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T. S. Sindhu1, Mohamed Yousuff Caffiyar, S. Santhosh, A. Srinivasan, K. Velu, M. Naveen Kumar, M. Avinesh,
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- Assistant Professor,, Associate Professor,, UG Student,, UG Student,, UG Student,, UG Student,, UG Student, C.Abdul Hakeem College Of Engineering and Technology, Melvisharam,, C.Abdul Hakeem College Of Engineering and Technology, Melvisharam,, C.Abdul Hakeem College Of Engineering and Technology, Melvisharam,, C.Abdul Hakeem College Of Engineering and Technology, Melvisharam,, C.Abdul Hakeem College Of Engineering and Technology, Melvisharam,, C.Abdul Hakeem College Of Engineering and Technology, Melvisharam,, C.Abdul Hakeem College Of Engineering and Technology, Melvisharam, Tamilnadu,, Tamilnadu,, Tamilnadu,, Tamilnadu,, Tamilnadu,, Tamilnadu,, Tamilnadu, India, India, India, India, India, India, India
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Abstract
nIn our technologically advanced era, where automation permeates every aspect of our lives, even plants have been transformed into smart entities. This article explores the integration of various technical components to imbue plants with self-maintenance capabilities, eliminating the need for human intervention. The system discussed herein regulates moisture levels and temperature within plants, ensuring optimal growing conditions. It incorporates alerts to notify users of deviations from preset parameters and activates a water pump for irrigation when necessary. To improve security and surveillance, the device also has motion detection capabilities. Key components include an ESP8266 Node MCU board, DHT11 temperature and humidity sensor, soil moisture sensor, PIR motion sensor, 18650 battery, relay module, and water pump. The system’s functionality is accessible and controllable via the Blynk Application, providing users with a user-friendly graphical interface for seamless interaction. The primary element of this idea is an agricultural system powered by water that eliminates the need for soil. This hydroponic automated system provides water and nutrients to the crops in response to input from sensors, including temperature and humidity monitors and electrical routes for physical occurrences.
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Keywords: : NodeMCU, ESP8266, Plant Monitor, Blynk IOT, Soil Moisture, Water Pump
n[if 424 equals=”Regular Issue”][This article belongs to Journal of Nuclear Engineering & Technology(jonet)]
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References
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| Volume | ||
| [if 424 equals=”Regular Issue”]Issue[/if 424][if 424 equals=”Special Issue”]Special Issue[/if 424] [if 424 equals=”Conference”][/if 424] | ||
| Received | July 17, 2024 | |
| Accepted | July 31, 2024 | |
| Published | August 16, 2024 |
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