Robust Soil Water Potential Sensor to Optimize Irrigation in Agriculture

Menne, David; Hübner, Christof; Trebbels, Dennis; Willenbacher, Norbert

doi:10.3390/s22124465

Cited by 11 publications

(7 citation statements)

References 34 publications

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“…Soil properties, meteorological data and seasonal fluctuations, seed quality, harvesting methods, monitoring of pests and diseases, managing nutrient deficiencies, and maintaining water requirements for the crops are all contributing factors for predicting the overall yield of a plant or crop. Precision agriculture has been used for years and now researchers are considering the use of variable rate technologies [70], sensor monitoring [16], and management systems to ensure better crop health [27], improved productivity [28], and better quality [71] of the produce. Sensor-and drone-assisted quality monitoring of horticultural crops [21], yield predicting sensors [72] on harvesters of various agronomic crops [73] (Figure 4), and use of the internet and real time data simulators [74] are receiving attention day by day, particularly for their use in large scale crop production.…”

Section: Yield Prediction In Smart Agriculturementioning

confidence: 99%

“…Additionally, with the help of data mining technologies [11], a large number of datasets, either agronomical [12], genomics [13], or meteorological [14], are partitioned into useful information to make easy and efficient decision making [15] in order to make farming activities more precise and efficient. Climaticor soil-related data in smart agriculture and farming is obtained using sensors [16], and then automatic processing of this big data is carried out with the help of modern methods and analysis tools, such as machine learning [17], spike and slab regression analysis, and time-series analysis [18]. This process gives the obtained data an easy, understandable, and knowledgeable form, which then warns the farmers about any upcoming climatic events, i.e., droughts or heavy rains, chances of insect or pest infestation, and the spread of infectious disease (i.e., fungal diseases) [19].…”

Section: Introductionmentioning

confidence: 99%

“…The internet of things provides efficient ways to assist the farmers and researchers in the agricultural crop production sector. Moreover, it assists the decision making by making various information readily available when it comes to soil [16], water [21], pesticides [22], fertilizers [23], and manures [24]. Climate change and global warming are the burning issues of the world, with a lot of studies and resources being spent to ensure a better future for the coming generations.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Application of Smart Techniques, Internet of Things and Data Mining for Resource Use Efficient and Sustainable Crop Production

et al. 2023

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Technological advancements have led to an increased use of the internet of things (IoT) to enhance the resource use efficiency, productivity, and cost-effectiveness of agricultural production systems, particularly under the current scenario of climate change. Increasing world population, climate variations, and propelling demand for the food are the hot discussions these days. Keeping in view the importance of the abovementioned issues, this manuscript summarizes the modern approaches of IoT and smart techniques to aid sustainable crop production. The study also demonstrates the benefits of using modern IoT approaches and smart techniques in the establishment of smart- and resource-use-efficient farming systems. Modern technology not only aids in sustaining productivity under limited resources, but also can help in observing climatic variations, monitoring soil nutrients, water dynamics, supporting data management in farming systems, and assisting in insect, pest, and disease management. Various type of sensors and computer tools can be utilized in data recording and management of cropping systems, which ensure an opportunity for timely decisions. Digital tools and camera-assisted cropping systems can aid producers to monitor their crops remotely. IoT and smart farming techniques can help to simulate and predict the yield production under forecasted climatic conditions, and thus assist in decision making for various crop management practices, including irrigation, fertilizer, insecticide, and weedicide applications. We found that various neural networks and simulation models could aid in yield prediction for better decision support with an average simulation accuracy of up to 92%. Different numerical models and smart irrigation tools help to save energy use by reducing it up to 8%, whereas advanced irrigation helped in reducing the cost by 25.34% as compared to soil-moisture-based irrigation system. Several leaf diseases on various crops can be managed by using image processing techniques using a genetic algorithm with 90% precision accuracy. Establishment of indoor vertical farming systems worldwide, especially in the countries either lacking the supply of sufficient water for the crops or suffering an intense urbanization, is ultimately helping to increase yield as well as enhancing the metabolite profile of the plants. Hence, employing the advanced tools, a modern and smart agricultural farming system could be used to stabilize and enhance crop productivity by improving resource use efficiency of applied resources i.e., irrigation water and fertilizers.

