DESIGN AND IMPLEMENTATION OF A WEATHER MONITORING SYSTEM FOR AN INTERNET OF THINGS (IOT)-BASED AGRICULTURAL CALENDAR SYSTEM
To build predictions for an agricultural calendar, a system that can accurately acquire weather data from a farming area is needed. Additionally, the system must be able to transfer data to and from the cloud. It should also anticipate usage in remote farming areas where electricity from the nati...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/85473 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | To build predictions for an agricultural calendar, a system that can accurately
acquire weather data from a farming area is needed. Additionally, the system must
be able to transfer data to and from the cloud. It should also anticipate usage in
remote farming areas where electricity from the national grid (PLN) might not be
available. Thus, the system needs to use a power supply from renewable energy
sources, specifically solar energy. This paper explains the design and
implementation of a weather monitoring system for an IoT-based agricultural
calendar system. The designed system consists of sensor nodes that can measure
weather parameters in a farming area such as air temperature, air pressure, air
humidity, soil moisture, sunlight intensity, wind direction, wind speed, and rainfall.
This weather data will then be sent to the cloud by a gateway periodically every 30
minutes to be further processed into weather predictions in the agricultural
calendar system. The gateway designed for this system uses a ESP-NOW protocol
to communicate with the irrigation system and a 4G network to communicate with
the cloud server. Additionally, the gateway has local storage to save weather data
that fails to be sent to the cloud due to an internet connection outage. The system
uses two power sources: power from the PLN and solar energy, ensuring the system
can function even when PLN electricity is down. In the design and implementation,
the weather monitoring system can already perform its main functions, which are
measuring weather parameters in the farming area and transferring data to the
cloud periodically. Furthermore, the accuracy level of the weather data measured
by this system meets the specified criteria, with air temperature accuracy (±0.2°C),
air humidity (±1% RH), sunlight intensity (±2% lux), and wind speed (±0.1 m/s).
However, this system still requires further development and testing to improve the
accuracy of other weather data and to develop an enclosure that ensures the
weather monitoring system meets the IP65 specification for optimal outdoor use. |
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