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1. Automatic Identification of Center Pivot Irrigation Systems from Landsat Images Using Convolutional Neural Networks

   https://doi.org/10.3390/agriculture8100147  

   Zhang, Chenxiao; Yue, Peng; Di, Liping; Wu, Zhaoyan (October 2018, Agriculture)

   Being hailed as the greatest mechanical innovation in agriculture since the replacement of draft animals by the tractor, center pivot irrigation systems irrigate crops with a significant reduction in both labor and water needs compared to traditional irrigation methods, such as flood irrigation. In the last few decades, the deployment of center pivot irrigation systems has increased dramatically throughout the United States. Monitoring the installment and operation of the center pivot systems can help: (i) Water resource management agencies to objectively assess water consumption and properly allocate water resources, (ii) Agro-businesses to locate potential customers, and (iii) Researchers to investigate land use change. However, few studies have been carried out on the automatic identification and location of center pivot irrigation systems from satellite images. Growing rapidly in recent years, machine learning techniques have been widely applied on image recognition, and they provide a possible solution for identification of center pivot systems. In this study, a Convolutional Neural Networks (CNNs) approach was proposed for identification of center pivot irrigation systems. CNNs with different structures were constructed and compared for the task. A sampling approach was presented for training data augmentation. The CNN with the best performance and less training time was used in the testing area. A variance-based approach was proposed to further locate the center of each center pivot system. The experiment was applied to a 30-m resolution Landsat image, covering an area of 20,000 km2 in North Colorado. A precision of 95.85% and a recall of 93.33% of the identification results indicated that the proposed approach performed well in the center pivot irrigation systems identification task. 

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2. Multi-Level Influences on Center-Pivot Irrigation Adoption in Alabama

   https://doi.org/10.3389/fsufs.2022.879161  

   Price, Ashleigh N.; Pathak, Ruchie; Guthrie, Gregory M.; Kumar, Mukesh; Moftakhari, Hamed; Moradkhani, Hamid; Nadolnyak, Denis; Magliocca, Nicholas R. (July 2022, Frontiers in Sustainable Food Systems)

   Rates of poverty and economic inequality in rural Alabama are among the nation's highest and increasing agricultural productivity can provide a needed boost to these communities. The transition from rain-fed to irrigation-fed (RFtoIF) agriculture has significantly increased farm productivity and profitability elsewhere in the United States. Despite this potential to enhance stability and resilience in rural economies, irrigated cropland accounts for only 5% of Alabama's total cropland as numerous barriers remain to irrigation adoption. To encourage RFtoIF transition, it is imperative to identify the challenges faced by individual farmers at farm, community, and state levels. This study presents a multi-level mixed effects survival analysis to identify the physiographic, socioecological, and economic factors that influence the location and timing of irrigation adoption. We integrate spatiotemporal cropland and climatological data with field-verified locations of center-pivot irrigation systems, local physiographic characteristics, and parcel-level surface water access and average well depth. Access to surface water, costs to access groundwater, and soil characteristics were generally important influences in all regions, but regions were differentiated by the extent to which new irrigation was more responsive to social influences vs. precipitation and price trends. Our findings also highlighted the diversity of farming conditions across the state, which suggested that diverse policy tools are needed that acknowledge the varying motivations and constraints faced by Alabama's farmers. 

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3. Dynamic life cycle economic and environmental assessment of residential solar photovoltaic systems

   https://doi.org/10.1016/j.scitotenv.2020.137932  

   Ren, Mingcheng; Mitchell, Clayton R.; Mo, Weiwei (June 2020, Science of the total environment)

