Precision agriculture research papers

precision agriculture research papers

Skip to search form Skip to main content You are currently offline. Some features of the site may not work correctly. Kayrouz Published Economics. Cost maps visually depict spatial differences in production costs. The visual depictions of these costs are represented using ArcGIS in an attempt to aide farmers in further decision making. Save to Library. Create Alert. Launch Research Feed. Share This Paper. Figures and Tables from this paper. Figures and Tables. One Citation. Citation Type.

Has PDF. Publication Type. More Filters. Components of Precision Agriculture. Research Feed. View 1 excerpt, references background. Precision agriculture — opportunities, benefits and pitfalls of site-specific crop management in Australia. Highly Influential. View 4 excerpts, references background. View 5 excerpts, references methods and background. Making GIS a versatile analytical tool for research in precision farming.

Related Papers. By clicking accept or continuing to use the site, you agree to the terms outlined in our Privacy PolicyTerms of Serviceand Dataset License.This unique opportunity will allow authors to continue to submit their research to this Call for Papers, including post collection launch, until December 14, Advances in plant phenomics and precision agriculture rely on research that spans disciplines and spatiotemporal scales.

From cell to field, from second to season, investigators seek to understand plant processes and environmental interactions, and to develop interventions for maximal resilience and yield. These efforts are fundamental to guaranteeing food security and sustainable crop production in the context of rising demand and increasingly challenging environments.

precision agriculture research papers

With its commitment to publication of rigorously validated, reproducible methods and tools, PLOS ONE is an ideal venue for the interdisciplinary research that is characteristic of plant phenomics and precision agriculture.

In this Call for Papers, we are inviting submissions that develop and test- in controlled environments or in the field- new technologies for phenotypic measurements and agricultural surveillance and intervention.

Research articles are selected for scientific rigor rather than perceived impact. Under this Call for Papers, authors are responsible for providing, where relevant and upon submission, the source code needed to replicate their findings, in a repository such as GitHub or Bitbucket or a cloud computing service such as Code Ocean. For any referenced third party code that cannot be shared, authors are responsible for including, in the Data Availability Statement, contact information and steps by which an interested reader can acquire the code.

Where relevant, authors are encouraged to provide executable documents, such as a Jupyter Notebook or an RMarkdownto increase reproducibility. Authors reporting new protocols are encouraged to register these on the protocols. For more information on our partnership with protocols. The Collection will publish October Dec 14 Bioinformatics pipelines In-field phenomic application Distributed research infrastructure Multi-environment networks Farmer support services.

A systematic literature review of the factors affecting the precision agriculture adoption process

Phenomics has the potential to improve the speed and sustainability of research and supply ecosystems for food, fuel, and fiber crops.

At the heart of phenomics research are hardware and software tools and methods that are developed by interdisciplinary teams.

Malia Gehan. PLOS ONE has been a great exception and publishes novel, interdisciplinary work of high quality from many different academic fields. Charlotta Mellander. Days to First Decision on average.

Plant phenomics papers published.Looks like you are currently in Russia but have requested a page in the United States site. Would you like to change to the United States site?

Kent ShannonDavid E. ClayNewell R. Newell R. Kitchen earned his B. He is internationally recognized for his research in precision agriculture systems, agroecosystem soil and water quality, and nutrient management. Research highlights include relating spatially-measured soil sensor data to soil characteristics and crop productivity, producing tools for delineating within-fi eld management zones, and developing strategies for variablerate N fertilizer application.

David E. Clay received a B. S degree from the University of Wisconsin MadisonM. Degree from the University of Idaho, and Ph. In addition, he is an Editor or author for 13 books and has published over papers. Clay's research goal is to develop and test sustainable precision agricultural management systems that enhance environmental quality, maintain rural economies, and improve energy and economic self-suffi ciency.

Based on his research, teaching, and service responsibilities he has received a number of awards including two papers that awarded paper of the year, being twice selected for the ASA precision Systems Impact award, being selected twice for the SDSU College of Agriculture and Biological Sciences Outstanding Researcher, editor on three books that were awarded excellence in extension materials greater than 15 papers, selected as a Fellow of the American Society of Agronomy inbeing awarded the PrecisionAG Award of Excellence in Education and research, and being awarded the SDSU F.

Butler Award for Excellence in Research. Kent Shannon grew up on a diversified crop and livestock farm northeast of Macon, Missouri and then attended the University of Missouri receiving a BS and MS degree in Agricultural Engineering in andrespectfully.

Kent started his extension career as an Agricultural Engineering Specialist in Northeast Missouri at Kirksville in Kent has worked to educate Missouri crop producers and their advisors through on-farm research and providing training and consultation on the use of spatial data analysis software GIS, Geographic Information Systemand GPS Global Positioning System software and hardware.

