The Effect of Misdetection Probability on the Performance of Cooperative-Relaying-Based Cognitive Radio Systems

Cognitive radio (CR) is a promising solution to address the more and more congested radio spectrum. Cooperative relaying can provide a better transmission performance for the secondary user (SU), while the performance of the primary user (PU, also named licensed user) should be preferentially protected especially when there is misdetection probability. In this paper, in order to keep the PU away from outage caused by the interference from the SU under a certain signal-to-noise ratio (SNR), the maximum SNR for the SU can be derived by using the rate decaying factor (RDF). Then, based on the maximum channel gain and the maximum SNR, the outage probability is analyzed using decode-and-forward (DF) relaying and amplify-and-forward (AF) relaying schemes. Numerical results show that the outage probability decreases when the power allocation factor increases for DF strategy, while the outage probability has error floor when the power allocation factor increases for AF strategy. And the relaying scheme based on the maximum channel gain outperforms that based on the maximum SNR when the power allocation factor and detection probability are small, while the relaying scheme based on the maximum SNR outperforms that based on the maximum channel gain when the power allocation factor is large. What is more, AF relaying has better outage performance in the practical implementation.


Introduction
In the CR system, the SUs share the PU bands.Therefore, it is a great challenge for CR systems to protect the PU signal away from the interference caused by the SU signal [1].How to deal with the interference which is caused by the misdetection probability in the CR sensing period is a critical issue.In other words, on one hand, the performance of the SU transmission should be improved; on the other hand, the PU's transmission quality should be guaranteed.This requires the cooperative relaying with perfect sensing ability.In [2] the ideal sensing result is assumed on the PU's bands, and SUs only can communicate with each other through the common existing bands when they are not occupied by the PUs.Therefore, there will be no direct communication link which can be performed if there is no common band.The concept of cooperative relaying has been incorporated into cognitive radio system when there is no direct transmission link between two cognitive users.Cooperative transmission can maintain the SU's average throughput.The reason is that the cooperative relaying nodes provide additional spatial and spectrum diversity which improves the performance of the transmission between the source and the destination [3].
The cooperative relay has two main strategies: DF relaying and AF relaying.Cooperative communication is an efficient strategy that overcomes most of the limitations in wireless communications systems [4,5].Using cooperation, the users require less total power to achieve a certain throughput [4].DF relaying uses relays to demodulate and decode the transmitted signal from the source before reencoding and retransmitting to the destination.Related Work.In [6], a closed-form solution for the outage probability of DF relaying when the statistics of the channels between the source, relays, and destination are assumed to be independent and identically distributed was presented, while an exact closed-form expression for the outage probability of DF relaying in independent but not identically distributed dissimilar Rayleigh fading channels was derived in [7].As a low-cost strategy, the AF relaying boosts the coverage and capacity of cellular networks, particularly in regions with signal shadowing [8].The outage probability is a criterion of the performance evaluation for cooperative relaying.The outage probability for AF relaying using variable gain nodes is accurately calculated in [9,10].Variable gain relay is a kind of common AF strategy which compensates the signal fading with the instantaneous channel state information (CSI).The fixed relay is another strategy which is analyzed in [11], while the instantaneous CSI in the fixed relay is not required compared with the variable gain relay.
The capacity theorems of DF relaying and AF relaying are proposed in [12].Reference [13] analyzes and compares the performances of AF, DF, selection DF, and incremental AF strategies.The optimal resource allocation is researched for the Gaussian parallel fading relay channel under both full duplex and half duplex where the source and relay nodes are subject to separate power constraints [14].The power allocation is investigated in a three-node CR network after the cooperative relay in direct, dual-hop, and relay channels is studied to acquire optimal throughput [15].In [16], in the case that the Rayleigh instantaneous channel gain is exponentially distributed and available, the optimal outage probability is achieved using power allocation under source node and select nodes.In [17], the authors derive the optimal power allocation scheme using selection amplify-and-forward (S-AF) relay nodes to maximize the capacity in Rayleigh fading channel with known complete CSI and channel statistics.The outage probabilities of DF relaying and AF relaying with different power allocation factors were analyzed in [18], while [19] analyzes the outage probability of DF relaying and AF relaying using channel gain and signal-to-noise ratio (SNR) with different time duration allocation factors.However the impact of misdetection (one is the case in which the PU occupies the bands and is detected to be busy and another is the case in which the PU occupies the bands but is detected to be free; only the second midsection can cause interference to PU) probability in spectrum sensing period on the data transmission has not been discussed.
In this paper, we propose the concept of rate decaying factor (RDF).Using RDF, the SUs maximum SNR is derived in the premise of PU transmission link without interruption under the right PUs SNR.Then, using maximum channel gain and maximum SNR schemes, we analyze and calculate the outage probabilities of DF relaying and AF relaying for the relay node under the maximum SUs SNR with different power allocation factors.

