The Prototype Design of Water pH and TDS Indicator Device based on Microcontroller Arduino

Raihanto, Muhammad Satya; Febrianti, Melinska Ayu; Yudhistira, Gisya Amanda; Qurtubi, None

doi:10.1109/ieeeconf53624.2021.9668165

Cited by 5 publications

(2 citation statements)

References 14 publications

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“…Then in research that has been conducted by Staudinger et al (2019), research was carried out by measuring pH parameters. This is in line with research conducted by Demetillo et al (2019) and Raihanto, et al (2021) who developed a prototype that can measure pH and TDS parameters using sensors integrated with microcontroller devices. Burke (2020) made oceanographic parameter measurements by observing temperature and dissolved oxygen parameters and Zhao (2020) also took TDS measurements integrated with GPS modules to inform water quality at certain locations.…”

Section: B Sensor Data Acquisition With Microcontrollersupporting

confidence: 89%

Oceanographic Parameter Measurement System Based on LoRA Communication Module

Amir,

Suwardoyo,

Pratami Irwan

2024

JITE

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Measurement of oceanographic parameters is needed to determine the condition of the ecosystem in the water area so that it can be the basis for carrying out conservation activities in marine waters. Measurement of physical and chemical parameters used manually which causes the data obtained is still susceptible to observational errors. In this study, a system was designed that can measure oceanographic parameters periodically. The designed system consists of a temperature sensor, turbidity sensor, pH sensor and TDS sensor integrated with a microcontroller device. The system consists of two main parts, a sensor node that has a function as a transmitter and a gateway that has a function as a receiver. Initial testing is done by calibrating and validating data for each sensor used. The next test was carried out by testing the transmission of data from the measurement of oceanographic parameters in the form of water pH, salinity, water temperature and water turbidity from the sensor node to the gateway using the LoRA Ebyte E220 communication module. The test results show that the sensor node measurement data can be sent to the gateway by setting the distance between devices as far as 500 meters. The resulting data transmission delay is in the range of 2-10 seconds

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Section: B Sensor Data Acquisition With Microcontrollersupporting

confidence: 89%

Oceanographic Parameter Measurement System Based on LoRA Communication Module

Amir,

Suwardoyo,

Pratami Irwan

2024

JITE

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“…To achieve this goal, preliminary studies were conducted to gain insights into existing hydroponic practices and the difficulties encountered in manually supplying nutrients. Subsequently, an automation system was meticulously designed and integrated with the hydroponic setup, using the Arduino Uno as the central control unit and TDS sensors to monitor and regulate nutrient levels [9,10]. Rigorous testing and calibration procedures were implemented to validate the accuracy and responsiveness of the automated system [11,12].…”

Section: Introductionmentioning

confidence: 99%

Development of an Automated Feeding System for Hydroponic Plant Nutrition Using Arduino Uno

Aisyah,

Suhendra,

Saharja

et al. 2024

KEG

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Hydroponic farming has been a promising alternative to traditional farming, but providing plants with proper and consistent nutrition remains challenging. The issue in the research is the inaccuracy of the nutrients provided to the plants, resulting in growth that does not meet the expectations. This study aims to develop an automated nutrition system for hydroponic farming using Arduino Uno and total dissolved solids (TDS) sensors. In conducting this research, the study began with a preliminary exploration, followed by the design and integration process. Subsequently, testing and experiments were conducted on a small scale. Preliminary studies were conducted to understand existing hydroponic practices and challenges in manually supplying nutrients. The design of an automation system with Arduino Uno and a TDS sensor is made to control nutrition automatically. Automation systems are tested and calibrated to ensure accuracy and proper response. Implementation on a small scale was done with a test group and a control group in hydroponics. Growth and yield data were collected and analyzed. The results showed that the automated system provided precise and consistent nutrition, increasing plant growth and yields compared to manual methods. This research makes a scientific contribution to developing sustainable and efficient agriculture. In conclusion, nutrition automation using Arduino Uno and TDS sensors is an effective solution to increase the efficiency and productivity of hydroponic farming. Keywords: hydroponics, automation, plant nutrition, Arduino Uno TDS sensor

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