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Variational procedure and generalized Lanczos recursion for small-amplitude classical oscillations

E.V. Tsiper

Department of Physics, SUNY at Stony Brook, Stony Brook, NY 11794
Variational procedure is developed that yields lowest frequencies of small-amplitude oscillations of classical Hamiltonian systems. Genuine Lanczos recursion is generalized to treat related non-Hermitian eigenvalue problems.

JETP Letters 70, 11, 751 (1999)
[Pis'ma v ZhETF 70, 11, 740 (1999)]
reprint: PDF


This article is cited in:
Vecharynski, E., Brabec, J., Shao, M., Govind, N. and Yang, C.,
Efficient block preconditioned eigensolvers for linear response time-dependent density functional theory.
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Wang, W.G., Zhang, L.H. and Li, R.C.,
Error bounds for approximate deflating subspaces for linear response eigenvalue problems.
Linear Algebra and its Applications, 528, pp.273-289, 2017.

Bai, Z., Li, R. and Lin, W.,
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Science China Mathematics, 59(8), pp.1443-1460, 2016.

Zhang, L.H., Lin, W.W. and Li, R.C.,
Backward perturbation analysis and residual-based error bounds for the linear response eigenvalue problem.
BIT Numerical Mathematics, 55(3), pp.869-896, 2015.

Teng, Z., Lu, L. and Li, R.C.,
Perturbation of partitioned linear response eigenvalue problems.
Electronic Transactions on Numerical Analysis, 44, pp.624-638, 2015.

Bai, Z. and Li, R.C.,
Recent progress in linear response eigenvalue problems.
In International Workshop on Eigenvalue Problems: Algorithms, Software and Applications in Petascale Computing (pp. 287-304). Springer, Cham, 2015.

Bai, Z. and Li, R.C.,
Recent progress in linear response eigenvalue problems.
In International Workshop on Eigenvalue Problems: Algorithms, Software and Applications in Petascale Computing (pp. 287-304). Springer, Cham, 2015.

Bai, Z. and Li, R.C.,
Minimization principles and computation for the generalized linear response eigenvalue problem.
BIT Numerical Mathematics, 54(1), pp.31-54, 2014.

Zhang, L.H., Xue, J. and Li, R.C.,
Rayleigh--Ritz Approximation For the Linear Response Eigenvalue Problem.
SIAM Journal on Matrix Analysis and Applications, 35(2), pp.765-782, 2014.

Bai, Z. and Li, R.C.,
Minimization principles for the linear response eigenvalue problem II: Computation.
SIAM Journal on Matrix Analysis and Applications, 34(2), pp.392-416, 2013.

Teng, Z. and Li, R.C.,
Convergence analysis of Lanczos-type methods for the linear response eigenvalue problem.
Journal of Computational and Applied Mathematics, 247, pp.17-33, 2013.

Bai, Z. and Li, R.C.,
Minimization principle for linear response eigenvalue problem iii: general case.
Mathematics preprint series, The University of Texas, Arlington, 2013.

Bai, Z. and Li, R.C.,
Minimization principles for the linear response eigenvalue problem I: Theory.
SIAM Journal on Matrix Analysis and Applications, 33(4), pp.1075-1100, 2012.

Bai, Z. and Li, R.C.,
Minimization principle for linear response eigenvalue problem with applications.
Technical Report 2011-06, Department of Mathematics, University of Texas at Arlington, 2011.

Tretiak, S., Isborn, C.M., Niklasson, A.M. and Challacombe, M.,
Representation independent algorithms for molecular response calculations in time-dependent self-consistent field theories.
The Journal of chemical physics, 130(5), p.054111, 2009.

Tsiper, E.V.,
Fractional charge revealed in computer simulations of resonant tunneling in the fractional quantum Hall regime.
Physical review letters, 97(7), p.076802, 2006.

Tsiper, E.V.,
Computer simulation of resonant tunneling through quantum antidot in the fractional quantum Hall regime: evidence of fractional quantization of electric charge.
Nanostructures: physics and technology, p.127, 2006.

Tretiak, S. and Chernyak, V.,
Resonant nonlinear polarizabilities in the time-dependent density functional theory.
The Journal of chemical physics, 119(17), pp.8809-8823, 2003.

Tretiak, S. and Mukamel, S.,
Density matrix analysis and simulation of electronic excitations in conjugated and aggregated molecules.
Chemical reviews, 102(9), pp.3171-3212, 2002.

Tsiper, E.V.,
A classical mechanics technique for quantum linear response.
Journal of Physics B: Atomic, Molecular and Optical Physics, 34(12), p.L401, 2001.

Tretiak, S.,
Random phase approximation/semiempirical computations of electronic structure of extended organic molecules.
Recent Research Developments in Physical Chemistry, 5, pp.721-45, 2001.