Identifiers
Linking ISSN (ISSN-L): 2332-2268
URL http://www.hrpub.org/journals/jour_archive.php?id=4
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Resource information
Title proper: Universal journal of agricultural research.
Country: United States
Medium: Online
Record information
Last modification date: 07/02/2021
Type of record: Confirmed
ISSN Center responsible of the record: ISSN National Centre for the USA For all potential issues concerning the description of the publication identified by this bibliographic record (missing or wrong data etc.), please contact the ISSN National Centre mentioned above by clicking on the link.
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Universal Journal of Agricultural Research
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23 citations
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Farmers' Perceptions on Climate Change: A Step toward Climate Change Adaptation in Sylhet Hilly Region
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Performance
No. of papers from the Journal in previous yearsYear | Papers |
---|
2024 | 45 |
2023 | 111 |
2022 | 74 |
2021 | 3 |
2020 | 19 |
2019 | 20 |
Reference management. Clean and simple.
Journal abbreviation: Universal journal of agricultural research
The abbreviation of the journal title " Universal journal of agricultural research " is " Univers. J. Agric. Res. ". It is the recommended abbreviation to be used for abstracting, indexing and referencing purposes and meets all criteria of the ISO 4 standard for abbreviating names of scientific journals.
Abbreviation rules
The table below outlines in detail the ISO 4 rules and matches to the ISSN maintained list of title word abbreviations ( TWA ) to derive the abbreviation.
Title | Abbreviation | Word/Stem/Rule |
---|
Universal | Univers. | matches the word "universal" |
journal | J. | matches the word "journal" |
of | | Rule 4.3: prepositions shall be omitted from title abbreviations. |
agricultural | Agric. | matches the stem "agricultur-" |
research | Res. | matches the stem "research-" |
Abbreviation systems
An ISO 4 abbreviation refers to a standardized method for abbreviating journal titles as defined by the International Organization for Standardization. This system ensures consistency and easy identification of journal titles across various databases and citation formats.
Journal title abbreviations are divided into ISO (International Organization for Standardization) for broad disciplines, NLM (National Library of Medicine) for biomedical and life sciences, and CASSI (CAS Source Index) for chemistry and related fields.
About the journal
Full journal title | Universal journal of agricultural research |
---|
Abbreviation | Univers. J. Agric. Res. |
---|
ISSN (print) | |
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ISSN (online) | |
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NLM catalog | |
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Other journal abbreviations
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Universal Journal of Agricultural Research - Impact Score, Ranking, SJR, h-index, Citescore, Rating, Publisher, ISSN, and Other Important Details
Published By: Horizon Research Publishing
Impact Score The impact Score or journal impact score (JIS) is equivalent to Impact Factor. The impact factor (IF) or journal impact factor (JIF) of an academic journal is a scientometric index calculated by Clarivate that reflects the yearly mean number of citations of articles published in the last two years in a given journal, as indexed by Clarivate's Web of Science. On the other hand, Impact Score is based on Scopus data.
Important details.
| Universal Journal of Agricultural Research |
| Journal |
| Agricultural and Biological Sciences (miscellaneous) (Q4); Agronomy and Crop Science (Q4); Food Science (Q4); Forestry (Q4); Plant Science (Q4) |
| 0.81 |
| 0.167 |
| 4 |
| 20949 |
| Horizon Research Publishing |
| United States |
| 23322268, 23322284 |
| 2020-2022 |
| Q4 |
(Last 3 Year) | 43 |
About Universal Journal of Agricultural Research
Universal Journal of Agricultural Research is a journal published by Horizon Research Publishing . This journal covers the area[s] related to Agricultural and Biological Sciences (miscellaneous), Agronomy and Crop Science, Food Science, Forestry, Plant Science, etc . The coverage history of this journal is as follows: 2020-2022. The rank of this journal is 20949 . This journal's impact score, h-index, and SJR are 0.81, 4, and 0.167, respectively. The ISSN of this journal is/are as follows: 23322268, 23322284 . The best quartile of Universal Journal of Agricultural Research is Q4 . This journal has received a total of 43 citations during the last three years (Preceding 2022).
Universal Journal of Agricultural Research Impact Score 2022-2023
The impact score (IS), also denoted as the Journal impact score (JIS), of an academic journal is a measure of the yearly average number of citations to recent articles published in that journal. It is based on Scopus data.
