TY - CONF
T1 - Harnessing Out-Of-Distribution Examples via Augmenting Content and Style
AU - Huang, Zhuo
AU - Xia, Xiaobo
AU - Shen, Li
AU - Han, Bo
AU - Gong, Mingming
AU - Gong, Chen
AU - Liu, Tongliang
N1 - Funding Information:
Li Shen was partially supported by the Major Science and Technology Innovation 2030 “New Generation Artificial Intelligence” key project No. 2021ZD0111700. Zhuo Huang was supported by JD Technology Scholarship for Postgraduate Research in Artificial Intelligence No. SC4103. Xiaobo Xia was supported by Australian Research Council Projects DE-190101473 and Google PhD Fellowship. Bo Han was supported by NSFC Young Scientists Fund No. 62006202, Guangdong Basic and Applied Basic Research Foundation No. 2022A1515011652 and RGC Early Career Scheme No. 22200720. Mingming Gong was supported by ARC DE210101624. Chen Gong was supported by NSF of China No. 61973162, NSF of Jiangsu Province No. BZ2021013, NSF for Distinguished Young Scholar of Jiangsu Province No. BK20220080, and CAAI-Huawei MindSpore Open Fund. Tongliang Liu was partially supported by Australian Research Council Projects IC-190100031, LP-220100527, DP-220102121, and FT-220100318.
Publisher Copyright:
© 2023 11th International Conference on Learning Representations, ICLR 2023. All rights reserved.
PY - 2023
Y1 - 2023
N2 - Machine learning models are vulnerable to Out-Of-Distribution (OOD) examples, and such a problem has drawn much attention. However, current methods lack a full understanding of different types of OOD data: there are benign OOD data that can be properly adapted to enhance the learning performance, while other malign OOD data would severely degenerate the classification result. To Harness OOD data, this paper proposes a HOOD method that can leverage the content and style from each image instance to identify benign and malign OOD data. Particularly, we design a variational inference framework to causally disentangle content and style features by constructing a structural causal model. Subsequently, we augment the content and style through an intervention process to produce malign and benign OOD data, respectively. The benign OOD data contain novel styles but hold our interested contents, and they can be leveraged to help train a style-invariant model. In contrast, the malign OOD data inherit unknown contents but carry familiar styles, by detecting them can improve model robustness against deceiving anomalies. Thanks to the proposed novel disentanglement and data augmentation techniques, HOOD can effectively deal with OOD examples in unknown and open environments, whose effectiveness is empirically validated in three typical OOD applications including OOD detection, open-set semi-supervised learning, and open-set domain adaptation.
AB - Machine learning models are vulnerable to Out-Of-Distribution (OOD) examples, and such a problem has drawn much attention. However, current methods lack a full understanding of different types of OOD data: there are benign OOD data that can be properly adapted to enhance the learning performance, while other malign OOD data would severely degenerate the classification result. To Harness OOD data, this paper proposes a HOOD method that can leverage the content and style from each image instance to identify benign and malign OOD data. Particularly, we design a variational inference framework to causally disentangle content and style features by constructing a structural causal model. Subsequently, we augment the content and style through an intervention process to produce malign and benign OOD data, respectively. The benign OOD data contain novel styles but hold our interested contents, and they can be leveraged to help train a style-invariant model. In contrast, the malign OOD data inherit unknown contents but carry familiar styles, by detecting them can improve model robustness against deceiving anomalies. Thanks to the proposed novel disentanglement and data augmentation techniques, HOOD can effectively deal with OOD examples in unknown and open environments, whose effectiveness is empirically validated in three typical OOD applications including OOD detection, open-set semi-supervised learning, and open-set domain adaptation.
UR - http://www.scopus.com/inward/record.url?scp=85150984997&partnerID=8YFLogxK
UR - https://iclr.cc/virtual/2023/poster/12215
U2 - 10.48550/arXiv.2207.03162
DO - 10.48550/arXiv.2207.03162
M3 - Conference paper
AN - SCOPUS:85150984997
SP - 1
EP - 19
T2 - 11th International Conference on Learning Representations, ICLR 2023
Y2 - 1 May 2023 through 5 May 2023
ER -