His current extension education focus continues to be in technology and how it can be utilized in agriculture with a current emphasis on drone technologies. Undetected location. NO YES.

Precision Agriculture Basics

Precision Agriculture Basics. Selected type: Paperback.To browse Academia. Skip to main content. Log In Sign Up. Papers People. Through this article, the author aims to identify the adoption rates and types of precision farming technologies embraced by farmers in the USA and the EU.

Research papers in relation to the adoption of precision agriculture technologies Research papers in relation to the adoption of precision agriculture technologies were collected and divided into two groups, according to their geographic region: USA and EU.

Books, scientific articles, reports and conference papers were reviewed and studied. Likewise, the material about the adoption of precision agriculture technologies was accumulated. The level of adoption in the USA differs from one state to another. United Kingdom, Denmark and Germany have higher rates of adoption compared with other countries in the EU. Save to Library. Journal of Agricultural Faculty of Gaziosmanpasa University. Abstract: Auto Guidance Abstract: Auto Guidance AG systems offer many advantages for farmers including more accuracy, more efficiency and agricultural input savings.

The adoption of AG systems is increasing in many countries. Also, their adoption rate is rising in Adana province and in other regions of Turkey. The aim of this study was to assess the experiences and satisfactions of 55 out of about farmers who used AG systems in Adana using face-to-face interviews. A large portion of the farmers The most common Participant farmers used the AG system mostly in tillage Most of the problems AbstractIdentifying specific requisite according to field design and management, analyzing those and finding out the most appropriate and best solution, using information and technology is precision agriculture.

precision agriculture research papers

Maximizing profits, reducing wastage of resources such as fertilizer and manpower are features of it. In this method of farming, advanced and updated technology tools and devices such as GPS and remote sensing are used to make the precise decision while performing agricultural tasks.

Its main objective is not having the same production everywhere but to manage and evenly divide resources available.

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This can be a solution to the problems faced by farmers globally all around. This paper focuses on comparing and analyzing precision agriculture against traditional techniques and tools. Robots used for agriculture purposes are known as Agribot or Agricultural robot.

This paper focuses on various robotics tools used in agriculture for performing agricultural tasks. Non-availability of skilled labour, increase in labour wages makes conditions worse. Keeping in mind the ICAR vision — "To harness science to ensure comprehensive and sustained physical, economic and ecological access to food and livelihood security to all Indians, through assessment, refinement, generation and adoption of appropriate technologies. In this method of farming, advanced and updated technologies such as GPS, stereo vision cameras, remote sensing and most importantly robotics are introduced to make it more precise and productive.

Although the Indian government designed and implemented various schemes for making agriculture more sustainable, more productive and climate-resilient and remunerative by introducing a golden fusion of information technology and space technology satellite. This technology mainly focused on soil and conservation measures, efficient water resource management, efficiently predicting upcoming disasters. Still as compare to developed nations Indias agriculture production is still low.

Comparison between countries based on land distribution and production [2] The Bar graphs below show a comparison between various countries based on land distribution in terms of a hectare per capita and production in Kg per hectare. From the data above it is clear that developed countries lead production capability because of precision agriculture whereas India lagging because of conventional approach it made in agriculture.

Hence India needs to move towards precision agriculture. Robotic pick and place arm, Mechanical harvesting, limb shaker, canopy shaker, Abscission Chemical.

For this GPS, data analysis techniques and past experience are taken into consideration. Whereas in India due to limited land availability enough importance is not given to this factor.

Usually, soil sensing is carried out to determine the constituents of soil what it requires in real-time. Initially, the nutrients are found by taking samples of soil from the fields in the lab and treating it with chemicals. The real part of soil sensing comes into picture during cultivation.

Technology holds an immense advantage in todays agriculture. Soil sensing is carried out by drones or robots loaded with sensors moving across the fields. Sensors: All these sensors are connected to a microcontroller to process the data obtained. The microcontroller processes the data, analyses, stores as well as sends to the operator. The microcontroller is controlled by a remote device over a network of frequency within the law. These devices are quite simple to use and can be handled easily by a poor educational background person also.

Soil sensing works accurately when bulks of data are available for comparison and obtaining results. Also, this technology can be used effectively in the irrigation process, by sensing dry parts of the field and providing the water to the same via drip irrigation. E-Nose: Electronic Nose sensor is being used to determine the metallic fumes from the soil, and thus identifying the mineral deposits in the soil.For agricultural industries to capture many environmental and economic benefits that have been demonstrated for precision agriculture PA technologies, an understanding of the factors affecting adoption of these technologies is required to adequately inform the development of PA approaches and the programs used to promote their use.

