A technique combining uniform asymptotic theory of diffraction and finite-difference time-domain (UTD/FDTD), suitable to characterize human exposure in realistic urban environments at a reasonable computational cost, is presented. The technique allows an accurate evaluation of field interaction with penetrable objects (walls, windows, furniture, etc.) and of power absorption in a high-resolution model of the exposed subject. The method has been applied to analyze the exposure of a subject standing behind a window in a building situated in front of a rooftop-mounted base-station antenna. A comparison of the obtained results with those computed neglecting the presence of the building (free-space condition) evidences that a realistic modeling of field propagation in the actual scenario is essential for an accurate evaluation of absorbed power distribution inside the human body.
A UTD/FDTD model to evaluate human exposure to base-station antennas in realistic urban environments / Bernardi, Paolo Italo; Cavagnaro, Marta; Cicchetti, Renato; Pisa, Stefano; Piuzzi, Emanuele; Testa, Orlandino. - 1:(2003), pp. 403-406. (Intervento presentato al convegno IEEE MTT-S International Microwave Symposium tenutosi a PHILADELPHIA, PA nel JUN 08-13, 2003) [10.1109/mwsym.2003.1210962].
A UTD/FDTD model to evaluate human exposure to base-station antennas in realistic urban environments
BERNARDI, Paolo Italo;CAVAGNARO, Marta;CICCHETTI, Renato;PISA, Stefano;PIUZZI, Emanuele;TESTA, Orlandino
2003
Abstract
A technique combining uniform asymptotic theory of diffraction and finite-difference time-domain (UTD/FDTD), suitable to characterize human exposure in realistic urban environments at a reasonable computational cost, is presented. The technique allows an accurate evaluation of field interaction with penetrable objects (walls, windows, furniture, etc.) and of power absorption in a high-resolution model of the exposed subject. The method has been applied to analyze the exposure of a subject standing behind a window in a building situated in front of a rooftop-mounted base-station antenna. A comparison of the obtained results with those computed neglecting the presence of the building (free-space condition) evidences that a realistic modeling of field propagation in the actual scenario is essential for an accurate evaluation of absorbed power distribution inside the human body.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
