A Faster Path to Continual Learning
Abstract
Continual Learning (CL) aims to train neural networks on a dynamic stream of tasks without forgetting previously learned knowledge. Among optimization-based approaches, C-Flat has emerged as a promising solution due to its plug-and-play nature and its ability to encourage uniformly low-loss regions for both new and old tasks. However, C-Flat requires three additional gradient computations per iteration, imposing substantial overhead on the optimization process. In this work, we propose C-Flat Turbo, a faster yet stronger optimizer that significantly reduces the training cost. We show that the gradients associated with first-order flatness contain direction-invariant components relative to the proxy-model gradients, enabling us to skip redundant gradient computations in the perturbed ascent steps. Moreover, we observe that these flatness-promoting gradients progressively stabilize across tasks, which motivates a linear scheduling strategy with an adaptive trigger to allocate larger turbo steps for later tasks. Experiments show that C-Flat Turbo is 1.0 to 1.25 faster than C-Flat across a wide range of CL methods, while achieving comparable or even improved accuracy.
Cite
@article{arxiv.2604.11064,
title = {A Faster Path to Continual Learning},
author = {Wei Li and Hangjie Yuan and Zixiang Zhao and Borui Kang and Ziwei Liu and Tao Feng},
journal= {arXiv preprint arXiv:2604.11064},
year = {2026}
}
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