Comparative Study of Homotopy Analysis and Renormalization Group Methods on Rayleigh and Van der Pol Equations

Palit, Aniruddha; Datta, Dilip

doi:10.1007/s12591-015-0253-y

Cited by 15 publications

(21 citation statements)

References 17 publications

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“…The importance of high precision computation in applied mathematics and science need not be overemphasized [5]. The higher precision quantitatively accurate computation of periodic orbits is facilitated in the framework of a novel asymptotic analysis [6][7][8][9], so as to allow significant numerical improvements in the computations of periodic orbits by the conventional asymptotic techniques such as renormalization group method(RGM) [10], multiple scale method (MSM) [1], homotopy analysis method [11,12] etc. As a prototype of strongly nonlinear oscillator, we consider here singularly perturbed Rayleigh Equation (SRLE) [1,4] equation with an external periodic excitation…”

Section: Introductionmentioning

confidence: 99%

“…where dots are used to designate the derivatives with respect to time. Rayleigh Equation, either regular or singularly perturbed, and a close cousin of Van der Pol equation [7], is one of the extensively studied nonlinear oscillatory systems because of its wide applications in acoustics, physiology and cardiac cycles, solid mechanics, electronics and nonlinear electrical circuits, musical instruments and many other different fields [1,2,13,14]. Singularly perturbed Rayleigh equation is equivalently related closely to the regularly perturbed Rayleigh equation (RLE)…”

Section: Introductionmentioning

confidence: 99%

“…In the present work, we investigate a modified and improved renormalization group (RG) method (IRGM) incorporating a novel asymptotic structure, called SL(2, R) duality structure, that is introduced and is being investigated previously by Datta et al [6][7][8][9]23] in various nonlinear applications. An application of IRGM and duality structure was presented in [7] in the context of Rayleigh equation (1.2) and Van der Pol equation (without forcing) ẍ + ε ẋ…”

Section: Introductionmentioning

confidence: 99%

“…To recall, the improvement of RG Method was made possible in [7] by introduction of SL(2, R) invariant, renormalized (control) variables, which can be used to ensure an improved convergence of approximate solutions through continuous deformations to the exact solution of the nonlinear oscillation problem concerned, with any desired accuracy level. The introduction of continuous deformation is based on the novel idea of nonlinear time [6,8,9,24], incorporating ideas of asymptotic duality structure and dynamically adustable time scales [8,9,24].…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Efficient Computation of Periodic Orbits of Forced Rayleigh Equation in the Framework of Novel Asymptotic Structures

Palit,

Datta,

Raut

2021

Preprint

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Higher precision efficient computation of period 1 relaxation oscillations of strongly nonlinear and singularly perturbed Rayleigh equations with external periodic forcing is presented. The computations are performed in the context of conventional renormalization group method (RGM). We demonstrate that although a slight homotopically modified RGM could generate approximate periodic orbits that agree qualitatively with the exact orbits, the method, nevertheless, fails miserably to reduce the large quantitative disagreement between the theoretically computed results with that of exact numerical orbits. In the second part of the work we present a novel asymptotic analysis incorporating SL(2,R) invariant nonlinear deformation of slower time scales, tn = ε n t, n → ∞, ε < 1, for asymptotic late time t, to a nonlinear time Tn = tnσ(tn), where the deformation factor σ(tn) > 0 respects some well defined SL(2,R) constraints. Motivations and detailed applications of such nonlinear asymptotic structures are explained in performing very high accuracy (> 98%) computations of relaxation orbits. Existence of an interesting condensation and rarefaction phenomenon in connection with dynamically adjustable scales in the context of a slow-fast dynamical system is explained and verified numerically.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Efficient Computation of Periodic Orbits of Forced Rayleigh Equation in the Framework of Novel Asymptotic Structures

Palit,

Datta,

Raut

2021

Preprint

Self Cite

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“…Kunihiro [28][29][30][31][32][33][34][35][36] tried to give the RG method a geometrical interpretation based on the classical theory of envelop in differential geometry. Furthermore the standard RG method and its geometrical formulas have been developed and applied to many problems [37][38][39][40][41][42][43][44][45][46][47][48][49][50][51][52][53][54][55][56] such as center manifolds [39], quantum kinetics [41,47], normal form theory [42], invariant manifold and reduction equation [43][44][45]52], variation of parameters [48] and resonance of quantum [51] and so forth. In addition, the error estimate of approximate solutions obtained by the RG method are given in [37,39,42], and comparison of RG method and homotopy analysis is discussed in [55].…”

Section: Introductionmentioning

confidence: 99%

The renormalization method based on the Taylor expansion and applications for asymptotic analysis

Liu

2017

Nonlinear Dyn

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Based on the Taylor expansion, we propose a renormalization method for asymptotic analysis. The standard renormalization group (RG) method for asymptotic analysis can be derived out from this new method, and hence the mathematical essence of the RG method is also recovered. The biggest advantage of the proposed method is that the secular terms in perturbation series are automatically eliminated, but in usual perturbation theory, we need more efforts and tricks to eliminate these terms. At the same time, the mathematical foundation of the method is simple and the logic of the method is very clear, therefore, it is very easy in practice. As application, we obtain the uniform valid asymptotic solutions to some problems including vector field, boundary layer and boundary value problems of nonlinear wave equations. Moreover, we discuss the normal form theory and reduction equations of dynamical systems. Furthermore, by combining the topological deformation and the RG method, a modified method namely the homotopy renormalization method (for simplicity, HTR) was proposed to overcome the weaknesses of the standard RG method. In this HTR method, since there is a freedom to choose the first order approximate solution in perturbation expansion, we can improve the global solution. In particular, for those equations including no a small parameter, the HTR method can also be applied. Some concrete applications including multi-solutions problems, the forced Duffing equation and the Blasius equation are given.

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Simplified Liénard Equation by Homotopy Analysis Method

Mitchell

2017

Differ Equ Dyn Syst

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Comparative Study of Homotopy Analysis and Renormalization Group Methods on Rayleigh and Van der Pol Equations

Cited by 15 publications

References 17 publications

Efficient Computation of Periodic Orbits of Forced Rayleigh Equation in the Framework of Novel Asymptotic Structures

Efficient Computation of Periodic Orbits of Forced Rayleigh Equation in the Framework of Novel Asymptotic Structures

The renormalization method based on the Taylor expansion and applications for asymptotic analysis

Simplified Liénard Equation by Homotopy Analysis Method

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