System Model
The failure of spectrum sensing causes the SU signal to interfere with the PU on certain spectrum bands.As depicted in Figure 1, The PU's signal is truncated by the SU's signal when the bands are occupied but detected to be free.The SU's signal is the same as PU: one is from the SU's base station and another is from the relay nodes.The SU's signal is truncated by the PU's signal when the bands are occupied but detected to be free.So the SU and PU may interfere with each other when the bands are misdetected. 0 represents the PU direct transmission link;  0 and  1 represent the interference links to the PU caused by the SU signal.On the other hand, the SU may be interfered with by the PU signal when it starts to utilize the PU spectrum bands in the case in which the PU is actually busy but is detected to be free; ℎ 0 represents the SU direct transmission link, ℎ 1 and ℎ 2 represent the relaying links of the SU, and  0 and  1 represent the interference links to the SU caused by the PU.Furthermore, we assume the system is a full duplex system.

Decode-and-Forward Relaying Strategy.
For DF strategy, there is the case that the PU is detected (  : PU is absent and is detected to be absent; PU is busy and is detected to be busy) or misdetected (  ; PU is absent but is detected to be busy; PU is busy but is detected to be absent).The received PU signal can be divided into two cases: one is the case in which the PU occupies bands and is detected to be busy; therefore the noise is the channel noise; the other is the case in which the PU occupies the bands but is detected to be free; thus the noises consist of not only the channel noise but also the SU signal.Considering these two cases, the received signal of PU ( pu ) can be represented as where  pu is the PU transmitting power,  su is the SU total transmitting power which contains the power of source node and relay nodes,  pu is the PU transmitting signal,  su is the SU transmitting signal, and we assume that {| pu | 2 } = {| su | 2 } = 1,  0 is the average channel gain of the PU link,  0 and  1 are the average channel gains of interference link to the PU,  pu is the PU noise,   is the detection probability in spectrum sensing period, and   = 1 −   is misdetection probability.
The received SU signal contains two main parts.The first part is the transmitted signal from the SU when the PU signal is absent and is actually detected to be free (  ); the noise is only the channel noise.The second part contains not only the channel noise but also the PU signal when the PU signal is present but detected to be free (  ).Take all cases into account; the received signal from the direct link of SU ( su ) can be represented as where h0 is the instantaneous channel gain of the SU direct link,  0 is the average channel gain of interference link to the SU,  is the SU base station (BS) power allocation factor, and  su is the SU noise.When multihop relaying is performed the received signal of the th node (  ) is where h 1 is the instantaneous channel gain of the relay link of the SU BS-to-relay nodes,  1 is the average channel gain value of interference link to the SU, and  ℎ 1 is the receiver noise.
The received signal from the relaying link of the SU ( −su ) is where h2 is the instantaneous channel gain of relay link from relay node to the SU and  ℎ 2 is the channel noise of relay to the SU.

