Title :
Assessment of a new indoor propagation prediction method based on a multi-resolution algorithm
Author :
Runser, Katia ; Gorce, Jean-Marie
Author_Institution :
INRIA, Lyon, France
fDate :
30 May-1 June 2005
Abstract :
The multi-resolution Fourier domain parflow (MR-FDPF) is a new indoor propagation prediction model based on a finite difference computation of the electrical field. The predictions made in two dimensions are fast: simulation lasts 6s for an 80×30 meters building floor at the resolution of 10 centimeters. At a coarser resolution, processing time can be reduced up to 0.6s. Prediction performance of our method is presented in this paper. A least-square calibration process based on signal power measurements is used to determine the propagation indices and attenuation factors of the constitutive materials of the building. The coverage predictions made with the calibrated MR-FDPF are challenged to real measurements and a mean squared error about 5dB is obtained.
Keywords :
Fourier analysis; electromagnetic wave scattering; field strength measurement; finite difference methods; indoor radio; least squares approximations; radiowave propagation; attenuation factors; building materials; calibrated MR-FDPF; coverage predictions; electrical field; finite difference computation; indoor propagation prediction model; least-square calibration; mean squared error; multi-resolution Fourier domain parflow; propagation indices; signal power measurements; Attenuation; Calibration; Computational modeling; Finite difference methods; Floors; Power measurement; Prediction methods; Predictive models; Signal processing; Signal resolution;
Conference_Titel :
Vehicular Technology Conference, 2005. VTC 2005-Spring. 2005 IEEE 61st
Print_ISBN :
0-7803-8887-9
DOI :
10.1109/VETECS.2005.1543244
