Abstract
The central role of water access for agriculture is a clear challenge anywhere in the world and particularly in areas with significant seasonal variation in rainfall such as in Eastern and Central Africa. The combination of modern sensor technologies, the Internet, and advanced irrigation equipment combined in an Internet of Things (IoT) approach allow a relatively precise control of agricultural irrigation and creating the opportunity for high efficiency of water use for agricultural demands. This IoT approach can thereby increase the resilience of agricultural systems in the face of complex demands for water use. Most previous works on agricultural IoT systems are in the context of countries with higher levels of economic development. However, in Rwanda, with a low level of economic development, the advantages of efficient water use from the application of IoT technology requires overcoming constraints such as lack of irrigation control for individual farmers, lack of access to equipment, and low reliability of power and Internet access. In this work, we describe an approach for adapting previous studies to the Rwandan context for rice (Oryza sativa) farming with irrigation. The proposed low cost system would automatically provide irrigation control according to seasonal and daily irrigational needs when the system sensors and communications are operating correctly. In cases of system component failure, the system switches to an alternative prediction mode and messages farmers with information about the faults and realistic irrigation options until the failure is corrected. We use simulations to demonstrate, for the Muvumba Rice Irrigation Project in Northeast Rwanda, how the system would respond to growth stage, effective rainfall, and evapotranspiration for both correct operation and failure scenarios.
Highlights
The efficient use of water for agriculture can be critical to ensure high yields and maximize economic benefits, especially for regions facing annual or seasonal strains on water availability.Around 90% of the population of Rwanda is engaged in agriculture considering farming for both subsistence and economic development [1,2]
The flowchart of the Internet of Things (IoT) system (Figure 2) has two decision pathways, one is the fully functioning automatic system, while the second initiates if there is a fault in the automatic system, thereby still providing actionable recommendations for the farmer until the fault is fixed
These data are from the Nyagatare weather station in Eastern province of Rwanda adjacent to the Muvumba Rice Plantation and provide us the ET and ERF values for Equation (1)
Summary
The efficient use of water for agriculture can be critical to ensure high yields and maximize economic benefits, especially for regions facing annual or seasonal strains on water availability.Around 90% of the population of Rwanda is engaged in agriculture considering farming for both subsistence and economic development [1,2]. The efficient use of water for agriculture can be critical to ensure high yields and maximize economic benefits, especially for regions facing annual or seasonal strains on water availability. The intensive practice of agriculture across Rwanda places a large demand on water resources, with an estimate of as much as 70% of the available water resources are used for agriculture [3]. One water intensive crop of increasing importance in Rwanda is rice (Oryza sativa), currently the second most important cereal. The total demand value is a typical seasonal water requirement for the growth
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