On Implementing a Homogeneous Interior-Point Algorithm for Nonsymmetric Conic Optimization
Publication: Research › Report – Annual report year: 2011
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On Implementing a Homogeneous Interior-Point Algorithm for Nonsymmetric Conic Optimization. / Skajaa, Anders; Jørgensen, John Bagterp; Hansen, Per Christian.
Kgs. Lyngby : DTU Informatics, Building 321, 2011. (IMM-Technical Report-2011-02).Publication: Research › Report – Annual report year: 2011
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TY - RPRT
T1 - On Implementing a Homogeneous Interior-Point Algorithm for Nonsymmetric Conic Optimization
A1 - Skajaa,Anders
A1 - Jørgensen,John Bagterp
A1 - Hansen,Per Christian
AU - Skajaa,Anders
AU - Jørgensen,John Bagterp
AU - Hansen,Per Christian
PB - DTU Informatics, Building 321
PY - 2011
Y1 - 2011
N2 - Based on earlier work by Nesterov, an implementation of a homogeneous infeasible-start interior-point algorithm for solving nonsymmetric conic optimization problems is presented. Starting each iteration from (the vicinity of) the central path, the method computes (nearly) primal-dual symmetric approximate tangent directions followed by a purely primal centering procedure to locate the next central primal-dual point. Features of the algorithm include that it makes use only of the primal barrier function, that it is able to detect infeasibilities in the problem and that no phase-I method is needed. The method further employs quasi- Newton updating both to generate (pseudo) higher order directions and to reduce the number of factorizations needed in the centering process while still retaining the ability to exploit sparsity. Extensive and promising computational results are presented for the p-cone problem, the facility location problem, entropy problems and geometric programs; all formulated as nonsymmetric conic optimization problems.
AB - Based on earlier work by Nesterov, an implementation of a homogeneous infeasible-start interior-point algorithm for solving nonsymmetric conic optimization problems is presented. Starting each iteration from (the vicinity of) the central path, the method computes (nearly) primal-dual symmetric approximate tangent directions followed by a purely primal centering procedure to locate the next central primal-dual point. Features of the algorithm include that it makes use only of the primal barrier function, that it is able to detect infeasibilities in the problem and that no phase-I method is needed. The method further employs quasi- Newton updating both to generate (pseudo) higher order directions and to reduce the number of factorizations needed in the centering process while still retaining the ability to exploit sparsity. Extensive and promising computational results are presented for the p-cone problem, the facility location problem, entropy problems and geometric programs; all formulated as nonsymmetric conic optimization problems.
BT - On Implementing a Homogeneous Interior-Point Algorithm for Nonsymmetric Conic Optimization
T3 - IMM-Technical Report-2011-02
T3 - en_GB
ER -