toplogo
Logg Inn

Efficient Building Footprint Extraction from High-resolution Remote Sensing Images via Progressive Lenient Supervision


Grunnleggende konsepter
The proposed BFSeg framework achieves consistent and high performance gain with little computational cost across multiple advanced backbone networks by utilizing a lightweight and effective decoder design and a lenient deep supervision and distillation strategy.
Sammendrag

The paper presents an efficient building footprint segmentation framework called BFSeg to address the challenges in transferring advanced encoder networks to remote sensing tasks.

Key highlights:

  • BFSeg proposes a densely connected coarse-to-fine feature fusion decoder network (LightFPN) that facilitates easy and fast feature fusion across scales, enabling effective transfer of advanced backbone networks.
  • To address the invalid model learning issues caused by inaccurate boundary regions in down-sampled ground truth during deep supervision, BFSeg introduces a lenient deep supervision and distillation strategy that focuses the model on learning from proper regions.
  • Extensive experiments on three large-scale building datasets demonstrate that BFSeg consistently outperforms state-of-the-art methods in both performance and efficiency across a wide range of advanced backbone networks.
edit_icon

Tilpass sammendrag

edit_icon

Omskriv med AI

edit_icon

Generer sitater

translate_icon

Oversett kilde

visual_icon

Generer tankekart

visit_icon

Besøk kilde

Statistikk
The efficacy of building footprint segmentation from remotely sensed images has been hindered by model transfer effectiveness. Many existing building segmentation methods were developed upon the encoder-decoder architecture, in which the encoder is finetuned from the newly developed backbone networks that are pre-trained on ImageNet. The heavy computational burden of the existing decoder designs hampers the successful transfer of these modern encoder networks to remote sensing tasks.
Sitater
"The efficacy of building footprint segmentation from remotely sensed images has been hindered by model transfer effectiveness." "The heavy computational burden of the existing decoder designs hampers the successful transfer of these modern encoder networks to remote sensing tasks."

Dypere Spørsmål

How can the proposed BFSeg framework be extended to other remote sensing tasks beyond building footprint extraction

The proposed BFSeg framework can be extended to other remote sensing tasks beyond building footprint extraction by adapting the architecture and strategies to suit the specific requirements of the new tasks. For instance, for tasks like land cover classification, vegetation mapping, or object detection in remote sensing images, BFSeg can be modified to incorporate different output layers and loss functions tailored to the specific classes or objects of interest. Additionally, the feature fusion and refinement mechanisms within BFSeg can be adjusted to capture the unique characteristics of different remote sensing tasks, such as texture patterns, spectral signatures, or spatial relationships. By customizing the framework to address the specific challenges and objectives of each task, BFSeg can be effectively applied to a wide range of remote sensing applications.

What are the potential limitations of the lenient deep supervision and distillation strategy, and how can they be addressed in future research

The lenient deep supervision and distillation strategy may have potential limitations, such as the risk of oversimplifying the learning process by masking impure regions. This could lead to the model missing out on valuable information from challenging areas that could contribute to improved performance. To address this limitation, future research could explore adaptive masking techniques that dynamically adjust the leniency of supervision based on the difficulty of the regions. Additionally, incorporating uncertainty estimation methods could help the model identify and focus on areas where it is uncertain, allowing for more targeted learning and better utilization of the available data. By refining the lenient strategy to adapt to the complexity and variability of the data, the model can achieve more robust and accurate learning outcomes.

What other techniques beyond the encoder-decoder architecture could be explored to further improve the efficiency and effectiveness of building footprint extraction from high-resolution remote sensing images

Beyond the encoder-decoder architecture, other techniques that could be explored to enhance the efficiency and effectiveness of building footprint extraction from high-resolution remote sensing images include: Attention Mechanisms: Introducing attention mechanisms can help the model focus on relevant spatial regions and features, improving the accuracy of building extraction by giving more weight to important areas. Graph Neural Networks: Utilizing graph neural networks can capture spatial dependencies and relationships between building pixels, enhancing the model's ability to understand the context and structure of buildings in the image. Reinforcement Learning: Incorporating reinforcement learning techniques can enable the model to learn optimal policies for building extraction tasks, allowing for adaptive and dynamic decision-making during the segmentation process. Generative Adversarial Networks (GANs): Leveraging GANs can aid in generating more realistic and detailed building footprints, improving the quality and fidelity of the extracted building boundaries in remote sensing images. By exploring these alternative techniques and integrating them into the existing framework, researchers can further advance the capabilities of building footprint extraction from high-resolution remote sensing data.
0
star