Prediction of Universal Journal of Agricultural Research Impact Score 2023
Impact Score 2022 of Universal Journal of Agricultural Research is 0.81 . If a similar downward trend continues, IS may decrease in 2023 as well.
Impact Score Graph
Check below the impact score trends of universal journal of agricultural research. this is based on scopus data..
Year | Impact Score (IS) |
2023/2024 | Coming Soon |
2022 | 0.81 |
2021 | 1.09 |
2020 | 0.00 |
Universal Journal of Agricultural Research h-index
The h-index of Universal Journal of Agricultural Research is 4 . By definition of the h-index, this journal has at least 4 published articles with more than 4 citations.
What is h-index?
The h-index (also known as the Hirsch index or Hirsh index) is a scientometric parameter used to evaluate the scientific impact of the publications and journals. It is defined as the maximum value of h such that the given Journal has published at least h papers and each has at least h citations.
Universal Journal of Agricultural Research ISSN
The International Standard Serial Number (ISSN) of Universal Journal of Agricultural Research is/are as follows: 23322268, 23322284 .
The ISSN is a unique 8-digit identifier for a specific publication like Magazine or Journal. The ISSN is used in the postal system and in the publishing world to identify the articles that are published in journals, magazines, newsletters, etc. This is the number assigned to your article by the publisher, and it is the one you will use to reference your article within the library catalogues.
ISSN code (also called as "ISSN structure" or "ISSN syntax") can be expressed as follows: NNNN-NNNC Here, N is in the set {0,1,2,3...,9}, a digit character, and C is in {0,1,2,3,...,9,X}
Universal Journal of Agricultural Research Ranking and SCImago Journal Rank (SJR)
SCImago Journal Rank is an indicator, which measures the scientific influence of journals. It considers the number of citations received by a journal and the importance of the journals from where these citations come.
Universal Journal of Agricultural Research Publisher
The publisher of Universal Journal of Agricultural Research is Horizon Research Publishing . The publishing house of this journal is located in the United States . Its coverage history is as follows: 2020-2022 .
Call For Papers (CFPs)
Please check the official website of this journal to find out the complete details and Call For Papers (CFPs).
How to publish in Universal Journal of Agricultural Research
If your area of research or discipline is related to Agricultural and Biological Sciences (miscellaneous), Agronomy and Crop Science, Food Science, Forestry, Plant Science, etc. , please check the journal's official website to understand the complete publication process.
Acceptance Rate
- Interest/demand of researchers/scientists for publishing in a specific journal/conference.
- The complexity of the peer review process and timeline.
- Time taken from draft submission to final publication.
- Number of submissions received and acceptance slots
- And Many More.
The simplest way to find out the acceptance rate or rejection rate of a Journal/Conference is to check with the journal's/conference's editorial team through emails or through the official website.
Frequently Asked Questions (FAQ)
What is the impact score of universal journal of agricultural research.
The latest impact score of Universal Journal of Agricultural Research is 0.81. It is computed in the year 2023.
What is the h-index of Universal Journal of Agricultural Research?
The latest h-index of Universal Journal of Agricultural Research is 4. It is evaluated in the year 2023.
What is the SCImago Journal Rank (SJR) of Universal Journal of Agricultural Research?
The latest SCImago Journal Rank (SJR) of Universal Journal of Agricultural Research is 0.167. It is calculated in the year 2023.
What is the ranking of Universal Journal of Agricultural Research?
The latest ranking of Universal Journal of Agricultural Research is 20949. This ranking is among 27955 Journals, Conferences, and Book Series. It is computed in the year 2023.
Who is the publisher of Universal Journal of Agricultural Research?
Universal Journal of Agricultural Research is published by Horizon Research Publishing. The publication country of this journal is United States.
What is the abbreviation of Universal Journal of Agricultural Research?
This standard abbreviation of Universal Journal of Agricultural Research is .
Is "Universal Journal of Agricultural Research" a Journal, Conference or Book Series?
Universal Journal of Agricultural Research is a journal published by Horizon Research Publishing.
What is the scope of Universal Journal of Agricultural Research?
- Agricultural and Biological Sciences (miscellaneous)
- Agronomy and Crop Science
- Food Science
- Plant Science
For detailed scope of Universal Journal of Agricultural Research, check the official website of this journal.
What is the ISSN of Universal Journal of Agricultural Research?
The International Standard Serial Number (ISSN) of Universal Journal of Agricultural Research is/are as follows: 23322268, 23322284.
What is the best quartile for Universal Journal of Agricultural Research?
