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Multi-Region Transfer Learning for Segmentation of Crop Field Boundaries in Satellite Images with Limited Labels (2404.00179v1)

Published 29 Mar 2024 in cs.CV and cs.LG

Abstract: The goal of field boundary delineation is to predict the polygonal boundaries and interiors of individual crop fields in overhead remotely sensed images (e.g., from satellites or drones). Automatic delineation of field boundaries is a necessary task for many real-world use cases in agriculture, such as estimating cultivated area in a region or predicting end-of-season yield in a field. Field boundary delineation can be framed as an instance segmentation problem, but presents unique research challenges compared to traditional computer vision datasets used for instance segmentation. The practical applicability of previous work is also limited by the assumption that a sufficiently-large labeled dataset is available where field boundary delineation models will be applied, which is not the reality for most regions (especially under-resourced regions such as Sub-Saharan Africa). We present an approach for segmentation of crop field boundaries in satellite images in regions lacking labeled data that uses multi-region transfer learning to adapt model weights for the target region. We show that our approach outperforms existing methods and that multi-region transfer learning substantially boosts performance for multiple model architectures. Our implementation and datasets are publicly available to enable use of the approach by end-users and serve as a benchmark for future work.

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Gorelick, N.; Hancher, M.; Dixon, M.; Ilyushchenko, S.; Thau, D.; and Moore, R. 2017. Google Earth Engine: Planetary-scale geospatial analysis for everyone. Remote Sensing of Environment. Kerner et al. (2022) Kerner, H. R.; Sahajpal, R.; Pai, D. B.; Skakun, S.; Puricelli, E.; Hosseini, M.; Meyer, S.; and Becker-Reshef, I. 2022. Phenological normalization can improve in-season classification of maize and soybean: A case study in the central US Corn Belt. Science of Remote Sensing, 100059. Meyer, Lemarchand, and Sidiropoulos (2020) Meyer, L.; Lemarchand, F.; and Sidiropoulos, P. 2020. A deep learning architecture for batch-mode fully automated field boundary detection. The International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, 43: 1009–1016. Nakalembe and Kerner (2022) Nakalembe, C.; and Kerner, H. 2022. Applications and Considerations for AI-EO for Agriculture in Sub-Saharan Africa. In AAAI Conference on Artificial Intelligence International Workshop on Social Impact of AI for Africa. North, Pairman, and Belliss (2018) North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Kerner, H. R.; Sahajpal, R.; Pai, D. B.; Skakun, S.; Puricelli, E.; Hosseini, M.; Meyer, S.; and Becker-Reshef, I. 2022. Phenological normalization can improve in-season classification of maize and soybean: A case study in the central US Corn Belt. Science of Remote Sensing, 100059. Meyer, Lemarchand, and Sidiropoulos (2020) Meyer, L.; Lemarchand, F.; and Sidiropoulos, P. 2020. A deep learning architecture for batch-mode fully automated field boundary detection. The International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, 43: 1009–1016. Nakalembe and Kerner (2022) Nakalembe, C.; and Kerner, H. 2022. Applications and Considerations for AI-EO for Agriculture in Sub-Saharan Africa. In AAAI Conference on Artificial Intelligence International Workshop on Social Impact of AI for Africa. North, Pairman, and Belliss (2018) North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Meyer, L.; Lemarchand, F.; and Sidiropoulos, P. 2020. A deep learning architecture for batch-mode fully automated field boundary detection. The International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, 43: 1009–1016. Nakalembe and Kerner (2022) Nakalembe, C.; and Kerner, H. 2022. Applications and Considerations for AI-EO for Agriculture in Sub-Saharan Africa. In AAAI Conference on Artificial Intelligence International Workshop on Social Impact of AI for Africa. North, Pairman, and Belliss (2018) North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Nakalembe, C.; and Kerner, H. 2022. Applications and Considerations for AI-EO for Agriculture in Sub-Saharan Africa. In AAAI Conference on Artificial Intelligence International Workshop on Social Impact of AI for Africa. North, Pairman, and Belliss (2018) North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27.
