Title :
Efficient simulation of digital transmission over WSSUS channels
Author :
Yip, Kun-wah ; Ng, Tung-Sang
Author_Institution :
Dept. of Electr. & Electron. Eng., Hong Kong Univ., Hong Kong
fDate :
12/1/1995 12:00:00 AM
Abstract :
This paper proposes an efficient Monte Carlo method which reduces computation for digital communication simulations over a multipath Rayleigh fading, wide-sense-stationary uncorrelated-scattering (WSSUS) channel. An equivalent discrete-time channel representation, which can be realized by a FIR filter with time-variant tap gains, is employed. In the proposed method, the tap gains are generated from a linear transformation of a set of orthogonal zero-mean complex Gaussian random processes. By the central limit theorem, each random process is approximated by summing a finite number of randomly generated phasors (Monte Carlo approximation). When compared with the tap gain generation method, which approximates the physical channel by the Monte Carlo approximation first and then generates the tap gain values, the proposed method demonstrates a considerable reduction in the required simulation time as well as improved accuracy under similar conditions
Keywords :
FIR filters; Gaussian processes; Monte Carlo methods; Rayleigh channels; approximation theory; digital radio; digital simulation; electromagnetic wave scattering; fading; filtering theory; multipath channels; random processes; simulation; FIR filter; Monte Carlo approximation; Monte Carlo method; WSSUS channels; accuracy; central limit theorem; digital communication; digital transmission; discrete-time channel representation; linear transformation; multipath Rayleigh fading channel; orthogonal zero-mean complex Gaussian random processes; randomly generated phasors; simulation time reduction; tap gain generation method; time-variant tap gains; wide-sense-stationary uncorrelated-scattering channel; Communication systems; Computational modeling; Delay; Digital communication; Finite impulse response filter; Monte Carlo methods; Random number generation; Random processes; Rayleigh channels; Rayleigh scattering;
Journal_Title :
Communications, IEEE Transactions on
