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Geocarto International Volume 38, 2023 - Issue 1
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Research Article

Sunflower crop yield prediction by advanced statistical modeling using satellite-derived vegetation indices and crop phenology

Khilola Amankulovaa Department of Geoinformatics, Physical and Environmental Geography, University of Szeged, Szeged, Hungary;b “Tashkent Institute of Irrigation and Agricultural Mechanization Engineers” National Research University, Tashkent, UzbekistanCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0001-6562-5616View further author information
ORCID Icon,
Nizom Farmonova Department of Geoinformatics, Physical and Environmental Geography, University of Szeged, Szeged, Hungary;b “Tashkent Institute of Irrigation and Agricultural Mechanization Engineers” National Research University, Tashkent, UzbekistanORCID Iconhttps://orcid.org/0000-0002-2491-9340View further author information
ORCID Icon,
Uzbekkhon Mukhtorovb “Tashkent Institute of Irrigation and Agricultural Mechanization Engineers” National Research University, Tashkent, UzbekistanORCID Iconhttps://orcid.org/0000-0002-8748-4129View further author information
ORCID Icon &
László Mucsia Department of Geoinformatics, Physical and Environmental Geography, University of Szeged, Szeged, HungaryORCID Iconhttps://orcid.org/0000-0002-5807-3742View further author information
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Article: 2197509 | Received 25 Oct 2022, Accepted 27 Mar 2023, Published online: 03 Apr 2023

