The human body is a very complex structure, which has not been studied explicitly, until today, for remote monitoring application or wireless communication. This paper presents a preliminary study in the will to demonstrate how the combination of primitive shapes such as spheres, cylinders and parallelepipeds allows creating a simplified 3-D body model sufficient to analyze the interaction mechanisms of electromagnetic waves and resulting more efficient than numerical tools in terms of computational requirements. A comparison between the electric field scattered from a simple geometrical shape and from the realistic face of a phantom will be presented to show the accuracy of the model. To conclude, some experimental results with simulated data will be compared in order to provide a preliminary validation of the method.
A 3-D body model for physical activity monitoring by microwave radiation / Manfredi, Giovanni; Petrini, Valerio; DI MATTIA, Valentina; Pieralisi, Marco; DE LEO, Alfredo; Russo, Paola; Cerri, Graziano; Scalise, Lorenzo. - ELETTRONICO. - (2015), pp. 1-4. (Intervento presentato al convegno 15th IEEE Mediterranean Microwave Symposium, MMS 2015 tenutosi a Lecce (Italy) nel Nov. 30 2015-Dec. 2 2015) [10.1109/MMS.2015.7375459].
A 3-D body model for physical activity monitoring by microwave radiation
MANFREDI, GIOVANNI;PETRINI, VALERIO;DI MATTIA, VALENTINA;PIERALISI, MARCO;DE LEO, ALFREDO;RUSSO, Paola;CERRI, GRAZIANO;SCALISE, Lorenzo
2015-01-01
Abstract
The human body is a very complex structure, which has not been studied explicitly, until today, for remote monitoring application or wireless communication. This paper presents a preliminary study in the will to demonstrate how the combination of primitive shapes such as spheres, cylinders and parallelepipeds allows creating a simplified 3-D body model sufficient to analyze the interaction mechanisms of electromagnetic waves and resulting more efficient than numerical tools in terms of computational requirements. A comparison between the electric field scattered from a simple geometrical shape and from the realistic face of a phantom will be presented to show the accuracy of the model. To conclude, some experimental results with simulated data will be compared in order to provide a preliminary validation of the method.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