The best quartile for Universal Journal of Agricultural Research is Q4.
What is the coverage history of Universal Journal of Agricultural Research?
The coverage history of Universal Journal of Agricultural Research is as follows 2020-2022.
Credits and Sources
- Scimago Journal & Country Rank (SJR), https://www.scimagojr.com/
- Journal Impact Factor, https://clarivate.com/
- Issn.org, https://www.issn.org/
- Scopus, https://www.scopus.com/
Note: The impact score shown here is equivalent to the average number of times documents published in a journal/conference in the past two years have been cited in the current year (i.e., Cites / Doc. (2 years)). It is based on Scopus data and can be a little higher or different compared to the impact factor (IF) produced by Journal Citation Report. Please refer to the Web of Science data source to check the exact journal impact factor ™ (Thomson Reuters) metric.
Impact Score, SJR, h-Index, and Other Important metrics of These Journals, Conferences, and Book Series
Journal/Conference/Book Title | Type | Publisher | Ranking | SJR | h-index | Impact Score |
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Check complete list
Universal Journal of Agricultural Research Impact Score (IS) Trend
Year | Impact Score (IS) |
2023/2024 | Updated Soon |
2022 | 0.81 |
2021 | 1.09 |
2020 | 0.00 |
Top Journals/Conferences in Agricultural and Biological Sciences (miscellaneous)
Top journals/conferences in agronomy and crop science, top journals/conferences in food science, top journals/conferences in forestry, top journals/conferences in plant science.
Journals Publication
Universal journal of agricultural research, issn: 2332-2284.
INDEXED IN Scopus , CAS, Google Scholar
Universal Journal of Agricultural Research is an international peer-reviewed journal that publishes original and high-quality research papers in all areas of agriculture . As an important academic exchange platform, scientists and researchers can know the most up-to-date academic trends and seek valuable primary sources for reference.
The subject areas include, but are not limited to the following fields:
Agricultural Chemistry
Sustainable Agriculture
Agricultural Economics
Agricultural Education
Agricultural Engineering
Agricultural Philosophy
Agriculture Extension
Agricultural Production
Agricultural Resources
Agroecology
Animal Husbandry
Aquaculture
Organic Agriculture
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- History & Past
- Current Days
- Vision 2020
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Agricultural Research
Subject Area and Category
- Agronomy and Crop Science
- Food Science
- Plant Science
Springer International Publishing AG
Publication type
2249720X, 22497218
Information
How to publish in this journal
The set of journals have been ranked according to their SJR and divided into four equal groups, four quartiles. Q1 (green) comprises the quarter of the journals with the highest values, Q2 (yellow) the second highest values, Q3 (orange) the third highest values and Q4 (red) the lowest values.
Category | Year | Quartile |
Agronomy and Crop Science | 2013 | Q2 |
Agronomy and Crop Science | 2014 | Q3 |
Agronomy and Crop Science | 2015 | Q2 |
Agronomy and Crop Science | 2016 | Q3 |
Agronomy and Crop Science | 2017 | Q3 |
Agronomy and Crop Science | 2018 | Q3 |
Agronomy and Crop Science | 2019 | Q3 |
Agronomy and Crop Science | 2020 | Q3 |
Agronomy and Crop Science | 2021 | Q2 |
Agronomy and Crop Science | 2022 | Q2 |
Agronomy and Crop Science | 2023 | Q2 |
Food Science | 2013 | Q2 |
Food Science | 2014 | Q3 |
Food Science | 2015 | Q2 |
Food Science | 2016 | Q3 |
Food Science | 2017 | Q3 |
Food Science | 2018 | Q3 |
Food Science | 2019 | Q3 |
Food Science | 2020 | Q3 |
Food Science | 2021 | Q3 |
Food Science | 2022 | Q2 |
Food Science | 2023 | Q3 |
Plant Science | 2013 | Q2 |
Plant Science | 2014 | Q3 |
Plant Science | 2015 | Q2 |
Plant Science | 2016 | Q3 |
Plant Science | 2017 | Q3 |
Plant Science | 2018 | Q3 |
Plant Science | 2019 | Q3 |
Plant Science | 2020 | Q3 |
Plant Science | 2021 | Q3 |
Plant Science | 2022 | Q2 |
Plant Science | 2023 | Q2 |
The SJR is a size-independent prestige indicator that ranks journals by their 'average prestige per article'. It is based on the idea that 'all citations are not created equal'. SJR is a measure of scientific influence of journals that accounts for both the number of citations received by a journal and the importance or prestige of the journals where such citations come from It measures the scientific influence of the average article in a journal, it expresses how central to the global scientific discussion an average article of the journal is.
