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innsikt - Machine Learning - # Data Augmentation with Generative Models

GeNIe: Generative Hard Negative Images Through Diffusion


Grunnleggende konsepter
Generative models like GeNIe can efficiently generate hard negative samples for training data augmentation, improving model performance in few-shot and long-tail distribution settings.
Sammendrag
  • Data augmentation is crucial for training deep learning models.
  • GeNIe leverages diffusion models to generate challenging samples by merging contrasting data points.
  • The choice of noise level in GeNIe plays a pivotal role in generating effective hard negative examples.
  • GeNIe-Ada adaptively selects the noise level per source image, enhancing performance.
  • Experimental results show the effectiveness of GeNIe in improving model accuracy across various datasets and settings.
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Statistikk
Recent advances in generative AI have enabled more sophisticated augmentation techniques (diffusion models). GeNIe introduces a novel augmentation method using a latent diffusion model conditioned on a text prompt. The proposed approach limits the number of diffusion iterations to retain low-level features from the source image while representing the target category. GeNIe demonstrates effectiveness in both few-shot and long-tail distribution settings.
Sitater
"We introduce GeNIe, a novel augmentation method leveraging a latent diffusion model conditioned on a text prompt." "Our extensive experiments demonstrate the effectiveness of our novel augmentation method."

Viktige innsikter hentet fra

by Soroush Abba... klokken arxiv.org 03-26-2024

https://arxiv.org/pdf/2312.02548.pdf
GeNIe

Dypere Spørsmål

How can GeNIe be adapted for datasets where images deviate from expected distributions

To adapt GeNIe for datasets where images deviate from expected distributions, several strategies can be employed: Fine-tuning the Generative Model: One approach is to fine-tune the generative model used in GeNIe on a small set of images from the specific dataset. By training the model on domain-specific data, it can learn to generate images that align better with the distribution of the target dataset. Domain-Specific Prompts: Tailoring text prompts used in GeNIe to reflect domain-specific characteristics can help guide the generative model towards generating more relevant and realistic images for datasets with unique distributions. Transfer Learning: Leveraging pre-trained models specifically trained on similar domains or tasks can provide a head start in adapting GeNIe for datasets with different image distributions. Fine-tuning these pre-trained models on new data can enhance their ability to generate appropriate augmentations. Data Preprocessing: Conducting preprocessing steps such as normalization, denoising, or feature extraction on input images before passing them through GeNIe can help mitigate discrepancies between expected and actual image distributions. By implementing these adaptations, GeNIe can be tailored effectively for datasets where images deviate from standard distributions.

What are the implications of using generative models like GeNIe for data augmentation in sensitive domains like medical imaging

Using generative models like GeNIe for data augmentation in sensitive domains like medical imaging carries significant implications: Privacy Concerns: Medical imaging often contains sensitive patient information. Generating synthetic medical images raises privacy concerns regarding patient confidentiality and data security. Proper anonymization techniques must be implemented to safeguard patient privacy. Ethical Considerations: The use of generated medical images may impact critical decisions related to patient care and treatment plans. Ensuring ethical guidelines are followed when utilizing augmented data is crucial to maintain integrity and trust within healthcare settings. Quality Assurance: In medical imaging, accuracy is paramount as decisions are based on detailed visual information provided by scans or tests. Any inaccuracies introduced by generative models during augmentation could have detrimental effects on diagnostic outcomes. 4Regulatory Compliance: Medical imaging practices are subject to strict regulatory standards (such as HIPAA). Using augmented data generated by AI models requires compliance with regulations governing data usage, storage, and sharing within healthcare environments.

How does the concept of hard negatives generated by GeNIe relate to traditional data augmentation methods like MixUp and CutMix

The concept of hard negatives generated by GeNIe differs from traditional methods like MixUp and CutMix in several ways: 1Hard Negatives vs Soft Augmentations: Hard negatives produced by GeNIE represent challenging samples that retain low-level features of source categories while embodying semantics of target categories - aiding in robustness against overfitting due to exposure only soft augmentations might not offer this level of challenge 2Semantic Consistency: While MixUp and CutMix blend two distinct samples at pixel levels without considering semantic consistency between classes; however ,GeNIE ensures that newly generated samples preserve contextual relevance while transitioning between source-target categories 3Adaptability: Unlike fixed transformations applied uniformly across all instances (as seen in traditional methods), GEnie's adaptive noise selection strategy allows tailoring augmentation intensity per sample basis ensuring optimal balance between preserving original features & incorporating desired class semantics
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