Wireless channels are commonly affected by short-term fading and long-term fading (shadowing). The shadowing effects must be taken into account also when mobility is present in the wireless scenario. Using a composite fading model, the total channel capacity can be studied for a scenario with short-term Rayleigh fading along with shadowing. This work provides quantitative results for these kinds of scenarios with Rayleigh fading and shadowing, considering also multiple-input and multiple-output systems, which have not been previously reported. In addition, the channel capacity has been studied in depth in its relation with the shadowing level, signal to noise ratio, and the number of elements in the multiple-input and multiple-output system. Moreover, the channel performance with shadowing has been compared to the one without it. Furthermore, Rician model with shadowing is studied and its results are reported. In addition, correlated and experimental results are provided. It is identified that the distributed MIMO systems can benefit from shadowing in Rician channels. This advantage has not been reported previously. This type of fading is proposed for massive MIMO by others and our results open the door to emulate massive MIMO on a reverberation chamber.
1. Introduction
Many theoretical and experimental studies have been carried out to predict the radio propagation characteristics. These studies aim to analyze propagation problems and propose statistical models for fading. Rayleigh, Rician, Nakagami-m, and Weibull are arguably the most popular statistical models for fading. All these fading models can be studied in scenarios on which the channel variations occur on a large scale period (i.e., variations due to turns in a corner, movements behind a large building, or the entrance to a building). This large-scale fading is often called shadowing.
This long-term energy variability in multipath fading channels is widely accepted to be properly described by lognormal statistics [1, 2]. While the use of multiple antennas at the transmitter and receiver provides reasonable protection against short-term fading, it does not offer any kind of protection against shadowing, as the mitigation of shadowing requires the use of macrodiversity [3]. Macrodiversity implies the combination of signals from two or more base stations, being separated by a certain distance.
Cooperative networking has emerged as a core component of future wireless networks since it provides high data rate communication over large geographical areas. In this situation, distributed multiple-input multiple-output (D-MIMO) communication arises as a promising tool for achieving large performance gains in wireless networks, similar to those provided by conventional MIMO in a point-to-point wireless channel. In these cases, wireless users with a single transmission and reception antenna cooperate in clusters to form distributed transmitting and receiving antenna arrays. A common assumption in the performance analysis of D-MIMO systems is that channels between different pairs of nodes are subject to independent fading [4, 5]. Analogous to the point-to-point case, this leads to capacity gains which are linear in the number of nodes (M) contained in the transmission and reception clusters. In a distributed configuration, nodes (or antennas) are typically further away one from the other than for a classical MIMO one, so that an independent and identically distributed (i.i.d) fading model can be considered appropriate.
A D-MIMO system is able to combine the advantages of a point-to-point MIMO and a distributed antenna system (DAS) [6] and to have the ability to exploit spatial micro- and macrodiversity simultaneously [7–9]. For that reason, the dual effect of fading and shadowing, that is, the composite fading channel that addresses both macroscopic and microscopic fading, is gaining attention again [10–12]. A composite probability density function model is used in [10] for the outage analysis of a MIMO scheme operating in shadowed fading channels. Moreover, in [11] correlated shadowing is analyzed. Therefore, in this paper an analysis of D-MIMO capacity for both the microscopic fading (Rayleigh and Rician) channel and the composite channel is performed. With this model it is presented that the shadowing can improve the capacity in some conditions when composite fading is considered.
The rest of the document is organized as follows. Section 2 describes the models used and Section 3 validates these models. Sections 4 and 5 provide D-MIMO capacity results for Rayleigh shadowed fading and Rician shadowed fading, respectively. Finally, in Section 6 correlated and experimental results are shown, and the conclusions are outlined in Section 7.
2. Composite Model for Microdiversity and Macrodiversity
In this work, a wireless communication system that employs T transmitting and R receiving antennas is considered. In what follows, the analysis is restricted to the frequency flat-fading case, with shadowing. It is assumed that the channel state information (CSI) is perfectly known by the receiver but is unknown by the transmitter and it is, therefore, unable to adapt its transmission strategy. At the receiver, the received signal y is given by(1)y=Hx+n,where x is the transmitted signal vector with total transmitted power E(xxT)=P and the terms of noise vector n are modeled as zero-mean complex Gaussian random variables with variance N0=2 per dimension and H is the channel matrix that can be modeled as [13–15](2)H=sxHmicro,where s is a log-normal random matrix representing the shadowing effects and Hmicro is a matrix representing the small-scale fading.
