A Derivative-Free Geometric Algorithm for Optimization on a Sphere

IF 1.2 Q2 MATHEMATICS, APPLIED
Yannan Chen
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引用次数: 2

Abstract

Optimization on a unit sphere finds crucial applications in science and engineering. However, derivatives of the objective function may be difficult to compute or corrupted by noises, or even not available in many applications. Hence, we propose a Derivative-Free Geometric Algorithm (DFGA) which, to the best of our knowledge, is the first derivative-free algorithm that takes trust region framework and explores the spherical geometry to solve the optimization problem with a spherical constraint. Nice geometry of the spherical surface allows us to pursue the optimization at each iteration in a local tangent space of the sphere. Particularly, by applying Householder and Cayley transformations, DFGA builds a quadratic trust region model on the local tangent space such that the local optimization can essentially be treated as an unconstrained optimization. Under mild assumptions, we show that there exists a subsequence of the iterates generated by DFGA converging to a stationary point of this spherical optimization. Furthermore, under the Lojasiewicz property, we show that all the iterates generated by DFGA will converge with at least a linear or sublinear convergence rate. Our numerical experiments on solving the spherical location problems, subspace clustering and image segmentation problems resulted from hypergraph partitioning, indicate DFGA is very robust and efficient for solving optimization on a sphere without using derivatives.
球面上的无导数几何优化算法
单位球面上的优化在科学和工程中有着重要的应用。然而,目标函数的导数可能难以计算或被噪声破坏,甚至在许多应用中不可用。因此,我们提出了一种无导数几何算法(DFGA),据我们所知,它是第一种无导数算法,采用信任域框架,探索球面几何来解决具有球面约束的优化问题。球面的良好几何形状使我们能够在球体的局部切线空间中的每次迭代中进行优化。特别地,通过应用Householder和Cayley变换,DFGA在局部切线空间上建立了一个二次信赖域模型,使得局部优化本质上可以被视为无约束优化。在温和的假设下,我们证明了存在DFGA生成的迭代子序列收敛到该球面优化的平稳点。此外,在Lojaseewicz性质下,我们证明了DFGA生成的所有迭代都将以至少线性或亚线性的收敛速度收敛。我们在解决超图分割引起的球面定位问题、子空间聚类和图像分割问题上的数值实验表明,DFGA在不使用导数的情况下,对于解决球面上的优化问题是非常稳健和有效的。
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来源期刊
CiteScore
2.70
自引率
0.00%
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