In recent years, machine learning has significantly shifted away from the assumption that training and testing data come from the same distribution. Researchers have identified that models perform better when handling data from multiple distributions. This adaptability is often achieved through what’s known as “rich representations,” which exceed the capabilities of models trained under traditional sparsity-inducing regularization or common stochastic gradient methods.
The challenge is optimizing machine learning models to perform well across various distributions, not just the one they were trained on. Models have been fine-tuned on large, pre-trained datasets specific to a task and then tested on a set of tasks designed to benchmark different aspects of the system. However, this method has limitations, especially when dealing with data distributions that diverge from the training set.
Researchers have explored various methods to obtain versatile representations, including engineering diverse datasets, architectures, and hyperparameters. Interesting results have been achieved by adversarially reweighting the training dataset and concatenating representations from multiple networks. Fine-tuning deep residual networks is a near-linear process, with the final training phase confined to a nearly convex attraction basin.
Researchers from New York University and Facebook AI Research have introduced a novel approach to achieving out-of-distribution (OOD) performance. They investigate the use of very high dropout rates as an alternative to ensemble techniques for obtaining rich representations. Conventionally, training a deep network from scratch with high dropout rates is nearly impossible due to the complexity and depth of the network. However, fine-tuning a pre-trained model under such conditions is feasible and surpasses the performance achieved by ensembles and weight-averaging methods like model soups.
The method employs a sophisticated fine-tuning process on a deep learning network with residual connections, primarily trained on extensive datasets. This process is characterized by applying very high dropout rates to the penultimate layer during fine-tuning, effectively blocking contributions from all residual blocks without creating new representations rather than leveraging existing ones. The technique stands out by utilizing a linear training approximation, where applying dropout acts as a form of milder regularization compared to its use in non-linear systems. Remarkably, this approach achieves comparable or superior performance to traditional methods like ensembles and weight averaging, showcasing its effectiveness across various DOMAINBED tasks.
Performance results underscore the effectiveness of this method. Fine-tuning with large dropout rates improved OOD performance across several benchmarks. For instance, on the VLCS dataset, a domain adaptation benchmark that poses significant challenges for generalization, models fine-tuned with this method showed substantial gains. The results indicate a considerable leap in OOD performance, affirming the method’s potential to enhance model robustness and reliability across diverse datasets.
In conclusion, the research provides a compelling case for reevaluating fine-tuning practices in machine learning. By introducing and validating very large dropout rates, the research has opened up avenues for developing more versatile and robust models capable of navigating the complexities of diverse data distributions. This method advances our understanding of rich representations and sets a new benchmark for OOD performance, marking a significant step forward in pursuing more generalized machine-learning solutions.
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The post This AI Paper from NYU and Meta Reveals ‘Machine Learning Beyond Boundaries – How Fine-Tuning with High Dropout Rates Outshines Ensemble and Weight Averaging Methods’ appeared first on MarkTechPost.
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