AlphaGrad: Non-Linear Gradient Normalization Optimizer
Abstract
We introduce AlphaGrad, a memory-efficient, conditionally stateless optimizer addressing the memory overhead and hyperparameter complexity of adaptive methods like Adam. AlphaGrad enforces scale invariance via tensor-wise L2 gradient normalization followed by a smooth hyperbolic tangent transformation, , controlled by a single steepness parameter . Our contributions include: (1) the AlphaGrad algorithm formulation; (2) a formal non-convex convergence analysis guaranteeing stationarity; (3) extensive empirical evaluation on diverse RL benchmarks (DQN, TD3, PPO). Compared to Adam, AlphaGrad demonstrates a highly context-dependent performance profile. While exhibiting instability in off-policy DQN, it provides enhanced training stability with competitive results in TD3 (requiring careful tuning) and achieves substantially superior performance in on-policy PPO. These results underscore the critical importance of empirical selection, revealing strong interactions between the optimizer's dynamics and the underlying RL algorithm. AlphaGrad presents a compelling alternative optimizer for memory-constrained scenarios and shows significant promise for on-policy learning regimes where its stability and efficiency advantages can be particularly impactful.
Cite
@article{arxiv.2504.16020,
title = {AlphaGrad: Non-Linear Gradient Normalization Optimizer},
author = {Soham Sane},
journal= {arXiv preprint arXiv:2504.16020},
year = {2025}
}