This paper presents an innovative microwave sensor designed to detect plant water stress and preliminary results from a measurement campaign conducted on olive trees' branches are also reported. The sensor's design, characterized by a dual-layer structure, has been carried out to achieve a good sensitivity obtained through a Q factor optimization procedure. Moreover, this configuration leads to compactness, enabling its use on small branches. The experiment has been conducted on 42 olive plants randomly divided into two water treatments: T0(no-irrigation) and T100 (full-irrigation). In accordance with the theoretical expectations, the study shows an upshift in the sensor resonant frequency as the irrigation water decreased. The obtained experimental results encourage future research and represent a notable advancement towards the non-destructive evaluation of plant water status, thereby improving sustainable agricultural practices.
Advances in Microwave Sensors for Non-Destructive Monitoring of Plant Water Status / Lazzoni V.; Brizi D.; Rossi R.; Argenti G.; Stagliano N.; Bindi M.; Monorchio A.. - ELETTRONICO. - (2024), pp. 2291-2292. (Intervento presentato al convegno 2024 IEEE International Symposium on Antennas and Propagation and INC/USNCURSI Radio Science Meeting, AP-S/INC-USNC-URSI 2024 tenutosi a "Fortezza da Basso" Convention Center, ita nel 2024) [10.1109/AP-S/INC-USNC-URSI52054.2024.10685975].
Advances in Microwave Sensors for Non-Destructive Monitoring of Plant Water Status
Rossi R.;Argenti G.;Stagliano N.;Bindi M.;
2024
Abstract
This paper presents an innovative microwave sensor designed to detect plant water stress and preliminary results from a measurement campaign conducted on olive trees' branches are also reported. The sensor's design, characterized by a dual-layer structure, has been carried out to achieve a good sensitivity obtained through a Q factor optimization procedure. Moreover, this configuration leads to compactness, enabling its use on small branches. The experiment has been conducted on 42 olive plants randomly divided into two water treatments: T0(no-irrigation) and T100 (full-irrigation). In accordance with the theoretical expectations, the study shows an upshift in the sensor resonant frequency as the irrigation water decreased. The obtained experimental results encourage future research and represent a notable advancement towards the non-destructive evaluation of plant water status, thereby improving sustainable agricultural practices.I documenti in FLORE sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.