Year | SJR |
2013 | 0.413 |
2014 | 0.314 |
2015 | 0.433 |
2016 | 0.319 |
2017 | 0.276 |
2018 | 0.267 |
2019 | 0.292 |
2020 | 0.319 |
2021 | 0.366 |
2022 | 0.373 |
2023 | 0.367 |
Evolution of the number of published documents. All types of documents are considered, including citable and non citable documents.
Year | Documents |
2012 | 44 |
2013 | 45 |
2014 | 46 |
2015 | 45 |
2016 | 49 |
2017 | 50 |
2018 | 53 |
2019 | 60 |
2020 | 71 |
2021 | 62 |
2022 | 77 |
2023 | 49 |
This indicator counts the number of citations received by documents from a journal and divides them by the total number of documents published in that journal. The chart shows the evolution of the average number of times documents published in a journal in the past two, three and four years have been cited in the current year. The two years line is equivalent to journal impact factor ™ (Thomson Reuters) metric.
Cites per document | Year | Value |
Cites / Doc. (4 years) | 2012 | 0.000 |
Cites / Doc. (4 years) | 2013 | 1.182 |
Cites / Doc. (4 years) | 2014 | 1.067 |
Cites / Doc. (4 years) | 2015 | 1.296 |
Cites / Doc. (4 years) | 2016 | 1.239 |
Cites / Doc. (4 years) | 2017 | 1.292 |
Cites / Doc. (4 years) | 2018 | 1.132 |
Cites / Doc. (4 years) | 2019 | 1.152 |
Cites / Doc. (4 years) | 2020 | 1.259 |
Cites / Doc. (4 years) | 2021 | 1.726 |
Cites / Doc. (4 years) | 2022 | 1.935 |
Cites / Doc. (4 years) | 2023 | 1.948 |
Cites / Doc. (3 years) | 2012 | 0.000 |
Cites / Doc. (3 years) | 2013 | 1.182 |
Cites / Doc. (3 years) | 2014 | 1.067 |
Cites / Doc. (3 years) | 2015 | 1.296 |
Cites / Doc. (3 years) | 2016 | 1.015 |
Cites / Doc. (3 years) | 2017 | 0.936 |
Cites / Doc. (3 years) | 2018 | 0.931 |
Cites / Doc. (3 years) | 2019 | 1.079 |
Cites / Doc. (3 years) | 2020 | 1.172 |
Cites / Doc. (3 years) | 2021 | 1.728 |
Cites / Doc. (3 years) | 2022 | 2.016 |
Cites / Doc. (3 years) | 2023 | 1.981 |
Cites / Doc. (2 years) | 2012 | 0.000 |
Cites / Doc. (2 years) | 2013 | 1.182 |
Cites / Doc. (2 years) | 2014 | 1.067 |
Cites / Doc. (2 years) | 2015 | 0.835 |
Cites / Doc. (2 years) | 2016 | 0.813 |
Cites / Doc. (2 years) | 2017 | 0.777 |
Cites / Doc. (2 years) | 2018 | 0.909 |
Cites / Doc. (2 years) | 2019 | 0.922 |
Cites / Doc. (2 years) | 2020 | 1.018 |
Cites / Doc. (2 years) | 2021 | 1.763 |
Cites / Doc. (2 years) | 2022 | 2.068 |
Cites / Doc. (2 years) | 2023 | 1.806 |
Evolution of the total number of citations and journal's self-citations received by a journal's published documents during the three previous years. Journal Self-citation is defined as the number of citation from a journal citing article to articles published by the same journal.
Cites | Year | Value |
Self Cites | 2012 | 0 |
Self Cites | 2013 | 5 |
Self Cites | 2014 | 10 |
Self Cites | 2015 | 9 |
Self Cites | 2016 | 2 |
Self Cites | 2017 | 5 |
Self Cites | 2018 | 3 |
Self Cites | 2019 | 3 |
Self Cites | 2020 | 10 |
Self Cites | 2021 | 2 |
Self Cites | 2022 | 4 |
Self Cites | 2023 | 0 |
Total Cites | 2012 | 0 |
Total Cites | 2013 | 52 |
Total Cites | 2014 | 95 |
Total Cites | 2015 | 175 |
Total Cites | 2016 | 138 |
Total Cites | 2017 | 131 |
Total Cites | 2018 | 134 |
Total Cites | 2019 | 164 |
Total Cites | 2020 | 191 |
Total Cites | 2021 | 318 |
Total Cites | 2022 | 389 |
Total Cites | 2023 | 416 |
Evolution of the number of total citation per document and external citation per document (i.e. journal self-citations removed) received by a journal's published documents during the three previous years. External citations are calculated by subtracting the number of self-citations from the total number of citations received by the journal’s documents.
