\mathbf {U}}_{x_{i-1}}\in \mathbb {C}^{M \times N}\) with \(\mathbf {U}_{Q}=\left [\widehat {\mathbf {U}}_{Q}^{H}\;\;\mathbf {*}]^{H}, \; \mathbf {U}_{x_{i-1}}=[\widehat {\mathbf {U}}_{x_{i-1}}^{H} \;\;\mathbf {*}\right ]^{H},\) and \({\bar {\mu }}\) is chosen such that \(\sum _{j=1}^{M} \boldsymbol {\Sigma }_{\textit {MQ}}^{-2}(j,j)({}{\bar {\mu }}^{-1/2}\gamma (j)-1)^{+}= \mathsf {tr}\{\mathbf {R}_{x_{i-1}}\}.\)
4 Simulation results
This section provides simulation results to illustrate the performance of the proposed designs. In all simulation results presented in this section, colored noise is generated by multiplying a matrix Gi with white noise vector wi [19], whose components are \(\mathcal {CN}(0,{\sigma _{w}^{2}})\). This means that the covariance matrix of colored noise is \(\mathbf {R}_{i}={\sigma _{w}^{2}}\mathbf {G}_{i}\mathbf {G}_{i}^{H}\). To have the average power of colored noise the same as that of white noise, Gi is chosen such that \(\mathsf {tr}\{\mathbf {G}_{i}\mathbf {G}_{i}^{H}\}=a_{i}\), i=1,…,N. The average transmitted power is chosen to be unity, the signal-to-noise ratio (SNR) in dB is defined as \({\sf SNR}=-10 \mathsf {log}_{10}{{\sigma _{w}^{2}}}\), and the average noise power can be calculated as \({\sigma _{w}^{2}}=10^{- \mathsf {SNR}/10}\).
The wireless channel model is assumed to be quasi-static block fading and spatially correlated by the Kronecker model with \(\sigma _{\textit {hi}}^{2}=1\). The one-ring model in ([13], Equation 6) is used to generate the elements of the covariance matrices Σri and Σti. Specifically, \(\boldsymbol {\Sigma }_{\textit {ti}}(n,m) \approx J_{0}\left (\Delta _{\textit {ti}} \frac {2\pi }{\lambda }d_{\textit {ti}}|m-n|\right)\), m,n=1,…,ai−1, and \(\mathbf {\Sigma }_{\textit {ri}}(u,v) \approx J_{0}\left (\Delta _{\textit {ri}} \frac {2\pi }{\lambda }d_{\textit {ri}}|u-v|\right)\), u,v=1,…,ai. Here, we chosen Δti=5πi/180 and Δri=10πi/180 are the angle spreads (in radian) of the transmitter and the receiver at the i-th hop; dti=0.5λ and dri=0.3λ are the spacings of the transmitting and receiving antenna arrays at the i-th hop; λ is the wavelength and J0(·) is the zeroth-order Bessel function of the first kind. Note that the angle spreads, Δti and Δri, the wavelength λ, and the antenna spacings, dti and dri, determine how correlated the fading is at the transmitting and receiving antenna arrays at each hop.
Figure 3 presents the mutual information of correlated four-hop wireless channels under colored noise with ideal channel state information at the transmitters (CSIT) when having 2×2 and 4×4 MIMO antennas. We used ‘SeDuMi’ [38] solver for the numerically optimal solution. It can be observed that the closed-form solution and the numerical solution yield the same optimal mutual information value.
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Figure 4 shows the mutual information of two-hop wireless 2×2 MIMO channels under colored noise in three cases: 1) the upper bound of the average end-to-end mutual information with the asymptotic design solution obtained from Section 2.3, 2) the average end-to-end mutual information with the asymptotic design, and 3) the average end-to-end mutual information with the optimal design solution obtained from the numerical interior-point-method. It can be seen in Figure 4 that the average end-to-end mutual information with asymptotic design is very closed to that obtained by the numerical interior point method. However, these mutual information values are less than and closed to the upper bound of the mutual information obtained by the asymptotic solution. It verifies that the asymptotic design can efficiently yield an acceptable mutual information while saving a huge computational complexity compared to the numerical design, especially when the system size is large.
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When precoding technique is applied, the wireless channel model has 4×4 MIMO antennas, and the vector x0 of a0 correlated source symbols are generated as x0=Gss0, where s0 is a length- a0 vector of uncorrelated symbols drawn from the Gray-mapped quadrature phase-shift keying (QPSK) constellation of unit energy. The matrix Gs is generated arbitrarily but normalized such that \(\mathbf {G}_{s} \mathbf {G}_{s}^{H}\) has unit elements on the diagonal. This ensures the same transmitted power as in the case of uncorrelated data symbols. Note that the correlation matrix of the source symbols is \(\mathbf {R}_{x_{0}}=\mathbf {G}_{s} \mathbf {G}_{s}^{H}\).
Figures 5, 6, and 7 present the end-to-end mutual information values of correlated wireless MIMO channels having correlated source symbols under colored noise in four cases: 1) with the precoding design in Section 3.2 to maximize the individual mutual information, 2) with the precoding design in Section 3.3 to minimize the individual soft detection error, 3) with the precoding design in ([27], Section V-C), and 4) without the precoding techniques.
