Abstract
Channel adaptive M-ary quadrature amplitude modulation (M-QAM) schemes have been developed to provide higher average link spectral efficiency by taking advantage of the timevarying nature of wireless fading channels. Much of the earlier work on such schemes uses the assumption that thresholds designed for additive white Gaussian noise (AWGN) channels can be directly applied to slowly varying block-fading channels. The thresholds are calculated with a commonly used approximation bit error rate (BER) expression in these schemes. The first aim of this paper was to investigate the accuracy of using this common BER expression in a fading channel. This was done by comparing the result of the average BER expression derived using the approximate expression with results of simulations over a Nakagami-m block-fading channel. The second aim was to show that the inaccuracy in the threshold values determined using the closed form approximation expression would lead to inappropriate operation of the adaptive M-QAM scheme in a fading channel. This was done by comparing expected theoretical values with the simulation results. Two alternative approximate BER expressions for M-QAM in AWGN were then presented and used to determine the average M-QAM of BER over a Nakagami-m fading channel. The comparison between the average BER expressions and the simulation showed a much closer match. More accurate thresholds for the adaptive M-QAM system were then determined using one of the two average BER expressions and the accuracy of these threshold points was then verified using simulation results.
Highlights
In order to achieve quality of service (QoS) targets such as bit error rate (BER) and throughput in a point-to-point wireless fading channel, it is critical to maximise the spectral efficiency of the transmissions
We investigated the accuracy of a commonly used approximate BER expression for M-ary quadrature amplitude modulation (M-QAM) in a fading channel
It was shown that the threshold points for an adaptive M-QAM system derived using the approximate BER expression lead to inappropriate operation of the system in a fading channel
Summary
In order to achieve quality of service (QoS) targets such as bit error rate (BER) and throughput in a point-to-point wireless fading channel, it is critical to maximise the spectral efficiency of the transmissions. The objective of all of these schemes is to enhance the spectral efficiency of the transmissions by using M-QAM to adapt the transmission rate to a time-varying fading channel. Previous research[1,2,3] has demonstrated the improvement in spectral efficiency of the adaptive system while achieving a specified QoS BER target in the operable signal-to-noise ratio (SNR) range. Previous studies[11,12,13,14] combined M-QAM adaptive modulation to the diversity combining technique to propose schemes where the modulation mode and the diversity combiner structure are adaptively determined based on the channel fade condition and the error-rate requirement. Nechiporenko et al.[15] analysed the performance of an amplified and forward co-operative system with constant-power, rate-adaptive M-QAM transmission
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