1994
DOI: 10.1007/bf03167209
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Lax pair and fixed point analysis of Karmarkar’s projective scaling trajectory for linear programming

Abstract: A Lax pair representation of a nonlinear dynamical system is presented which emerges in linear programming as a continuous version of Karmarkar's projective scaling algorithm. Karmarkar's continuous trajectory is also shown to be a gradient system. An expression of solution in a rational form is found by integrating the associated dynamical system. Fixed points of the trajectory also studied.Key words: Karmarkar's projective sca/ing algorithm, Lax pair form, gradient system, Toda lattice w I n t r o d u c t i … Show more

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Cited by 9 publications
(11 citation statements)
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“…Due to the account given below, however, geometric studies were not made in [19] either on the search sequence in the ESOT generated by the Grover-type search algorithm or on the reduced search sequence in the QIS: Instead of geometric studies on the search sequences, it is the gradient dynamical system associated with the negative von Neumann entropy as the potential that is discussed in [19] on inspired by a series works of Nakamura [20][21][22] on complete integrablity of algorithms arising in applied mathematics. The result on the gradient system in [19] has drawn the author's interest to publish [23,24] on the gradient systems on the QIS realizing the Karmarkar flow for linear programming and a Hebb-type learning equation for multivariate analysis, while geometric studies on the search sequences were left undone.…”
Section: Quantum Search For An Ordered Tuple Of Multi-qubits -A Briefmentioning
confidence: 99%
See 1 more Smart Citation
“…Due to the account given below, however, geometric studies were not made in [19] either on the search sequence in the ESOT generated by the Grover-type search algorithm or on the reduced search sequence in the QIS: Instead of geometric studies on the search sequences, it is the gradient dynamical system associated with the negative von Neumann entropy as the potential that is discussed in [19] on inspired by a series works of Nakamura [20][21][22] on complete integrablity of algorithms arising in applied mathematics. The result on the gradient system in [19] has drawn the author's interest to publish [23,24] on the gradient systems on the QIS realizing the Karmarkar flow for linear programming and a Hebb-type learning equation for multivariate analysis, while geometric studies on the search sequences were left undone.…”
Section: Quantum Search For An Ordered Tuple Of Multi-qubits -A Briefmentioning
confidence: 99%
“…The quotient space M 1 (2 n , ℓ)/ ∼ is realized as P ℓ defined by (21), where the projection of M 1 (2 n , ℓ) to P ℓ is given by…”
Section: Geometric Reduction Of the Regular Part Of The Esot To The Qismentioning
confidence: 99%
“…(ET))~ The asymptotics (19) imply that the Hebbian learning equation (2) with (1) yields the first principal component of the input data set. Another proof of (19) was given in [21] for the case where the covariance matrix E[XX -r] is positive semide¡…”
Section: V(rc) = 2 E~\i R)mentioning
confidence: 99%
“…Another proof of (19) was given in [21] for the case where the covariance matrix E[XX -r] is positive semide¡…”
Section: V(rc) = 2 E~\i R)mentioning
confidence: 99%
See 1 more Smart Citation