Recent advancement in vehicular wireless applications
is also a major contributing factor in spectrum scarcity.
Cognitive radio system is a mechanism which allows unlicensed
cognitive users (CUs) to utilize idle unused bands. Fast and
reliable detection of primary legacy user is the key component of
cognitive radio networks. However, hidden terminal and low SNR
problems due to shadow fading put fundamental limit to the sensing
performance and practical entailments in design of the cognitive
vehicular networks. Extensive modeling is being carried out to
specify varying channel characteristics, particularly multipath
fading and shadowing. Energy detection-(ED-) based spectrum
sensing is a viable choice for many vehicle-to-vehicle (V2V)
and vehicle to-road-side infrastructure (V2I) communications.
This paper examines the performance of spectrum sensing
using ED over Gamma-shadowed Nakagami-m composite fading
channel to cater for both small-and-large scale fading. The
results highlight the notable impact of shadowing spread and
fading severity on detection performance. The relevant simulation
results are presented to support our analytical results for average
detection probability. Furthermore, these results are investigated
and compared to other compound and classical channels.
1. Introduction
Radio spectrum is a limited resource, and almost all frequency bands are allocated to licensed users. The underutilization of spectrum bands extends to the definition of term spectrum hole as shown in Figure 1. It is actually an allotted band of frequencies, but at a specific time and geographic perspective, the band is not being employed by that user [1]. Cognitive radio is a compelling and innovative need for future wireless demands. There is a tremendous possibility to improve spectrum efficiency and quality of services through shared utilization. This system has also attracted a lot of interest in intelligent transportation networks (ITS). Cognitive radio-based vehicular transportation system in V2I and V2V communications and even interactions among on board devices within vehicles will help improve radio resource, energy efficiency, traffic network management, vehicular diagnostics and reduce accidents by road traffic awareness and route planning [2].
Spectrum holes concept.
Spectrum sensing is the first step, as it should be carried out before permitting a cognitive client to approach an authorized channel. Fast and reliable detection of licensed user is the key component of cognitive radio networks. Thus, CUs need to have such cognitive abilities along with monitoring of substitute spectral route for possible band evacuation and minimum interference aggregation to other CUs [1].
In wireless communication, fading effect degrades signal propagation. This also places a primary constraint on sensing performance. Many propagation campaigns have been performed to investigate the statistics of shadow-fading in radio environments. Vehicle-to-roadside communications such as an automatic toll collection system has to grapple several channel variations particularly shadowing and multipath fading. Although the vehicle-mounted antenna ensures line-of-sight (LOS) connection to the beacon antenna, the shadow-fading due to reflections and scattering from the vehicle's own motor-hood or from other nearby large vehicles is a common problem as presented in Figure 2. Composite fading models like Suzuki, Loo, Rice-lognormal and Nakagami-lognormal, and so forth, are used to represent combine multipath and shadowing effects in wireless communications [3, pages 72–74]. They all rely on conventional lognormal distribution to model shadowing. However, capacity measurement and performance of spectrum sensing and access under multipath and shadowing using lognormal fading channel are somehow complex and do not lead to closed-form solutions. Alternatively, Gamma distribution is proposed to model the variations of average power which interprets shadow fading as close as lognormal distribution [4].
Shadowing in spatial environment.
Energy detection [5] is proposed for spectrum sensing in cognitive radios due to its simplicity, low computational cost and ability to be applied on any kind of deterministic signal. In cognitive vehicular ad hoc network (VANET), ED can be applied to increase bandwidth efficiency. Licensed TV bands holders are primary users whereas vehicles and roadside infrastructure on highways and suburban cities will act as secondary users. As most of TV bands are blank, CUs in vehicular communication will perform ED-based sensing to find many unused spectrum bands. This assumption provides opportunistic spectrum access for wireless V2V and V2I communications. These ED-based cognitive vehicular systems lead to increased safety and information agility for vehicles on the road affected by multipath fading and shadowing. Moreover, the primary user transmission is modeled as a signal with known power, and hence energy detector is optimal [6, page 141]. In addition to cognitive radio, ED has found many applications in ultra wide-band technologies. Thus, performance analysis of energy detector in vehicular wireless networks with a variety of integrated techniques, is of particular interest.
