IPRSDP: a primal-dual interior-point relaxation algorithm for semidefinite programming

IF 1.6 2区数学 Q2 MATHEMATICS, APPLIED

Computational Optimization and Applications Pub Date : 2024-02-21 DOI:10.1007/s10589-024-00558-8

Rui-Jin Zhang, Xin-Wei Liu, Yu-Hong Dai

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引用次数: 0

Abstract

We propose an efficient primal-dual interior-point relaxation algorithm based on a smoothing barrier augmented Lagrangian, called IPRSDP, for solving semidefinite programming problems in this paper. The IPRSDP algorithm has three advantages over classical interior-point methods. Firstly, IPRSDP does not require the iterative points to be positive definite. Consequently, it can easily be combined with the warm-start technique used for solving many combinatorial optimization problems, which require the solutions of a series of semidefinite programming problems. Secondly, the search direction of IPRSDP is symmetric in itself, and hence the symmetrization procedure is not required any more. Thirdly, with the introduction of the smoothing barrier augmented Lagrangian function, IPRSDP can provide the explicit form of the Schur complement matrix. This enables the complexity of forming this matrix in IPRSDP to be comparable to or lower than that of many existing search directions. The global convergence of IPRSDP is established under suitable assumptions. Numerical experiments are made on the SDPLIB set, which demonstrate the efficiency of IPRSDP.

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IPRSDP：半定式编程的原始双内部点松弛算法

本文提出了一种基于平滑障碍增强拉格朗日的高效原始双内点松弛算法，称为 IPRSDP，用于求解半定式编程问题。与经典的内点法相比，IPRSDP 算法有三个优点。首先，IPRSDP 不要求迭代点是正定的。因此，它可以很容易地与用于求解许多组合优化问题的热启动技术相结合，这些问题需要求解一系列半定式编程问题。其次，IPRSDP 的搜索方向本身是对称的，因此不再需要对称化程序。第三，由于引入了平滑障碍增强拉格朗日函数，IPRSDP 可以提供舒尔补矩阵的显式形式。这使得 IPRSDP 中形成该矩阵的复杂度与许多现有搜索方向相当，甚至更低。在适当的假设条件下，建立了 IPRSDP 的全局收敛性。在 SDPLIB 集上进行的数值实验证明了 IPRSDP 的效率。

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来源期刊

Computational Optimization and Applications 数学-应用数学

CiteScore

3.70

自引率

9.10%

发文量

审稿时长

10 months

期刊介绍： Computational Optimization and Applications is a peer reviewed journal that is committed to timely publication of research and tutorial papers on the analysis and development of computational algorithms and modeling technology for optimization. Algorithms either for general classes of optimization problems or for more specific applied problems are of interest. Stochastic algorithms as well as deterministic algorithms will be considered. Papers that can provide both theoretical analysis, along with carefully designed computational experiments, are particularly welcome. Topics of interest include, but are not limited to the following: Large Scale Optimization, Unconstrained Optimization, Linear Programming, Quadratic Programming Complementarity Problems, and Variational Inequalities, Constrained Optimization, Nondifferentiable Optimization, Integer Programming, Combinatorial Optimization, Stochastic Optimization, Multiobjective Optimization, Network Optimization, Complexity Theory, Approximations and Error Analysis, Parametric Programming and Sensitivity Analysis, Parallel Computing, Distributed Computing, and Vector Processing, Software, Benchmarks, Numerical Experimentation and Comparisons, Modelling Languages and Systems for Optimization, Automatic Differentiation, Applications in Engineering, Finance, Optimal Control, Optimal Design, Operations Research, Transportation, Economics, Communications, Manufacturing, and Management Science.