On the Fourier Extension of Nonperiodic Functions

Huybrechs, Daan

doi:10.1137/090752456

Cited by 124 publications

(138 citation statements)

References 31 publications

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“…Related contributions are due to Gelb, Tadmor, and Tanner [23,43]. A Padé algorithm was proposed in [13], and further contributions in this area include [30] and [41]. For an excellent survey of much of this subject see [43].…”

Section: Examples Of Approximationmentioning

confidence: 99%

Impossibility of Fast Stable Approximation of Analytic Functions from Equispaced Samples

Platte

Trefethen²,

Kuijlaars³

2011

SIAM Rev.

131

145

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Section: Examples Of Approximationmentioning

confidence: 99%

Impossibility of Fast Stable Approximation of Analytic Functions from Equispaced Samples

Platte

Trefethen²,

Kuijlaars³

2011

SIAM Rev.

131

145

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“…Numerical tests indicate that this approach allows for a quite robust "black-box" construction of linear rational interpolants in the fewest possible nodes. We hope that our results enhance the understanding of the convergence behavior of linear barycentric interpolation and that they make it possible to compare such interpolation schemes with other available methods for interpolation in equispaced nodes, such as the approach proposed in [14] and in the references therein, that in [15], or the schemes reviewed and cited in [18].…”

Section: Resultsmentioning

confidence: 78%

“…, and let R > 0 be the smallest number such that f is analytic in the interior of C R defined in (14). Then the rational interpolants r n defined by (2), with limiting node measure μ and d(n)/n → C, satisfy lim sup In Figure 3 we illustrate the level lines C R for the parameter C = 0.2 with equispaced nodes on the left and with nodes distributed according to the density dμ/ dx = φ(x) = (4 + arctan(4x))/8 on the right.…”

Section: Lemma 3 For Anymentioning

confidence: 99%

Convergence of Linear Barycentric Rational Interpolation for Analytic Functions

Güttel

Klein

2012

SIAM J. Numer. Anal.

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Polynomial interpolation to analytic functions can be very accurate, depending on the distribution of the interpolation nodes. However, in equispaced nodes and the like, besides being badly conditioned, these interpolants fail to converge even in exact arithmetic in some cases. Linear barycentric rational interpolation with the weights presented by Floater and Hormann can be viewed as blended polynomial interpolation and often yields better approximation in such cases. This has been proven for differentiable functions and indicated in several experiments for analytic functions. So far, these rational interpolants have been used mainly with a constant parameter usually denoted by d, the degree of the blended polynomials, which leads to small condition numbers but to merely algebraic convergence. With the help of logarithmic potential theory we derive asymptotic convergence results for analytic functions when this parameter varies with the number of nodes. Moreover, we present suggestions for how to choose d in order to observe fast and stable convergence, even in equispaced nodes where stable geometric convergence is provably impossible. We demonstrate our results with several numerical examples.Math Subject Classification: 65D05, 65E05, 41A20

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“…The orthogonal set of basis functions employed for the pseudospectral optimal control approach is based on half-range Chebyshev Fourier functions [10], defined from trigonometric polynomials called half-range Chebyshev polynomials T k and U k respectively of the first and second kind. Definition 1.…”

Section: Pseudospectral Optimal Controlmentioning

confidence: 99%

Receding horizon pseudospectral optimal control for wave energy conversion

Genest

Ringwood

2016

2016 UKACC 11th International Conference on Control (CONTROL)

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Abstract-The present study introduces a real-time control algorithm for applications involving energy maximisation and subject to technological limitations. Development of Wave energy converters constitutes an actual topic of research, in their designs and fluid-interactions, and particularly on their controllability. Immersed WECs are subject to fluid-interaction forces, generating unusual solicitations specific to hydrodynamic equation, such as radiation force or excitation forces.Various control strategies were recently developed and more advance control algorithms are currently applied on WECS, such as Model Predictive Control [1], or Pseudospectral optimal control [2]. Such control strategies, capable of maximizing the energy production while insuring the respect of path constraints, are more realistic and applicable in real conditions involving technological limitation aspects. This paper presents a receding horizon type control, based on pseudospectral approach in the control problem resolution. Dealing with irregular waves on a fixed control horizon, the presented control need to work with nonperiodic functions, implying the change of the basis functions involved in the description of the state and control variables, namely the halfrange Chebyshev Fourier functions.Application of the receding horizon control is presented for a generic WEC, and compared with a standard MPC algorithm.

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On the Fourier Extension of Nonperiodic Functions

Cited by 124 publications

References 31 publications

Impossibility of Fast Stable Approximation of Analytic Functions from Equispaced Samples

Impossibility of Fast Stable Approximation of Analytic Functions from Equispaced Samples

Convergence of Linear Barycentric Rational Interpolation for Analytic Functions

Receding horizon pseudospectral optimal control for wave energy conversion

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