Joint TAS and Power Allocation for IHDAF Relaying M2M Cooperative Networks

Abstract

The outage probability (OP) performance of multiple-relay-based incremental hybrid decode-amplify-forward (IHDAF) relaying mobile-to-mobile (M2M) networks with transmit antenna selection (TAS) over N-Nakagami fading channels is investigated in this paper. The closed-form expressions for approximate OP of the optimal and suboptimal TAS schemes are derived. The power allocation problem is formulated for performance optimization. Then the OP performance under different conditions is evaluated through numerical simulations to verify the analysis. The simulation results showed that optimal TAS scheme has a better OP performance than suboptimal TAS scheme; the power-allocation parameter has an important influence on the OP performance.

1. Introduction

In recent years, with the increasing demand for high-data-rate services,mobile-to-mobile (M2M) communication has attracted wide research interest [1]. In M2M communication scenarios, mobile user equipments can directly communicate to each other without the relay of base station. In particular, compared to the traditional cellular communication mode, it requires only half of the resources, thus it can offer better spectral efficiency and reduce the traffic load of the core network [2]. M2M communication has many advantages, such as increasing data rate, reducing energy cost, reducing transmission delays, and extending coverage area. M2M communication can enable new peer-to-peer and location-based applications and services. Due to its advantages, M2M communication is widely employed in many popular wireless communication systems, such as inter-vehicular communications, intelligent highway applications and mobile ad-hoc applications [3]. In contrast to conventional fixed-to-mobile (F2M) cellular radio systems, in M2M systems both the transmitter and receiver are in motion and equipped with low elevation antennas.The classical Rayleigh, Rician, or Nakagami fading channels have been found not to be applicable in M2M communication[4]. It has been observed that the effects of fading may be far severe than what can be modeled using the Nakagami distribution. Experimental results and theoretical analysis demonstrate that cascaded fading channels provide an accurate statistical model for M2M communication [5]. Cascaded Rayleigh (also named as N-Rayleigh) fading channel is presented in [6]. For N = 2, this reduces to double-Rayleigh fading model in [7]. Moreover, this model has been extended to N-Nakagami fading model in [8]. For N= 2, this reduces to double-Nakagami fading model in [9].

However, M2M communication may generate interference into the existing cellular network. The M2M transmit power and the distance between the users of a M2M pair needs to be constrained to have reliable cellular communication. A relay placed in between a M2M pair can extend the coverage area with less transmit power. This allows longer distance communication through M2M mode. Therefore, the relay-assisted M2M cooperative communication is attracting more and more attention. An approximation for average symbol error probability (ASEP) was derived for multiple-mobile-relay-based fixed-gain amplify-and-forward (FAF) relaying M2M cooperative networks over N-Nakagami fading channels in [10].

Some low-complexity cooperative diversity protocols such as selective relaying (SR) and incremental relaying (IR) schemes have been proposed for wireless cooperative networks. Taking the IR scheme into consideration, a new relaying scheme termed as incremental hybrid decode-amplify-forward (IHDAF) relaying was proposed in [11].

Multiple-input-multiple-output (MIMO) arises as a promising tool to enhance the reliability and capacity of wireless systems. However, multiple radio frequency chains must be implemented in MIMO systems, and it brings a corresponding increase in hardware complexity. In this situation, transmit antenna selection (TAS) arises as a practical way to reduce the system complexity. The exact closed-form expressions for outage probability (OP) of MIMO systems with two TAS selection schemes were derived in [12]. Both M2M communication and TAS are effective to improve the spectral efficiency and reduce the traffic load of the central network. However, to the best knowledge of the author, the OP performance of IHDAF relaying M2M networks with TAS and power allocation over N-Nakagami fading channels has not been investigated in the literature. Moreover, most results mentioned above do not take the power allocation into account. This is an important issue and will be discussed in this paper as it affects the OP performance. The main contributions are listed as follows:

The rest of the paper is organized as follows. Section 2 briefly reviews the research results related to this topic. The multiple-mobile-relay-based M2M system model is presented in Section 3. Section 4 provides the exact closed-form OP expressions for optimal TAS scheme. The exact closed-form OP expressions for suboptimal TAS scheme are derived in Section 5. In Section 6, the OP is optimized based on the power-allocation parameter. Section 7 conducts Monte Carlo simulations to verify the analytical results. Concluding remarks are given in Section 8.

