Design of Ontology of Indigenous Knowledge on Agriculture in Iran with an emphasis on video retrieval

Document Type : مقالات پژوهشی

Authors

1 Ph.D. student. Dept.Library and Information Science, Ferdowsi University of Mashhad. Mashhad. Iran.

2 Ph.D., Professor., Dept.Library and Information Science, Ferdowsi University of Mashhad. Mashhad. Iran.

3 PhD., Professor Dept Computer Engineering,Ferdowsi University of Mashhad, Mashhad. Iran.

10.22067/infosci.2024.82708.1166

Abstract

Introduction: Indigenous knowledge on agriculture in Iran depends on the biodiversity of various agricultural and garden plants, and the climate of each region. To introduce different indigenous species and cultivars that have been identified by agricultural researchers and provide the possibility of searching and retrieving various properties of these cultivars and the suitable cultivation area in Iran, IranAgriOnt was designed and due to the nature of indigenous knowledge on agriculture, for the design, video retrieval was considered. The present study has created the ontology of cultivars of agricultural and horticultural plants of Iran with the aim of using ontology in organizing the Indigenous Knowledge on Agriculture in Iran. In the design of this ontology for the purpose of vide retrieval, its related properties and relationships have been created. Among the extensive of indigenous agriculture knowledge due to the importance of biodiversity of plant species, This study identified the concepts and properties related to agricultural and horticultural cultivars in different regions of Iran.

Methods: The ontology was designed using the content analysis. The ontology was assessed using qualitative assessment based on the criteria determined by the experts. To describe the visual properties of the video, MPEG7 has been used. IranAgriOnt is designed by Protege 5.5 and consists of three main parts: class, property and individual. For ontology design, the videos and written sources of indigenous knowledge on agriculture were searched and analyzed. next the concepts in the texts and videos and the relationships between them were identified. Sampling at this stage was purposive and continued until saturation was reached. The concepts, properties and relationships obtained were compared with the concepts found in the agricultural ontologies, thesaurus books and ontologies studied in the subject domain and video ontologies to select the correct concept and term. The classes, sub-classes and properties of objects and to some extent the properties of detected data related to video retrieval were adapted to MPEG7 and they were presented to the agricultural experts. After many trials and errors and holding numerous group or two-person meetings (subject expert, computer experts and researcher) of the classes and properties approved by the subject experts were arranged in order and the ontology obtained. Individuals were first entered the Excel and then the ontology. The computer experts tested the Iranian indigenous knowledge ontology by creating various queries in JavaScript. IranAgriOnt gave positive answers to various queries and was approved by the computer experts. The indigenous knowledge researchers evaluated the ontological model. At this stage, criteria-based approach was used and the agricultural experts evaluated and approved the designed ontology.

Background: Related works were examined in two categories of Agricultural Indigenous Knowledge and video.Indigenous Knowledge and Agricultural ontologies were the Agricultural Ontology Service Concept Server (AOS/CS) designed by the Food and Agriculture Organization (FAO), the Crop ontology (CO) designed and used by the Consultative Group on International Agricultural Research (CGIAR) and The Plant Ontology (PO) created by the Plant Ontology Consortium and Agricultural gene ontology (AGO) is a subset of gene ontology (GO), which was created in order to recognize and analyze the genes of agricultural species to meet analysis demands from new technologies and research. Also, the countries of Spain, China, Nigeria, Sri Lanka, Malaysia, Thailand, Japan, Indonesia, India and Pakistan designed the ontology of indigenous agricultural knowledge. The works related to video ontology were also analyzed in order to identify the concepts and peroperties necessary in the design of video ontology from 2005 to 2018.

Findings: In general, 26 classes have been created in this ontology, 20 of which are subclasses. It also includes 22 object properties, 33 data properties and more than two hundred individuals.

In terms of using MPEG7, using the OWL and ontology design by Protégé, the present study is consistent with the related studies results.

For the description of low- and high-level properties in the ontology, the study, has selected visual descriptors of color and shape. these properties are considered as properties of individuals of the class of Cultivar.

In IranAgriOnt, did not find it appropriate to describe some low-level properties of the video, which were mentioned in MPEG7 for video description,