Furthermore, we assume that the shadowing value s equally affects all the elements of Hmicro and s is independent from Hmicro. At this point, the generation of the s matrix is [7](3)s=fNor-Lμ,σ,R,T+j∗fNor-Lμ,σ,R,T,where fNor-L(μ,σ,R,T) produces Gaussian random variables matrix with dimensions R×T with a log-normal distribution with mean equal to μ and variance equal to σ. The other term of H is calculated for Rayleigh fading in the following way:(4)Hmicro_Ray=fNorR,T+j∗fNorR,T,where fNor(R,T) produces a random signal with dimensions R×T with mean equal to 0 and variance equal to 1.
If it is desired to generate a channel matrix for Rician fading, the transformation developed by [16] may be applied to Hmicro_Ray. This transformation is applied in [17, 18] to obtain Hmicro_Rician.
Thus, it is possible to generate the H channel matrix with Rayleigh or Rician fading and lognormal shadowing for any parameter of shadowing and any number of elements using (2). Finally, the instantaneous channel capacity for MIMO systems can be calculated with the well-known expression defined in [19]:(5)C=log2detIR+SNRTH∗HT,where det[] is the determinant of [], SNR is the signal to noise ratio, and HT is the conjugate transpose of H. The system has T antennas at the transmitter and R antennas at the receiver, and IR is the identity matrix with dimensions R×R. The ergodic (mean) capacity of the random MIMO channel is the mean over a variety of channel realizations of the ergodic fading process. In this paper we use 100000 realizations for each emulated point.
3. Validation Model for Lognormal Distribution Matrix
The equations for estimating the ergodic Shannon capacity of a log-normal channel have been recently presented in the literature [20, 21], and an interesting review of the state of the art and a new formula can be found in [22]. In this paper, the validation is carried out through a comparison of capacity results for a 1×1 scheme. Our simulation model is evaluated by comparing its results to those obtained using the model of [20]. Figure 1 shows that our simulation model matches properly the results of applying this model.
Ergodic capacity versus SNR for Laourine’s method and our own method.
4. Results for Composite Channel (Rayleigh + Shadowing)
Most of the referred literature [10–12] and other existing literature are centered on the effect of macrodiversity and microdiversity on the average error probability. However, there is a lack of studies of both effects on MIMO capacity, and only a few results [13–15, 23] have been published. In [13] Gauss-Hermite integration is used for presenting an approximated capacity expression. The work in [14] is centered on the analysis of the capacity with different adaptive schemes. In [15], it is proposed that shadowing can change the performance of MIMO systems and a preliminary analysis for D-MIMO systems with both fading effects is provided in [23]. However, in the works referred above, a study of the performance of D-MIMO capacity has not been found, and it is presented in this work.
Figure 2 shows the capacity versus SNR for Rayleigh fading plus shadowing in 8×8 systems. This plot includes the Rayleigh-only fading for comparison purposes. As it is expected when introducing the shadowing effect, a loss of capacity is observed. This loss increases when the σ of shadowing is increased.
Capacity versus SNR for Rayleigh shadowing fading, with an 8×8 system.
Figure 3 shows the capacity regarding the σ of lognormal fading for different number of elements with SNR=20 dB. For the sake of comparison, the Rayleigh fading capacity is also included. In this figure, it is possible to observe that the shadowing behavior is very different with the variation of the number of elements, having a greater influence when the number of elements is higher. Figure 4 shows the decrease of capacity relative to Rayleigh-only fading regarding σ-shadowing for different number of elements with SNR=10 dB (Figure 4(a)) and SNR=25 dB (Figure 4(b)). This figure provides that the capacity decreases as the shadowing is increased. In this figure, it can be noticed that, for low SNR, the percentage of capacity loss is higher (for example, in the 2×2 MIMO system with SNR=10 dB the capacity decrease is 40% while for SNR=25 dB the capacity decrease is 26%). These figures show the level in which the shadowing begins to affect the ergodic capacity of the D-MIMO channel, information which is quite useful for the system designer.
Capacity versus shadowing fading, with SNR=20 dB.
Capacity increase relative to Rayleigh-only fading versus sigma shadowing, (a) with SNR=10 dB, (b) with SNR=25 dB.
