Torque-Aware Momentum
Keywords: optimization, deep learning, momentum
TL;DR: We propose an optimizer that incorporates a damping factor based on the alignment between gradients and momentum, improving stability in the update direction during training.
Abstract: Efficiently exploring complex loss landscapes is key to the performance of deep neural networks. While momentum-based optimizers are widely used in state-of-the-art setups, classical momentum can still struggle with large, misaligned gradients, leading to oscillations. To address this, we propose Torque-Aware Momentum (TAM), which introduces a damping factor based on the angle between the new gradients and previous momentum, stabilizing the update direction during training. Empirical results show that TAM, which can be combined with both SGD and Adam, enhances exploration, handles distribution shifts more effectively, and improves generalization performance across various tasks, including image classification and large language model fine-tuning, when compared to classical momentum-based optimizers.
Primary Area: optimization
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Submission Number: 9972
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