Cites | Year | Value |
External Cites per document | 2012 | 0 |
External Cites per document | 2013 | 1.068 |
External Cites per document | 2014 | 0.955 |
External Cites per document | 2015 | 1.230 |
External Cites per document | 2016 | 1.000 |
External Cites per document | 2017 | 0.900 |
External Cites per document | 2018 | 0.910 |
External Cites per document | 2019 | 1.059 |
External Cites per document | 2020 | 1.110 |
External Cites per document | 2021 | 1.717 |
External Cites per document | 2022 | 1.995 |
External Cites per document | 2023 | 1.981 |
Cites per document | 2012 | 0.000 |
Cites per document | 2013 | 1.182 |
Cites per document | 2014 | 1.067 |
Cites per document | 2015 | 1.296 |
Cites per document | 2016 | 1.015 |
Cites per document | 2017 | 0.936 |
Cites per document | 2018 | 0.931 |
Cites per document | 2019 | 1.079 |
Cites per document | 2020 | 1.172 |
Cites per document | 2021 | 1.728 |
Cites per document | 2022 | 2.016 |
Cites per document | 2023 | 1.981 |
International Collaboration accounts for the articles that have been produced by researchers from several countries. The chart shows the ratio of a journal's documents signed by researchers from more than one country; that is including more than one country address.
Year | International Collaboration |
2012 | 2.27 |
2013 | 15.56 |
2014 | 17.39 |
2015 | 8.89 |
2016 | 4.08 |
2017 | 12.00 |
2018 | 13.21 |
2019 | 6.67 |
2020 | 14.08 |
2021 | 9.68 |
2022 | 11.69 |
2023 | 12.24 |
Not every article in a journal is considered primary research and therefore "citable", this chart shows the ratio of a journal's articles including substantial research (research articles, conference papers and reviews) in three year windows vs. those documents other than research articles, reviews and conference papers.
Documents | Year | Value |
Non-citable documents | 2012 | 0 |
Non-citable documents | 2013 | 3 |
Non-citable documents | 2014 | 4 |
Non-citable documents | 2015 | 4 |
Non-citable documents | 2016 | 1 |
Non-citable documents | 2017 | 0 |
Non-citable documents | 2018 | 0 |
Non-citable documents | 2019 | 1 |
Non-citable documents | 2020 | 1 |
Non-citable documents | 2021 | 1 |
Non-citable documents | 2022 | 0 |
Non-citable documents | 2023 | 0 |
Citable documents | 2012 | 0 |
Citable documents | 2013 | 41 |
Citable documents | 2014 | 85 |
Citable documents | 2015 | 131 |
Citable documents | 2016 | 135 |
Citable documents | 2017 | 140 |
Citable documents | 2018 | 144 |
Citable documents | 2019 | 151 |
Citable documents | 2020 | 162 |
Citable documents | 2021 | 183 |
Citable documents | 2022 | 193 |
Citable documents | 2023 | 210 |
Ratio of a journal's items, grouped in three years windows, that have been cited at least once vs. those not cited during the following year.
Documents | Year | Value |
Uncited documents | 2012 | 0 |
Uncited documents | 2013 | 24 |
Uncited documents | 2014 | 48 |
Uncited documents | 2015 | 65 |
Uncited documents | 2016 | 67 |
Uncited documents | 2017 | 74 |
Uncited documents | 2018 | 79 |
Uncited documents | 2019 | 72 |
Uncited documents | 2020 | 75 |
Uncited documents | 2021 | 64 |
Uncited documents | 2022 | 60 |
Uncited documents | 2023 | 67 |
Cited documents | 2012 | 0 |
Cited documents | 2013 | 20 |
Cited documents | 2014 | 41 |
Cited documents | 2015 | 70 |
Cited documents | 2016 | 69 |
Cited documents | 2017 | 66 |
Cited documents | 2018 | 65 |
Cited documents | 2019 | 80 |
Cited documents | 2020 | 88 |
Cited documents | 2021 | 120 |
Cited documents | 2022 | 133 |
Cited documents | 2023 | 143 |
Evolution of the percentage of female authors.