The vehicular environment vision requires reliable, low latency wireless communication methods. One core issue is to detect and understand the nature of the wireless channel encountered by vehicular radios. The fading channels considered for are classical lognormal and Rayleigh fading channels. Previous research has primarily focused and examined ED, without (explicitly) taking into account fading channels that consist of composite distributions. The investigation over Gamma-shadowed Nakagami-m channel in [7, 8] consisted mainly on error performance, whereas spectrum sensing or estimation of detection probability is still an unexplored region.
This paper specifically focuses the performance analysis of energy detector in vehicular networks under Gamma-shadowed Nakagami-m fading channel model. The organization of the paper is as follows. In Section 2, detailed model of ED for spectrum sensing is discussed with its significance in vehicular networks. Section 3 defines the statistics of composite fading model with Gamma PDF as an alternative replacement for lognormal distribution. Composite fading channel statistics and signal-to-noise ratio (SNR) analysis for ED with respect to shadow-fading parameters are characterized in Section 4. The approximated expression for average detection probability over composite fading is obtained in Section 5 using series representation of Marcum-Q function. Further, Section 6 contains numerical and simulation results which also verify our theoretical formulations, and discussion about sensing and receiver performance in terms of fading parameters. Finally, Section 7 contains some concluding remarks.
2. Energy Detection in Vehicular Technologies
Energy detection is an efficient and fast noncoherent technique that essentially computes a running average of the signal power over a window of prespecified spectrum length. This is the simplest sensing method that requires no a priori knowledge about the transmitted signals. In addition to vehicular communications, the significance of energy detector finds many applications in wide-band technologies [9]. Performance analysis of ED over a variety of fading channels in vehicular network is considerably important and requires detailed investigation.
ED has already been recognized as an efficient sensing method for cognitive radio. In vehicular networks cognitive radio is a new paradigm to alleviate the bandwidth scarcity problem which will be an issue in near future. Similar to many cognitive radio systems, cognitive VANET faces the challenge of spectrum sensing, that is, the vehicles need to detect the presence or absence of licensed primary users with high reliability [9].
The block diagram of the energy detector is shown in Figure 3. The signal x(t) is received and filtered with a bandpass filter (BPF) in order to limit the noise and to select the bandwidth of interest. The noise in the output of the filter has a band-limited, flat spectral density. Next, the energy detector consists a squaring device and a finite time integrator. The output signal Y from the integrator as given in [5]
Y=1T∫t-Tt|x(τ)|2dτ.
Block diagram of energy detector.
Finally, this output signal Y is compared to the threshold λ, in order to decide whether a signal is present or not. The threshold is set according to the statistical properties of the output Y when only noise is present. Thus, spectrum sensing is equivalent to detect the presence of an unknown deterministic signal in the radio spectrum band which generally defines a binary hypothesis-testing problem as
y(t)={n(t)H0:signalisabsent,hx(t)+n(t)H1:signalispresent,
where h is the channel response and n(t) is the Gaussian random variable with zero mean and N01W variance; n~N(0,N01W) where N01 is the single sided noise spectral density and W is the bandwidth. A sample function of time period T of a process which is band limited to W can be approximately described by a set of 2u number of sample values, that is, u=TW, where T and W are selected to limit u to an integer value [5]. Using this fact, the statistics of the detector decision variable Y of the primary signal is a sum of 2u zero and non zero mean Gaussian random variables under H0 and H1 respectively. The approximated noise energy over a time period (0,T) for detector Y is formulated as [10]
Y=2N01∫0Tn2(t)dt=∑i=12u(niN01W)2:H0.
Similarly, Y under H1 is constructed as
Y=2N01∫0Ty2(t)dt=∑i=12u(hixi+niN01W)2:H1.
Here, we assume that the h is constant over the 2u samples.
Thus, the probability density function (PDF) of Y is a central chi-square variable χ2u2 with 2u degrees of freedom for H0 and noncentral chi-square variable χ2u2(2γ) with 2u degrees of freedom and a noncentrality parameter 2γ under H1 respectively, which can be written asfY(y)={12uΓ(u)yu-1e-y/2:H0,12(y2γ)(u-1)/2e-(2γ+y)/2Iu-1(2γy):H1,
where γ is the SNR, that is, γ=h2Es/N01 and Es is defined as observed signal energy, Γ(·) is gamma function and In(·) is nth order modified Bessel function of the first kind. The exact closed-form equations for probabilities of detection Pd, false alarm Pf, and missed detection Pm over additive white Gaussian noise (AWGN) channel are given by [10]Pd=Pr{Y>λ∣H1}=Qu(2γ,λ),
where λ is the threshold for signal sample and QM(·,·) is generalized Mth order Marcum-Q function defined as [11, Equation (2.1-122), page 44]QM(α,β)=∫β∞tMαM-1e-(t2+α2)/2IM-1(αt)dt,
where IM-1(·) is the modified Bessel function of (M-1)th order. The probability of false alarm is expressed as
Pf=Pr{Y>λ∣H0}=Γ(u,λ/2)Γ(u),
where Γ(·,·) is an upper incomplete gamma function which is defined as Γ(m,n)=∫n∞tm-1e-tdt [12, Equation (8.350-2), page 899]. Since γ does not appear in (8), average false alarm probability over any fading channel will be similar (8).
