Self-paced learning has been beneficial for tasks where some initial knowledge is available, such as weakly supervised learning and domain adaptation, to select and order the training sample sequence, from easy to complex. However its applicability remains unexplored in unsupervised learning, whereby the knowledge of the task matures during training. We propose a novel HYperbolic Self-Paced model (HYSP) for learning skeleton-based action representations. HYSP adopts self-supervision: it uses data augmentations to generate two views of the same sample, and it learns by matching one (named online) to the other (the target). We propose to use hyperbolic uncertainty to determine the algorithmic learning pace, under the assumption that less uncertain samples should be more strongly driving the training, with a larger weight and pace. Hyperbolic uncertainty is a by-product of the adopted hyperbolic neural networks, it matures during training and it comes with no extra cost, compared to the established Euclidean SSL framework counterparts. When tested on three established skeleton-based action recognition datasets, HYSP outperforms the state-of-the-art on PKU-MMD I, as well as on 2 out of 3 downstream tasks on NTU-60 and NTU-120. Additionally, HYSP only uses positive pairs and bypasses therefore the complex and computationally-demanding mining procedures required for the negatives in contrastive techniques. Code is available at https://github.com/paolomandica/HYSP.

HYperbolic Self-Paced Learning for Self-Supervised Skeleton-based Action Representations / Franco, Luca; Mandica, Paolo; Munjal, Bharti; Galasso, Fabio. - (2023). (Intervento presentato al convegno International Conference on Learning Representations tenutosi a Kigali, Rwanda).

HYperbolic Self-Paced Learning for Self-Supervised Skeleton-based Action Representations

Luca Franco
Co-primo
;
Paolo Mandica
Co-primo
;
Bharti Munjal;Fabio Galasso
Ultimo
2023

Abstract

Self-paced learning has been beneficial for tasks where some initial knowledge is available, such as weakly supervised learning and domain adaptation, to select and order the training sample sequence, from easy to complex. However its applicability remains unexplored in unsupervised learning, whereby the knowledge of the task matures during training. We propose a novel HYperbolic Self-Paced model (HYSP) for learning skeleton-based action representations. HYSP adopts self-supervision: it uses data augmentations to generate two views of the same sample, and it learns by matching one (named online) to the other (the target). We propose to use hyperbolic uncertainty to determine the algorithmic learning pace, under the assumption that less uncertain samples should be more strongly driving the training, with a larger weight and pace. Hyperbolic uncertainty is a by-product of the adopted hyperbolic neural networks, it matures during training and it comes with no extra cost, compared to the established Euclidean SSL framework counterparts. When tested on three established skeleton-based action recognition datasets, HYSP outperforms the state-of-the-art on PKU-MMD I, as well as on 2 out of 3 downstream tasks on NTU-60 and NTU-120. Additionally, HYSP only uses positive pairs and bypasses therefore the complex and computationally-demanding mining procedures required for the negatives in contrastive techniques. Code is available at https://github.com/paolomandica/HYSP.
2023
International Conference on Learning Representations
Computer Science - Computer Vision and Pattern Recognition; Computer Science - Computer Vision and Pattern Recognition; Computer Science - Artificial Intelligence; Computer Science - Learning
04 Pubblicazione in atti di convegno::04b Atto di convegno in volume
HYperbolic Self-Paced Learning for Self-Supervised Skeleton-based Action Representations / Franco, Luca; Mandica, Paolo; Munjal, Bharti; Galasso, Fabio. - (2023). (Intervento presentato al convegno International Conference on Learning Representations tenutosi a Kigali, Rwanda).
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/1675023
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