English

Parameter Efficient Fine-tuning of Self-supervised ViTs without Catastrophic Forgetting

Computer Vision and Pattern Recognition 2024-07-08 v2

Abstract

Artificial neural networks often suffer from catastrophic forgetting, where learning new concepts leads to a complete loss of previously acquired knowledge. We observe that this issue is particularly magnified in vision transformers (ViTs), where post-pre-training and fine-tuning on new tasks can significantly degrade the model's original general abilities. For instance, a DINO ViT-Base/16 pre-trained on ImageNet-1k loses over 70% accuracy on ImageNet-1k after just 10 iterations of fine-tuning on CIFAR-100. Overcoming this stability-plasticity dilemma is crucial for enabling ViTs to continuously learn and adapt to new domains while preserving their initial knowledge. In this work, we study two new parameter-efficient fine-tuning strategies: (1)~Block Expansion, and (2) Low-rank adaptation (LoRA). Our experiments reveal that using either Block Expansion or LoRA on self-supervised pre-trained ViTs surpass fully fine-tuned ViTs in new domains while offering significantly greater parameter efficiency. Notably, we find that Block Expansion experiences only a minimal performance drop in the pre-training domain, thereby effectively mitigating catastrophic forgetting in pre-trained ViTs.

Keywords

Cite

@article{arxiv.2404.17245,
  title  = {Parameter Efficient Fine-tuning of Self-supervised ViTs without Catastrophic Forgetting},
  author = {Reza Akbarian Bafghi and Nidhin Harilal and Claire Monteleoni and Maziar Raissi},
  journal= {arXiv preprint arXiv:2404.17245},
  year   = {2024}
}

Comments

Accepted at eLVM Workshop, CVPR, 2024

R2 v1 2026-06-28T16:07:27.964Z