Figure 5 shows the capacity increase in relative percentage for Rayleigh fading versus the σ of lognormal fading for different number of elements, with SNR=25 dB. Figure 6 shows the capacity increase regarding the number of elements and the σ shadowing, on a 3D contour plot, for SNR=10 dB (Figure 6(a)) and SNR=25 dB (Figure 6(b)). From these figures, it can be concluded that for a high number of elements, the capacity loss is higher in absolute terms, but slightly lower in relative terms. Also, it is important to notice that the number of elements has more influence than the shadowing in the capacity value, as it is provided in Figure 6.
Capacity Increase versus number of elements shadowing σ fading, with SNR=25 dB.
Capacity versus the number of elements versus σ shadowing, on a 3D contour plot, (a) with SNR=10 dB and (b), SNR=25 dB.
Finally in this section, different histograms are provided in Figure 7. In this figure, it is shown the probability distribution function of capacity in relation to the capacity of MIMO channel for a 10×10 system and SNR=35 dB. Also, in this figure it is plotted the mean capacity (with a dot) and the box-plot of capacity with the same color than the curve. It is observed that an increase in the shadowing level produces an increase in standard deviation of capacity; that is, the σ increase produces the spread of the channel capacity.
Histogram of different 10×10 MIMO systems with SNR=30 dB.
5. Results for Composite Channel (Rician + Shadowing)
Rician fading occurs when one of the paths, typically a line of sight signal, is much stronger than the others. The K-factor is the results of dividing the higher path between the sum of all others paths. The K-factor of more general Rician-fading environments changes as the distance of receiver to transmitter changes. The composite channel of Rician fading with shadowing is studied in [24, 25]. In [14], a semianalytical expression is presented for the probability density function and in [26]; new accurate formulas for obtaining symbol error outage are presented. However, in the literature, up to the authors’ knowledge, no work about Shannon capacity for D-MIMO systems with a composite Rician-shadowed channel has been presented. In this section, in a similar way to the previous one, the Shannon capacity for the composite Rician plus shadowing channel is provided. Figure 8 shows the capacity regarding the SNR for this composite channel, with several σ values and several K-factor values. It is remarkable that the Rician K-factor has more influence than the shadowing for this 4×4 example: it can be observed that the different lines are grouped regarding the K-factor (one group with diamonds (K=-6 dB) and the other with squares (K=7 dB)).
Capacity versus SNR for Rician plus shadowing fading with several σ and several K-factor values.
A statistical study of MIMO capacity is performed in systems under composite Rician fading. Figure 9 shows the probability density function of capacity considering the capacity for the 8×8 MIMO system, with SNR=30 dB and Rician K-factor = −10 dB (Figure 9(a)), Rician K-factor = −0.5 dB (Figure 9(b)), Rician K-factor = 4.7 dB (Figure 9(c)), and Rician K-factor = 9 dB (Figure 9(d)). In this figure, it is also plotted the mean capacity (with a dot) and the box-plot of capacity with the same color than the curve. It is important to note that the increase in the shadowing severity produces an increase in the spread of the channel capacity. This agrees with previous results for 1×1 channels [27]. Moreover, it is observed that the mean value of the channel increases or decreases depending on the K-factor (see the different subfigures in Figure 9). All data of mean and standard deviation are depicted in Table 1 for the 8×8 MIMO system with SNR=30 dB.
Standard deviation and mean value of capacity for an 8×8 MIMO system with SNR = 30 dB in composite fading.
σ
K=-10 dB
K=-0.5 dB
K=4.7 dB
K=9 dB
Mean
Std.
Mean
Std.
Mean
Std.
Mean
Std.
1 dB
68.5
2.4
61.7
2.2
51.4
1.9
46.0
1.7
3 dB
68.3
2.4
62.0
2.3
53.4
2.0
49.6
2.0
5 dB
67.5
2.6
62.0
2.5
55.4
2.4
53.1
2.3
7 dB
65.9
2.8
61.3
2.7
56.4
2.7
55.0
2.7
9 dB
63.4
3.1
59.7
3.1
56.2
3.1
55.2
3.1
11 dB
59.9
3.5
57.0
3.5
54.6
3.5
54.0
3.5
Probability density function of capacity versus capacity for 8×8 MIMO system, (a) with SNR=30 dB and Rician K-factor = −10 dB, (b) Rician K-factor = −0.5 dB, (c) Rician K-factor = 4.7 dB, and (d) Rician K-factor = 9 dB.
