English

Optimization-Derived Learning with Essential Convergence Analysis of Training and Hyper-training

Machine Learning 2022-06-17 v1

Abstract

Recently, Optimization-Derived Learning (ODL) has attracted attention from learning and vision areas, which designs learning models from the perspective of optimization. However, previous ODL approaches regard the training and hyper-training procedures as two separated stages, meaning that the hyper-training variables have to be fixed during the training process, and thus it is also impossible to simultaneously obtain the convergence of training and hyper-training variables. In this work, we design a Generalized Krasnoselskii-Mann (GKM) scheme based on fixed-point iterations as our fundamental ODL module, which unifies existing ODL methods as special cases. Under the GKM scheme, a Bilevel Meta Optimization (BMO) algorithmic framework is constructed to solve the optimal training and hyper-training variables together. We rigorously prove the essential joint convergence of the fixed-point iteration for training and the process of optimizing hyper-parameters for hyper-training, both on the approximation quality, and on the stationary analysis. Experiments demonstrate the efficiency of BMO with competitive performance on sparse coding and real-world applications such as image deconvolution and rain streak removal.

Keywords

Cite

@article{arxiv.2206.07875,
  title  = {Optimization-Derived Learning with Essential Convergence Analysis of Training and Hyper-training},
  author = {Risheng Liu and Xuan Liu and Shangzhi Zeng and Jin Zhang and Yixuan Zhang},
  journal= {arXiv preprint arXiv:2206.07875},
  year   = {2022}
}

Comments

Accepted by ICML 2022

R2 v1 2026-06-24T11:53:08.413Z