Development And Testing Of Monitoring Tools With The Addition Of Automatic PH Control Systems To Hydroponic Red Spinach Plants (Amaranthus Tricolor L.)

Introduction

In recent years, modern agriculture has increasingly turned to technology to improve efficiency and production results. One of the innovations that can be applied is a microcontroller-based nutritional pumping system. This study aims to develop and test monitoring devices equipped with an automatic pH control system for hydroponic red spinach plants (Amaranthus tricolor L.). The primary objective is to analyze the influence of the pump servo angle integrated with an automatic pH control device on plant growth.

Methodology

This study uses a complete non-factorial random design, which allows for a more in-depth analysis of the variables studied. The experimental design involves the use of a servo pump with adjustable angles to control the flow of nutrients to the plants. The automatic pH control system is integrated with the servo pump to maintain optimal pH levels for the plants. The experiment is conducted in a controlled environment, and the results are analyzed to determine the optimal servo angle for plant growth.

Results

The results of this study show that the most optimal opening of the servo pump was 75 ° (S2). At this angle, plant height growth reaches an average of 24.22 cm. In addition, the highest number of leaves is also found in the same open angle, with an average of 15 leaves per plant. In terms of weight, both wet and dry, the open angle of 75 ° (S2) shows the highest result, namely the average wet weight of 21.6 grams and the average dry weight of 2.27 grams.

Additional Analysis and Explanation

The success of the development of this system is very dependent on the right technology to monitor and control the growth environment. With the application of automatic pH control, the planting can maintain optimal conditions for plants, which in turn supports better growth. In hydroponics, the right pH is very important because it affects the availability of nutrients for plants. Therefore, using a adjustable pumping system, such as servo, is an effective solution to manage nutrients.

The results of this study indicate that the open angle of the servo pump 75 ° (S2) provides the most satisfying results in increasing the growth of red spinach plants. This discovery can be a reference for hydroponic farmers to further maximize their nutritional pumping system. In addition, good results on the physical size of plants, such as height and number of leaves, reflect better plant health and higher potential yields.

Implications and Future Research

With advances in technological advances, the application of automatic control systems in agriculture, especially hydroponics, will be increasingly important. In the future, further research can be focused on the development of algorithms to optimize servo settings based on changing environmental conditions, thereby increasing agricultural efficiency and productivity.

Through this research, it is expected to provide benefits for farmers and researchers in developing more effective hydroponic practices, and making a monitoring system that is smarter and more responsive to plant needs. The development of this system can also be applied to other types of crops, and can be used as a reference for further research in the field of hydroponics.

Conclusion

In conclusion, this study demonstrates the effectiveness of using a microcontroller-based nutritional pumping system with automatic pH control in improving the growth of hydroponic red spinach plants. The results of this study show that the optimal servo angle of 75 ° (S2) provides the most satisfying results in increasing the growth of red spinach plants. This discovery can be a reference for hydroponic farmers to further maximize their nutritional pumping system.

Recommendations

Based on the results of this study, the following recommendations are made:

• The use of a microcontroller-based nutritional pumping system with automatic pH control can be applied to other types of crops.
• Further research can be focused on the development of algorithms to optimize servo settings based on changing environmental conditions.
• The development of this system can be used as a reference for further research in the field of hydroponics.

Limitations

This study has several limitations, including:

• The experiment was conducted in a controlled environment, and the results may not be applicable to real-world conditions.
• The study only focused on the growth of red spinach plants, and further research is needed to determine the effectiveness of this system on other types of crops.

Future Directions

Future research can be focused on the development of algorithms to optimize servo settings based on changing environmental conditions, thereby increasing agricultural efficiency and productivity. Additionally, the development of this system can be applied to other types of crops, and can be used as a reference for further research in the field of hydroponics.

Conclusion

In conclusion, this study demonstrates the effectiveness of using a microcontroller-based nutritional pumping system with automatic pH control in improving the growth of hydroponic red spinach plants. The results of this study show that the optimal servo angle of 75 ° (S2) provides the most satisfying results in increasing the growth of red spinach plants. This discovery can be a reference for hydroponic farmers to further maximize their nutritional pumping system.

Q: What is the main objective of this study?

A: The main objective of this study is to analyze the influence of the pump servo angle integrated with an automatic pH control device on plant growth.

Q: What type of experimental design was used in this study?

A: This study uses a complete non-factorial random design, which allows for a more in-depth analysis of the variables studied.

Q: What is the optimal servo angle for plant growth?

A: The results of this study show that the most optimal opening of the servo pump was 75 ° (S2). At this angle, plant height growth reaches an average of 24.22 cm.

Q: What is the importance of pH control in hydroponics?

A: In hydroponics, the right pH is very important because it affects the availability of nutrients for plants. Therefore, using a adjustable pumping system, such as servo, is an effective solution to manage nutrients.

Q: What are the benefits of using a microcontroller-based nutritional pumping system with automatic pH control?

A: The benefits of using a microcontroller-based nutritional pumping system with automatic pH control include improved plant growth, increased efficiency, and higher potential yields.

Q: Can this system be applied to other types of crops?

A: Yes, the development of this system can be applied to other types of crops, and can be used as a reference for further research in the field of hydroponics.

Q: What are the limitations of this study?

A: This study has several limitations, including the experiment being conducted in a controlled environment, and the results may not be applicable to real-world conditions.

Q: What are the future directions for this research?

A: Future research can be focused on the development of algorithms to optimize servo settings based on changing environmental conditions, thereby increasing agricultural efficiency and productivity.

Q: What are the implications of this study for farmers and researchers?

A: This study provides benefits for farmers and researchers in developing more effective hydroponic practices, and making a monitoring system that is smarter and more responsive to plant needs.

Q: Can this system be used as a reference for further research in the field of hydroponics?

A: Yes, the development of this system can be used as a reference for further research in the field of hydroponics.

Q: What are the potential applications of this system in agriculture?

A: The potential applications of this system in agriculture include improving plant growth, increasing efficiency, and higher potential yields.

Q: Can this system be used in commercial hydroponic farms?

A: Yes, this system can be used in commercial hydroponic farms to improve plant growth, increase efficiency, and higher potential yields.

Q: What are the potential benefits of using this system in commercial hydroponic farms?

A: The potential benefits of using this system in commercial hydroponic farms include improved plant growth, increased efficiency, and higher potential yields.

Q: Can this system be used in other types of agriculture?

A: Yes, the development of this system can be applied to other types of agriculture, and can be used as a reference for further research in the field of agriculture.

Q: What are the potential applications of this system in other types of agriculture?

A: The potential applications of this system in other types of agriculture include improving plant growth, increasing efficiency, and higher potential yields.

Q: Can this system be used in conjunction with other technologies?

A: Yes, this system can be used in conjunction with other technologies, such as sensors and automation systems, to improve plant growth, increase efficiency, and higher potential yields.

Q: What are the potential benefits of using this system in conjunction with other technologies?

A: The potential benefits of using this system in conjunction with other technologies include improved plant growth, increased efficiency, and higher potential yields.