Leveraging Remote Sensing Data for Yield Prediction with Deep Transfer Learning

Huber, Florian; Inderka, Alvin; Steinhage, Volker

doi:10.3390/s24030770

Cited by 4 publications

(1 citation statement)

References 33 publications

(52 reference statements)

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“…The paradigm of transfer learning, in which pretrained models serve as the backbone for high-level vision tasks, has become a fundamental approach in the fields of segmentation and object detection [34][35][36][37][38][39]. This section provides a rigorous mathematical formulation of how this methodology is adapted for these specific tasks.…”

Section: Transfer Learning As a Foundation For Segmentation And Objec...mentioning

confidence: 99%

Deep Transfer Learning Using Real-World Image Features for Medical Image Classification, with a Case Study on Pneumonia X-ray Images

Gu,

Lee

2024

Bioengineering

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Deep learning has profoundly influenced various domains, particularly medical image analysis. Traditional transfer learning approaches in this field rely on models pretrained on domain-specific medical datasets, which limits their generalizability and accessibility. In this study, we propose a novel framework called real-world feature transfer learning, which utilizes backbone models initially trained on large-scale general-purpose datasets such as ImageNet. We evaluate the effectiveness and robustness of this approach compared to models trained from scratch, focusing on the task of classifying pneumonia in X-ray images. Our experiments, which included converting grayscale images to RGB format, demonstrate that real-world-feature transfer learning consistently outperforms conventional training approaches across various performance metrics. This advancement has the potential to accelerate deep learning applications in medical imaging by leveraging the rich feature representations learned from general-purpose pretrained models. The proposed methodology overcomes the limitations of domain-specific pretrained models, thereby enabling accelerated innovation in medical diagnostics and healthcare. From a mathematical perspective, we formalize the concept of real-world feature transfer learning and provide a rigorous mathematical formulation of the problem. Our experimental results provide empirical evidence supporting the effectiveness of this approach, laying the foundation for further theoretical analysis and exploration. This work contributes to the broader understanding of feature transferability across domains and has significant implications for the development of accurate and efficient models for medical image analysis, even in resource-constrained settings.

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