HiResNet: A Low-to-High Deep Learning Framework for Updating Large-Scale Land Cover Inventory. Mohammadimanesh, F., Marjani, M., & Mahdianpari, M. IEEE Transactions on Geoscience and Remote Sensing, 64:1–20, 2026.
HiResNet: A Low-to-High Deep Learning Framework for Updating Large-Scale Land Cover Inventory [link]Paper  doi  abstract   bibtex   
Large-scale land cover (LC) mapping is critical for monitoring Earth’s surface and managing environmental changes. While machine learning (ML) and deep learning (DL) methods have significantly advanced LC mapping efforts, the reliance on high-quality training labels remains a major limitation due to their time-intensive and costly collection process. To address this challenge, we propose HiResNet, a novel DL framework that combines a multiscale feature extractor (MSFE) within convolutional neural networks (CNNs), a vision transformer (ViT) architecture, and a weakly-supervised loss function, to produce a 10 m LC map using an existing low-resolution (LR) 30 m LC map. In particular, this framework reduces the dependence on high-resolution (HR) training labels while generating HR (10 m) LC maps using Sentinel-2 imagery and LR 30 m labels. The capability of the proposed method is evaluated in the province of Ontario (ON), Canada, a region characterized by a diverse landscape and different LC types, covering approximately 1.07 million km2. The results demonstrate a remarkable capability of the proposed model to enhance spatial resolution and achieve high classification accuracy, with an overall accuracy (OA) of 89% for large-scale LC classification. Compared to conventional methods and advanced DL architectures, such as Random Forest (RF), ViT, HRNet, SegFormer, DeepLabV3, and L2HNet, the proposed method exhibits a superior performance by handling class imbalances and extracting complex features. Furthermore, uncertainty estimation using Shannon entropy and class disagreement metrics demonstrates that the highest levels of uncertainty are associated with object edges, narrow features (e.g., rivers and roads), and complex LC classes like forests.
@article{mohammadimanesh_hiresnet_2026,
	title = {{HiResNet}: {A} {Low}-to-{High} {Deep} {Learning} {Framework} for {Updating} {Large}-{Scale} {Land} {Cover} {Inventory}},
	volume = {64},
	issn = {1558-0644},
	shorttitle = {{HiResNet}},
	url = {https://ieeexplore.ieee.org/document/11460176},
	doi = {10.1109/TGRS.2026.3676677},
	abstract = {Large-scale land cover (LC) mapping is critical for monitoring Earth’s surface and managing environmental changes. While machine learning (ML) and deep learning (DL) methods have significantly advanced LC mapping efforts, the reliance on high-quality training labels remains a major limitation due to their time-intensive and costly collection process. To address this challenge, we propose HiResNet, a novel DL framework that combines a multiscale feature extractor (MSFE) within convolutional neural networks (CNNs), a vision transformer (ViT) architecture, and a weakly-supervised loss function, to produce a 10 m LC map using an existing low-resolution (LR) 30 m LC map. In particular, this framework reduces the dependence on high-resolution (HR) training labels while generating HR (10 m) LC maps using Sentinel-2 imagery and LR 30 m labels. The capability of the proposed method is evaluated in the province of Ontario (ON), Canada, a region characterized by a diverse landscape and different LC types, covering approximately 1.07 million km2. The results demonstrate a remarkable capability of the proposed model to enhance spatial resolution and achieve high classification accuracy, with an overall accuracy (OA) of 89\% for large-scale LC classification. Compared to conventional methods and advanced DL architectures, such as Random Forest (RF), ViT, HRNet, SegFormer, DeepLabV3, and L2HNet, the proposed method exhibits a superior performance by handling class imbalances and extracting complex features. Furthermore, uncertainty estimation using Shannon entropy and class disagreement metrics demonstrates that the highest levels of uncertainty are associated with object edges, narrow features (e.g., rivers and roads), and complex LC classes like forests.},
	urldate = {2026-05-27},
	journal = {IEEE Transactions on Geoscience and Remote Sensing},
	author = {Mohammadimanesh, Fariba and Marjani, Mohammad and Mahdianpari, Masoud},
	year = {2026},
	keywords = {NALCMS},
	pages = {1--20},
}
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