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Regularized Newton Method with Global \({\boldsymbol{\mathcal{O}(1/{k}^2)}}\) Convergence

Konstantin Mishchenko

2023SIAM Journal on Optimization25 citationsDOI

Abstract

.We present a Newton-type method that converges fast from any initialization and for arbitrary convex objectives with Lipschitz Hessians. We achieve this by merging the ideas of cubic regularization with a certain adaptive Levenberg–Marquardt penalty. In particular, we show that the iterates given by \(x^{k+1}=x^k - (\nabla^2 f(x^k) + \sqrt{H\|\nabla f(x^k)\|} \mathbf{I} )^{-1}\nabla f(x^k)\) , where \(H\gt 0\) is a constant, converge globally with a \(\mathcal{O}(\frac{1}{k^2})\) rate. Our method is the first variant of Newton's method that has both cheap iterations and provably fast global convergence. Moreover, we prove that locally our method converges superlinearly when the objective is strongly convex. To boost the method's performance, we present a line search procedure that does not need prior knowledge of \(H\) and is provably efficient.Keywordssecond-order optimizationNewton's methodLevenberg–Marquardt algorithmglobal convergenceMSC codes65K05

Topics & Concepts

MathematicsIterated functionLipschitz continuityLine searchInitializationRate of convergenceRegularization (linguistics)Regular polygonLocal convergenceNewton's methodConstant (computer programming)Subgradient methodApplied mathematicsConvergence (economics)Convex optimizationMathematical optimizationMathematical analysisIterative methodComputer scienceGeometryKey (lock)Nonlinear systemRADIUSComputer securityProgramming languagePhysicsArtificial intelligenceQuantum mechanicsEconomic growthEconomicsAdvanced Optimization Algorithms ResearchSparse and Compressive Sensing TechniquesStochastic Gradient Optimization Techniques
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