Figure 10 shows the probability density function of capacity regarding the capacity for the 8×8 MIMO system with SNR=30 dB and σ=1 dB (Figure 10(a)), σ=4 dB (Figure 10(b)) σ=7 dB (Figure 10(c)), and σ=10 dB (Figure 10(d)). In this figure, it is observed that the different curves in the same figure have similar standard deviation; that is, the channel with the same shadowing has similar spread of the channel capacity. In addition, it is possible to note that the increase of Rician K-factor produces a decrease of mean capacity (the distribution curve moves towards the left) and a slight reduction of the spread of the channel capacity. This reduction when the K-factor is increased agrees with the reported results in [28]. This effect decreases when the σ is increased (for example the standard deviation change when σ=1 dB from 2.4 with K-factor = −10 dB to 1.7 with K=10 dB, although when σ=11 dB the standard deviation is constant for all Rician K-factor values). That is, when the K-factor is increased the spread of the channel capacity is decreased. However, this effect is neglected when the shadowing is present with a high σ value. Thus, the effect of Rician fading can be compensated with the effect of Shadowing. This fact takes some advantage of the systems that work under Rician composite fading from the systems that work only under Rician-only fading, that is, D-MIMO systems from MIMO systems. Figure 11 shows the capacity versus K-factor, with the shadowing as a parameter, for a 2×2 (Figure 11(a)), a 3×3 (Figure 11(b)), a 4×4 (Figure 11(c)), and a 5×5 (Figure 11(d)) system. In this figure, it is possible to observe that the Rician-only fading (red line) suffers more degradation with the increase of K-factor than the Rician composite fading (the rest of lines). In these figures, it is possible to observe that, for a low K-factor (similar to the Rayleigh case), the shadowing decreases the capacity in all the cases. In this figure, it can be also noticed that the lowest capacity degradation, when the K-factor is increased, is produced for the higher σ shadowing values. This is due to the environment that has been already degraded with the shadowing and it is difficult to degrade more the signal.
Probability density function of capacity versus capacity for the 8×8 MIMO system, (a) with SNR=30 dB and σ=1 dB, (b) σ=4 dB, (c) σ=7 dB, and (d) σ=10 dB.
Capacity versus K-factor with shadowing as parameter, (a) for 2×2, (b) 3×3, (c) 4×4, and (d) 5×5 systems.
It is remarkable that the shadowing has more influence than the Rician K-factor for 2×2 systems. However, when the number of elements is increased this situation changes: for a 3×3 system the influence of both phenomena is similar and for a 4×4 and 5×5 system the Rician K-factor has more influence than the shadowing. This phenomenon, observed in this research for the first time, is a key result and one of the main contributions of this paper. That is, for a high K-factor, the shadowing can compensate the lack of scattering that is produced in Rician-only fading. In other words, when the K-factor is high, the line-of-sigh (LOS) component is predominant; however, when the shadowing is introduced the LOS is lost, that is, the effect of shadowing compensates the effect of Rician fading. Thus, when the shadowing is introduced some paths between the transmitters and receivers are blocked and some new paths are added (not always), producing a new scenario. This fact is reflected in the increase of the capacity spread (the standard deviation of capacity increases its value), and an increase in the mean capacity is produced. As a result, it is reported for the first time that shadowing can increase the capacity of D-MIMO systems.
The following figures (Figures 12 and 13) show up to what extent the shadowing level begins to increase the ergodic capacity of the D-MIMO channel, information which is of interest for the system designer. Figure 12 shows the capacity increase relative to Rician-only channel versus the number of elements, with shadowing as a parameter, for different K-factor values: K=-7 dB (Figure 12(a)), K=2 dB (Figure 12(b)), K=6 dB (Figure 12(c)), and K=10 dB (Figure 12(d)). It is remarkable that in Figure 12(a) with K=-7 dB, there is not positive capacity increase. However, when the K-factor is increased correlatively in Figures 12(b), 12(c), and 12(d), the increment of capacity is positive for some values and higher when the K-factor is higher. Also, it is possible to notice that the capacity increase is positive as a general rule when both the K-factor and the number of elements are high. Thus, in some cases, the capacity of the Rician-shadowed channel exceeds the one of the Rician-only channel. That is, the D-MIMO system with Rician fading and distributed antennas that experiences log-normal shadowing can exceed the capacity of traditional MIMO systems with Rician-only channel.