 

2. Related work

Cooperative diversity has been recently proposed as an efficient solution to many challenging physical-layer problems in M2M communication field.Using FAF relaying, the pairwise error probability (PEP) of two relay-assisted vehicular scenarios over double-Nakagami fading channels was obtained in [13]. In [14], the OP performance of a mobile-relay-based two-way AF relaying system over N-Nakagami fading channels was investigated. The lower bound on OP of variable-gain AF relaying over N-Nakagami fading channels was investigated in [15]. By the moment generating function (MGF) method [16],the approximate ASEP performance of the mobile-relay-based M2M system over N-Nakagami fading channels was investigated in [17].

In regular cooperative-diversity networks, in addition to the direct link, all relays participate in sending the source signal to the destination. It wastes the channel resource because the relay forwards the signal every time regardless of the channel conditions. Since the relay and the source need to use orthogonal channels, additional resources will be used for relaying even if the relaying is not needed because the direct signal is good enough. To solve these problems, some low-complexity cooperative diversity protocols are proposed. Closed-form expressions for the error probability and average achievable rate of incremental DF (IDF) and incremental AF (IAF) relaying with a single relay over Rayleigh fading channels were derived in [18]. In [19], closed-form expressions for OP of IAF relaying M2M cooperative networks with relay selection over N-Nakagami fading channels were derived. Exact average bit error probability (BEP) expressions for IDF relaying M2M cooperative networks over N-Nakagami fading channels were derived in [20].

In [21], a novel cooperative diversity protocol called hybrid decode-amplify-forward (HDAF) was proposed. This protocol combined AF and SDF relaying. However, only the SEP performance was considered, and the analysis was based on the assumption that the relay can determine whether each received symbol was correctly detected or not, which was not practical in real systems. To provide a practical HDAF protocol, the forwarding decisions at the relay were based on the signal-to-noise ratio (SNR) of the received signal in [22], and closed-form expressions for the bit error probability of SNR-based HDAF relaying over independent non-identical flat Rayleigh fading channels with maximum ratio combining (MRC) were derived. Taking the IR scheme into consideration, a new relaying scheme termed as incremental HDAF (IHDAF) relaying was proposed in [11]. Closed-form expressions for the OP and bit error rate (BER) of the IHDAF relaying scheme were derived and presented over independent non-identical Rayleigh fading channels.

TAS can be introduced as a means to alleviate MIMO hardware complexity, while still retaining the diversity advantages. Owing to its simplicity and minimal communication requirements, many works has been done on TAS in MIMO systems. In [23], the performance of a dual-hop AF relay network with optimal and suboptimal TAS schemes was investigated. Closed-form expressions for OP and symbol error rate (SER) of TAS in multi-relay MIMO networks over Rician, Nakagami-m, Weibull, and generalized-K fading channels were derived in [24]. A good approximation of the distribution of the mutual information in the TAS system over Rayleigh fading channels was derived in [25], and it showed that channel hardening phenomenon was still retained as full complexity with antenna selection.

 

3. The System and Channel Model

3.1 System Model

Consider a cooperation model shown in Fig. 1, namely a single mobile source (MS) node, L mobile relay (MR) nodes, and a single mobile destination (MD) node. The nodes operate in half-duplex mode, MS is equipped with Nt antennas, MD is equipped with Nr antennas, whereas MR is equipped with a single antenna.