   With the increasing implementation of solar photovoltaic (PV) systems, comprehensive methods and tools are required to dynamically assess their economic and environmental costs and benefits under varied spatial and temporal contexts. This study integrated system dynamics modeling with life cycle assessment and life cycle cost assessment to evaluate the cumulative energy demand, carbon footprint, water footprint, and life cycle cost of residential grid-connected (GC) and standalone (SA) solar PV systems. The system dynamics model was specifically used for simulating the hourly solar energy generation, use, and storage during the use phase of the solar PVs. The modeling framework was then applied to a residential prototype house in Boston, MA to investigate various PV panel and battery sizing scenarios. When the SA design is under consideration, the maximum life cycle economic saving can be achieved with 20 panels with no battery in the prototype house, which increases the life cycle economic savings by 511.6% as compared to a baseline system sized based upon the engineering rule-of-thumb (40 panels and 40 batteries), yet decreases the demand met by 55.7%. However, the optimized environmental performance was achieved with significantly larger panel (up to 300 units) and battery (up to 320 units) sizes. These optimized configurations increase the life cycle environmental savings of the baseline system byup to 64.6%, but significantly decrease the life cycle economic saving by up to 6868.4%. There is a clear environmental and economic tradeoff when sizing the SA systems. When the GC system design is under consideration, both the economic and environmental benefits are the highest when no battery is installed, and the benefits increase with the increase of panel size. However, when policy constraints such as limitations/caps of grid sell are in place, tradeoffs would present as whether or not to install batteries for excess energy storage. 

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4. Irrigation benefits outweigh costs in more US croplands by mid-century

   https://doi.org/10.1038/s43247-023-00889-0  

   Partridge, Trevor; Winter, Jonathan; Kendall, Anthony; Basso, Bruno; Pei, Lisi; Hyndman, David (August 2023, Communications Earth & Environment)

   Abstract Irrigation can increase crop yields and could be a key climate adaptation strategy. However, future water availability is uncertain. Here we explore the economic costs and benefits of existing and expanded irrigation of maize and soybean throughout the United States. We examine both middle and end of the 21st-century conditions under future climates that span the range of projections. By mid-century we find an expansion in the area where the benefits of irrigation outweigh groundwater pumping and equipment ownership costs. Increased crop water demands limit the region where maize could be sustainably irrigated, but sustainably irrigated soybean is likely feasible throughout regions of the midwestern and southeastern United States. Shifting incentives for installing and maintaining irrigation equipment could place additional challenges on resource availability. It will be important for decision makers to understand and account for local water demand and availability when developing policies guiding irrigation installation and use. 

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5. Effects of Deficit Irrigation in Pepper Plants (Capsicum annuum) Grown Under Greenhouse Conditions

   Morgan, Eva I; Zamora, Erik; Nelson, Shad D; Donato-Molina, Consuelo; Anoruo, Ambrose (January 2024, World Journal of Agriculture and Soil Science)

   Water is a vital component for agricultural productivity; however, freshwater supplies are limited and are dwindling worldwide. Water for agriculture is an extreme issue for the southern region of Texas, where water supplies from reservoirs are used for municipal, industrial, and agricultural purposes. Due to intensive and prolonged intermittent droughts in south Texas, freshwater sources can deplete rapidly leaving growers on water restrictions. One potential solution of reducing the amount of water for crops is by applying less water than recommended crop evapotranspiration requires. Deficit irrigation (DI) is the practice of applying lower amounts of water than general crop requirements to increase water use efficiency for economic benefit. Deficit irrigation practice has been shown to be beneficial to some fruit and vegetable crops, but to a lesser extent in south Texas for mild heat pepper plant production. The purpose of this project was to analyze how watering jalapeño and serrano pepper plants at different levels of DI would impact plant growth and fruit yield in a greenhouse study. Deficit irrigation treatments were performed by irrigating pots at increasing the number of days between irrigation events (water application: 2, 4, 8, and 12 days) to create increasing water stress levels to plants. Plant growth and biomass data was collected to determine the impact of increasing deficit irrigation on plant shoot productivity. In both varieties, plant biomass steadily decreased as water application decreased. Serrano peppers grown at both 4d and 2d between water application events produced identical yields, however, increased water stress immediately impacted jalapeño peppers with lower yield. The encouraging results from serrano peppers suggest a potential economic benefit for deficit irrigation water use practices applied to this pepper variety. 

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