Threshold λ for ED is calculated for a specified Pf using (8), whereas conventional optimality principle, Neyman-Pearson criterion maximizes Pd for a given Pf and equivalent to the likelihood ratio test (LRT) of Y indicated as LR(Y). In general, there is no LOS path present between the secondary user and the primary transmitter. Hence, the received primary signal is a superposition of many non LOS signals and is well approximated to Gaussian random variables according to central limit theorem [13]. In our consideration, when both the primary signal and noise are treated as Gaussian processes, energy detector can meet any desired Pd and Pf simultaneously, hence the threshold λ is optimal [14]. Finally, the probability of missed detection can be evaluated as
Pm=1-Pr{Y>λ∣H1}=1-Qu(2γ,λ).
Since Pf is independent of SNR due to the concept of no signal transmission, Pd in (6) is dealt only for nonfading environment, where channel h is deterministic. While a varying h due to shadowing and multipath fading gives probability of detection on the instantaneous SNR γ [15]. In this case, the average probability of detection Pd is assessed by averaging (6) over fading statistics.
The IEEE 802.22 draft standard addresses fixed-access devices and targets rural area applications. Energy detector has been tested for spectrum sensing in cognitive radio. Also ED is a non coherent reception technique which is implementable either using analog or digital design. The experimental test bed description and algorithms of ED in cognitive radio are given in [16, 17]. The SNR limitation is dealt with the help of collaboration of users [18] and continuous research work is ongoing to overcome ED limitations.
3. Composite Channel Model for Shadow Fading
In vehicular communication, a signal is assumed to pass through a large number of attenuating materials before reaching to the destination. Owing to the short range of typical V2V and V2I links, a more precise description of the fluctuations is often given by small-scale fading models. These fluctuations are caused by constructive and destructive interference between multipath components. Nakagami distribution can model fading conditions like Rayleigh or Rician statistics, depending on whether or not there is a LOS. The fading statistics for V2V propagation channel under realistic suburban driving conditions is modeled and analyzed by Nakagami distribution [19].
The PDF fX(x) of the envelope X, under Nakagami fading conditions describes the magnitude of the received envelope by the distributions given asfX(x)=2mmx2m-1e-(m/p)x2Γ(m)pm,x≥0.5,
where Γ(·) is the gamma function and m is the Nakagami fading parameter. p=E[x2] is the average power of the received signal, E[·] represents statistical average operator.
The average power p is deterministic in the absence of shadowing. However, V2I and V2V channel variations due to obstructions and large size vehicles, and so forth, exhibit shadowing effect. Thus, mean power of the signal becomes random and (10) can be written by conditioning the envelope as [20]fX∣P(x∣p)=2mmx2m-1e-(m/p)x2Γ(m)pm,x,p>0.
The composite PDF with fading and shadowing is therefore written asfX(x)=∫0∞fX∣P(x∣p)fP(p)dp,
where fP(p) is the PDF of average power due to shadowing. If fP(p) is lognormally distributed and m≠1, fX(x) will be Nakagami-lognormal composite distribution. Nevertheless, due to the inherent analytical complication of handling correlated lognormal random variables, it is often inconvenient for further performance measurements and will not lead to a closed-form solution [15, 20].
3.1. Gamma Distribution: Alternative to Lognormal Distribution
Lognormal distribution is generally used to model average power variations. Empirical studies have shown that p has a lognormal PDF [21, Equation (1.5), page 21], that is,fP(p)=1p2πσ2exp(-(20logp-μdBm)22σ2),p>0,
where σ is the standard deviation for shadowing, whereas σ→0 corresponds to no shadowing. The local mean power p fluctuates about a constant area mean power μdBm, that is, μdBm=30+10E[Log10p] [21, Equation (2.202), page 98]. Composite fading channel with Nakagami PDF and lognormally distributed power has involved complicated integral form, also from above discussion even fitting this PDF to real data in vehicular communications is a difficult task. Hence, a closed-form expression for various system computations is a challenging problem. Based on theoretical results and measured data, an alternative substitute is the two-parameter Gamma distribution, which approximates several PDFs and justifies the lognormal distribution [4, 22].