Fig. 1.The system model

We assume that Nt antennas at MS and Nr antennas at MD have the same distance to the MR nodes. Using the approach in [13], the relative gain of the MS to MD link is GSD=1, the relative gain of the MS to MRl link is GSRl=(dSD/dSRl)v, and the relative gain of the MRl to MD link is GRDl=(dSD/dRDl)v, where v is the path loss coefficient, and dSD, dSRl, and dRDl represent the distances of the MS to MD, MS to MRl, and MRl to MD links, respectively [26]. To indicate the location of MRl with respect to MS and MD, the relative geometrical gain μl = GSRl/GRDl (in decibels) is defined. When MRl has the same distance to MS and MD, μl is 1 (0 dB).When MRl is close to MD, μl has negative values. When MRl is close to MS, μl has positive values.

Let MSi denote the ith transmit antenna at MS, MDj denote the jth receive antenna at MD, so h=hk, k∈{SDij, SRil, RDlj}, represent the complex channel coefficients of MSi→MDj, MSi→MRl, and MRl→MDj links, respectively. Assume that the ith antenna at MS is used to transmit the signal, during the first time slot, the received signal rSDij at MDj can be written as

The received signal rSRil at MRl can be written as

where x denotes the transmitted signal, nSRil and nSDij are the zero-mean complex Gaussian random variables with variance N0/2 per dimension. During two time slots, the total energy used by MS and MR is E. K is the power-allocation parameter.

During the second time slot, only the best MR decides whether to forward the signal to the MDj by comparing the instantaneous SNR γSDij to a threshold γP. γSDij denotes the instantaneous SNR of the MSi to MDj link.

If γSDij>γP, the MDj will broadcast a ‘success’ message to the MSi and the best MR. Then MSi will transmit the next message, and the best MR remains silent.

If γSDij <γP, the MDj will broadcast a ‘failure’ message to the MSi and the best MR. The best MR decides whether DF or AF cooperation is utilized to forward the received signal to the MDj by comparing the instantaneous SNR γSRi to a threshold γT, where γSRi represents the SNR of the link between MSi and the best MR. The best MR is selected based on the following criterion

where γSRil represents the SNR of MSi→ MRl link, and

If γSRi>γT, the best MR then decodes and forwardes the signal xr to MDj. Based on the DF cooperation protocol, the received signal at MDj is given by

where nRDj is a conditionally zero-mean complex Gaussian random variable with variance N0/2 per dimension.

If selection combining (SC) method is used at MDj, the output SNR can then be calculated as

where γRDj represents the SNR of the link between the best MR and MDj .

If γSRi<γT, the best MR amplifies and forwards the signal to MDj. Based on the AF cooperation protocol, the received signal at MDj is then given by

where

The output SNR of end-to-end link can then be calculated as

As far as we know, a convenient mathematical method to obtain PDF and CDF of γSRDij exactly is still unachievable. Here, we adopt the method in [27] to obtain an approximate γSRDij. At high SNR, the γSRDij can be approximated as

By using the well-known inequality in [28], we can obtain an upper bound as

If SC method is used at MDj, the output SNR can then be calculated as

Using SC method at MD, the output SNR can then be calculated as

where

The optimal TAS scheme should select the transmit antenna w that maximizes the output SNR at MD, namely

The suboptimal TAS scheme is to select the transmit antenna that only maximizes the instantaneous SNR of the direct link MSi →MDj, namely

3.2 Channel model

We assume that the links in the system are subject to independently and identically distributed (i.n.i.d) N-Nakagami fading. h follows N-Nakagami distribution, which is given as[8]

where N is the number of cascaded components, at is a Nakagami distributed random variable with PDF as

Γ(·) is the Gamma function, m is the fading coefficient and Ω is a scaling factor.

With the aid of [8], the PDF of h is given by

where G[·] is the Meijer’s G-function[8].

Let y=|hk|2 represents the square of the amplitude of hk. The corresponding CDF and PDF of y can be given as [8]

 

4. The OP of Optimal TAS Scheme

The OP of optimal TAS scheme can be expressed as

4.1 γth<γp

When γp>γth>γT, the OP of optimal TAS scheme can be expressed as

where γth is a given threshold for correct detection at MD.

The G1 is evaluated as

Next, the G2 is evaluated.

