An Improved IoT-based Prototype for Fish Feeding and Monitoring System
An Improved IoT-based Prototype for Fish Feeding and Monitoring System
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Keywords

IoT
ESP32
Blynk app
turbidity
pH
servo motor
feeding

How to Cite

Ferdaus Anam Jibon, Farjana Sultana Rafi, Zinia Binte Jamal, Afia Anjum, & Md. Ashraful Islam. (2024). An Improved IoT-based Prototype for Fish Feeding and Monitoring System. Global Journal of Computer Science and Technology, 24(B1), 1–25. Retrieved from https://gjcst.com/index.php/gjcst/article/view/1654

Abstract

Fish farming can help meet the ever-increasing demand for seafood and offer nutritious protein to people in underdeveloped countries while additionally minimizing pressure on wild fish The global population is supported economically by the fishing industry and related sectors for 10 12 of the total Presently cutting-edge technologies such as AI Machine Learning Automated Planning Data Analytics and IoT are being used in fish farming to increase production efficiency and sustainability In this research we proposed an IoT-based improved technique for fish feeding and monitoring that will enhance the efficiency of fish farming and increase production while avoiding threats to the environment This proposed approach uses a microcontrollerESP32 that gathers data from temperature turbidity pH and ultrasonic sensors alongside a Wi-Fi webcam detecting fish movement It will be linked to the Blynk app which gathers and sends this data informing users about water conditions Another remarkable feature is the ability for customers to remotely initiate water-changing procedures and customize feeding parameters using their mobile devices This method aims to reveal an unprecedented integration of essential sensors encompassing fish rearing fish movement tracking remotely manipulating wastewater via a smartphone supervising the feeding system and comprehensive water quality monitoring a unique combination that distinguishes it from existing research Based on the test results the servo motor for feeding and changing water gave successful results every time the success rate of every sensor was around 87 97 with an error rate of not more than 7 Future endeavors involve extending this research to encompass varying pond sizes incorporating tailored sensors optimized for pond conditions thus rendering them apt for fish culture
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