References

  • Adeleke BS, Babalola OO. 2020. Oilseed crop sunflower (Helianthus annuus) as a source of food: nutritional and health benefits. Food Sci Nutr. 8(9):4666–4684.
  • Amankulova K, Farmonov N, Gudmann A, Mucsi L. 2021. Investigation the reason of affected Hybrid Corn in Agricultural Fields by Using Multi-Temporal Sentinel-2 Images in Mezőhegyes, South-Eastern Hungary.
  • Amankulova K, Farmonov N, Mucsi L. 2023. Time-series analysis of Sentinel-2 satellite images for sunflower yield estimation. Smart Agric Technol. 3:100098. https://doi.org/10.1016/j.atech.2022.100098.
  • Andrianasolo FN, Casadebaig P, Maza E, Champolivier L, Maury P, Debaeke P. 2014. Prediction of sunflower grain oil concentration as a function of variety, crop management and environment using statistical models. Eur J Agron. 54:84–96.
  • Bell MA. 1994. Guide to plant and crops sampling: measurements and observations for agronomic and physiological research in small grain cereals. Mexico: CIMMYT.
  • Blackmore BS, Marshall CJ. 2015. Yield mapping; errors and algorithms. In: robert PC, Rust RH, Larson WE., editors, ASA, CSSA, and SSSA Books. Madison, WI, USA: American Society of Agronomy, Crop Science Society of America, Soil Science Society of America; p. 403–415.
  • Breiman L. 2001. Random forests. ]Mach Learn. 45(1):5–32.
  • Bolton DK, Friedl MA. 2013. Forecasting crop yield using remotely sensed vegetation indices and crop phenology metrics. Agric For Meteorol. 173:74–84.
  • Chen X, Feng L, Yao R, Wu X, Sun J, Gong W. 2021. Prediction of maize yield at the city level in China using multi-source data. Remote Sens. 13(1):146.
  • Das AC, Noguchi R, Ahamed T. 2021. An assessment of drought stress in tea estates using optical and thermal remote sensing. Remote Sens. 13(14):2730.
  • European Space Agency. STEP—Science Toolbox Exploitation Platform. [accessed 2021 Feb 15] 362. http://step.esa.int.
  • Fieuzal R, Marais Sicre C, Baup F. 2017. Estimation of sunflower yield using a simplified agrometeorological model controlled by optical and SAR satellite data. IEEE J Sel Top Appl Earth Observ Remote Sens. 10(12):5412–5422.
  • Ghosh P, Mandal D, Bhattacharya A, Nanda MK, Bera S. 2018. Assessing crop monitoring potential of sentinel-2 in a spatio-temporal scale. Int Arch Photogramm Remote Sens Spatial Inf Sci. XLII–5:227–231. https://doi.org/10.5194/isprsarchives-XLII-5-227-2018
  • Gitelson AA, Kaufman YJ, Merzlyak MN. 1996. Use of a green channel in remote sensing of global vegetation from EOS-MODIS. Remote Sens Environ. 58(3):289–298.
  • Guo Y, Fu Y, Hao F, Zhang X, Wu W, Jin X, Robin Bryant C, Senthilnath J. 2021. Integrated phenology and climate in rice yields prediction using machine learning methods. Ecol Indic. 120:106935.
  • Haerani H, Apan A, Basnet B. 2018. Mapping of peanut crops in Queensland, Australia, using time-series PROBA-V 100-m normalized difference vegetation index imagery. J Appl Remote Sens. 12(03):1.
  • Huang J, Wang X, Li X, Tian H, Pan Z. 2013. Remotely sensed rice yield prediction using multi-temporal NDVI data derived from NOAA’s-AVHRR. PLoS ONE. 8(8):e70816.
  • Huete A, Didan K, Miura T, Rodriguez EP, Gao X, Ferreira LG. 2002. Overview of the radiometric and biophysical performance of the MODIS vegetation indices. Remote Sens Environ. 83(1-2):195–213.
  • Huete AR. 1988. A soil-adjusted vegetation index (SAVI). Remote Sens Environ. 25(3):295–309.
  • Hunt ML, Blackburn GA, Carrasco L, Redhead JW, Rowland CS. 2019. High resolution wheat yield mapping using Sentinel-2. Remote Sens Environ. 233:111410.
  • Jaafar HH, Ahmad FA. 2015. Crop yield prediction from remotely sensed vegetation indices and primary productivity in arid and semi-arid lands. Int J Remote Sens. 36(18):4570–4589.
  • Jeong JH, Resop JP, Mueller ND, Fleisher DH, Yun K, Butler EE, Timlin DJ, Shim K-M, Gerber JS, Reddy VR, et al. 2016. Random forests for global and regional crop yield predictions. Plos One. 11(6):e0156571.
  • Jin X, Kumar L, Li Z, Xu X, Yang G, Wang J. 2016. Estimation of winter wheat biomass and yield by combining the AquaCrop model and field hyperspectral data. Remote Sens. 8(12):972.
  • Kayad A, Sozzi M, Gatto S, Marinello F, Pirotti F. 2019. Monitoring within-field variability of corn yield using sentinel-2 and machine learning techniques. Remote Sens. 11(23):2873.
  • Kayad AG, Al-Gaadi KA, Tola E, Madugundu R, Zeyada AM, Kalaitzidis C. 2016. Assessing the spatial variability of alfalfa yield using satellite imagery and ground-based data. Plos One. 11(6):e0157166.
  • Khaki S, Wang L. 2019. Crop yield prediction using deep neural networks. Front Plant Sci. 10:621.
  • Kharel TP, Maresma A, Czymmek KJ, Oware EK, Ketterings QM. 2019. Combining spatial and temporal corn silage yield variability for management zone development. Agron J. 111(6):2703–2711.
  • Kim N, Lee Y-W. 2016. Machine learning approaches to corn yield estimation using satellite images and climate data: a case of Iowa State. J. Korean Soc. Surv. Geod. Photogramm. Cartogr. 34(4):383–390.
  • Li W, Weiss M, Waldner F, Defourny P, Demarez V, Morin D, Hagolle O, Baret F. 2015. A Generic algorithm to estimate LAI, FAPAR and FCOVER variables from SPOT4_HRVIR and landsat sensors: evaluation of the consistency and comparison with ground measurements. Remote Sens. 7(11):15494–15516.
