Efficiently Escaping Saddle Points in Bilevel Optimization

Minhui Huang; Xuxing Chen; Kaiyi Ji; Shiqian Ma; Lifeng Lai

Efficiently Escaping Saddle Points in Bilevel Optimization

Minhui Huang
, Xuxing Chen
, Kaiyi Ji
, Shiqian Ma
, Lifeng Lai

Department of Computer Science and Engineering

University of California at Davis
Rice University

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Bilevel optimization is one of the fundamental problems in machine learning and optimization. Recent theoretical developments in bilevel optimization focus on finding the first-order stationary points for nonconvex-strongly-convex cases. In this paper, we analyze algorithms that can escape saddle points in nonconvex-strongly-convex bilevel optimization. Specifically, we show that the perturbed approximate implicit differentiation (AID) with a warm start strategy finds an ∊-approximate local minimum of bilevel optimization in Õ(∊⁻²) iterations with high probability. Moreover, we propose an inexact NEgative-curvature-Originated-from-Noise Algorithm (iNEON), an algorithm that can escape saddle point and find local minimum of stochastic bilevel optimization. As a by-product, we provide the first nonasymptotic analysis of perturbed multi-step gradient descent ascent (GDmax) algorithm that converges to local minimax point for minimax problems.

Original language	English
Journal	Journal of Machine Learning Research
Volume	26
State	Published - 2025

Keywords

Bilevel optimization
inexact NEON
local minimax point
minimax problem
saddle point

Cite this

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title = "Efficiently Escaping Saddle Points in Bilevel Optimization",

abstract = "Bilevel optimization is one of the fundamental problems in machine learning and optimization. Recent theoretical developments in bilevel optimization focus on finding the first-order stationary points for nonconvex-strongly-convex cases. In this paper, we analyze algorithms that can escape saddle points in nonconvex-strongly-convex bilevel optimization. Specifically, we show that the perturbed approximate implicit differentiation (AID) with a warm start strategy finds an ∊-approximate local minimum of bilevel optimization in {\~O}(∊−2) iterations with high probability. Moreover, we propose an inexact NEgative-curvature-Originated-from-Noise Algorithm (iNEON), an algorithm that can escape saddle point and find local minimum of stochastic bilevel optimization. As a by-product, we provide the first nonasymptotic analysis of perturbed multi-step gradient descent ascent (GDmax) algorithm that converges to local minimax point for minimax problems.",

keywords = "Bilevel optimization, inexact NEON, local minimax point, minimax problem, saddle point",

author = "Minhui Huang and Xuxing Chen and Kaiyi Ji and Shiqian Ma and Lifeng Lai",

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year = "2025",

language = "English",

volume = "26",

journal = "Journal of Machine Learning Research",

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TY - JOUR

T1 - Efficiently Escaping Saddle Points in Bilevel Optimization

AU - Huang, Minhui

AU - Chen, Xuxing

AU - Ji, Kaiyi

AU - Ma, Shiqian

AU - Lai, Lifeng

PY - 2025

Y1 - 2025

N2 - Bilevel optimization is one of the fundamental problems in machine learning and optimization. Recent theoretical developments in bilevel optimization focus on finding the first-order stationary points for nonconvex-strongly-convex cases. In this paper, we analyze algorithms that can escape saddle points in nonconvex-strongly-convex bilevel optimization. Specifically, we show that the perturbed approximate implicit differentiation (AID) with a warm start strategy finds an ∊-approximate local minimum of bilevel optimization in Õ(∊−2) iterations with high probability. Moreover, we propose an inexact NEgative-curvature-Originated-from-Noise Algorithm (iNEON), an algorithm that can escape saddle point and find local minimum of stochastic bilevel optimization. As a by-product, we provide the first nonasymptotic analysis of perturbed multi-step gradient descent ascent (GDmax) algorithm that converges to local minimax point for minimax problems.

AB - Bilevel optimization is one of the fundamental problems in machine learning and optimization. Recent theoretical developments in bilevel optimization focus on finding the first-order stationary points for nonconvex-strongly-convex cases. In this paper, we analyze algorithms that can escape saddle points in nonconvex-strongly-convex bilevel optimization. Specifically, we show that the perturbed approximate implicit differentiation (AID) with a warm start strategy finds an ∊-approximate local minimum of bilevel optimization in Õ(∊−2) iterations with high probability. Moreover, we propose an inexact NEgative-curvature-Originated-from-Noise Algorithm (iNEON), an algorithm that can escape saddle point and find local minimum of stochastic bilevel optimization. As a by-product, we provide the first nonasymptotic analysis of perturbed multi-step gradient descent ascent (GDmax) algorithm that converges to local minimax point for minimax problems.

KW - Bilevel optimization

KW - inexact NEON

KW - local minimax point

KW - minimax problem

KW - saddle point

UR - https://www.scopus.com/pages/publications/85218338927

M3 - Article

AN - SCOPUS:85218338927

SN - 1532-4435

VL - 26

JO - Journal of Machine Learning Research

JF - Journal of Machine Learning Research

ER -

Efficiently Escaping Saddle Points in Bilevel Optimization

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Keywords

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