Criteria and Bias of Parameterized Linear Regression under Edge of Stability Regime
Abstract
Classical optimization theory requires a small step-size for gradient-based methods to converge. Nevertheless, recent findings challenge the traditional idea by empirically demonstrating Gradient Descent (GD) converges even when the step-size η exceeds the threshold of 2/L, where L is the global smooth constant. This is usually known as the Edge of Stability (EoS) phenomenon. A widely held belief suggests that an objective function with subquadratic growth plays an important role in incurring EoS. In this paper, we provide a more comprehensive answer by considering the task of finding linear interpolator β ∈ Rd for regression with loss function l(·), where β admits parameterization as β = w2+ - w2-. Contrary to the previous work that suggests a subquadratic l is necessary for EoS, our novel finding reveals that EoS occurs even when l is quadratic under proper conditions. This argument is made rigorous by both empirical and theoretical evidence, demonstrating the GD trajectory converges to a linear interpolator in a non-asymptotic way. Moreover, the model under quadratic l, also known as a depth-2 diagonal linear network, remains largely unexplored under the EoS regime. Our analysis then sheds some new light on the implicit bias of diagonal linear networks when a larger step-size is employed, enriching the understanding of EoS on more practical models.
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