  • Liaw A, Wiener M, Breimann L, Cutler A. 2018. Randomforest: breiman and Cutler’s random forests for classification and regression. [accessed 2021 Jan 15]. https://cran.r-project.org/web/packages/randomForest/randomForest.pdf
  • Lancashire PD, Bleiholder H, Boom TVD, Langelüddeke P, Stauss R, Weber E, Witzenberger A. 1991. A uniform decimal code for growth stages of crops and weeds. Ann Appl Biol. 119(3):561–601.
  • Lokupitiya E, Denning S, Paustian K, Baker I, Schaefer K, Verma S, Meyers T, Bernacchi CJ, Suyker A, Fischer M. 2009. Incorporation of crop phenology in Simple Biosphere Model (SiBcrop) to improve land-atmosphere carbon exchanges from croplands. Biogeosciences. 6(6):969–986.
  • Micheneau A, Champolivier L, Dejoux J-F, Ahmad AB, Pontet C, et al. 2017. Predicting sunflower grain yield using remote sensing data and statistical models. 2017 EFITA WCCA Congress, Jul 2017, Montpellier, France. 254 p. ffhal-02737612f.
  • Mitchell JJ, Glenn NF, Sankey TT, Derryberry DR, Germino MJ. 2012. Remote sensing of sagebrush canopy nitrogen. Remote Sens Environ. 124:217–223.
  • Narin OG, Abdikan S. 2022. Monitoring of phenological stage and yield estimation of sunflower plant using Sentinel-2 satellite images. Geocarto Int. 37(5):1378–1392.
  • Narin OG, Sekertekin A, Saygin A, Balik Sanli F, Gullu M. 2021. Yield estimation of sunflower plant with CNN and ANN using sentinel-2. Int Arch Photogramm Remote Sens Spatial Inf Sci. XLVI-4/W5-2021:385–389.
  • OECD, Food and Agriculture Organization of the United Nations. 2016. OECD-FAO Agricultural Outlook 2016-2025, OECD-FAO Agricultural Outlook. OECD.
  • Operational drought and water scarcity management system (OVF). [accessed 2022 Feb 15]. https://aszalymonitoring.vizugy.hu/
  • Open Access Hub. [accessed 2021 Sep 1]. https://scihub.copernicus.eu/..
  • Pal US, Patra RK, Sahoo NR, Bakhara CK, Panda MK. 2015. Effect of refining on quality and composition of sunflower oil. J Food Sci Technol. 52(7):4613–4618.
  • Panda SS, Ames DP, Panigrahi S. 2010. Application of vegetation indices for agricultural crop yield prediction using neural network techniques. Remote Sens. 2(3):673–696.
  • Panek E, Gozdowski D. 2020. Analysis of relationship between cereal yield and NDVI for selected regions of Central Europe based on MODIS satellite data. Remote Sens Appl Soc Environ. 17:100286.
  • Piragnolo M, Masiero A, Pirotti F. 2017. Open source R for applying machine learning to RPAS remote sensing images. Open Geospatial Data Softw Stand. 2:16.
  • Pirotti F, Sunar F, Piragnolo M. 2016. Benchmark of machine learning methods for classification of a sentinel-2 image. Int Arch Photogramm Remote Sens Spatial Inf Sci. XLI-B7:335–340.
  • Ruml M, Vulic T. 2005. Importance of phenological observations and predictions in agriculture. J Agric Sci BGD. 50(2):217–225.
  • Satir O, Berberoglu S. 2016. Crop yield prediction under soil salinity using satellite derived vegetation indices. Field Crops Res. 192:134–143.
  • Schwalbert RA, Amado T, Corassa G, Pott LP, Prasad PVV, Ciampitti IA. 2020. Satellite-based soybean yield forecast: integrating machine learning and weather data for improving crop yield prediction in southern Brazil. Agric For Meteorol. 284:107886.
  • Shammi SA, Meng Q. 2021. Use time series NDVI and EVI to develop dynamic crop growth metrics for yield modeling. Ecol Indic. 121:107124.
  • Singh R, Semwal DP, Rai A, Chhikara RS. 2002. Small area estimation of crop yield using remote sensing satellite data. Int J Remote Sens. 23(1):49–56.
  • Sakamoto T, Gitelson AA, Arkebauer TJ. 2013. MODIS-based corn grain yield estimation model incorporating crop phenology information. Remote Sens Environ. 131:215–231.
  • Szabó S, Szopos NM, Bertalan-Balázs B, László E, Milošević DD, Conoscenti C, Lázár I. 2019. Geospatial analysis of drought tendencies in the carpathians as reflected in a 50-year time series. HunGeoBull; 68(3):269–282.
  • Thylén L, Murphy DPL. 1996. The control of errors in momentary yield data from combine harvesters. J Agric Eng Res. 64(4):271–278.
  • Trépos R, Champolivier L, Dejoux J-F, Al Bitar A, Casadebaig P, Debaeke P. 2020. Forecasting sunflower grain yield by assimilating leaf area index into a crop model. Remote Sens. 12(22):3816.
  • Tucker CJ. 1979. Red and photographic infrared linear combinations for monitoring vegetation. Remote Sens Environ. 8(2):127–150.
  • Wang AX, Tran C, Desai N, Lobell D, Ermon S. 2018. Deep Transfer Learning for Crop Yield Prediction with Remote Sensing Data. In Proceedings of the 1st ACM SIGCAS Conference on Computing and Sustainable Societies. ACM, Menlo Park, Netherlands and San Jose CA USA; p. 1–5.
  • Wang M, Tao F, Shi W. 2014. Corn yield forecasting in Northeast China using remotely sensed spectral indices and crop phenology metrics. J Integr Agric. 13(7):1538–1545.
  • Xue J, Su B. 2017. Significant remote sensing vegetation indices: a review of developments and applications. J Sens. 2017:1–17.
  • Zhou J, Khot LR, Bahlol HY, Boydston R, Miklas PN. 2016. Evaluation of ground, proximal and aerial remote sensing technologies for crop stress monitoring. IFAC-Pap. 49:22–26.

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