Transferable Contextual Network for Rural Road Extraction from UAV-Based Remote Sensing Images

Transferable Contextual Network for Rural Road Extraction from UAV-Based Remote Sensing Images

Road extraction from UAV-based remote sensing images in rural areas presents significant challenges due to the diverse and complex characteristics of rural roads. Additionally, acquiring UAV remote sensing data for rural areas is challenging due to the high cost of equipment, the lack of clear road...

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Bibliographic Details
Main Authors: Jian Wang, Renlong Wang, Yahui Liu, Fei Zhang, Ting Cheng
Format: Article
Language:English
Published: MDPI AG 2025-02-01
Series:Sensors
Subjects:
remote sensing
rural road extraction
semantic segmentation
Stable Diffusion
Online Access:https://www.mdpi.com/1424-8220/25/5/1394
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Summary:Road extraction from UAV-based remote sensing images in rural areas presents significant challenges due to the diverse and complex characteristics of rural roads. Additionally, acquiring UAV remote sensing data for rural areas is challenging due to the high cost of equipment, the lack of clear road boundaries requiring extensive manual annotation, and limited regional policy support for UAV operations. To address these challenges, we propose a transferable contextual network (TCNet), designed to enhance the transferability and accuracy of rural road extraction. We employ a Stable Diffusion model for data augmentation, generating diverse training samples and providing a new method for acquiring remote sensing images. TCNet integrates the clustered contextual Transformer (CCT) module, clustered cross-attention (CCA) module, and CBAM attention mechanism to ensure efficient model transferability across different geographical and climatic conditions. Moreover, we design a new loss function, the Dice-BCE-Lovasz loss (DBL loss), to accelerate convergence and improve segmentation performance in handling imbalanced data. Experimental results demonstrate that TCNet, with only 23.67 M parameters, performs excellently on the DeepGlobe and road datasets and shows outstanding transferability in zero-shot testing on rural remote sensing data. TCNet performs well on segmentation tasks without any fine-tuning for regions such as Burgundy, France, and Yunnan, China.
ISSN:1424-8220

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