Development of a Wireless Sensor Network and IoT-based Smart Irrigation System

Ndunagu, Juliana Ngozi; Ukhurebor, Kingsley Eghonghon; Akaaza, Moses; Onyancha, Robert Birundu

doi:10.1155/2022/7678570

Cited by 21 publications

(6 citation statements)

References 22 publications

(35 reference statements)

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“…Another interesting finding is that the system can adjust in real time to changes in the weather. Changes in the weather may have a significant impact on agricultural production, making it essential to have a system that can dynamically modify water delivery depending on real-time circumstances [23]- [34]. The system's intelligence and adaptability are on full display in its abilities to optimize water distribution in the face of adverse weather.…”

Section: Resultsmentioning

confidence: 99%

An adaptive neuro-fuzzy inference system-based irrigation sprinkler system for dry season farming

Tyokighir,

Mom,

Eghonghon Ukhurebor

et al. 2024

Bulletin EEI

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In recent years, the management of irrigation systems has emerged as one of the most pressing concerns in the agricultural industry, especially in areas that experience dry seasons. In this research, an adaptive neuro-fuzzy inference system (ANFIS)-based irrigation system that uses a hot and cold sprinkler mechanism is presented. The goal of the system is to reduce the amount of water needed for farming and increase crop output during dry seasons. Adaptive control of water release is achieved via the use of MATLAB and the ANFIS model. This is done in response to changes in soil moisture, ambient temperature, and crop water demand. According to the findings, the suggested system performs noticeably better than conventional irrigation methods in terms of both the amount of water used and the number of crops produced.

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Section: Resultsmentioning

confidence: 99%

An adaptive neuro-fuzzy inference system-based irrigation sprinkler system for dry season farming

Tyokighir,

Mom,

Eghonghon Ukhurebor

et al. 2024

Bulletin EEI

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“…The system achieves 89% accuracy, a 10% misclassification rate, 79% sensitivity, 93% specificity, and 81% precision in threshold metrics classification evaluation. The system's 97% and 98% prediction accuracy indicate reliable and efficient irrigation and water resource management, potentially boosting agricultural production in rural areas [36] is used to measure soil moisture content in the field. The required soil moisture threshold value is described, and if soil moisture exceeds or decreases from the threshold value, the soil moisture sensor will send the current soil moisture value to the server through the node MCU.…”

Section: Knnmentioning

confidence: 99%

Developing a Hybrid Irrigation System for Smart Agriculture Using IoT Sensors and Machine Learning in Sri Ganganagar, Rajasthan

Kaur,

Bhatt,

Raja

2024

Journal of Sensors

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The agriculture sector is one of the largest consumers of fresh water. Different types of irrigation systems are available, including center pivot, drip and sprinkler systems, and linear motion systems. However, the complex structure of existing irrigation systems and their high maintenance costs encourage Indian farmers to continue using these methods. Due to its ease of use and low energy consumption, surface irrigation is one of the most popular irrigation techniques. Although the main reasons for poor irrigation application efficiency are uneven irrigation water distribution and deep absorption, using a variety of technologies, countries are trying to increase the sustainability of agriculture. Automated irrigation systems contribute significantly to water conservation. The combination of automation and Internet of Things (IoT) improves agricultural practices. These technologies help farmers understand their crops, minimize their impact on the environment, and preserve resources. They also enable efficient monitoring of the weather, water resources, and soil. This research proposes an intelligent, low-cost field irrigation system. The proposed prototype can measure soil moisture, rain status, wind speed, water level, temperature, and humidity using a hardware sensor and unit. To decide whether to turn on or off the motor, a variety of sensors are used to get a range of readings and conclusions. They enable automatic watering when soil moisture levels are below a certain threshold, and if soil moisture is equal to the required moisture, then the irrigation process stops. Every few minutes, the sensors measure the environmental factors. Data are collected and stored on a ThingSpeak cloud server for analysis. To evaluate the data we collected, we used a variety of models, such as K-nearest neighbors (KNN), Naïve Bayes, random forest, and logistic regression. Compared to other Naïve Bayes and random forest models, the accuracy rate was 98.8%, the mean square error was 0.16, and the results of logistic regression, KNN, and SVM were in order: (98.3%/1.66), (99.3%/0.66), and (99.5%/0.5), respectively. In the end, an automated irrigation system run on IoT applications gives farmers access to remote monitoring and control, as well as information about the specifics of the irrigation field.

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“…The irrigation schedule is used to determine whether or not to begin pumping water based on the threshold value. A web application was developed to monitor and control the system based on the data collected (Ndunagu et al, 2022). All forms of life, from plants to animals to humans, require water in order to survive.…”

Section: Literture Reviewmentioning

confidence: 99%

“…The process of watering a surface specifically so that vegetation might flourish there is known as irrigation. A body of water is guided by canals, ditches, pipelines, or even just the course of the water itself (Ndunagu, et al, 2022). In arid regions, proper water management is crucial.…”

Section: Introductionmentioning

confidence: 99%

Ontology-Based Smart Irrigation System: Enhancing Agricultural Water Management

Nisa,

Azam,

Rafiq

et al. 2024

ABBDM

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An Ontology-Based Smart Irrigation System is presented in this research with the goal of improving agricultural water management. The main issue discussed is the inefficiency of conventional irrigation techniques, which results in water waste and lower crop yields. The process used entails creating an ontology, which includes defining concepts, establishing relationships, identifying domains, and populating the ontology. In order to facilitate real-time monitoring and decision-making, the irrigation system also incorporates sensors, actuators, and data processing algorithms. The main conclusions show that the ontology-based approach boosts crop output, encourages sustainable farming practices, and enhances water consumption efficiency. The findings of this study imply that ontology-based smart irrigation systems present a viable way to deal with the problems associated with water scarcity, improve agricultural output, and reduce their negative effects on the environment. The research adds to the expanding corpus of information on intelligent irrigation systems and emphasizes the significance of implementing cutting-edge technologies for agriculture's sustainable water management.

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Development of a Wireless Sensor Network and IoT-based Smart Irrigation System

Cited by 21 publications

References 22 publications

An adaptive neuro-fuzzy inference system-based irrigation sprinkler system for dry season farming

An adaptive neuro-fuzzy inference system-based irrigation sprinkler system for dry season farming

Developing a Hybrid Irrigation System for Smart Agriculture Using IoT Sensors and Machine Learning in Sri Ganganagar, Rajasthan

Ontology-Based Smart Irrigation System: Enhancing Agricultural Water Management

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