A systematic review of the literature was undertaken to explore the processes of adoption of PA technologies, using an innovation diffusion framework to analyse the complex interactions between different factors in the adoption process. A total of 34 relevant publications were extracted from Scopus database following a systematic search and analysis process.

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PA technologies adoption research has predominantly been undertaken in the United States and Germany, with industrial crops receiving the most research attention. Relative advantage and motivation were the most frequently mentioned factors affecting PA technologies adoption. However, very few studies have examined multiple components of the complex adoption process, and most were narrowly focussed on assessing the impact of a single aspect. The conclusions drawn from the review are that many of the determinants of innovation diffusion that have been examined in other industry contexts were absent in the PA technologies adoption literature, and that the complexity and multidimensional nature of the adoption process was very poorly represented.

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Precision agriculture: Applicability and opportunities for Nigerian agriculture. Middle East Journal of Scientific Research, 13 9— Google Scholar. Ajzen, I. The theory of planned behavior.

Organizational Behavior and Human Decision Processes, 50 2— Anselmi, A. Aubert, B. Decision Support Systems, 54 1— Bagheri, N. Solutions for fast development of precision agriculture in Iran. Batte, M. Precision farming adoption and use in Ohio: Case studies of six leading-edge adopters. Computers and Electronics in Agriculture, 38 2— Binswanger, H. Agricultural mechanization: A comparative historical perspective. Research Observer, 1, 27— Boyer, C.

Precision Agriculture and Robotics

Cotton producer awareness and participation in cost-sharing programs for precision nutrient-management technology. Journal of Agricultural and Resource Economics, 41 181— Busse, M.

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Innovation mechanisms in German precision farming. Precision Agriculture, 15 4— Daberkow, S. Farm and operator characteristics affecting the awareness and adoption of precision agriculture technologies in the US. Precision Agriculture, 4 2—To browse Academia.

Skip to main content. Log In Sign Up. Papers People. Nitrogen and chlorophyll status determination in durum wheat as influenced by fertilization and soil management: Preliminary results. Handheld chlorophyll meters as Soil Plant Analysis Development SPAD have proven to be useful tools for rapid, no-destructive assessment of chlorophyll and nitrogen status in various crops.

This method is used to diagnose the need of This method is used to diagnose the need of nitrogen fertilization to improve the efficiency of the agricultural system and to minimize nitrogen losses and deficiency. The objective of this study is to evaluate the effect of repeated conservative agriculture practices on the SPAD readings, leaves chlorophyll concentration and Nitrogen Nutrition Index NNI relationships in durum wheat under Mediterranean conditions.

The experimental site is a part of a long-term-experiment established in and is still on-going where three tillage managements and three nitrogen fertilizer treatments were repeated in the same plots every year.

The results show that the SPAD can be used for a correct assessment of chlorophyll and nitrogen status in durum wheat but also to evaluate indirectly the content of soil organic matter and nitrogen availability during different growth stages of the crop cycle.

Save to Library. Setting of a precision farming robotic laboratory for cropping system sustainability and food safety and security: preliminary results.

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The acceleration of Digital Agriculture is evident through the increased adoption of digital technologies on farms including smart machines, sensors and cloud computing.

In this paper we present the preliminary results of the research In this context, as first result, an interdepartmental Research and Services Center called "Smart Farming" has been set up with the aim to strengthen multidisciplinary collaborations in the fields of Agriculture and Forestry, Geomatics, ICT and Robotics. Future research activities are certainly needed to fully explore the potentialities of conservation agriculture and precision farming, and to drive the transition process from conventional agriculture to modern conservation agriculture and precision farming techniques.

In-depth studies are planned on the combined effect of nitrogen fertilization and soil management on the main production variables of durum wheat in order to evaluate whether specific tools for precision agriculture applications can find significant diffusion even in Mediterranean cereal based cropping systems.

Mapping the distribution of healthcare facilities using Geospatial Information Science in Keiyo North constituency. This research was undertaken to identify gaps in the distribution of healthcare facilities and to perform a suitability analysis to assess areas that are fit for establishment of new healthcare facilities in Keiyo North constituency. Image analysis aplications in precision agriculture.

Unmanned Aircraft Vehicles UAVs are currently used for multiple applications in various fields: forestry, geology, the livestock sector and security. Among the most common applications, it is worth to stand out the image acquisition, Among the most common applications, it is worth to stand out the image acquisition, irrigation, transport, surveillance and others. The study that one presents treats of the implementations that are realized by means of aerial images acquired with UAVs directed to the farming.

Images acquired until recent years had been using satellites, however due to the high costs that are incurred and low accessibility to these technologies, UAVs, have become a tool for greater precision and scope for making decisions in agriculture.

Information from databases of international magazines, groups and research centers is taken to determine the current state of implementations in Precision Agriculture PA.

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