Abstract

Motivated by recent interest in dynamic spectrum sharing between primary and secondary spectrum users, we investigate slow adaptive quadrature amplitude modulation (QAM) under third-party received power constraints. The optimal rate and power adaptation schemes are derived to maximize the average spectral efficiency (SE) for the secondary users. Additionally, closed-form expressions of the achievable SE are presented for correlated lognormal shadow fading environments. Our analytical and numerical results underscore the importance of exploiting shadowing correlation in the proposed adaptive schemes.

1. Introduction

Opportunistic secondary access of licensed spectrum bands permits secondary users to transmit on these spectral bands as long as the primary licensee's interference temperature is below its tolerable level. This spectrum sharing approach has motivated recent studies of the channel capacity with constrained received-signal power at a third-party receiver [1, 2]. Figure 1 shows the associated system model in which a secondary transmitter communicates with a secondary receiver over a licensed-band, resulting in interference to a primary user. The channel gain between the transmitter and the primary receiver is denoted as 𝑔; the channel gain between this transmitter and the secondary receiver is denoted as . In [1], authors assume additive white Gaussian noise (AWGN) channels, where 𝑔 and are deterministic. In [2], authors assume flat fading channels, where the instantaneous values of 𝑔 and are known at the transmitter. This letter presents a communication-theoretic study of a similar system model but assuming the transmitter is only aware of slow fading conditions. We assume discrete-time block fading channels with stationary and ergodic time-varying power gains 𝑔=𝑔𝑟𝑔 and =𝑟; 𝑟𝑔 and 𝑟 are (unitmean) fast small-scale fading coefficients, and 𝑔 and are slow large-scale fading coefficients. Due to (bandwidth, delay) limitations of the feedback channel, we assume only and its correlation with 𝑔 are reliably known at the transmitter. The correlation between 𝑔 and can be fed back by a band manager [3], which coordinates the two parties. The transmitter then uses this information to apply a slow adaptive quadrature amplitude modulation (QAM) technique [4, 5]. We derive the optimal rate and power adaptation policies that maximize the average spectral efficiency (SE) for secondary users. Under optimal adaptation, we present closed-form expressions for achievable SE in correlated lognormal shadowing environments. The results underscore the importance of knowing/estimating shadow fading correlations in the proposed adaptive scheme.


Figure 1 
System model.

2. Optimal Power and Rate Adaptation

Assuming unit power AWGN at the primary and secondary receivers, the instantaneous BER for 𝑀-QAM can be approximated as [6, 7]𝙱𝙴𝚁in()𝑐1exp𝑐2𝑃𝑀1,(1) where 𝑃 is the transmit power, 𝑀 is the QAM constellation size. 𝑐1 and 𝑐2 are two parameters optimized via curve fitting. Assuming Nakagami-𝑚 fading, the short-term average BER over fast fading can be calculated as𝙱𝙴𝚁st()=0𝙱𝙴𝚁in𝑟𝑓𝑟𝑟𝑑𝑟=0𝙱𝙴𝚁in𝑟𝑚𝑚𝑟𝑚1Γ(𝑚)exp𝑚𝑟𝑑𝑟=𝑐1𝑐2𝑃()𝑚(𝑀()1)+1𝑚,(2) where 𝑃() and 𝑀() are two transmission parameters adaptive to . We consider here continuous rate adaptation, where the set of signal constellations is unrestricted [7, 8], that is, our results will provide an upper bound if only a discrete finite set of constellations is available. It is worth noting that in [5], exact average BER expression has been derived for discrete rate QAM with diversity reception over flat fading and shadowing channels. We do not apply this accurate expression in our analysis here due to the intractability of noninvertible integrals. Instead, we employ the approximation above as it provides analytical means to derive power and rate adaptation schemes for the system under study.