Lognormal and Gamma PDFs are interchangeable in simulating real data when σdB is not large, that is, ≤6 [23]. For this, we compared the average detection probability variations over Gamma and lognormal fading channels in Figure 4 for Gamma shadowing parameter m0 with respective lognormal σdB spreads. It is evident from simulation results that for σdB<6, Gamma PDF is a good fit for lognormal distribution. Furthermore, when signal amplitude follows Nakagami-m distribution, the PDF of SNR γ, which is the sum of n independent and identically distributed (i.i.d) exponential random variables is Gamma distributed.
A comparison of average detection probability (Pd) variations between lognormal σdB spread and Gamma distributions shadowing parameter m0 values, keeping time bandwidth product u=5 and false alarm probability Pf=0.01.
Considering P=X2, the obtained result will be the PDF of P can be expressed as [11, Equation (2.1-105), page 41]
fP(p)=12πσ2pexp(-p2σ2),p≥0
if P is defined as P=∑i=1nXi2, where i=1,2,…,n are statistically i.i.d Gaussian random variables with zero mean and variance σ2. The characteristics function of P is represented as [11, Equation (2.1-107), page 41]
ϕP(jv)=1(1-j2vσ2)n/2.
The inverse transform of this characteristic function leads to central chi-square distribution with n degree of freedom, that is,fP(p)=p(n/2)-1σn2n/2Γ(n/2)exp(-p2σ2),p≥0,
substituting p0=2σ2 and m0=n/2 is simplified to Gamma PDF asfP(p)=pm0-1Γ(m0)p0m0exp(-pp0),
where p0 is the measure of average power and m0 is the order of Gamma PDF that inversely reflects shadowing severity. By changing m0, several distributions like lognormal, Gaussian, and so forth, can be obtained [8, 20]. The parameters m0 and p0 of Gamma distribution are related with their respective lognormal mean and the variance as m0=1/(eσ2-1) and p0=μ(m0+1)/m0, where σ=σdB/8.686 and μ are defined as the standard deviation and average power related to lognormal PDF respectively. The equivalent values of σdB and m0 are found accordingly and indicated in Table 1.
Gamma m0 and lognormal σdB values relationships.
σdB
2
4
6
m0
18.41
4.23
1.64
3.2. Gamma-Shadowed Nakagami-m Fading Distribution for Multipath and Shadowing
In radio propagation, shadowing and multipath fading appear simultaneously. Conversely, the channel model most frequently employed in vehicular communication do not distinguish the two effects. The Gamma-shadowed Nakagami-m (composite) distribution provides analytical restraint in terms of simplicity with which parameters can be computed. By substituting (17) and (11) in (12), the compound envelope of X consists of both multipath and shadowing is obtained in (18) as [20] fX(x)=∫0∞fX∣P(x∣p)fP(p)dp=2cΓ(m0)Γ(m)(cx2)m0+m-1Km0-m(cx),x>0,
where c=2m/p0 and Km0-m() is the modified Bessel function of order (m0-m).
The numerically evaluated PDFs of composite and Nakagami fading are plotted in Figure 5. It is found that when the effect of shadowing is decreased at large value of m0=50, the composite PDF exactly overlaps the Nakagami PDF and represents both multipath and shadowing effects.
The composite PDF over various shadowing parameter m0 values with corresponding Nakagami-m keeping m=0.8.
4. Composite Fading Channel Statistics
The moments of the compound envelope PDF are expressed as [20]Ec[Xt]=Γ(m0+t/2)Γ(m+t/2)Γ(m0)Γ(m)(2c)t.
From above formula, amount of fading (AF) defined as Af can be obtained as [20]Af=variance[X2]E[X2]2=mm0+m2m0+mm02m2m02>0.
The value of Af ranges from zero to infinity, corresponding to no fading to severe multipath fading and shadowing. By using (20) AF curves are simulated over a range of m0 for various m values as depicted in Figure 6. It is found that AF is related inversely with fading severity, and become independent for shadowing parameter m0>5 corresponds to 3.71σdB spread.
Amount of fading with respect to shadowing parameter m0 taking different values of fading severity parameter m.