Amplify-and-Forward Relaying Strategy.
For AF strategy, the channel noise introduced from the relay in the receiver is not considered for simplicity; in the case in which the PU is detected (  ) or misdetected (  ) when it is actually present, the received signal of the PU ( pu ) can be represented as where  = 1/ℎ 1 is the relay scale of AF relaying.The received signal for the th relay node of the relay link is the same as (2).
The SU received signal of the relay link in the condition that the spectrum bands are detected and misdetected for the AF strategy can be represented as The Scheme for Selecting Node.
(1) The maximum channel gain scheme: the maximum channel gain node is selected from the relay nodes through comparing the received signals; when the maximum channel gain is larger than the direct link channel gain, the relay link is selected to transmit the signal; otherwise the direct link is selected.
(2) The maximum SNR scheme: the maximum SNR node is selected from the relay nodes through comparing the received signals; when the maximum SNR is larger than the direct link SNR, the relay link is selected to transmit the signal; otherwise the direct link is selected.
The remainder of the paper is organized as follows.The system model and the relay nodes selected scheme are proposed in Section 2. In Section 3, the SUs' maximum SNR is derived through RDF in the premise of keeping PUs away from interruption under a certain PUs' SNR; then the outage probabilities of DF relaying and AF relaying based on the selected relay node using maximum channel gain and maximum SNR with different power allocation factors are analyzed.In Section 4, numerical results are discussed.In Section 5, we draw the conclusion.

System Analysis
3.1.Decode-and-Forward Relaying 3.1.1.Max Channel Gain.The average SNR of the PU when using the DF strategy can be written as where we consider  pu ,  su ,  ℎ 2 , and  ℎ 1 are the additive white Gaussian noises (AWGN) with zero mean and variance { pu ,  su ,  ℎ 1 ,  ℎ 2 } =  0 , where [⋅] denotes the expectation. DF   is the PU SNR under the probability of detection which can be written as su is the SU SNR, and  DF   is the PU SNR under the misdetection probability which can be written as The criterion to keep the PU away from interruption is (1/2) log(1 +  aver ) >  max pu ( aver is the average SNR considering the PU interference signal).The maximum transmission Mobile Information Systems rate will be changed if the SNR changes; therefore we put forward the concept of rate decaying factor (RDF) and define the RDF as follows: where ) is the maximum transmission rate without SU interference and  max pu is the maximum transmission considering the SU interference.The PU maximum transmission rate will decrease due to the interference from the SU signal.
The SU SNR of the direct link is The SNR probability density function (PDF) of the direct link for DF strategy is derived in Appendix  =  + : where The SNR of SU BS-to-relaying node link for DF strategy is The SNR of the relay node-to-SU for DF strategy is Then the SNR PDF of the relay node-to-SU link for DF strategy is derived in Appendix  =  3 + : where , and  =  0 2  pu + 1.The outage probability of the SU using maximum channel gain for DF strategy is and the probability of selecting the maximum channel gain node is where   is the probability of the case when the th node channel gain is less than the maximum channel gain.

Max Signal-to-Noise Ratio.
The SNR PDF of direct link using maximum SNR scheme is the same as (16).The SNR PDF of relay node-to-SU is the same as (19).The SNR PDF of SU BS-to-relay node is where The outage probability of the SU using maximum SNR for DF strategy is where selecting maximum SNR relay node probability is 3.2.Amplify-and-Forward Relaying 3.2.1.Max Channel Gain.The SU SNR of the direct link for AF strategy can be written as and the SNR PDF of the direct link for AF strategy is where The SNR of SU BS-to-relay nodes is The SNR of the selected relay node-to-SU is Then the SNR PDF of the selected relay node-to-SU is where ) . (30) 3.2.2.Max Signal-to-Noise Ratio.The SNR PDF of direct link using max SNR scheme is the same as (26).The SNR PDF of the selected node-to-SU using max SNR scheme is the same as (29).The SNR PDF of SU BS-to-relay nodes using max SNR scheme is where The outage probability of the SU using maximum SNR for AF strategy is the same as (23).

