This work proposes a novel wearable passive microwave sensor in the 2.45 GHz ISM band, to detect the presence of aqueous solutions on the skin surface. The sensing sub-system consists of a modified open-end coupled-lines microwave filter, with one (or more) open termination replaced by a resonant openend stub, integrating a microfluidic channel. In this way the filter behavior is strictly related to the microfluidic channel content. The equivalent circuit of the microfluidic channel is derived from EM simulation, to allow accurate and efficient design of the whole sensor system. In order to provide power remotely, a narrowband antenna is seamless connected to the filter input port and the channel content may be transduced at the filter output by a low-power detector. The chosen novel topology is suitable for both its frequency selective behavior, which turns to a highaccuracy fluid discrimination, and the ease of implementation in flexible and thin substrates, allowing the realization of a lowcost wearable sensor.
A wearable passive microwave fluid sensor wirelessly activated / F. Benassi, N. Zincarelli, D. Masotti, A. Costanzo. - ELETTRONICO. - (2019), pp. 236-240. (Intervento presentato al convegno Wireless Power Week 2019 tenutosi a Londra nel 17-21 Giugno 2019) [10.1109/WPTC45513.2019.9055618].
A wearable passive microwave fluid sensor wirelessly activated
F. Benassi;N. Zincarelli;D. Masotti;A. Costanzo
2019
Abstract
This work proposes a novel wearable passive microwave sensor in the 2.45 GHz ISM band, to detect the presence of aqueous solutions on the skin surface. The sensing sub-system consists of a modified open-end coupled-lines microwave filter, with one (or more) open termination replaced by a resonant openend stub, integrating a microfluidic channel. In this way the filter behavior is strictly related to the microfluidic channel content. The equivalent circuit of the microfluidic channel is derived from EM simulation, to allow accurate and efficient design of the whole sensor system. In order to provide power remotely, a narrowband antenna is seamless connected to the filter input port and the channel content may be transduced at the filter output by a low-power detector. The chosen novel topology is suitable for both its frequency selective behavior, which turns to a highaccuracy fluid discrimination, and the ease of implementation in flexible and thin substrates, allowing the realization of a lowcost wearable sensor.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