Capacity increase versus the number of elements, with shadowing as parameter and for different K-factor, (a) K=-7 dB, (b) K=2 dB, (c) K=6 dB, and (d) K=10 dB.
Capacity increase (%) versus the K-factor and versus shadowing, (a) with SNR=5 dB and number of elements equal to 2, (b) SNR=5 dB and 7 elements, (c) SNR=20 dB and 2 elements, and (d) SNR=20 dB and 7 elements.
Figure 13 shows the capacity increase (%) regarding the K-factor and shadowing, in a 3D contour plot, with SNR=5 dB and number of elements equal to 2 (Figure 13(a)), with SNR=5 dB and 7 elements (Figure 13(b)), with SNR=20 dB and 2 elements (Figure 13(c)), and with SNR=20 dB and 7 elements (Figure 13(d)). In this figure, it is noticed that the capacity increase depends on the number of elements and the SNR value because the four different plots have great difference. In Figures 13(a) and 13(c) with low number of elements, the capacity increase is almost constant with the K-factor and only varies with the shadowing. However, in Figures 13(b) and 13(d), when the number of elements is 7, the maximum increment (red zone) is concentrated for a high K-factor. It is also observed that, with small number of elements, there is generally a decrease in capacity relative to the Rician-only channel. With a large number of elements there can be a substantial increase. As a conclusion, D-MIMO systems with log-normal shadowing and Rician fading have a clear advantage over MIMO systems that experience Rician fading only in specific conditions (mainly for high number of elements and high K-factor).
6. Correlated and Experimental Results6.1. Correlated Results
Typically, the Hmicro is calculated with (2), forming an uncorrelated Hmicro matrix. However, in this section, it is tried to test a correlated MIMO distributed system. Thus, it is necessary to generate one correlated Hmicro matrix. The procedure (method) to generate the correlated Hmicro matrix is as follows.
P realizations of vector L with dimensions 1×T are generated. The number P varies and is higher than 10: (6)L1=fNor1,T+j∗fNor(1,T)L2=fNor1,T+j∗fNor(1,T)⋮LP=fNor1,T+j∗fNor1,T.
A random vector W, between 0 and 1 and with dimensions 1×P, that represents different weights, will be used to combine different L vectors in a fixed way: (7)W=fNor1,P.
A fixed vector B, with dimensions (1×T), combination of L vectors, is calculated. This term is calculated in order to introduce high correlation:(8)B=L1∗W1+L2∗W2+⋯+LP∗WP.
A set of R vectors “WW,” which are random vectors between 0 and 1 with dimensions 1×P, is defined. These vectors represent different weights, which will be used to be combined with the different L vectors: (9)WW1=fNor1,PWW2=fNor1,P⋮WWR=fNor1,P.
A set of R vectors “BB,” one for each reception antenna, is calculated in order to introduce low correlation; these matrices are a linear combination of L matrices weighted with the different WW vectors. That is, for 1 to R, it is done:(10)BB1=L1∗WW11+L2∗WW12+⋯+LP∗WW1PBB2=L1∗WW21+L2∗WW22+⋯+LP∗WW2P⋮BBR=L1∗WWR1+L2∗WWR2+⋯+LP∗WWRP.
A set of R random vectors “AA,” one for each reception antenna, is calculated in order to randomize. That is, for 1 to R it is done:(11)AA1=fNor1,T+j∗fNor(1,T)AA2=fNor1,T+j∗fNor(1,T)⋮AAR=fNor1,T+j∗fNor1,T.
Finally, to calculate each HH vector, the previous calculated vectors (B, BB, and AA) are combined in a weighed way. That is, HH vectors are composed by a fixed term “B,” a high correlated term “BB,” and a random term “AA.” Thus, modifying the scalar values (a, b, and c), it is possible to obtain any correlation for H matrix. That is, for 1 to R it is done:(12)HH1=a∗B+b∗BB1+c∗AA1HH2=a∗B+b∗BB2+c∗AA2⋮HHR=a∗B+b∗BBR+c∗AAR.
The H matrix is generated concatenating the different HH matrix from 1 to R:(13)Hmicro=HH1,HH2⋯HHR.
The Hmicro matrix is normalized with Frobenius norm in order to obtain one Hmicro matrix with zero mean.