For a given noise uncertainty, there exist a SNR wall, below which the ED cannot notice the existence of unknown deterministic signal [14]. Due to shadowing and fading effects, it is possible that user experiences very low SNR conditions and hence, its performance diminishes. For detection improvement in such situations, channel SNR values associated with the shadow-fading condition must be monitored carefully. The SNR of composite envelope is obtained from (19) as given by [20]:SNR=1m0m[Γ(m0)Γ(m)/Γ(m0+0.5)Γ(m+0.5)]2-1.
By using (21), we plotted SNR variations as a function of fading severity index m depicted in Figure 7. It is observed that larger values of m0 correspond to high SNR values. However, for m>0.5 change in SNR gradually decreases. When the user is in shadow fading environment with low SNR, the detection threshold λ of ED should be adjusted adaptively.
Composite fading channel signal-to-noise ratio (SNR) as a function of shadowing parameter m0 over different values of fading severity parameter m.
5. Average Detection Probability over Composite Fading Channel
The average probability of detection P̅d over fading statistics is determined as [10]:P¯d=∫0∞Qu(2γ,λ)fγ(γ)dγ,
where fγ(γ) is the PDF of SNR under shadow fading.
When envelope of received signal due to shadow-fading is modeled as Nakagami distribution the SNR PDF can be modeled as Gamma distribution [20]fγ∣γ¯(γ)=mmγm-1Γ(m)γ¯mexp(-mγγ¯),γ≥0,m≥0.5,
where Γ(·) is the gamma function and m is the Nakagami fading parameter. γ¯=E[h2Eb/N01] is the average SNR or average power of the received signal being random, hence reflects the existence of shadowing. The two-parameter Gamma distribution which has shown a good justification of lognormal PDF is defined asfγ¯0(γ)=m0m0γm0-1Γ(m0)γ¯0m0exp(-γγ¯0),
where γ¯0 is the measure of average power and is related to the average SNR γ¯, m0 is order of Gamma PDF and a measure of channel shadowing. The PDF of received SNR in combined shadow fading situation is given as [20]fγ(γ)=∫0∞f(γ∣γ¯)fP(p).
Substituting (23) and the two-parameter Gamma PDF from (24) in (25), and by changing variables fγ(γ), the PDF of received SNR in combined shadow fading environment can be obtained as [8]fγ(γ)=2Γ(m)Γ(m0)(c02)m0+m×γ((m0+m)/2)-1Km0-m(c0γ),γ>0,
where c0=2mm0/γ¯0 is scaling parameter related to γ¯ and Km0-m(·) is the modified Bessel function of order (m0-m).
The probability of detection over fading environment is evaluated using complicated integral forms involving Marcum-Q function. Further, these integrals cannot be solved in closed-forms in general with the available integral results [24]. In order to avoid such mathematical difficulties and to evaluate integrals involving Marcum-Q function with exponentials and Bessel functions having complicated arguments, alternative series representation of Marcum-Q function is used.
The generalized Marcum-Q function Qu(a,b) in its alternative series representation for 2γ>λ≥0, as given in [24]Qu(2γ,λ)=1-e(-(2γ+λ)/2)∑n=u∞(λ2γ)n/2In(2λγ),
where In(·) is the nth order modified Bessel function of the first kind. By substituting (27) and (26) in (22), the average detection probability over compound fading channel Pd can be written asP¯d=∫0∞(1-e(-(2γ+λ)/2)∑n=u∞(λ2γ)n/2In(2λγ))×2Γ(m)Γ(m0)(c02)m0+mγ((m0+m)/2)-1Km0-m(c0γ)dγ.
By using the fact ∫0∞fγ(γ)dγ=1, (28) will be simplified as, P¯d=1-2e-λ/2Γ(m)Γ(m0)(c02)m0+m∑n=u∞(λ2)n/2×∫0∞e-γγ(-n+m0+m)/2-1In(2λγ)Km0-m(c0γ)dγ.
However, integral of the Bessel functions product In(·) and Km0-m(·) with exponentials and powers does not lead to a closed-form, therefore we evaluated (29) numerically and compared it with our simulation results.
6. Numerical and Simulation Results
The performance of energy detector over composite fading channel for vehicular communications is presented in terms of average detection probability P¯d and complementary receiver operating characteristic (ROC) curves, that is, Pm versus Pf. By varying the average SNR γ¯0, while keeping all the other parameters such as threshold λ, time bandwidth product u, fading metric m and shadowing parameter m0 constant, the behavior of P¯d is shown. In the second scenario, detector performance is evaluated by means of complementary ROC curves similar to [10], that is, P¯m versus Pf where P¯m=1-P¯d.
