Development of smart monitoring system for fishpond management/ Bianca B. Alcantara, Justine Claire L. Ballonado, Frederick D. Catabay, Kathy A. Evale, John Brenson G. Gantalao and Hedryx J. Rodriguez.--

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Alcantara, Bianca B [author]

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Material type: Text

TextPublication details: Technological University of the Philippines, Manila. 2024Description: xiv, 138 pages. 29cmContent type:

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BTH TK 147 A43 2024

Dissertation note: College of Industrial Technology.-- Bachelor of Engineering Technology major in Electrical Technology: Technological University of the Philippines, Manila. 2024 Summary: Aquaculture, particularly fishpond farming, is essential for meeting global food demands and sustaining livelihoods, but poor water quality often hampers productivity and increases fish vulnerability to diseases. This study focuses on the development of a smart monitoring system for fishpond management to address these challenges by enhancing efficiency, sustainability, and production outcomes. The main objective of this study is to develop a machine that measures temperature, pH level, and dissolved oxygen to increase the production of fish and to take action immediately to prevent devastating loss. Powered by solar energy and utilizing an Arduino Uno microcontroller, the system ensures eco- friendliness and efficient data management. The test results indicated that water temperature ranged from 26.19°C to 26.87°C, pH levels showed slight daily variations between 6.21 and 6.58, and dissolved oxygen levels exhibited significant fluctuations, particularly on Day 3 (9 mg/L to 14 mg/L and down to 6 mg/L). These findings highlight the need for continuous monitoring to maintain optimal water quality. The system was evaluated by 40 individuals, including fishermen, fishpond owners, engineers, students, and fish vendors, who rated its performance as excellent with a mean score of 4.57. This innovative solution offers a sustainable approach to fishpond maintenance, boosting productivity and ensuring better-quality aquaculture products. Keywords: aquaculture, fishpond farming, fishpond management, smart monitoring system

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Item type	Current library	Shelving location	Call number	Copy number	Status	Date due	Barcode
Bachelor's Thesis CIT	TUP Manila Library	Thesis Section-2nd floor	BTH TK 147 A43 2024 (Browse shelf(Opens below))	c.1	Not for loan		BTH0005918

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Bachelor's thesis

College of Industrial Technology.-- Bachelor of Engineering Technology major in Electrical Technology: Technological University of the Philippines, Manila. 2024

Includes bibliographic references and index.

Aquaculture, particularly fishpond farming, is essential for meeting global food demands
and sustaining livelihoods, but poor water quality often hampers productivity and increases
fish vulnerability to diseases. This study focuses on the development of a smart monitoring
system for fishpond management to address these challenges by enhancing efficiency,
sustainability, and production outcomes. The main objective of this study is to develop a
machine that measures temperature, pH level, and dissolved oxygen to increase the
production of fish and to take action immediately to prevent devastating loss. Powered by

solar energy and utilizing an Arduino Uno microcontroller, the system ensures eco-
friendliness and efficient data management. The test results indicated that water

temperature ranged from 26.19°C to 26.87°C, pH levels showed slight daily variations
between 6.21 and 6.58, and dissolved oxygen levels exhibited significant fluctuations,
particularly on Day 3 (9 mg/L to 14 mg/L and down to 6 mg/L). These findings highlight
the need for continuous monitoring to maintain optimal water quality. The system was
evaluated by 40 individuals, including fishermen, fishpond owners, engineers, students,
and fish vendors, who rated its performance as excellent with a mean score of 4.57. This
innovative solution offers a sustainable approach to fishpond maintenance, boosting
productivity and ensuring better-quality aquaculture products.

Keywords: aquaculture, fishpond farming, fishpond management, smart monitoring
system

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