Ryo Shigeta scite author profile

Soil moisture is an important property for agriculture, but currently commercialized soil moisture sensors are too expensive for many farmers. The objective of this study is to develop a low-cost soil moisture sensor using capacitors on a film substrate and a capacitive touch integrated circuit. The performance of the sensor was evaluated in two field experiments: a grape field and a mizuna greenhouse field. The developed sensor captured dynamic changes in soil moisture at 10, 20, and 30 cm depth, with a period of 10–14 days required after sensor installation for the contact between capacitors and soil to settle down. The measured soil moisture showed the influence of individual sensor differences, and the influence masked minor differences of less than 0.05 m3·m−3 in the soil moisture at different locations. However, the developed sensor could detect large differences of more than 0.05 m3·m−3, as well as the different magnitude of changes, in soil moisture. The price of the developed sensor was reduced to 300 U.S. dollars and can be reduced even more by further improvements suggested in this study and by mass production. Therefore, the developed sensor will be made more affordable to farmers as it requires low financial investment, and it can be utilized for decision-making in irrigation.

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Soil-Monitoring Sensor Powered by Temperature Difference between Air and Shallow Underground Soil

Ikeda

Shigeta

Shiomi

et al. 2020

Proc. ACM Interact. Mob. Wearable Ubiquitous Technol.

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Energy harvesting (EH) technologies are useful for the semi-permanent operation of wireless sensor networks, especially, for agricultural monitoring as the networks need to be installed in large areas where power supply is unavailable. In this paper, we propose a battery-free soil-monitoring sensor for agriculture, which leverages the temperature difference between near-surface air and shallow underground soil using a thermoelectric generator (TEG). The performance of systems driven by the TEG mainly depends on the average temperature between the hot and cold sides of the TEG (T) and the temperature difference across the TEG (∆T). If T is low and ∆T is small, it is challenging to earn enough power to drive wireless microcontroller unit; however, with our dedicated electric circuit, and thermal designs including impedance matching of thermal circuit and suppression of heat loss, the sensor can harvest more than a hundred microwatt on average from the temperature difference between the air and underground soil at a depth of 30 cm. The performance of the energy harvester is evaluated both by numerical analysis using temperature data collected from various farm fields and by a prototype implementation. Moreover, the prototype was deployed to farm fields in Japan and India. Our field experiment results revealed that the prototype could harvest 100 µW-370 µW on average, and drive a wireless microcontroller unit to perform soil monitoring. CCS Concepts: • Hardware → Renewable energy; Sensor applications and deployments; • Human-centered computing → Ubiquitous and mobile computing systems and tools.

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Power harvesting from microwave oven electromagnetic leakage

Kawahara

Bian

Shigeta

et al. 2013

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In this paper, we considered the possibility of using electricity harvested from the microwave field leaked from commercial microwave ovens. Our experimental results showed that the leakage received by a dipole antenna was about 0 dBm (1 mW) at a point 5 cm in front of the door. A rectenna consisting of a dipole antenna and charge pump can convert the leaked microwave energy into a DC current. When a microwave oven is operated for 2 min, 9.98 mJ of energy was harvested. We demonstrated that this energy is sufficient for powering a digital cooking timer to count down for 3 min and beep for 2.5 s. The operation of other kitchen devices was also demonstrated.

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Implementation of wide range soil moisture profile probe by coplanar plate capacitor on film substrate

Shirahama

Shigeta

Kawahara

et al. 2015

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Ryo Shigeta

Ambient RF Energy Harvesting Sensor Device With Capacitor-Leakage-Aware Duty Cycle Control

Low-Cost Soil Moisture Profile Probe Using Thin-Film Capacitors and a Capacitive Touch Sensor

Soil-Monitoring Sensor Powered by Temperature Difference between Air and Shallow Underground Soil

Power harvesting from microwave oven electromagnetic leakage

Implementation of wide range soil moisture profile probe by coplanar plate capacitor on film substrate

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