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Section: Yield Prediction In Smart Agriculturementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Application of Smart Techniques, Internet of Things and Data Mining for Resource Use Efficient and Sustainable Crop Production

et al. 2023

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“…Terrestrial water storage is composed of five parts: soil water, surface water, ice and snow water, groundwater, and canopy water. Soil water content directly affects the weathering of soil minerals and the leaching of vegetation nutrients from soil [20] and indirectly affects the change in canopy water storage of vegetation communities [21]. Seasonal ice and snow water have made an important contribution to alleviating regional water shortages and restoring ecosystems [22].…”

Section: Introductionmentioning

confidence: 99%

Associations between Surface Deformation and Groundwater Storage in Different Landscape Areas of the Loess Plateau, China

Liu,

Zhang,

Fan

et al. 2024

Land

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The Loess Plateau is an important grain-producing area and energy base in China and is an area featuring dramatic changes in both surface and underground processes. However, the associations between surface deformation and groundwater storage changes in different landscape types in the region are still unclear. Based on Sentinel-1 and GRACE (Gravity Recovery and Climate Experiment) data, this study monitored and verified the surface deformation and groundwater storage changes in different landscape types, such as those of the Kubuqi Desert, Hetao Irrigation District, Jinbei Mining Area, and Shendong Mining Area, in the Loess Plateau of China from 2020 to 2021. Through time series and cumulative analysis using the same spatial and temporal resolution, the associations between these two changes in different regions are discussed. The results show that: (1) the surface deformation rates in different landscape types differ significantly. The minimum surface deformation rate in the Kubuqi Desert is −5~5 mm/yr, while the surface deformation rates in the Hetao Irrigation District, the open-pit mine recovery area in the Jinbei Mining Area, and the Shendong Mining Area are −60~25 mm/yr, −25~25 mm/yr, and −95.33~26 mm/yr, respectively. (2) The regional groundwater reserves all showed a decreasing trend, with the Kubuqi Desert, Hetao Irrigation District, Jinbei Mining Area, and Shendong Mining Area declining by 359.42 mm, 103.30 mm, 45.60 mm, and 691.72 mm, respectively. (3) The surface elasticity deformation had the same trend as the temporal fluctuation in groundwater storage, and the diversion activity was the main reason why the temporal surface deformation in the Hetao Irrigation District lagged behind the change in groundwater storage by 1~2 months. The measure of “underground water reservoirs in coal mines” slows down the rate of collapse of coal mine roof formations, resulting in the strongest time-series correlation between mild deformation of the surface of the Shendong mine and changes in the amount of groundwater reserves (R = 0.73). This study analyzes the associations between surface deformation and groundwater storage changes in different landscape areas of the Loess Plateau of China and provides new approaches to analyzing the dynamic associations between the two and the causes of changes in both variables.

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“…Its low price makes this sensor one of the most widely used in the agricultural sector for the measure of SMP (Montesano et al, 2015). Yet, the use of tensiometers for irrigation purposes has disadvantages such as its high maintenance, its bad performance in dry soil conditions (Muñoz-Carpena et al, 2005) and its limited measurement range (Menne et al, 2022). Granular matrix sensors are an adaptation of the gypsum block ones, since they consist of two electrodes located above a gypsum wafer, embedded within a granular fill matrix.…”

Section: Soil Matric Potentialmentioning

confidence: 99%

Precision irrigation in citrus with different water qualities

García¹

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Citrus latifolia is increasingly being cultivated in Mediterranean areas, where the need for precise irrigation implies a sound knowledge of the crop's water requirements, which is carried out by monitoring the tree water status in the plant-soil-atmosphere system. Two year-old lime trees (Citrus latifolia Tan. cv. Bearss) were cultivated in 45 L weighing pot-lysimeters filled with a clay-loam soil and equipped with soil water sensors for recording the real-time soil water status. Irrigation, drainage, pot weight, and agro-meteorological variables were also recorded in real-time. Plant water relations -stem (Ψ stem ) and leaf (Ψ leaf ) water potentials, and leaf gas exchange -were periodically measured throughout the experiment. The automated irrigation protocol based on the volumetric soil water content was set to prevent tree water stress (with mean seasonal values of Ψ stem above -0.8 MPa and 7 μmol m − 2 s − 1 and 80 mmol m − 2 s − 1 , for net phtosynthesis and stomatal conductance, respectively). From the soil water pot balance, the computed fortnightly ET mean values throughout the growing season varied from 0.25 to 2.56 L plant − 1 day − 1 in winter and summer months, respectively. Maximum ET values occurred in July when evaporative demand was highest and lime fruits were in their most active growing phase. For day length, lime tree biomass changes were negligible, and the pot tree weight variations served for ET water balance validation (r 2 =0.92***). The contribution of this work is that it establishes a scalable weighing lysimeter prototype for determining the ET of lime trees grown in Mediterranean semi-arid conditions, using real-time soil water balance monitoring managed by an irrigation automation protocol. This approach could be replicated for precise ET measurements in other crops.

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Robust Soil Water Potential Sensor to Optimize Irrigation in Agriculture

Cited by 11 publications

References 34 publications

Application of Smart Techniques, Internet of Things and Data Mining for Resource Use Efficient and Sustainable Crop Production

Application of Smart Techniques, Internet of Things and Data Mining for Resource Use Efficient and Sustainable Crop Production

Associations between Surface Deformation and Groundwater Storage in Different Landscape Areas of the Loess Plateau, China

Precision irrigation in citrus with different water qualities

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