Keywords

Main Subjects


Arnaud, E., Guerrero, A. F., Laporte, M.-A., Castiblanco, V., Antezana, E., Menda, N., Shrestha, R., Dreher, K. A., Hualla, V., Salas, E., Mendes, T., Makunde, G., & Pot, D. (2022). Crop ontology governance and stewardship framework [Technical and research document]. http://agritrop.cirad.fr/604066/1/Governance%20of%20CO_Proposal_200122%20.pdf
Asim, M. N., Wasim, M., Khan, M. U. G., Mahmood, N., & Mahmood, W. (2019). The use of ontology in retrieval: a study on textual, multilingual, and multimedia retrieval. IEEE Access, 7, 21662-21686. https://doi.org/10.1109/ACCESS.2019.2897849.
Athanasiadis, T., Tzouvaras, V., Petridis, K., Precioso, F., Avrithis, Y., & Kompatsiaris, Y. (2005). Using a Multimedia Ontology Infrastructure for Semantic Annotation of Multimedia Content. SemAnnot@ ISWC,
Cherry, A., & Mukunda, K. (2015). A case study in indigenous classification: Revisiting and reviving the Brian Deer scheme. Cataloging & Classification Quarterly, 53(5-6), 548-567. https://doi.org/10.1080/01639374.2015.1008717
Cobos, Y., Sarasua, C., Linaza, M. T., Jimenez, I., & Garcia, A. (2008, 15-16 Dec. 2008). Retrieving Film Heritage Content Using an MPEG-7 Compliant Ontology. 2008 Third International Workshop on Semantic Media Adaptation and Personalization,
Cooper, L., Walls, R. L., Elser, J., Gandolfo, M. A., Stevenson, D. W., Smith, B., Preece, J., Athreya, B., Mungall, C. J., & Rensing, S. (2013). The plant ontology as a tool for comparative plant anatomy and genomic analyses. Plant and Cell Physiology, 54(2), e1-e1. https://doi.org/10.1093/pcp/pcs163
Du, Z., Zhou, X., Ling, Y., Zhang, Z., & Su, Z. (2010). agriGO: a GO analysis toolkit for the agricultural community. Nucleic acids research, 38(suppl_2), W64-W70. https://doi.org/10.1093/nar/gkq310
Forutani, S., Nowkarizi, M., Kiani, M. R., & Mokhtari Aski, H. R. (2018). The role of rural libraries in preserving the indigenous knowledge of rural residents: The case of South Khorasan Province. World Journal of Science, Technology and Sustainable Development, 15(3), 245-256. https://doi.org/10.1108/WJSTSD-12-2017-0044
Forutani, S., Nowkarizi, M., Kiani, M. R., & Mokhtari Aski, H. R. (2018). Providing a proposed protocol to preserve indigenous knowledge in rural libraries. Library and Information Science Research, 8(2), 243-263. https://doi.org/10.22067/riis.v0i0.65302 [In Persian]
Ghosh, H., Poornachander, P., Mallik, A., & Chaudhury, S. (2007). Learning ontology for personalized video retrieval Workshop on multimedia information retrieval on The many faces of multimedia semantics, Augsburg, Bavaria, Germany. https://doi.org/10.1145/1290067.1290075
Gyasi, E. (2001). Managing Diversity In The Agricultural Landscape Case Study-Ghana Managing Biodiversity in Agricultural Ecosystems International Symposium, Montreal, Canada. https://archive.unu.edu/env/plec/cbd/Montreal/abstracts/Gyasi.pdf
Indika, A., Ginige, A., & Wikramanayake, G. (2016). Developing a community-based knowledge system: a case study using Sri Lankan agriculture. International Journal on Advances in ICT for Emerging Regions (ICTer), 8, 1. https://doi.org/10.4038/icter.v8i3.7164
Jebaraj, J., & Sathiaseelan, J. (2017). An Exploratory Study on Agriculture Ontology: A Global Perspective. International Journal of Advanced Research in Computer Science and Software Engineering, 7(6), 202-206. https://doi.org/10.23956/ijarcsse/V7I6/0148
Kazi Tani, M.Y, Ghomari, A, Lablack, A, Bilasco, A. M. (2017). OVIS: ontology video surveillance indexing and retrieval system. Int J Multimed Info Retr (2017) 6:295–316. DOI 10.1007/s13735-017-0133-z
Li, J., Ding, Y., Shi, Y., & Zhang, J. (2010). Building a large annotation ontology for movie video retrieval. International Journal of Digital Content Technology and its Applications, 4(5), 74-81. https://doi.org/http://dx.doi.org/10.4156/jdcta.vol4.issue5.8
Mekonen, S. (2017). Roles of traditional ecological knowledge for biodiversity conservation. Journal of Natural Sciences Research, 7(15), 21-27. https://core.ac.uk/download/pdf/234657468.pdf
Mustapha, S. M. F. D. S., & Ukpe, E. (2013). Agriculture Ontology for Sustainable Development in Nigeria. Advances in Computing, 3(3), 57-59. https://doi.org/10.5923/j.ac.20130303.04
Pokharel, S., Sherif, M. A., & Lehmann, J. (2014). Ontology based data access and integration for improving the effectiveness of farming in nepal. 2014 IEEE/WIC/ACM International Joint Conferences on Web Intelligence (WI) and Intelligent Agent Technologies (IAT),
Sahri, Z., Nordin, S., & Harun, H. (2012). Malaysia indigenous herbs knowledge representation. https://repo.uum.edu.my/id/eprint/11056/1/CR130.pdf
Sikos, L. F. (2018) VidOnt: a core reference ontology for reasoning over video scenes, Journal of Information and Telecommunication, 2:2, 192-204, DOI:10.1080/24751839.2018.1437696
Simou, N., Tzouvaras, V., Avrithis, Y., Stamou, G., & Kollias, S. (2005). A visual descriptor ontology for multimedia reasoning. https://doi.org/10.1007/11738695_8
Soergel, D., Lauser, B., Liang, A., Fisseha, F., Keizer, J., & Katz, S. (2004). Reengineering thesauri for new applications: the AGROVOC example. Journal of digital information, 4, 1-23. http://eprints.rclis.org/15694/
Thenmozhi, D., & Aravindan, C. (2018). Ontology-based Tamil–English cross-lingual information retrieval system. Sādhanā, 43(10), 157. https://doi.org/10.1007/s12046-018-0942-7
Tian, T., Liu, Y., Yan, H., You, Q., Yi, X., Du, Z., Xu, W., & Su, Z. (2017). agriGO v2. 0: a GO analysis toolkit for the agricultural community, 2017 update. Nucleic acids research, 45(W1), W122-W129. https://doi.org/10.1093/nar/gkx382
Van Der Pol, F., & Nederlof, S. (2010). Natural Resource Management in West Africa: Towards a Knowledge Management Strategy. ‎ KIT Publishers. https://www.amazon.com/Natural-Resource-Management-West-Africa/dp/9460220940#detailBullets_feature_div
Wei, Y.-y., Wang, R.-j., Hu, Y.-m., & Xue, W. (2012). From web resources to agricultural ontology: a method for semi-automatic construction. Journal of Integrative Agriculture, 11(5), 775-783. https://doi.org/10.1016/S2095-3119(12)60067-7
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