Simulation and Performance Analysis
In this section, the numerical simulations are performed using the analysis of outage probability which is obtained in the previous section.We assume that  pu = 1 bps/Hz and relay nodes  = 8, the average channel gain value is 1/  , where  is the channel distance of each link, and  is pass loss exponent ( = 2 assumed).We also assume that  0 = 2.5,  1 = 1.5,  0 = 1,  0 = 2.5,  1 = 1.5,  ℎ0 = 2.5,  ℎ1 = 1.5,  ℎ2 = 1,  0 = 2.5, and  1 = 1.5.For all the simulations, we make the assumption that the distributions of the noise parts of the received PU or SU signals are Gaussian.
Figure 2 shows the SU outage probability versus power allocation factor  with different values of PU SNR when the detection probability is set to 0.9.One sees that the SU outage probability decreases when PU SNR increases and the power allocation factor increases.
Figure 3 shows the SU outage probability versus detection probability   and SU BS power allocation factor  when PU SNR is set to 20 dB.One sees that the SU outage probability decreases when the detection probability increases and SU BS power allocation factor increases.
Figure 4 shows the SU outage probability versus power allocation factor  with different values of PU SNR when the detection probability is set to 0.9.One observes that the SU outage probability decreases when PU SNR increases and the detection probability increases.Compared with Figure 2, the performance of using maximum channel gain is better than using maximum SNR when the SU BS power allocation factor  ∼ [0-0.1], while it is worse when the SU BS power allocation factor  ∼ [0.1-1].
Figure 5 shows the SU outage probability versus detection probability   and power allocation factor  when the PU SNR is set to 20 dB.One sees that the SU outage probability decreases when the detection probability increases and SU BS the PU SNR is 20 dB.In Figure 7, one sees that the SU outage probability decreases when the detection probability increases; one also observes that the SU outage probability can reach an error floor when the SU BS power allocation factor changes with different detection probability.Moreover, the larger the detection probability is, the smaller the SU BS power allocation factor corresponding to the minimum outage probability will be.the detection probability is set to 0.9.One observes that the SU outage probability decreases when the BS power allocation factor increases and the SU power allocation factor  ∼ [0-0.55], while the SU outage probability increases when the SU power allocation factor  ∼ [0.55-0.1]and PU SNR is 30 dB.On the other hand, the larger the PU SNR is, the smaller the SU BS power allocation factor corresponding to the minimum outage probability will be.Compared with Figure 6, the performance of using maximum channel gain is better than using maximum SNR when the SU BS power allocation factor  ∼ [0-0.1], while it is worse when the SU BS power allocation factor  ∼ [0.1-1].
Figure 9 shows the SU outage probability versus detection probability   and power allocation factor  when the PU SNR is set to 20 dB.One observes that SU outage probability can reach an error floor when the SU BS power allocation factor changes with different detection probability.What is more, the larger the detection probability is, the smaller the SU BS power allocation factor corresponding to the minimum outage probability will be.Otherwise, compared with Figure 7, the performance of using maximum channel gain is better than that using maximum SNR when the detection probability   < 0.60, while it is worse when the detection probability   > 0.60.The performance of using maximum channel gain is better than using maximum SNR when the SU BS power allocation factor  ∼ [0-0.1], while it is worse when the SU BS power allocation factor  ∼ [0.1-1].
Figure 10 shows the SU outage probability versus detection probability   , maximum channel gain, maximum SNR, and power allocation factor  when the PU SNR is set to 20 dB.When   = 0.7, the outage probability of maximum channel gain is better than maximum SNR while  < 0.75; when   = 0.8, the outage probability of maximum channel gain is better than maximum SNR in the case of  < 0.45;

Figure 6 :Figure 7 :
Figure 6: Max channel gain node with different  and   using AF.

Figure 8 Figure 8 :
Figure 8: Max SNR with different  and   using AF.
and  =  0 2  pu + 1.The outage probability of the SU using maximum channel gain for AF strategy is the same as (20); the probability of selecting the maximum channel gain relay node is   AF su + (1 −   )  ( AF su / (1 +  0 2  pu ))