Toward a Unified Theory of Gradient Descent under Generalized Smoothness
Abstract
We study the classical optimization problem x ∈ Rd f(x) and analyze the gradient descent (GD) method in both nonconvex and convex settings. It is well-known that, under the L-smoothness assumption (\|∇2 f(x)\| ≤ L), the optimal point minimizing the quadratic upper bound f(xk) + ∇ f(xk), xk+1 - xk + L2 \|xk+1 - xk\|2 is xk+1 = xk - γk ∇ f(xk) with step size γk = 1L. Surprisingly, a similar result can be derived under the -generalized smoothness assumption (\|∇2 f(x)\| ≤ (\|∇ f(x)\|)). In this case, we derive the step size γk = ∫01 d v(\|∇ f(xk)\| + \|∇ f(xk)\| v). Using this step size rule, we improve upon existing theoretical convergence rates and obtain new results in several previously unexplored setups.
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