Meta-Learning to Improve Pre-Training
This addresses the problem of inefficient hyperparameter tuning in pre-training for machine learning practitioners, offering a scalable solution but is incremental as it builds on existing meta-learning and PT methods.
The paper tackles the challenge of tuning hyperparameters in pre-training (PT) for neural networks, proposing a gradient-based meta-learning algorithm that improves predictive performance, achieving up to 3.9% AUROC gain on protein-protein interaction graphs and up to 1.9% on electrocardiography data.
Pre-training (PT) followed by fine-tuning (FT) is an effective method for training neural networks, and has led to significant performance improvements in many domains. PT can incorporate various design choices such as task and data reweighting strategies, augmentation policies, and noise models, all of which can significantly impact the quality of representations learned. The hyperparameters introduced by these strategies therefore must be tuned appropriately. However, setting the values of these hyperparameters is challenging. Most existing methods either struggle to scale to high dimensions, are too slow and memory-intensive, or cannot be directly applied to the two-stage PT and FT learning process. In this work, we propose an efficient, gradient-based algorithm to meta-learn PT hyperparameters. We formalize the PT hyperparameter optimization problem and propose a novel method to obtain PT hyperparameter gradients by combining implicit differentiation and backpropagation through unrolled optimization. We demonstrate that our method improves predictive performance on two real-world domains. First, we optimize high-dimensional task weighting hyperparameters for multitask pre-training on protein-protein interaction graphs and improve AUROC by up to 3.9%. Second, we optimize a data augmentation neural network for self-supervised PT with SimCLR on electrocardiography data and improve AUROC by up to 1.9%.