Year | Female Percent |
2012 | 16.00 |
2013 | 17.29 |
2014 | 25.00 |
2015 | 29.73 |
2016 | 26.25 |
2017 | 24.16 |
2018 | 20.96 |
2019 | 25.00 |
2020 | 25.65 |
2021 | 28.37 |
2022 | 26.30 |
2023 | 27.81 |
Evolution of the number of documents cited by public policy documents according to Overton database.
Documents | Year | Value |
Overton | 2012 | 8 |
Overton | 2013 | 3 |
Overton | 2014 | 2 |
Overton | 2015 | 5 |
Overton | 2016 | 2 |
Overton | 2017 | 3 |
Overton | 2018 | 1 |
Overton | 2019 | 5 |
Overton | 2020 | 2 |
Overton | 2021 | 4 |
Overton | 2022 | 3 |
Overton | 2023 | 0 |
Evoution of the number of documents related to Sustainable Development Goals defined by United Nations. Available from 2018 onwards.
Documents | Year | Value |
SDG | 2018 | 26 |
SDG | 2019 | 18 |
SDG | 2020 | 34 |
SDG | 2021 | 36 |
SDG | 2022 | 41 |
SDG | 2023 | 18 |
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- DOI: 10.13189/UJAR.2017.050301
- Corpus ID: 168840748
Horticulture Development in Nepal: Prospects, Challenges and Strategies
- M. Thapa , Sanjay Dhimal
- Published 1 May 2017
- Agricultural and Food Sciences
- Universal Journal of Agricultural Research
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18 Citations
Horti-tourism; an approach for strengthening farmers’ economy in the post-covid situation, characterization of farming system and determinants of adoption of horticultural enterprises in achham, nepal, commercial vegetable farming: constraints and opportunities of farmers in kirtipur, nepal, comparative study of vegetable biodiversity in terai and hilly belts of chitwan, nepal, crop protection practices in traditional agriculture in mid-hills of western nepal: a case of palpa and gulmi district, trend analysis on production, import, and export of vegetable sub-sector in nepal.
Vegetable Farming and Farmers’ Livelihood: Insights from Kathmandu Valley, Nepal
In-vitro mass propagation of limonium sinuatum l. mill. (statice), production economics and determinants for adoption of commercial vegetable production in kathmandu nepal, growth of market gardening for local sales in the mount everest tourist region of pharak, nepal, 10 references, related papers.
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Research progress on autonomous operation technology for agricultural equipment in large fields.
1. Introduction
2. onboard environmental sensing technology, 3. complete-coverage path-planning technology, 3.1. classical path-planning algorithm, 3.2. bionics-based path-planning algorithms, 4. autonomous operation control technology, 5. conclusions and prospection, 5.1. conclusions, 5.2. prospection, author contributions, data availability statement, conflicts of interest.
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Click here to enlarge figure
Method | Sensor Type | Characteristics | Sensing Task |
---|
Vision Sensors | Monocular Camera | Monocular cameras are low cost and provide rich image information, but lack depth data and are susceptible to environmental influences. | Farmland boundary detection, navigation line extraction |
Binocular Camera | Binocular cameras can provide rich image information and highly reliable depth information, but the configuration and calibration are more complicated; the computation is large, and parallax calculation depends on computing resources. | Farmland boundary detection, navigation line extraction |
RGB-D Camera | RGB-D camera can provide an RGB map and a depth map, and the calculation amount is small. However, the measurement range is narrow, the noise level is high, the field of view is small, and it is easily interfered with by daylight. | Farmland boundary detection |
Radar Sensor | Lidar | LIDAR is highly accurate, stable, and reliable. However, it has a high cost, is susceptible to dust interference with the limited detection range, and cannot recognize color and texture in farmland boundary identification and navigation line extraction. | Navigation line extraction |
Camera Type | Features | Advantages | Common Cameras |
---|
RGB Cameras | A standard color camera that captures images in the red, green, and blue color channels. | RGB cameras provide rich color and texture information that helps distinguish between different types of obstacles, are low cost, and are easy to integrate and deploy. | Logitech C920, Sony Alpha Series (Logitech, Lausanne, Switzerland) |