Detector behavior characterization over various parameters is important in order to adjust numerous vehicular environments. The detector threshold λ is calculated for Pf=0.01 from (8) taking u=1,5,10 as shown in Figure 8. It can be observed that the detector performance with smaller number of samples (lower u) for energy Es is better if compared with that obtained from greater number of samples. The detector threshold λ is found at specified Pf. An increase in the threshold value of the detector, that is, larger u leads to reduction in both the false alarm and detection probabilities.
Average detection probability (P¯d) variations over various time bandwidth product (u) values in compound fading channel while taking false alarm probability Pf=0.01.
By using (29) average P¯d over varying γ¯0 is computed with the help of MATHEMATICA 7. Figure 9 illustrates the average Pd variations over composite fading channel at m0=18.41 and 4.23 corresponding to σdB=2 and 6 respectively. Both analytical and simulated results interpret sufficient detector performance over high average SNR, that is, SNR>10 dB, also higher values of m0 reflects better detection over specified SNRdB. However, for low SNR region the deteriorating performance can be improved using spatial diversity and appropriate combining techniques.
Average detection probability (P¯d) both analytical and simulation for composite fading taking m=1, u=5, and Pf=0.01.
The detection performance of composite fading channel rendering both multipath and shadowing effects at different range of m0 is evaluated in Figure 10. The better detection is illustrated as the effect of shadowing diminishes at higher values of m0, keeping fading characteristics m=1 unchanged. The similar phenomenon is obtained at smaller values of lognormal shadowing statistics σdB≤2 referring to light to moderate shadowed scenario. Whereas for heavier shadowed region, that is, σdB>6 to achieve a good fit is not possible. However, fading severity index m>1 keeps composite channel to overcome the shadowing and LOS communication can be considered which is common in vehicular networks.
A comparison of average detection probability (P¯d) variations between lognormal and composite fading channel keeping fading severity parameter m=1, time bandwidth product u=5 and false alarm probability Pf=0.01.
Complementary ROC plot (Pm versus Pf) for composite channel is plotted in contrast to Gamma, lognormal and Nakagami channels as shown in Figure 11. Both the Gamma and lognormal are offering similar detection characteristics for the selected parameters.It is evident that composite fading channel exhibits the combine fading properties of Gamma and Nakagami-m fading channel.
Complementary ROC (Pm versus Pf) of composite fading channel over different shadowing parameter m0 values in comparison with Nakagami-m fading channel. AWGN curve is provided for reference.
In Figure 12 the ROC curve of Gamma-shadowed Nakagami-m composite fading clearly indicates a substantial detection performance improvement in contrast to Loo and Suzuki mixed distribution channels where k represents carrier to multipath ratio in Loo distribution. Another prominent feature of the versatile Gamma-shadowed Nakagami-m composite channel is having minimum set of parameters as summarized in Table 2 from which diverse shadow fading environments can be approximated.
Input parameters of different shadow fading distributions.
Channel/parameter
m
m0
σdB
k
μdB
Composite
1
18.41
—
—
—
Loo
—
—
2
5
-6
Suzuki
—
—
2
—
−6
Complementary ROC (Pm versus Pf) of different mixed distribution fading channel over shadowing factor σdB=2 and fading severity parameter k=m=1. AWGN curve is provided for reference.
7. Conclusion
In the standardization process of vehicular networks, channel models are required to evaluate and select the proposed physical layer modulation and coding schemes. We have presented spectrum sensing using energy detection over Gamma-shadowed Nakagami-m composite fading model. The scheme can be effectively deployed in vehicular networks and help to combat against spectrum scarcity. To avoid computational complexities of the integrals involving Marcum-Q function, we apply PDF-based approximation and alternative series representation of generalized Marcum-Q function. Employing these approaches the average detection probability is evaluated. Analytical and simulation results are provided to support the theoretical formulations and derivations. The presented results show that spectrum sensing and access in vehicular communication can be improved by modeling the wireless environment precisely. Gamma-Shadowed Nakagami-m fading channel based energy detection provides fast and reliable sensing in cognitive vehicular networks. The numerical and simulation results provide insight and can serve as a quick way of assessing performance. From the presented results it is clear that a channel model composed of mixed distributions is useful for designing vehicular wireless systems and networks.
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