Application of hierarchical matrices for computing the Karhunen–Loève expansion

Khoromskij, Boris N.; Litvinenko, Alexander; Matthies, Hermann G.

doi:10.1007/s00607-008-0018-3

Cited by 76 publications

(96 citation statements)

References 38 publications

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“…The kernel is chosen to be a member of the Matérn covariance family, the exponential covariance kernel κ(x, y) = exp(− x − y /l), where l is the integral length scale and is chosen to be 1. It can be shown that this kernel satisfies the requirements of asymptotic smoothness [33] as stated in Section 2. We also make the following choices for the parameters: we pick η = 0.75 and n min = 32.…”

Section: H-matrix Approximation Of Covariance Matricesmentioning

confidence: 88%

“…In terms of applications, it is useful to consider three kinds of covariance kernels [33]: 1. isotropic and translation invariant, i.e., κ(x, y) = κ(|x−y|); 2. stationary and anisotropic, i.e., κ(x, y) = κ(x − y); 3. non-stationary. Some possible choices for the covariance kernel κ(·, ·) arise from the Matérn family of covariance kernels [34], corresponding to a stationary and isotropic stochastic process.…”

Section: Covariance Functionsmentioning

confidence: 99%

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Application of Hierarchical Matrices to Linear Inverse Problems in Geostatistics

Saibaba

Ambikasaran

et al. 2012

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

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Nous commençons par décrire brièvement l'approche géostatistique dans le contexte d'un problème inverse linéaire, puis discutons les difficultés rencontrées dans le cadre d'une implémentation à grande échelle. Ensuite, en utilisant une approche basée sur les matrices hiérarchiques, nous montrons comment réduire le coût de calcul d'un produit matrice-vecteur de O(m 2 ) à O(m log m) dans le cas de matrices de covariance denses ; m désignant ici le nombre d'inconnues. Combinée avec un solveur de Krylov, qui ne requiert pas la construction explicite de la matrice, cette méthode conduit à un algorithme beaucoup plus rapide pour résoudre le système d'équations associé à l'approche géostatistique. Nous illustrons enfin la performance de notre algorithme dans un situation spécifique, surveiller la concentration de CO 2 à l'aide de la tomographie sismique entre puits. Abstract -Application of Hierarchical Matrices to Linear Inverse Problems in Geostatistics -Characterizing the uncertainty in the subsurface is an important step for exploration and extraction of natural resources, the storage of nuclear material and gasses such as natural gas or CO 2 . Imaging the subsurface can be posed as an inverse problem and can be solved using the geostatistical approach [Kitanidis P.K. (2007) Geophys. Monogr. Ser. 171, 19-30, doi:10.1029/171GM04;Kitanidis (2011 Kitanidis ( ) doi: 10.1002

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Section: H-matrix Approximation Of Covariance Matricesmentioning

confidence: 88%

Section: Covariance Functionsmentioning

confidence: 99%

Application of Hierarchical Matrices to Linear Inverse Problems in Geostatistics

Saibaba

Ambikasaran

et al. 2012

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

View full text Add to dashboard Cite

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“…However, in the presence of round-off errors, these quantities are not numerically zero. We compare the results for three different covariance kernels defined in (15) and we have A = M QM and B = M . The results are summarized in Table II.…”

Section: Accuracy Of Qr With Weighted Inner Productmentioning

confidence: 99%

“…To demonstrate the effect of correlation length l on the accuracy of the randomized calculations, we consider the following numerical experiment. The eigenvalues are computed for the KLE using the covariance kernel κ ν=5/2 as defined in Equation (15). The domain for the computations is [−1, 1] and the number of grid points are 501.…”

Section: Effect Of Correlation Length Lmentioning

confidence: 99%

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Randomized algorithms for generalized Hermitian eigenvalue problems with application to computing Karhunen–Loève expansion

Saibaba

Lee

Kitanidis

2015

Numerical Linear Algebra App

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SUMMARYWe describe randomized algorithms for computing the dominant eigenmodes of the Generalized Hermitian Eigenvalue Problem (GHEP) Ax = λBx, with A Hermitian and B Hermitian and positive definite. The algorithms we describe only require forming operations Ax, Bx and B −1 x and avoid forming square-roots of B (or operations of the form, B 1/2 x or B −1/2 x). We provide a convergence analysis and a posteriori error bounds that build upon the work of [13,16,18] (which have been derived for the case B = I). Additionally, we derive some new results that provide insight into the accuracy of the eigenvalue calculations. The error analysis shows that the randomized algorithm is most accurate when the generalized singular values of B −1 A decay rapidly. A randomized algorithm for the Generalized Singular Value Decomposition (GSVD) is also provided. Finally, we demonstrate the performance of our algorithm on computing the KarhunenLoève expansion, which is a computationally intensive GHEP problem with rapidly decaying eigenvalues.

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Uncertainty in cardiac myofiber orientation and stiffnesses dominate the variability of left ventricle deformation response

Rodríguez‐Cantano

Sundnes

Rognes

2019

Numer Methods Biomed Eng

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Computational cardiac modelling is a mature area of biomedical computing and is currently evolving from a pure research tool to aiding in clinical decision making. Assessing the reliability of computational model predictions is a key factor for clinical use, and uncertainty quantification (UQ) and sensitivity analysis are important parts of such an assessment. In this study, we apply UQ in computational heart mechanics to study uncertainty both in material parameters characterizing global myocardial stiffness and in the local muscle fiber orientation that governs tissue anisotropy. The uncertainty analysis is performed using the polynomial chaos expansion (PCE) method, which is a nonintrusive meta‐modeling technique that surrogates the original computational model with a series of orthonormal polynomials over the random input parameter space. In addition, in order to study variability in the muscle fiber architecture, we model the uncertainty in orientation of the fiber field as an approximated random field using a truncated Karhunen‐Loéve expansion. The results from the UQ and sensitivity analysis identify clear differences in the impact of various material parameters on global output quantities. Furthermore, our analysis of random field variations in the fiber architecture demonstrate a substantial impact of fiber angle variations on the selected outputs, highlighting the need for accurate assignment of fiber orientation in computational heart mechanics models.

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Application of hierarchical matrices for computing the Karhunen–Loève expansion

Cited by 76 publications

References 38 publications

Application of Hierarchical Matrices to Linear Inverse Problems in Geostatistics

Application of Hierarchical Matrices to Linear Inverse Problems in Geostatistics

Randomized algorithms for generalized Hermitian eigenvalue problems with application to computing Karhunen–Loève expansion

Uncertainty in cardiac myofiber orientation and stiffnesses dominate the variability of left ventricle deformation response

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