Depth Camera | In addition to capturing RGB images, it also acquires depth information for each pixel. | Combining depth information and RGB images improves the accuracy and reliability of obstacle detection, providing more precise obstacle localization, especially in complex environments. | Intel RealSense (Intel, Santa Clara, CA, USA), Microsoft Kinect 360 (Microsoft 360, Washington, DC, USA) |
Stereo Camera | Captures stereo images through two cameras and uses parallax to calculate depth information. | Provides high-precision depth perception for fine obstacle detection tasks and is more reliable than a single depth camera in terms of detection accuracy and range. | ZED Series (ZED Series, San Francisco, America), Bumblebee2 (Teledyne FLIR, Washington, DC, USA) |
Panoramic Camera | Capable of capturing images or videos with a 360-degree field of view. | In obstacle detection, it provides a comprehensive view of the environment, reduces blind spots, and improves the coverage and accuracy of obstacle detection. | Ricoh Theta (RICOH, Tōkyō, Japan), Insta360 Pro (insta360, Shenzhen, China) |
Classification | Common Algorithms | Common Application Areas |
---|
Algorithms based on graph search | Dijkstra, A *, D * | Global path planning |
Algorithm based on sampling | RRT | Global path planning |
Algorithms based on artificial potential fields | Artificial potential field method | Local path planning |
Algorithms based on curve fitting | Arcs and straight lines, polynomial curves, spline curves, Bessel curves, differential flatness | Local path planning |
Algorithms based on numerical optimization | Describing and solving planning problems using objective functions and constraints | Local path planning |
Intelligent algorithms based on bionics | Genetic algorithms, particle swarm optimization algorithms, ant colony algorithms | Global path planning, local path planning |
Step | GA | PSO | ACO |
---|
Initialization | Initialize population | Initialize particles | Initialize ants |
Fitness Eval. | Evaluate fitness | Evaluate fitness | Evaluate fitness |
Selection | Roulette wheel selection | N/A | Select next node based on probability |
Crossover | Single-point crossover | N/A | N/A |
Mutation | Swap mutation | N/A | N/A |
Update Ind. | Replace individual | Update velocity and position | Update pheromone |
Update Best | Find best individual | Update global best | Find global best path |
Iteration Loop | Repeat for max generations | Repeat for max iterations | Repeat for max iterations |
Return Result | Return best individual | Return global best | Return global best path |
Algorithm Category | Global Search Ability | Convergence Speed | Computational Complexity | Adaptability | Scalability |
---|
Genetic algorithm | ★★★★ | ★★ | ★★★★ | ★★★★ | ★★★ |
Particle swarm optimization | ★★★★ | ★★★★★ | ★★★ | ★★★ | ★★★★ |
Ant colony algorithm | ★★★★★ | ★★★ | ★★★★ | ★★★★ | ★★★★ |
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Share and Cite
Wei, W.; Xiao, M.; Duan, W.; Wang, H.; Zhu, Y.; Zhai, C.; Geng, G. Research Progress on Autonomous Operation Technology for Agricultural Equipment in Large Fields. Agriculture 2024 , 14 , 1473. https://doi.org/10.3390/agriculture14091473
Wei W, Xiao M, Duan W, Wang H, Zhu Y, Zhai C, Geng G. Research Progress on Autonomous Operation Technology for Agricultural Equipment in Large Fields. Agriculture . 2024; 14(9):1473. https://doi.org/10.3390/agriculture14091473
Wei, Wenbo, Maohua Xiao, Weiwei Duan, Hui Wang, Yejun Zhu, Cheng Zhai, and Guosheng Geng. 2024. "Research Progress on Autonomous Operation Technology for Agricultural Equipment in Large Fields" Agriculture 14, no. 9: 1473. https://doi.org/10.3390/agriculture14091473
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An international peer-reviewed journal that publishes original and high-quality research papers in all areas of agriculture. The journal covers various fields such as agricultural chemistry, engineering, economics, management, policy, technology, and more.
Scimago Journal Rank provides information on the scientific influence and prestige of journals in various categories and fields. See the SJR, quartile, citations, documents and self-cites of Universal Journal of Agricultural Research, a US-based journal in agricultural and biological sciences.
The main reason is the high incidence of informal employment including women and children. In 2019, for example, 86.6% of total labor force in agriculture was in informal status. While the rate is ...
Resurchify provides impact factor, ranking, h-index, SJR, publisher, ISSN and other details of Universal Journal of Agricultural Research, a Q4 journal in agricultural and biological sciences. See the latest and past metrics, coverage history and call for papers of this journal.
