Soferi_mix -

Deep learning models for medical imaging require massive training datasets to achieve high accuracy. However, gathering labeled medical data is costly and ethically complex. Data augmentation—the process of creating "new" samples from existing ones—is the primary solution. has emerged as a specialized technique to address the unique structural features of medical images, such as tumors or lesions, which are often analyzed in patches rather than whole-slide images. 2. Methodology

SoftMix operates on the principle of from different images to create a composite training sample. Unlike traditional "Mixup" (which blends images pixel-wise) or "CutMix" (which replaces a hard rectangular patch), SoftMix utilizes a "softer" approach to blending boundaries. Selection : Two images from the training set are selected. Patching : The images are divided into discrete patches. soferi_mix

Abstract

: The final label is a weighted average based on the proportion and "softness" of the patches included from each class. 3. Comparative Analysis Traditional Augmentation Technique Rotation/Flipping Hard patch replacement Soft-edged patch mixing Information Loss High (removes original data) Boundary Effects Sharp/Artificial Smooth/Natural Medical Context Often obscures small lesions Preserves contextual features 4. Results and Discussion Deep learning models for medical imaging require massive

Recent reviews of over 100 medical image augmentation papers indicate that methods like SoftMix significantly reduce in small datasets. In patched classification tasks—such as identifying malignant vs. benign tissue—SoftMix helps the model learn more generalized features by preventing it from relying on sharp, artificial edges created by other mixing techniques. 5. Conclusion has emerged as a specialized technique to address