Title :
Fast simulation of diversity Nakagami fading channels using finite-state Markov models
Author :
Iskander, Cyril-Daniel ; Mathiopoulos, P. Takis
Author_Institution :
Dept. of Electr. & Comput. Eng., British Columbia Univ., Canada
Abstract :
We designed a multi-channel Nakagami fading simulator by modeling the received combined signal-to-noise ratio as a finite-state Markov chain, following a previously proposed approach. Our model generates directly the error process at the output of a diversity receiver and can emulate selection, maximal-ratio, and equal-gain combining. As the order of diversity increases, the savings in computational complexity improve linearly with respect to a traditional waveform simulator. The level crossing rates of the simulated envelope are shown to be very close to their theoretical values. The simulator´s performance is also evaluated in terms of the accuracy of the obtained bit error rates, for both uncoded and coded systems. The simulator speeds up the performance evaluation of high-rate communication links where a high number of samples is needed.
Keywords :
Markov processes; computational complexity; digital simulation; diversity reception; error statistics; fading channels; radio receivers; telecommunication computing; BER; Nakagami fading channels; bit error rates; computational complexity; diversity channels; diversity receiver; equal-gain combining; finite state Markov channel; finite-state Markov models; maximal-ratio combining; radio broadcast receivers; selection combining; signal-to-noise ratio; simulation software; Bit error rate; Computational complexity; Computational modeling; Councils; Diversity reception; Fading; Hidden Markov models; Rayleigh channels; Signal design; Signal to noise ratio;
Journal_Title :
Broadcasting, IEEE Transactions on
DOI :
10.1109/TBC.2003.817096
