Intra-field crop yield variability by assimilating cubesat lai in the apsim crop model
Intra-field crop yield variability by assimilating cubesat lai in the apsim crop model
Predicting within-field crop yield early in the season can help address crop production challenges to improve farmers' economic return. While yield prediction with remote sensing has been a research aim for years, it is only recently that observations with the suited spatial and temporal resolutions have become accessible to improve crop yield predictions. Here we developed a yield prediction framework that integrates daily high-resolution (3 m) CubeSat imagery into the APSIM crop model. The approach trains a regression model that correlates simulated yield to simulated leaf area index (LAI) from APSIM. That relationship is then employed to determine the optimum date at which the regression best predicts yield from the LAI. Additionally, our approach can forecast crop yield by utilizing a particle filter to assimilate CubeSat-based LAI in the model APSIM to generate yield maps at 3 m several weeks before the optimum regression date. Our method was evaluated for a rainfed site located in the US Corn belt, using a collection of spatially varying yield data. The proposed approach does not need in situ data to rain the regression, with outcomes reporting that even with a single assimilation step, accurate yield predictions were provided up to 21 days before the optimum regression date. The spatial variability of crop yield was reproduced fairly well, with a good correlation against in situ measurements (R2 Combining double low line 0.73 and RMSE Combining double low line 1.69), demonstrating that high-resolution yield predictions early in the season have great potential to meet and improve upon digital agricultural goals.
APSIM, Crop modeling, Crop yield prediction, CubeSat, LAI, Particle filter
1045-1052
Ziliani, M. G.
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Altaf, M. U.
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Aragon, B.
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Houborg, R.
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Franz, T. E.
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Lu, Y.
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Sheffield, J.
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Hoteit, I.
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McCabe, M. F.
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30 May 2022
Ziliani, M. G.
d2034537-1e6a-4b97-8d45-43e870f1dc22
Altaf, M. U.
69b3da0e-be4b-4cfc-87d0-10d20ba9e203
Aragon, B.
eefbf0ec-d571-4a1f-be10-a532b772ce07
Houborg, R.
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Franz, T. E.
104c40b7-8da2-4af6-9f32-d6f2fe0541eb
Lu, Y.
5b66e605-28ae-42cd-8c1c-c0e9b93bbcb8
Sheffield, J.
dd66575b-a4dc-4190-ad95-df2d6aaaaa6b
Hoteit, I.
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McCabe, M. F.
728c3adf-8316-4a9f-9409-a5b0a2125482
Ziliani, M. G., Altaf, M. U., Aragon, B., Houborg, R., Franz, T. E., Lu, Y., Sheffield, J., Hoteit, I. and McCabe, M. F.
(2022)
Intra-field crop yield variability by assimilating cubesat lai in the apsim crop model.
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences - ISPRS Archives, 43-B3 (B3-2022), .
(doi:10.5194/isprs-archives-XLIII-B3-2022-1045-2022).
Abstract
Predicting within-field crop yield early in the season can help address crop production challenges to improve farmers' economic return. While yield prediction with remote sensing has been a research aim for years, it is only recently that observations with the suited spatial and temporal resolutions have become accessible to improve crop yield predictions. Here we developed a yield prediction framework that integrates daily high-resolution (3 m) CubeSat imagery into the APSIM crop model. The approach trains a regression model that correlates simulated yield to simulated leaf area index (LAI) from APSIM. That relationship is then employed to determine the optimum date at which the regression best predicts yield from the LAI. Additionally, our approach can forecast crop yield by utilizing a particle filter to assimilate CubeSat-based LAI in the model APSIM to generate yield maps at 3 m several weeks before the optimum regression date. Our method was evaluated for a rainfed site located in the US Corn belt, using a collection of spatially varying yield data. The proposed approach does not need in situ data to rain the regression, with outcomes reporting that even with a single assimilation step, accurate yield predictions were provided up to 21 days before the optimum regression date. The spatial variability of crop yield was reproduced fairly well, with a good correlation against in situ measurements (R2 Combining double low line 0.73 and RMSE Combining double low line 1.69), demonstrating that high-resolution yield predictions early in the season have great potential to meet and improve upon digital agricultural goals.
Text
isprs-archives-XLIII-B3-2022-1045-2022
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Published date: 30 May 2022
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Publisher Copyright:
© Authors 2022
Venue - Dates:
2022 24th ISPRS Congress on Imaging Today, Foreseeing Tomorrow, Commission III, , Nice, France, 2022-06-06 - 2022-06-11
Keywords:
APSIM, Crop modeling, Crop yield prediction, CubeSat, LAI, Particle filter
Identifiers
Local EPrints ID: 471535
URI: http://eprints.soton.ac.uk/id/eprint/471535
ISSN: 1682-1750
PURE UUID: c7a74bf4-ce0e-4cb0-ac72-74544cb3b804
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Date deposited: 10 Nov 2022 17:34
Last modified: 17 Mar 2024 03:40
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Contributors
Author:
M. G. Ziliani
Author:
M. U. Altaf
Author:
B. Aragon
Author:
R. Houborg
Author:
T. E. Franz
Author:
Y. Lu
Author:
I. Hoteit
Author:
M. F. McCabe
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