Recent Trends in Control and Converter (e-ISSN: 3048-8311)

This study aims to introduce an Arduino Uno-based water quality monitoring system for aquaculture. By referring to a cloud database, it enables the user to remotely monitor the fish farm and gain immediate control over various environmental data for the pond. Temperature, saltiness, pH worth and water level detecting modules are communicated in this observing framework. With real-time data observation and automated alerts, the proposed aquaculture water quality module makes it possible to optimize pond conditions, thereby reducing fish mortality, enhancing fish growth, and optimizing aquaculture harvest.

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Chen, J. H., Sung, W. T., & Lin, G. Y. (2015, October). Automated monitoring system for the fish farm aquaculture environment. In 2015 IEEE International Conference on Systems, Man, and Cybernetics (pp. 1161-1166). IEEE.

Salim, T. I., Haiyunnisa, T., & Alam, H. S. (2016, November). Design and implementation of water quality monitoring for eel fish aquaculture. In 2016 International Symposium on Electronics and Smart Devices (ISESD) (pp. 208-213). IEEE.

Garcia, M., Trambulo, E. M., Pajarillo, J., Apsay, M. R. B., Tenorio, J. E., & Chua, M. G. (2013, August). Development of dissolved oxygen monitoring system for fish ponds. In 2013 IEEE 3rd International Conference on System Engineering and Technology (pp. 83-88). IEEE.