Given the short-term average BER constraint 𝙱𝙴𝚁st=𝙱𝙴𝚁, the optimal rate adaptation policy must satisfy𝑀()=1+𝐾𝑃(),(3)where𝐾=𝑐2𝑚𝑐1/𝙱𝙴𝚁1/𝑚1.(4)Furthermore, the optimal power adaptation policy for maximal long-term average SE is the solution tomax𝑃()𝔼log21+𝐾𝑃()subjectto𝔼𝑔𝑟𝑔𝑃()𝑃𝐼,𝑃()0,(5)where 𝑃𝐼 is the maximal average interference power tolerable at the primary receiver.

For this problem, we can show the following.

Case 1 (when /𝔼{𝑔} is not a constant). The optimal power allocation policy is 𝑃()=1𝐾𝔼𝑔1𝜅01/𝔼𝑔+waterllingover/𝔼𝑔,(6)where ()+=max(0,), and 𝜅0 is the solution of 𝔼{𝔼{𝑔}𝑃()}=𝑃𝐼. Note that 𝜅0 is the cutoff ratio of /𝐸{𝑔} and𝑃()0,if/𝐸𝑔𝜅0,=0,otherwise.(7)𝑃() is the product of a water-filling solution over /𝔼{𝑔} and (𝐾𝔼{𝑔})1. Since 𝔼{𝑔} is a function of , 𝑃() is not a pure water-filling solution in general. However, when 𝑔 and are independent such that 𝔼{𝑔|}=𝐸{𝑔}, (6) reduces to the classic water-filling solution.
Using the optimal power and rate adaptation scheme, the long-term average SE can be expressed as𝚂𝙴=/𝔼𝑔𝜅0log2𝜅0𝔼𝑔𝑓()𝑑.(8)

Case 2 (when /𝔼{𝑔} is equal to a constant). In this case, the optimal power allocation policy is channel inversion:𝑃()=𝑅𝑃𝐼,(9)and the average SE becomes 𝚂𝙴=log21+𝐾𝑅𝑃𝐼.(10)

3. Lognormal Shadowing

In contrast to the small-scale fading effects, which are typically independent from one terminal to another, shadowing effects tend to be correlated over much larger distances. For example, [9] presents shadowing cross correlation between several base stations and a mobile terminal in a 1900 MHz GSM system; the resulting correlations range from 0.34 to 0.43.

For correlated lognormal shadowing, we can write 𝑔=𝑒𝑋𝑔 and =𝑒𝑋, where 𝑋𝑔 and 𝑋 are jointly Gaussian distributed with means 𝜇𝑔 and 𝜇, variances 𝜎2𝑔 and 𝜎2, and a correlation coefficient 𝜌. Using this model, we can write 𝔼𝑔=𝜎𝑔/𝜎𝜌exp𝜇𝑔𝜎𝑔𝜎𝜌𝜇+1𝜌2𝜎2𝑔2.(11)Based on (11), we observe that the optimal power and rate adaptation scheme depends on the relationship between 𝜎 and 𝜌𝜎𝑔, which dictates if 𝔼{𝑔} is a linear function of . We consider all three possible functional relationships between 𝔼{𝑔} and . Substituting (11) into the analytical expressions presented in Section 2 and resorting to commonly used manipulations, we have the following.

Case 1 (when 𝜎>𝜌𝜎𝑔). The probability of service (i.e., the complement of the outage probability) is𝑃𝑟𝔼𝑔𝜅0=𝑃𝑟exp𝜇+𝜓(𝜅0)𝜎=𝑄𝜓𝜅0,(12)where 𝑄() is the Gaussian right-tail probability function, and𝜓𝜅0=1𝜎𝜌𝜎𝑔log𝜅0+𝜇𝑔𝜇+1𝜌2𝜎2𝑔2.(13)The achievable average SE is𝚂𝙴=log2(𝑒)𝜎𝜌𝜎𝑔×12𝜋exp𝜓2𝜅02𝜓𝜅0𝑄𝜓𝜅0,(14)where 𝜅0 is solved from𝐾𝑃𝐼=𝐾𝔼𝑔𝑟𝑔𝑃()=𝐾𝔼𝔼𝑔𝑃()=1𝜅0𝑄𝜓𝜅0exp𝜎2𝑔+𝜎22𝜌𝜎𝑔𝜎2+𝜇𝑔𝜇×𝑄𝜓𝜅0+𝜎𝜌𝜎𝑔.(15)

Case 2 (when 𝜎=𝜌𝜎𝑔). In this case,𝐸𝑔=exp𝜇𝜇𝑔+𝜎2𝜎2𝑔2=𝑅.(16)Thus, the optimal adaptation policy is channel inversion, and the achievable SE can be obtained by substituting (16) into (10).

