Abstract
The interaction between electromagnetic waves and matter has led to the development of applications to detect and characterise them. The conventional systems use the emission, transmission and reception of waves at a specific frequency range to detect medium parameters (constant dielectric, permittivity, conductivity or permeability) of an analysed area. The interaction between the electromagnetic wave and the analysed medium depends on the range of frequency used. This phenomenon is used in different disciplines and working environments, geoscience or medical disciplines are examples where the use of electromagnetic waves provides non-intrusive applications with clear benefits. Each frequency of signal transmitted and received is analysed to determine the interaction produced in absolute measurements. In this work a method based in differential measurement technique is proposed as a novel way of detecting and characterizing electromagnetic matter characteristics. The theoretical results show that it is possible to obtain benefits from the behaviour of the wave-medium interaction using differential measurement on reception of electromagnetic waves at different frequencies. Differential measures introduce advantages in detection processes and increase development possibilities of new non-intrusive applications.
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Ferrández-Pastor, F.J., García-Chamizo, J.M., Nieto-Hidalgo, M. (2016). Electromagnetic Multi-frequency Model and Differential Measuring in Remote Sensing Applications. In: García, C., Caballero-Gil, P., Burmester, M., Quesada-Arencibia, A. (eds) Ubiquitous Computing and Ambient Intelligence. IWAAL AmIHEALTH UCAmI 2016 2016 2016. Lecture Notes in Computer Science(), vol 10070. Springer, Cham. https://doi.org/10.1007/978-3-319-48799-1_22
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