4.2 γth>γp

When γth >γp, γth >γT, the OP of optimal TAS scheme can be expressed as

The I1 is given as

The I2 is evaluated as

 

5. The OP of Suboptimal TAS Scheme

5.1 γth<γp

When γp>γth>γT, the OP of suboptimal TAS scheme can be expressed as

where

The GG1 is evaluated as

Next, the GG2 is evaluated.

5.2 γth>γp

When γth > γp, γth >γT, the OP of suboptimal TAS scheme can be expressed as

The II1 is given as

Next, the II2 is evaluated.

 

6. ABEP-Optimized Power Allocation

To further improve the performance, we aim to optimally allocate the power between broadcasting and relaying phases. For optimization of the power allocation, we consider OP as our objective function. The resulting OP needs to be minimized with respect to the power-allocation parameter K.

Fig. 2 presents the effect of the power-allocation parameter K on the OP performance when γth=5dB, γT=2dB, γp=6dB. The number of cascaded components is N=2. The fading coefficient is m=2. The relative geometrical gain is μ=0dB. The number of transmit antennas is Nt=2. The number of mobile relays is L=2. The number of receive antennas is Nr=2. Simulation results show that the OP performance is improved with the SNR increased. For example, when K=0.7, the OP is 3.3×10-1 with SNR=5dB, 4.6×10-3 with SNR=10dB, 1.0×10-6 with SNR=15dB. When SNR=5dB, the optimum value of K is 0. 99; SNR=10dB, the optimum value of K is 0.60; SNR=15dB, the optimum value of K is 0. 52. This indicates that the equal power allocation (EPA) scheme is not the best scheme.

Fig. 2.The effect of the power-allocation parameter K on the OP performance

Unfortunately, an analytical solution for power allocation values in the general case is very difficult. We resort to numerical methods to solve this optimization problem. The optimum power allocation (OPA) values can be obtained a priori for given values of operating SNR and propagation parameters. The OPA values can be stored for use as a lookup table in practical implementation.

In Table 1, we present optimum values of K with the relative geometrical gain μ. The number of cascaded components is N=2, the fading coefficient is m=2, the relative geometrical gain is μ=5dB, 0dB,-5dB, the number of transmit antennas is Nt=2, the number of mobile relays is L=2, the number of receive antennas is Nr=2, and the given threshold is γth=5dB, γT=2dB, γp=6dB. For example, when μ=5dB, the SNR is low, nearly all the power should be used in broadcast phase. As the SNR increased, the optimum values of K are reduced, and more than 50% of the power should be used in broadcast phase.

Table 1.OPA parameters K

Fig. 3 presents the effect of the relative geometrical gain μ on the OP performance when γth=5dB, γT=2dB, γp=6dB. The values of K are used in Table 1. Simulation results show that the OP performance is improved as μ reduced. For example, when SNR=10dB, the OP is 3.6×10-3 for μ=5dB, 4.5×10-5 for μ=0dB, and 1.9×10-7 for μ=-5dB. This indicates that the best location for the relay is near the destination. For a fixed μ, an increase in the SNR reduces the OP.

Fig. 3.The effect of the relative geometrical gain μ on the OP performance

 

7. Numerical Results

In this section, we present Monte-Carlo simulations to confirm the derived analytical results. The simulation results are obtained for BPSK modulations. Additionally,random number simulation was done to confirm the validity of the analytical approach. All the computations were done in Matlab and some of the integrals were verified through Maple. The links between MS→MD, MS→MR and MR→MD are modeled as N-Nakagami distribution. The total energy is E =1. The fading coefficient is m=1, 2, 3, the number of cascaded components is N=2, 3, 4, the number of mobile relays is L=2, the number of receive antennas is Nr=2, and the number of transmit antennas is Nt=1, 2, 3, respectively.