Case 3 (when 𝜎<𝜌𝜎𝑔). The probability of service is𝑃𝑟𝔼𝑔𝜅0=𝑃𝑟exp𝜇+𝜓𝜅0𝜎=1𝑄𝜓𝜅0.(17)The achievable average SE is𝚂𝙴=log2(𝑒)𝜌𝜎𝑔𝜎×12𝜋exp𝜓2𝜅02+𝜓𝜅01𝑄𝜓𝜅0,(18)where 𝜅0 is solved from𝐾𝑃𝐼=1𝜅01𝑄𝜓𝜅0exp𝜎2𝑔+𝜎22𝜌𝜎𝑔𝜎2+𝜇𝑔𝜇×1𝑄𝜓𝜅0+𝜎𝜌𝜎𝑔.(19)

4. Numerical Results

In our numerical results, we assume 𝙱𝙴𝚁=103, the instantaneous BER approximation parameters 𝑐1=0.2 and 𝑐2=1.6 [7], the tolerable interference-to-noise ratio (INR) at the primary receiver is 0 dB, the fast fading is Rayleigh distributed, and the slow large-scale fading conditions are lognormal. In Figure 2, we plot the average SE versus the path loss difference 𝜇,dB𝜇𝑔,dB, assuming that 𝜎𝑔,dB=𝜎,dB=8 dB. Note that 𝜇{𝑔,},dB=10log10(𝑒)𝜇{𝑔,} and 𝜎{𝑔,},dB=10log10(𝑒)𝜎{𝑔,}. 𝑔 and are assumed correlated with (a) 𝜌=0, 0.3, and 0.7; and (b) 𝜌=0, 0.3, 0.8, and 1. For negative correlations, the average SE increases as 𝜌 decreases. This is because (1) higher implies lower 𝑔, providing better opportunity for secondary transmissions; and (2) smaller 𝜌 (or larger |𝜌|) implies heavier correlation, implying gives more complete information on 𝑔 and enables better adaptation over the time-varying channel. As reference, we also plot the average SE achieved using the variable-rate constant-power adaptation scheme. We observe that by adapting the transmit power, we can achieve much higher average SE when the correlation is heavy. When no correlation exists, the increase in SE, achieved via classic water-filling solution, is not significant compared with the constant-power scheme. For positive correlations, we do not see a clear trend between the average SE and 𝜌 due to two contrary effects. On the one hand, 𝑔 and are varying statistically along the same direction; thus, a large 𝜌 limits good transmission opportunities for the secondary system. On the other hand, heavier correlation provides more complete channel information, aiding in channel adaptation. We can observe that when the path-loss difference is small, the average SE increases as 𝜌 decreases, which means that the first effect is dominant. However, the second effect becomes dominant as the path-loss difference increases, for example, when 𝜇,dB𝜇𝑔,dB is greater than 18 dB, the average SE for 𝜌=1 (achieved by the channel inversion) becomes the highest amongst all curves.

(a) Negative correlation
(a) Negative correlation
(b) Possitive correlation
(b) Possitive correlation
Figure 2 
Average SE versus the path loss difference 𝜇 , d B 𝜇 𝑔 , d B . 𝜎 𝑔 , d B = 𝜎 , d B = 8 dB.

5. Conclusions

We investigate slow adaptive QAM technique under the third-party received power constraints. Optimal rate and power adaptations are derived to maximize average SE for secondary users. We present closed-form expressions of achievable SE for correlated lognormal shadowing environments. Results underscore the importance of exploiting shadowing correlation in proposed adaptive schemes.