共查询到17条相似文献,搜索用时 343 毫秒
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利用核函数及其性质,对P_*(k)阵线性互补问题提出了一种新的宽邻域不可行内点算法.对核函数作了一些适当的改进,所以是不同于Peng等人介绍的自正则障碍函数.最后证明了算法具有近似O((1+2k)n3/4log(nμ~0)/ε)多项式复杂性,是优于传统的基于对数障碍函数求解宽邻域内点算法的复杂性. 相似文献
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对P*(k)-阵线性互补问题提出了一种高阶内点算法.算法的每步迭代是基于线性规划原始-对偶仿射尺度算法的思想来确定迭代方向,再通过适当选取步长,得到算法的多项式复杂性. 相似文献
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本文基于一个带参数的函数,为P*(κ)线性互补问题设计出了一个大步校正内点算法.算法讨论沿用了Peng等在文[9]对互补问题基于自正则函数的讨论模式.但是,与Peng的算法不同的是,我们所考虑的带参数的函数是非自正则的.算法最终被证明具有较好的多项式复杂性. 相似文献
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本文对P_*(κ)线性互补问题设计了一种基于核函数的全-Newton步不可行内点算法,是对Mansouri等人提出的单调线性互补问题全-Newton步不可行内点算法的改进与推广.算法的主迭代由一个可行步和几个中心步构成且可行步采用小步校正.通过建立和应用一些新的技术性结果,证明了算法的多项式复杂性为O((1+2κ)~(3/2)(1og_2log_264(1+2κ))nlogmax{(x0)Ts0,||r0||}/ε),当k=0时,与当前单调线性互补问题的不可行内点算法最好的迭代复杂性界一致.最后,用Matlab数值实验验证了算法的可行性. 相似文献
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本文通过使用高界校正技术,给出了一个求解P*(k)阵线性互补问题的宽域路径跟踪算法,其迭代复杂性为渐近O((k+1)L).通过使用秩-1校正技术,其每步的计算复杂性从常规的O(n3)约减到O(n2.5);因此,算法总的计算复杂性为渐近O((k+1)n3L). 相似文献
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对线性互补问题提出了一种新的宽邻域预估校正算法,算法是基于经典线性规划路径跟踪算法的思想,将Maziar Salahi关于线性规划预估校正算法推广到线性互补问题中,给出了算法的具体迭代步骤并讨论了算法迭代复杂性,最后证明了算法具有多项式复杂性为O(ηlog(X~0)~Ts~0/ε)。 相似文献
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本文采用一簇新的核函数设计原始-对偶内点算法用于解决P*(κ)线性互补问题.通过利用一些优良、简洁的分析工具,证明该算法具有O(q(2κ+1)n1/p(logn)1+1/qlog(n/ε))迭代复杂性. 相似文献
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本文研究了P(K)-阵线性互补问题宽邻域高阶内点算法.利用线性规划的原始-对偶仿射尺度算法来确定迭代方向,得到了算法的收敛性及迭代复杂性,其算法是有效可行的. 相似文献
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Jianming Miao 《Mathematical Programming》1995,69(1-3):355-368
An interior-point predictor-corrector algorithm for theP
*()-matrix linear complementarity problem is proposed. The algorithm is an extension of Mizuno—Todd—Ye's predictor—corrector algorithm for linear programming problem. The extended algorithm is quadratically convergent with iteration complexity
. It is the first polynomially and quadratically convergent algorithm for a class of LCPs that are not necessarily monotone. 相似文献
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Behrouz Kheirfam 《Numerical Algorithms》2014,66(2):349-361
We present a predictor-corrector path-following interior-point algorithm for \(P_*(\kappa )\) horizontal linear complementarity problem based on new search directions. In each iteration, the algorithm performs two kinds of steps: a predictor (damped Newton) step and a corrector (full Newton) step. The full Newton-step is generated from an algebraic reformulation of the centering equation, which defines the central path and seeks directions in a small neighborhood of the central path. While the damped Newton step is used to move in the direction of optimal solution and reduce the duality gap. We derive the complexity for the algorithm, which coincides with the best known iteration bound for \(P_*(\kappa )\) -horizontal linear complementarity problems. 相似文献
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In this paper, a new full Nesterov–Todd step infeasible interior-point method for Cartesian \(P_*(\kappa )\) linear complementarity problem over symmetric cone is considered. Our algorithm starts from a strictly feasible point of a perturbed problem, after a full Nesterov–Todd step for the new perturbed problem the obtained strictly feasible iterate is close to the central path of it, where closeness is measured by some merit function. Furthermore, the complexity bound of the algorithm is the best available for infeasible interior-point methods. 相似文献
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Zhongyi Liu Yue Chen Wenyu Sun Zhihui Wei 《Computational Optimization and Applications》2012,52(2):373-391
Recently an infeasible interior-point algorithm for linear programming (LP) was presented by Liu and Sun. By using similar predictor steps, we give a (feasible) predictor-corrector algorithm for convex quadratic programming (QP). We introduce a (scaled) proximity measure and a dynamical forcing factor (centering parameter). The latter is used to force the duality gap to decrease. The algorithm can decrease the duality gap monotonically. Polynomial complexity can be proved and the result coincides with the best one for LP, namely, $O(\sqrt{n}\log n\mu^{0}/\varepsilon)$ . 相似文献
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In this paper, we consider a full-Newton step feasible interior-point algorithm for \(P_*(\kappa )\)-linear complementarity problem. The perturbed complementarity equation \(xs=\mu e\) is transformed by using a strictly increasing function, i.e., replacing \(xs=\mu e\) by \(\psi (xs)=\psi (\mu e)\) with \(\psi (t)=\sqrt{t}\), and the proposed interior-point algorithm is based on that algebraic equivalent transformation. Furthermore, we establish the currently best known iteration bound for \(P_*(\kappa )\)-linear complementarity problem, namely, \(O((1+4\kappa )\sqrt{n}\log \frac{n}{\varepsilon })\), which almost coincides with the bound derived for linear optimization, except that the iteration bound in the \(P_{*}(\kappa )\)-linear complementarity problem case is multiplied with the factor \((1+4\kappa )\). 相似文献
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Behrouz Kheirfam 《Journal of Optimization Theory and Applications》2014,161(3):853-869
In this paper, we first present a full-Newton step feasible interior-point algorithm for solving horizontal linear complementarity problems. We prove that the full-Newton step to the central path is quadratically convergent. Then, we generalize an infeasible interior-point method for linear optimization to horizontal linear complementarity problems based on new search directions. This algorithm starts from strictly feasible iterates on the central path of a perturbed problem that is produced by a suitable perturbation in the horizontal linear complementarity problem. We use the so-called feasibility steps that find strictly feasible iterates for the next perturbed problem. By using centering steps for the new perturbed problem, we obtain a strictly feasible iterate close enough to the central path of the new perturbed problem. The complexity of the algorithm coincides with the best known iteration bound for infeasible interior-point methods. 相似文献
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Wen-baoAi 《计算数学(英文版)》2004,22(3):437-446
In this paper we present a dynamic optimal method for adjusting the centering parameter in the wide-neighborhood primal-dual interior-point algorithms for linear programming, while the centering pararheter is generally a constant in the classical wideneighborhood primal-dual interior-point algorithms. The computational results show that the new method is more efficient. 相似文献