  8. Google Earth Engine: Planetary-scale geospatial analysis for everyone. Remote Sensing of Environment. Kerner et al. (2022) Kerner, H. R.; Sahajpal, R.; Pai, D. B.; Skakun, S.; Puricelli, E.; Hosseini, M.; Meyer, S.; and Becker-Reshef, I. 2022. Phenological normalization can improve in-season classification of maize and soybean: A case study in the central US Corn Belt. Science of Remote Sensing, 100059. Meyer, Lemarchand, and Sidiropoulos (2020) Meyer, L.; Lemarchand, F.; and Sidiropoulos, P. 2020. A deep learning architecture for batch-mode fully automated field boundary detection. The International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, 43: 1009–1016. Nakalembe and Kerner (2022) Nakalembe, C.; and Kerner, H. 2022. Applications and Considerations for AI-EO for Agriculture in Sub-Saharan Africa. In AAAI Conference on Artificial Intelligence International Workshop on Social Impact of AI for Africa. North, Pairman, and Belliss (2018) North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Kerner, H. R.; Sahajpal, R.; Pai, D. B.; Skakun, S.; Puricelli, E.; Hosseini, M.; Meyer, S.; and Becker-Reshef, I. 2022. Phenological normalization can improve in-season classification of maize and soybean: A case study in the central US Corn Belt. Science of Remote Sensing, 100059. Meyer, Lemarchand, and Sidiropoulos (2020) Meyer, L.; Lemarchand, F.; and Sidiropoulos, P. 2020. A deep learning architecture for batch-mode fully automated field boundary detection. The International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, 43: 1009–1016. Nakalembe and Kerner (2022) Nakalembe, C.; and Kerner, H. 2022. Applications and Considerations for AI-EO for Agriculture in Sub-Saharan Africa. In AAAI Conference on Artificial Intelligence International Workshop on Social Impact of AI for Africa. North, Pairman, and Belliss (2018) North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Meyer, L.; Lemarchand, F.; and Sidiropoulos, P. 2020. A deep learning architecture for batch-mode fully automated field boundary detection. The International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, 43: 1009–1016. Nakalembe and Kerner (2022) Nakalembe, C.; and Kerner, H. 2022. Applications and Considerations for AI-EO for Agriculture in Sub-Saharan Africa. In AAAI Conference on Artificial Intelligence International Workshop on Social Impact of AI for Africa. North, Pairman, and Belliss (2018) North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Nakalembe, C.; and Kerner, H. 2022. Applications and Considerations for AI-EO for Agriculture in Sub-Saharan Africa. In AAAI Conference on Artificial Intelligence International Workshop on Social Impact of AI for Africa. North, Pairman, and Belliss (2018) North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27.
  9. Phenological normalization can improve in-season classification of maize and soybean: A case study in the central US Corn Belt. Science of Remote Sensing, 100059. Meyer, Lemarchand, and Sidiropoulos (2020) Meyer, L.; Lemarchand, F.; and Sidiropoulos, P. 2020. A deep learning architecture for batch-mode fully automated field boundary detection. The International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, 43: 1009–1016. Nakalembe and Kerner (2022) Nakalembe, C.; and Kerner, H. 2022. Applications and Considerations for AI-EO for Agriculture in Sub-Saharan Africa. In AAAI Conference on Artificial Intelligence International Workshop on Social Impact of AI for Africa. North, Pairman, and Belliss (2018) North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Meyer, L.; Lemarchand, F.; and Sidiropoulos, P. 2020. A deep learning architecture for batch-mode fully automated field boundary detection. The International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, 43: 1009–1016. Nakalembe and Kerner (2022) Nakalembe, C.; and Kerner, H. 2022. Applications and Considerations for AI-EO for Agriculture in Sub-Saharan Africa. In AAAI Conference on Artificial Intelligence International Workshop on Social Impact of AI for Africa. North, Pairman, and Belliss (2018) North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Nakalembe, C.; and Kerner, H. 2022. Applications and Considerations for AI-EO for Agriculture in Sub-Saharan Africa. In AAAI Conference on Artificial Intelligence International Workshop on Social Impact of AI for Africa. North, Pairman, and Belliss (2018) North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27.