Find the ISSN and bibliographic record of Universal journal of agricultural research, an online publication from the United States. The ISSN Portal provides data sources, newsletter, FAQ and contact information.
The results revealed that the seeds have high ability to absorb water and exhibited high rate of germination, especially in the second wk after sowing (96%). Seeds placed on the soil surface ...
Universal Journal of Agricultural Research 7(5): 177-188, 2019 179 . affected by temperature and soil moisture thus nutrients may be released when the plant does not need them [67].
An open access journal that publishes papers on biology and agriculture topics. Browse the latest publications, citations, authors and institutions related to this journal.
The abbreviation of the journal title " Universal journal of agricultural research " is " Univers. J. Agric. Res. ". It is the recommended abbreviation to be used for abstracting, indexing and referencing purposes and meets all criteria of the ISO 4 standard for abbreviating names of scientific journals. Organize your papers in one place.
The Universal Journal of Agricultural Research is ranked 20949 among 27955 Journals, Conferences, and Book Series. As per SJR, this journal is ranked 0.167. SCImago Journal Rank is an indicator, which measures the scientific influence of journals. It considers the number of citations received by a journal and the importance of the journals from ...
A research paper on the impact of some factors on coffee producers towards sustainable rural development in Lagawe, Ifugao, Philippines. The paper used a multi-method approach and proposed a framework for a sustainable coffee industry viable business.
A peer-reviewed journal that publishes original and high-quality research papers in all areas of agriculture. Indexed in Scopus, CAS, Google Scholar and Flipping Circle, it covers topics such as agronomy, animal husbandry, aquaculture, organic agriculture and more.
Universal Journal of Agricultural Research. Sign up to set email alerts | ISSN(s): 2332-2268, 2332-2284 ... scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations-citations that display the context of the citation and describe whether the article provides ...
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Published in Universal Journal of… 1 September 2019 Agricultural and Food Sciences, Environmental Science The Effects of Chemical Fertilizers and organic manure on soil fertility focuses primarily on the behavior of nitrogen (N) and phosphorus (P) in soil because these two nutrients are the main nutrients that limit crop yields and they are ...
Scope. The main objective of this initiative is to promote agricultural research and development. The journal will publish high quality original research papers and critical reviews on emerging fields and concepts for providing future directions. The publications will include both applied and basic research covering the following disciplines of ...
This paper investigates the factors affecting rice production in the Philippines using panel data analysis and the augmented Cobb-Douglas Production function. It finds that land area, fertilizer application, and climate variables have significant effects on rice output in irrigated and rainfed areas.
Universal Journal of Agricultural Research; Nepal has different ecological belts endowed with different types of climates due to its geographical locations for the production of horticultural crops. Government organizations were not in existence for the development of horticulture sector before 1950, yet growing of fruits, vegetables, spices ...
Universal Journal of Agricultural Research 10(6): 595-609, 2022 599 . yellow and green-colored font was used on a green and . white-colored background. Coffee C uses black plastic .
Get access to Universal Journal of Agricultural Research details, impact factor, Journal Ranking, H-Index, ISSN, Citescore, Scimago Journal Rank (SJR). Check top authors, submission guidelines, Acceptance Rate, Review Speed, Scope, Publication Fees, Submission Guidelines at one place. Improve your chances of getting published in Universal Journal of Agricultural Research with Researcher.Life.
Agriculture is a labor-intensive industry. However, with the demographic shift toward an aging population, agriculture is increasingly confronted with a labor shortage. The technology for autonomous operation of agricultural equipment in large fields can improve productivity and reduce labor intensity, which can help alleviate the impact of population aging on agriculture. Nevertheless ...
This article presents a study on coffee land mapping using unmanned aerial vehicles (UAVs) multispectral remote sensing in Megamendung Village, Bogor Regency, Indonesia. The authors aim to identify the distribution and number of Arabica coffee plants using UAV image data and compare them with the land suitability analysis.
Universal Journal of Agricultural Research 12(3): 445-454, 2024 447 consequences of food insecurity and socioeconomic downturn. This study on the retrospective assessment of changes in yield quantity of selected arable crops in the study area is aim to evaluate past food production experiences occasioned by physical, cultural and economic ...
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conducted on the effects of legumes in the diet on animal. production an d have noted significant increases in animal. production (Lazie r, 1994). The obje ctives of th is study. were to determine ...