Fig. 4 presents the OP performance of optimal TAS scheme when γth=5dB, γT=2dB, γp=6dB. Fig. 5 presents the OP performance of optimal TAS scheme when γth=5dB, γT=2dB, γp=2dB.The number of cascaded components is N=2. The fading coefficient is m=1. The power-allocation parameter is K=0.5. The number of transmit antennas is Nt=1, 2, 3. The number of mobile relays is L=2. The number of receive antennas is Nr=2.The relative geometrical gain is μ=0dB. In order to verify our analytical results, we have also plotted simulation based results. We see that the analytical results match perfectly with the simulations. As expected, the OP is improved as the number of transmit antennas increased. For example, when γth>γp, SNR=10dB, Nt=1, the OP is 2.2×10-1, Nt=2, the OP is 5.0×10-2, Nt=3, the OP is 1.1×10-2. With Nt fixed, an increase in the SNR decreases the OP.

Fig. 4.The OP performance of optimal TAS scheme when γth<γp

Fig. 5.The OP performance of optimal TAS scheme when γth>γp

Fig. 6 presents the OP performance of suboptimal TAS scheme when γth=5dB, γT=2dB, γp=6dB. Fig. 7 presents the OP performance of suboptimal TAS scheme when γth=5dB, γT=2dB, γp=2dB.The number of cascaded components is N=2. The fading coefficient is m=1. The power-allocation parameter is K=0.5. The number of transmit antennas is Nt=1, 2, 3. The number of mobile relays is L=2. The number of receive antennas is Nr=2.The relative geometrical gain is μ=0dB. In order to verify our analytical results, we have also plotted simulation based results. From Fig. 6 and Fig. 7, we can obtain that the analytical results match perfectly with the simulations. As expected, the OP is improved as the number of transmit antennas increased. For example, when γth=5dB, γT=2dB, γp=2dB, SNR=12dB, Nt=1, the OP is 2.0×10-1, Nt=2, the OP is 5.7×10-2, Nt=3, the OP is 1.5×10-2. With Nt fixed, an increase in the SNR decreases the OP.

Fig. 6.The OP performance of suboptimal TAS scheme when γth<γp

Fig. 7.The OP performance of suboptimal TAS scheme when γth<γp

In Fig. 8, we compare the theoretical OP performance of optimal TAS scheme and suboptimal TAS scheme by varying the number of antennas Nt, when γth=5dB, γT=2dB, γp=2dB. The number of cascaded components is N=2. The fading coefficient is m=1. The power-allocation parameter is K=0.5.The relative geometrical gain is μ=0dB. The number of transmit antennas is Nt =2,3. The number of mobile relays is L=2. The number of receive antennas is Nr=2. To avoid clutter, we have not plotted the simulation based results. In all cases, as expected, when Nt is fixed, optimal TAS scheme has a better OP performance in all SNR regimes. As predicted by our analysis, the performance gap between two TAS schemes decreases when Nt is increased. When the SNR is low, the OP performance gap between optimal TAS scheme with Nt=2 and suboptimal TAS scheme with Nt=3 is negligible, as the SNR increases, the OP performance gap also increases.

Fig. 8.The OP performance comparison of two TAS schemes

Fig. 9 illustrates the OP performance of IAF, IDF, IHDAF three relaying schemes. The number of cascaded components is N=2. The fading coefficient is m=2. The power-allocation parameter is K=0.5.The relative geometrical gain is μ=0dB. The number of transmit antennas is Nt =2. The number of mobile relays is L=2. The number of receive antennas is Nr=2.The given threshold is γth=5dB, γT=2dB, γp=6dB. In all cases, as expected, IDF scheme has a better OP performance than IAF scheme in all SNR regimes. When the SNR is low, IDF scheme outperforms the other two schemes significantly. With the SNR increases, IHDAF scheme outperforms the other two schemes significantly.

Fig. 9.The OP performance comparison of three relaying schemes

 

8. Conclusion

The exact closed-form OP expressions for IHDAF relaying M2M networks with TAS over N-Nakagami fading channels are derived in this paper. The simulation results show that optimal TAS scheme has a better OP performance than suboptimal TAS scheme; the power-allocation parameter K has an important influence on the OP performance. Expressions were derived which can be used to evaluate the OP performance of vehicular communication systems employed in inter-vehicular, intelligent highway and mobile ad-hoc applications.