Abstract
A smart sensor label based on the integration of ultra high frequency (UHF) radio frequency identification (RFID) technology and sensors is presented. The label is composed of a semi-active system that measures temperature, light, relative humidity and gravimetric water content (GWC) in the soil. The deployed system provides a simple, cost effective solution to monitor and control the growing of plants in modern agriculture and is intended be a part of a smart wireless sensor network (WSN) for agricultural monitoring. This paper is focused on analysis and development of a moisture sensor to measure GWC. It is based on a capacitance measurement solution, the accuracy of which is enhanced using several sensor driving frequencies. Thanks to the cancellation of supply voltage variations, the modeling of the GWC sensor and readout circuit was correct. The results we measured were close to modeled values. The maximum measurement resolution of the capacitive moisture sensor was 0.07 pF. To get the GWC from measured capacitance, a scale was used to weigh the mass of water in the soil. The comparison between capacitance measurement and calculated soil GWC is presented. The RFID measurement system has energy harvesting capabilities and an ultra-low power microcontroller, which uses embedded software to control the measurement properties. The microcontroller has to choose the appropriate model depending on the measured amplitude and chosen frequency to calculate the actual voltage on the sensing capacitor.
Highlights
Radio-frequency identification (RFID) devices come in two types: (1) readers that generate magnetic fields or electromagnetic (EM) waves from their antennas and issue commands, and (2) tags that are powered from the reader’s magnetic field or EM waves and respond to its commands
In this paper we provide an example of a semi active ultra high frequency (UHF) RFID based sensor system for monitoring soil moisture and environmental parameters including temperature, humidity and light
Relative humidity and temperature were measured above the flower pot
Summary
Radio-frequency identification (RFID) devices come in two types: (1) readers that generate magnetic fields or electromagnetic (EM) waves from their antennas and issue commands, and (2) tags that are powered from the reader’s magnetic field or EM waves and respond to its commands. The use of unmanned aerial vehicles (UAV) has been explored in conjunction with RFID and WSN technologies to achieve a remote or automatic operation of the sensor network with limited communication range [4]. This idea is very applicable in this work, as the sensors could be read out with a reader attached to a UAV. Monitoring soil parameters in the field with an NFC device is impractical due to their short range (up to 10 cm) This range is further reduced when powering external sensors in addition to the tag itself, and can go as low as 1 cm, as demonstrated in [7].
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