Active Learning (AL) has emerged as a powerful approach for minimizing labeling costs by selectively sampling the most informative data for neural network model development. Effective AL for large-scale vision-language models necessitates addressing challenges in uncertainty estimation and efficient sampling given the vast number of parameters involved. In this work, we introduce a novel parameter-efficient learning methodology that incorporates uncertainty calibration loss within the AL framework. We propose a differentiable loss function that promotes uncertainty calibration for effectively selecting fewer and most informative data samples for fine-tuning. Through extensive experiments across several datasets and vision backbones, we demonstrate that our solution can match and exceed the performance of complex feature-based sampling techniques while being computationally very efficient. Additionally, we investigate the efficacy of Prompt learning versus Low-rank adaptation (LoRA) in sample selection, providing a detailed comparative analysis of these methods in the context of efficient AL.
@article{arxiv.2507.21521,
title = {Optimizing Active Learning in Vision-Language Models via Parameter-Efficient Uncertainty Calibration},
author = {Athmanarayanan Lakshmi Narayanan and Amrutha Machireddy and Ranganath Krishnan},
journal= {arXiv preprint arXiv:2507.21521},
year = {2025}
}
Comments
International Joint Conference on Neural Networks 2025 (Accepted)