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A new computational technique for the stability analysis of slender rods (1992)

Sinha, S. C. ; Liu, Tai-Sheng ; Senthilnathan, N. R.

Springer

Archive of applied mechanics 62 (1992), S. 347-360

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ISSN: 1432-0681

Source: Springer Online Journal Archives 1860-2000

Topics: Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics

Description / Table of Contents: Übersicht Es wird ein neues Berechnungsverfahren für die Stabilitätsanalyse schlanker Stäbe mit veränderlichem Querschnitt unter allgemeinen Belastungen vorgestellt. Dabei werden die abhängigen Variablen und die variablen Koeffizienten der Bestimmungsgleichung in eine endliche Reihe von Tschebyscheff-Polynomen entwickelt. Die wesentliche Eigenschaft dieses Verfahrens ist die Reduzierung des ursprünglichen Randwertproblems einer Differentialgleichung auf ein algebraisches Eigenwertproblem. Angewandt wird die vorgeschlagene Methode auf die Euler-Knickung und das Flatterverhalten eines Kragträgers unter tangentialer Folgelast als konstanter Streckenlast. Die numerischen Ergebnisse nach diesem Verfahren erweisen sich als sehr genau im Vergleich zu Ergebnissen anderer Methoden, die in der Literatur zu finden sind. Es wird gezeigt, daß bei dieser Methode auch symbolische Lösungsverfahren angewandt werden können. Der Vorzug dieser neuen Methode gegenüber den Standard-Lösungsverfahren wie Finite-Differenzen- und Galerkin-Verfahren wird diskutiert.

Notes: Summary A new computational technique for the stability analysis of slender rods with variable cross-sections under general loading conditions is presented. In this approach, the dependent variable and the variable coefficients appearing in the governing equations are expanded in a finite series of Chebyshev polynomials. The main feature of this technique is that the original boundary value problem associated with the differential equation is reduced to an algebraic eigenvalue problem. The proposed technique is applied to study the static buckling of Euler column and the flutter behavior of a cantilever column subjected to uniformly distributed tangential loading. The numerical results from the suggested technique are found to be extremely accurate when compared to other techniques available in literature. It is shown that this approach can also be employed in a symbolic form. The merits of the present method in comparison to the standard solution procedures like finite difference and Galerkin methods are discussed.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00788642

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A new numerical technique for the analysis of parametrically excited nonlinear systems (1993)

Sinha, S. C. ; Senthilnathan, N. R. ; Pandiyan, R.

Springer

Nonlinear dynamics 4 (1993), S. 483-498

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ISSN: 1573-269X

Keywords: Nonlinear dynamic systems ; parametric excitation ; numerical integration ; Picard iteration ; Chebyshev polynomials ; periodic and aperiodic solutions

Source: Springer Online Journal Archives 1860-2000

Topics: Mathematics

Notes: Abstract A new computational scheme using Chebyshev polynomials is proposed for the numerical solution of parametrically excited nonlinear systems. The state vector and the periodic coefficients are expanded in Chebyshev polynomials and an integral equation suitable for a Picard-type iteration is formulated. A Chebyshev collocation is applied to the integral with the nonlinearities reducing the problem to the solution of a set of linear algebraic equations in each iteration. The method is equally applicable for nonlinear systems which are represented in state-space form or by a set of second-order differential equations. The proposed technique is found to duplicate the periodic, multi-periodic and chaotic solutions of a parametrically excited system obtained previously using the conventional numerical integration schemes with comparable CPU times. The technique does not require the inversion of the mass matrix in the case of multi degree-of-freedom systems. The present method is also shown to offer significant computational conveniences over the conventional numerical integration routines when used in a scheme for the direct determination of periodic solutions. Of course, the technique is also applicable to non-parametrically excited nonlinear systems as well.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00053692

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