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In Figure 5, the wireless channel under consideration has only one hop. In this single-hop scheme, the proposed design to maximize the mutual information is obviously optimal as the end-to-end mutual information is also the mutual information at the only hop. As expected, three systems having the precoding techniques perform better than the system without being applied the precoding technique. It can be observed that the mutual information with the precoding design to maximize the mutual information is better than that of the precoding design to minimize the soft detection error. However, the more important observation is that both the end-to-end mutual information values of the wireless systems having the proposed precoding designs are larger than the mutual information value of the design in ([27], Section V-C). This performance gain is reasonable as the design in ([27], Section V-C) only proposed optimal precoding directions with equal power allocation, while in our designs two precoding problems of transmitted power allocation and transmitted signal direction are optimally designed at each hop.
In Figure 6, the simulation results for the two-hop wireless MIMO channels are illustrated. In this two-hop scheme, although the end-to-end mutual information values of the wireless systems having the proposed precoding designs are better than that of the wireless system having the precoding design in ([27], Section V-C), it is very interesting that the precoding design to minimize the soft detection error gives a better capacity performance than that of the precoding design to maximize the mutual information.
When the wireless channels have four hops, as shown in Figure 7, the precoding design to minimize the individual soft detection error yields a significant performance gain than that of the design to maximize the individual mutual information value. It is also depicted in Figure 7 that all the proposed precoding designs for four-hop wireless channels have a better performance than that of the system without the precoding technique.
5 Conclusions
In this paper, the closed-form source symbol covariance is designed to maximize the mutual information between the channel input and the channel output of correlated wireless multi-hop MIMO systems when having the full knowledge of channel at the transmitters. When having only channel statistics at the transmitters, the numerically optimal source symbol covariance and a sub-optimal source symbol covariance in closed form are designed to maximize the average end-to-end mutual information. Moreover, two sets of precoding matrices are sub-optimally designed for generally correlated multi-hop MIMO channels. The first design is obtained by maximizing the mutual information between the input and output signals at each hop while the second design is obtained by minimizing the MSE of the soft detection at each hop. Simulation results show that the proposed precoding designs significantly increase the end-to-end mutual information of the wireless system, while it does not spend system resources such as transmission power or bandwidth.
6 Appendix
Theorem 3.
([42], p. 522) Suppose that y and x are two random variables of zero mean with the covariance matrix:
Here, \(\mathbf {R}_{y}^{\dag }\) is the pseudo-inverse of Ry.
Theorem 4.
([1], Lemma 2) For any zero-mean random vector x with the covariance \(\mathsf {E}\{\mathbf {xx}^{H}\}=\mathbf {R}_{x_{0}}\), the entropy [36] of x satisfies:
$$\mathcal{H}(\mathbf{x})\leq \log\det(\pi e \mathbf{R}_{x_{0}}) $$
with equality if and only if x is a circularly symmetric complex Gaussian random variable with zero mean and covariance \(\mathbf {R}_{x_{0}}\), i.e., among the random variables with the same mean and covariance, the Gaussian one gives the largest entropy.
Proof of Theorem1.
The function F(Q)= log det(I+QP) is not readily spectral. However, we can deduce Equation 11 to spectral optimization by making the SVD of P=UHDPU and changing the variable \(\mathbf {X}=\sqrt {\mathbf {D}_{P}}\mathbf {U}\mathbf {Q}\mathbf {U}^{H}\sqrt {\mathbf {D}_{P}}\) in Equation 12, it can be seen that \(\mathsf {tr}(\mathbf {Q})=\mathsf {tr}(\mathbf {U}^{H}\mathbf {D}_{P}^{-1/2}\mathbf {X}\mathbf {D}_{P}^{-1/2}\mathbf {U})= \mathsf {tr}(\mathbf {D}_{P}^{-1}\mathbf {X})\). Therefore, the optimization problem (12) is now expressed as follows:
where the function X→ log det(I+X) is spectral and the function \(\mathbf {X}\rightarrow \text {Trace}(\mathbf {D}_{P}^{-1}\mathbf {X})\) is linear and thus differentiable. According to [43]:
In the next few lines, we will prove that the optimal solution X is an diagonal matrix so Equations 35 and 36 have the same optimal solution. The Lagragian of Equation 36 is:
Since log det(I+X) is concave and − log det(I+X) is convex so Equation 36 is a convex programming. According to the Karush-Kuhn-Tucker (KKT) condition [44] for the optimality of convex programming, the optimal solution to the optimization problem in Equation 36 and the corresponding Lagrange multipliers must satisfy the following necessary and sufficient conditions:
From Equation 37, it is clear that X is diagonal, and therefore, Equations 35 and 36 are equivalent. Solving Equations 37 and 38 gives the following water-filling solution:
where x+= max{0,x} and μ is chosen such that \(\text {Trace}\left (\mathbf {D}_{P}^{-1}\mathbf {X}\right)=P\). The optimal solution is Q=UH\(\left (\mathbf {D}_{P}^{-1/2}\mathbf {XD}_{P}^{-1/2}\right)\mathbf {U}=\mathbf {U}^{H}\mathbf {D}_{P}^{-1}\mathbf {XU}\).
Acknowledgements
This research is funded by Vietnam National Foundation for Science and Technology Development (NAFOSTED) under grant number 102.02-2012.28.
Open AccessThis article is distributed under the terms of the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0), which permits use, duplication, adaptation, distribution, and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.
Competing interests
The authors declare that they have no competing interests.