  10. A deep learning architecture for batch-mode fully automated field boundary detection. The International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, 43: 1009–1016. Nakalembe and Kerner (2022) Nakalembe, C.; and Kerner, H. 2022. Applications and Considerations for AI-EO for Agriculture in Sub-Saharan Africa. In AAAI Conference on Artificial Intelligence International Workshop on Social Impact of AI for Africa. North, Pairman, and Belliss (2018) North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Nakalembe, C.; and Kerner, H. 2022. Applications and Considerations for AI-EO for Agriculture in Sub-Saharan Africa. In AAAI Conference on Artificial Intelligence International Workshop on Social Impact of AI for Africa. North, Pairman, and Belliss (2018) North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). 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Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. North, H. C.; Pairman, D.; and Belliss, S. E. 2018. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. 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Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27.
  12. Boundary delineation of agricultural fields in multitemporal satellite imagery. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 12(1): 237–251. Persello et al. (2019) Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Persello, C.; Tolpekin, V.; Bergado, J. R.; and de By, R. A. 2019. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27.
  13. Delineation of agricultural fields in smallholder farms from satellite images using fully convolutional networks and combinatorial grouping. Remote Sensing of Environment, 231: 111253. Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (2021) (DLR)Planet, Radiant Earth Foundation, Western Cape Department of Agriculture, and German Aerospace Center (DLR). 2021. A Fusion Dataset for Crop Type Classification in Western Cape, South Africa (Version 1.0). PlantVillage (2019) PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27.
  14. PlantVillage. 2019. PlantVillage Kenya Ground Reference Crop Type Dataset (Version 1.0). Sadeh et al. (2019) Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Sadeh, Y.; Zhu, X.; Chenu, K.; and Dunkerley, D. 2019. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27.
  15. Sowing date detection at the field scale using CubeSats remote sensing. Computers and Electronics in Agriculture, 157: 568–580. Thomas et al. (2020) Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Thomas, N.; Neigh, C.; Carroll, M.; McCarty, J.; and Bunting, P. 2020. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27.
  16. Fusion approach for remotely-sensed mapping of agriculture (FARMA): A scalable open source method for land cover monitoring using data fusion. Remote Sensing, 12(20): 3459. Waldner and Diakogiannis (2020) Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Waldner, F.; and Diakogiannis, F. I. 2020. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27.
  17. Deep learning on edge: Extracting field boundaries from satellite images with a convolutional neural network. Remote Sensing of Environment, 245: 111741. Wang, Waldner, and Lobell (2022) Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Wang, S.; Waldner, F.; and Lobell, D. B. 2022. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27.
  18. Unlocking large-scale crop field delineation in smallholder farming systems with transfer learning and weak supervision. arXiv preprint arXiv:2201.04771. Watkins and Van Niekerk (2019) Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Watkins, B.; and Van Niekerk, A. 2019. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27.
  19. A comparison of object-based image analysis approaches for field boundary delineation using multi-temporal Sentinel-2 imagery. Computers and Electronics in Agriculture, 158: 294–302. Yan and Roy (2014) Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yan, L.; and Roy, D. 2014. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27.
  20. Automated crop field extraction from multi-temporal Web Enabled Landsat Data. Remote Sensing of Environment, 144: 42–64. Yosinski et al. (2014) Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27. Yosinski, J.; Clune, J.; Bengio, Y.; and Lipson, H. 2014. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27.
  21. How transferable are features in deep neural networks? Advances in Neural Information Processing Systems, 27.
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