Thus, it is possible to generate the Hmicro channel matrix with Rayleigh distribution with any number of elements (R and T) and any level of correlation. From Hmicro, it is possible to generate any Hmicro channel matrix with Rician distribution, with the same procedure than the one developed in [29] or provided in the previous section. Thus, with the model developed in Section 2 it is possible to compute any H matrix with correlated composite fading (Rayleigh/Rician plus shadowing).
Figure 14 shows a 4×4 system with different correlation and different composite fading (Rayleigh and Rician with different K-factor). In order to simplify, the mean value of all antenna pair is the value taken. In this figure, it is possible to observe than the correlation affects more to Rayleigh composite fading than to Rician fading. Also, it is possible to see that, in correlated systems, it is possible to increase capacity for some shadowing values even for Rayleigh fading. Further results for other propagation models may be found in [30].
Distributed MIMO capacity versus shadowing level for correlated system with composite fading, Rayleigh and Rician (with different K-factor).
6.2. Experimental Results
In this subsection, the model proposed above to is applied measured data in reverberation chamber (RC). Therefore, the composite fading for Rayleigh/Rician plus shadowing is obtained for the data measured in RC. With this model it is possible to emulate composite fading in the RC, in a similar way to [16], where a postprocess technique is proposed to emulate the Rician channel on the RC. In this case, the Hmicro in (2) is in fact a real matrix measured in RC. It is also very interesting that this type of fading is also proposed for massive MIMO [29, 31] and these experimental results open the door to emulate massive MIMO on RC.
In order to obtain experimental results, different nonisotropic scenarios made in [32, 33] are evaluated. Three different systems are evaluated; for system A, an empty RC is used, providing the typical isotropic scattering (Scenario A of [32]). For system B, one piece of absorber is used, consisting of 24 cones, placed on the right hand side wall of the chamber (Scenario B of [32]). Two 30 cm high hollow cylinders of 5 cm radius, made of Teflon (PTFE) and filled with lossy CENELEC head simulating liquid (HSL) at the frequency of interest, are introduced in the empty chamber to provide the setup of system C (Scenario D of [32]). The antenna spacing for the array is 0.25 d/λ in all scenarios, for more information on the measurement setup, the reader is referred to [32]. Figure 15 shows the distributed MIMO capacity for 3×3 systems A, B, and C with composite fading, that is, Rayleigh and Rician (with different K-factor) plus different shadowing level. In this figure, the same behavior for measured systems is observed, compared to the simulated results from previous sections. That is, the shadowing can increase the capacity in some conditions, as it is reported previously.
Distributed MIMO capacity for system A, B, and C versus shadowing level for composite fading, Rayleigh and Rician (with different K-factor).
7. Conclusions
In this paper, the capacity behavior of a D-MIMO system for a composite Rayleigh shadowing channel has been studied. Experimentation for different shadowing intensity levels is provided, showing a wide variety of results of these systems, depending on the number of elements and the SNR. These results show up to what extent shadowing level begins to affect the ergodic capacity of the D-MIMO channel, information which is of interest for the system designer.
In addition, for the first time (in similar way to Rayleigh fading), results of ergodic capacity of D-MIMO system for a composite Rician shadowing fading are provided for different shadowing intensity levels showing a wide variety of results of these systems, depending on the number of elements and the SNR. In addition, a statistic study of the channel capacity has been performed, which lets us identify how the shadowing can compensate the effect of Rician fading. This makes us conclude that when the K-factor is high, the line-of-sigh (LOS) component is predominant. However, when the shadowing is introduced, the LOS is lost and the effect of shadowing compensates the effect of Rician fading. This fact takes some advantage of the systems that work under Rician composite fading from the systems that work under Rician-only fading, that is, D-MIMO systems from MIMO systems. Thus, it is identified that the D-MIMO systems can benefit from shadowing in Rician channels. This advantage has not been reported previously.
The D-MIMO system with Rician fading and distributed antennas that experience log-normal shadowing can exceed the capacity of traditional MIMO systems with Rician-only channel. Thus, in a similar way, as it happened with MIMO systems, considering multipath propagation (initially considered to be a restriction but now turned to be the solution to reach higher capacities), the cooperative networks can take advantage of shadowing, which has been typically considered as a restriction in order to reach higher capacities. In addition, correlated and experimental results have been shown. More studies on the correlated and experimental results will be done in future work.
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
Acknowledgments
This work has been supported by “Gobierno de Extremadura” with project number IB13113, PYR-2014 GENIL project (PYR-2014-CEB09-0010/MICINN), and CEIbioTIC project (mP_TIC_11).
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