虚假关系
计算机科学
杠杆(统计)
一般化
人工智能
机器学习
推论
因果模型
因果结构
因果推理
代表(政治)
光学(聚焦)
联营
任务分析
依赖关系(UML)
对比度(视觉)
稳健性(进化)
潜变量
任务(项目管理)
数据挖掘
航程(航空)
解耦(概率)
语义学(计算机科学)
模式
变量(数学)
模态(人机交互)
作者
Jie Wen,Y.X. Liu,Chao Huang,Chengliang Liu,Yong Xu,Xiaochun Cao
标识
DOI:10.1109/tpami.2025.3621250
摘要
Fine-tuning pre-trained vision-language models (VLMs) has shown substantial benefits in a wide range of downstream tasks, often achieving impressive performance with minimal labeled data. Parameter-efficient fine-tuning techniques, in particular, have demonstrated their effectiveness in enhancing downstream task performance. However, these methods frequently struggle to generalize to out-of-distribution (OOD) data due to their reliance on non-causal representations, which can introduce biases and spurious correlations that negatively impact decision-making. Such spurious factors hinder the model's generalization ability beyond the training distribution. To address these challenges, in this paper, we propose a novel causal intervention-based prompt tuning method to adapt VLMs to few-shot OOD generalization. Specifically, we leverage the front-door adjustment technique from causal inference to mitigate the effects of spurious correlations and enhance the model's focus on causal relationships. Built upon VLMs, our approach begins by decoupling causal and non-causal representations in the vision-language alignment process. The causal representation that captures only essential semantically relevant information can serve as a mediator variable between the input image and output label, mitigating the biases from the latent confounder. To further enrich this causal representation, we propose a novel text-based diversity augmentation technique that uses textual features to provide additional semantic context. This augmentation technique can enhance the diversity of the causal representation, making it more robust and generalizable to various OOD scenarios. Experimental results across multiple OOD datasets demonstrate that our method significantly outperforms existing approaches, achieving state-of-the-art generalization performance.
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