Interior-Point Methods for Cartesian P*(κ)-Linear Complementarity Problems over Symmetric Cones Based on the Eligible Kernel Functions

Goran Lesaja

Interior-Point Methods for Cartesian P*(κ)-Linear Complementarity Problems over Symmetric Cones Based on the Eligible Kernel Functions

Mathematical Sciences

Research output: Contribution to conference › Presentation

Abstract

An interior-point method (IPM) for Cartesian P *(κ)- linear complementarity problems over symmetric cones (SCLCP) is analysed and the complexity results are presented. The Cartesian P *(κ)- SCLCPs have been recently introduced as the generalization of the more commonly known and more widely used monotone-SCLCPs. The IPM is based on the barrier functions that are defined by a large class of univariate functions called eligible kernel functions, which have recently been successfully used to design new IPMs for various optimization problems. Eligible barrier (kernel) functions are used in calculating the Nesterov–Todd search directions and the default step-size which lead to very good complexity results for the method. For some specific eligible kernel functions, we match the best-known iteration bound for the long-step methods while for the short-step methods the best iteration bound is matched for all cases.

Original language	American English
State	Published - Nov 13 2011
Event	Institute for Operations Research and the Management Sciences Annual Conference (INFORMS) - Duration: Oct 1 2017 → …

Conference

Conference	Institute for Operations Research and the Management Sciences Annual Conference (INFORMS)
Period	10/1/17 → …

Disciplines

Mathematics

Keywords

Barrier functions
Cartesian P*(K) property
Euclidean Jordan algebras and symmetric cones
Interior-point method
Kernal functions
Linear complementarity problem
Polynomial complexity

Cite this

@conference{02d43351312e42e3ac9eb210addbbe98,

title = "Interior-Point Methods for Cartesian P*(κ)-Linear Complementarity Problems over Symmetric Cones Based on the Eligible Kernel Functions",

abstract = " An interior-point method (IPM) for Cartesian P *(κ)- linear complementarity problems over symmetric cones (SCLCP) is analysed and the complexity results are presented. The Cartesian P *(κ)- SCLCPs have been recently introduced as the generalization of the more commonly known and more widely used monotone-SCLCPs. The IPM is based on the barrier functions that are defined by a large class of univariate functions called eligible kernel functions, which have recently been successfully used to design new IPMs for various optimization problems. Eligible barrier (kernel) functions are used in calculating the Nesterov–Todd search directions and the default step-size which lead to very good complexity results for the method. For some specific eligible kernel functions, we match the best-known iteration bound for the long-step methods while for the short-step methods the best iteration bound is matched for all cases.",

keywords = "Barrier functions, Cartesian P*(K) property, Euclidean Jordan algebras and symmetric cones, Interior-point method, Kernal functions, Linear complementarity problem, Polynomial complexity",

author = "Goran Lesaja",

year = "2011",

month = nov,

day = "13",

language = "American English",

note = "Institute for Operations Research and the Management Sciences Annual Conference (INFORMS) ; Conference date: 01-10-2017",

}

TY - CONF

T1 - Interior-Point Methods for Cartesian P*(κ)-Linear Complementarity Problems over Symmetric Cones Based on the Eligible Kernel Functions

AU - Lesaja, Goran

PY - 2011/11/13

Y1 - 2011/11/13

N2 - An interior-point method (IPM) for Cartesian P *(κ)- linear complementarity problems over symmetric cones (SCLCP) is analysed and the complexity results are presented. The Cartesian P *(κ)- SCLCPs have been recently introduced as the generalization of the more commonly known and more widely used monotone-SCLCPs. The IPM is based on the barrier functions that are defined by a large class of univariate functions called eligible kernel functions, which have recently been successfully used to design new IPMs for various optimization problems. Eligible barrier (kernel) functions are used in calculating the Nesterov–Todd search directions and the default step-size which lead to very good complexity results for the method. For some specific eligible kernel functions, we match the best-known iteration bound for the long-step methods while for the short-step methods the best iteration bound is matched for all cases.

AB - An interior-point method (IPM) for Cartesian P *(κ)- linear complementarity problems over symmetric cones (SCLCP) is analysed and the complexity results are presented. The Cartesian P *(κ)- SCLCPs have been recently introduced as the generalization of the more commonly known and more widely used monotone-SCLCPs. The IPM is based on the barrier functions that are defined by a large class of univariate functions called eligible kernel functions, which have recently been successfully used to design new IPMs for various optimization problems. Eligible barrier (kernel) functions are used in calculating the Nesterov–Todd search directions and the default step-size which lead to very good complexity results for the method. For some specific eligible kernel functions, we match the best-known iteration bound for the long-step methods while for the short-step methods the best iteration bound is matched for all cases.

KW - Barrier functions

KW - Cartesian P(K) property

KW - Euclidean Jordan algebras and symmetric cones

KW - Interior-point method

KW - Kernal functions

KW - Linear complementarity problem

KW - Polynomial complexity

M3 - Presentation

T2 - Institute for Operations Research and the Management Sciences Annual Conference (INFORMS)

Y2 - 1 October 2017

ER -

Interior-Point Methods for Cartesian P*(κ)-Linear Complementarity Problems over Symmetric Cones Based on the Eligible Kernel Functions

Abstract

Conference

Disciplines

Keywords

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