Tytuł artykułu
Autorzy
Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
The Newton–Raphson method, which is based on the Taylor series and uses the tangent stiffness matrix, has been widely used to solve nonlinear problems. In this paper, a Newton-like algorithm is used for analyses involving geometric nonlinearity. This iterative technique that requires two initial guesses is known as two-point iterative method. In this method, a real function is assumed to approximate the tangent stiffness matrix of the structure. This paper, proposes an efficient function for reducing the computing time and, number of iterations in the Newton–Raphson method coupled with the two-point methodology. The computational nonlinear analysis on planar frames shows that the proposed strategy can reduce the computing time up to around 40%. Compared with the classic Newton–Raphson algorithm, the presented method proposes a methodology which also can reduce the number of iterations.
Czasopismo
Rocznik
Tom
Strony
485--492
Opis fizyczny
Bibliogr. 16 poz., tab., wykr.
Twórcy
autor
- Department of Civil Engineering, Shahid Bahonar University of Kerman, P.O.Box 76169133 Kerman, Iran
autor
- Department of Civil Engineering, Shahid Bahonar University of Kerman, P.O.Box 76169133 Kerman, Iran
Bibliografia
- [1] A. Kassimali, Large deformation analysis of elasticplastic frames, ASCE Journal of Structural Engineering 109 (8) (1983) 1869–1886.
- [2] H. Saffari, M.J. Fadaee, R. Tabatabaei, Nonlinear analysis of space trusses using modified normal flow algorithm, ASCE Journal of Structural Engineering 134 (6) (2008) 998–1005.
- [3] R. Tabatabaei, H. Saffari, Large strain analysis of two-dimensional frames by the normal flow algorithm, Structural Engineering and Mechanics 36 (5) (2010) 529–544.
- [4] M.H. Scott, F.C. Filippou, Response gradients for nonlinear beam-column elements under large displacements, ASCE Journal of Structural Engineering 133 (2) (2007) 155–165.
- [5] A. Kassimali, J.J. Garcilazo, Geometrically nonlinear analysis of plane frames subjected to temperature changes, ASCE Journal of Structural Engineering 136 (11) (2010) 1342–1349.
- [6] R. Tabatabaei, R.H. Saffari, M.J. Fadaee, Application of normal flow algorithm in modal adaptive pushover analysis, Journal of Construction Steel Research 65 (1) (2009) 89–96.
- [7] M.A. Noor, Some iterative methods free from second derivatives for nonlinear equations, Applied Mathematics and Computation 192 (1) (2007) 101–106.
- [8] M.A. Noor, K.I. Noor, Fifth-order iterative methods for solving nonlinear equations, Applied Mathematics and Computation 188 (1) (2007) 406–410.
- [9] M.S. Petkovic, L.D. Petkovic, Families of optimal multipoint methods for solving nonlinear equations: a survey, Applicable Analysis and Discrete Mathematics 4 (1) (2010) 1–22.
- [10] H. Saffari, I. Mansouri, Non-linear analysis of structures using two-point method, International Journal of Non-Linear Mechanics 46 (6) (2011) 834–840.
- [11] H. Saffari, I. Mansouri, M.H. Bagheripour, H. Dehghani, Elasto-plastic analysis of steel plane frames using Homotopy Perturbation method, Journal of Constructional Steel Research 70 (2012) 350–357.
- [12] S.L. Chan, P.P.T. Chui, Non-linear Static and Cyclic Analysis of Steel Frames with Semi-rigid Connections, Elsevier Science, The Netherlands, 2000.
- [13] M.A. Noor, F. Ahmad, S. Javeed, Two-step iterative methods for nonlinear equations, Applied Mathematics and Computation 181 (2) (2006) 1068–1075.
- [14] E.W. Williams, An approach to the nonlinear behaviour of the members of a rigid joint plane framework with finite deflections, The Quarterly Journal of Mechanics and Applied Mathematics 17 (4) (1964) 45–469.
- [15] S.A. Ragon, Z. Gurdal, L.T. Watson, A comparison of three algorithms for tracing nonlinear equilibrium paths of structural systems, International Journal of Solids and Structures 39 (3) (2002) 689–698.
- [16] K.V. Spiliopoulos, T.N. Patsios, An efficient mathematical programming method for the elastoplastic analysis of frames, Engineering Structure 32 (5) (2010) 1199–1214.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-c5ab56ba-a580-404f-a088-695fd5bd046e