Bibliographies thématiques / Boundary element methods

Littérature scientifique sur le sujet « Boundary element methods »

Auteur : Grafiati

Publié le 4 juin 2021

Mis à jour le 6 septembre 2023

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Articles de revues sur le sujet "Boundary element methods"

Nedelec, Jean-Claude, Goong Chen et Jianxin Zhou. « Boundary Element Methods. » Mathematics of Computation 60, n^o 202 (avril 1993) : 851. http://dx.doi.org/10.2307/2153130.

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Chaillat-Loseille, Stéphanie, Ralf Hiptmair et Olaf Steinbach. « Boundary Element Methods ». Oberwolfach Reports 17, n^o 1 (9 février 2021) : 273–376. http://dx.doi.org/10.4171/owr/2020/5.

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Feischl, Michael, Thomas Führer, Norbert Heuer, Michael Karkulik et Dirk Praetorius. « Adaptive Boundary Element Methods ». Archives of Computational Methods in Engineering 22, n^o 3 (27 juin 2014) : 309–89. http://dx.doi.org/10.1007/s11831-014-9114-z.

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Khoromskij, B. N., et J. M. Melenk. « Boundary Concentrated Finite Element Methods ». SIAM Journal on Numerical Analysis 41, n^o 1 (janvier 2003) : 1–36. http://dx.doi.org/10.1137/s0036142901391852.

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Beskos, D. E., et U. Heise. « Boundary Element Methods in Mechanics ». Journal of Applied Mechanics 55, n^o 4 (1 décembre 1988) : 997. http://dx.doi.org/10.1115/1.3173761.

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Bonnet, Marc, Giulio Maier et Castrenze Polizzotto. « Symmetric Galerkin Boundary Element Methods ». Applied Mechanics Reviews 51, n^o 11 (1 novembre 1998) : 669–704. http://dx.doi.org/10.1115/1.3098983.

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This review article concerns a methodology for solving numerically, for engineering purposes, boundary and initial-boundary value problems by a peculiar approach characterized by the following features: the continuous formulation is centered on integral equations based on the combined use of single-layer and double-layer sources, so that the integral operator turns out to be symmetric with respect to a suitable bilinear form. The discretization is performed either on a variational basis or by a Galerkin weighted residual procedure, the interpolation and weight functions being chosen so that the variables in the approximate formulation are generalized variables in Prager’s sense. As main consequences of the above provisions, symmetry is exhibited by matrices with a key role in the algebraized versions; some quadratic forms have a clear energy meaning; variational properties characterize the solutions and other results, invalid in traditional boundary element methods enrich the theory underlying the computational applications. The present survey outlines recent theoretical and computational developments of the title methodology with particular reference to linear elasticity, elastoplasticity, fracture mechanics, time-dependent problems, variational approaches, singular integrals, approximation issues, sensitivity analysis, coupling of boundary and finite elements, and computer implementations. Areas and aspects which at present require further research are identified, and comparative assessments are attempted with respect to traditional boundary integral-elements. This article includes 176 references.

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Costabel, Martin. « Principles of boundary element methods ». Computer Physics Reports 6, n^o 1-6 (août 1987) : 243–74. http://dx.doi.org/10.1016/0167-7977(87)90014-1.

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Hsiao, George C. « Boundary element methods—An overview ». Applied Numerical Mathematics 56, n^o 10-11 (octobre 2006) : 1356–69. http://dx.doi.org/10.1016/j.apnum.2006.03.030.

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Faust, G., et J. Szimmat. « Developments in boundary element methods ». Computer Methods in Applied Mechanics and Engineering 60, n^o 2 (février 1987) : 253–54. http://dx.doi.org/10.1016/0045-7825(87)90112-5.

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Faermann, Birgit. « Adaptive galerkin boundary element methods ». ZAMM - Journal of Applied Mathematics and Mechanics / Zeitschrift für Angewandte Mathematik und Mechanik 78, S3 (1998) : 909–10. http://dx.doi.org/10.1002/zamm.19980781527.

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Thèses sur le sujet "Boundary element methods"

Of, Günther, Gregory J. Rodin, Olaf Steinbach et Matthias Taus. « Coupling Methods for Interior Penalty Discontinuous Galerkin Finite Element Methods and Boundary Element Methods ». Universitätsbibliothek Chemnitz, 2012. http://nbn-resolving.de/urn:nbn:de:bsz:ch1-qucosa-96885.

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This paper presents three new coupling methods for interior penalty discontinuous Galerkin finite element methods and boundary element methods. The new methods allow one to use discontinuous basis functions on the interface between the subdomains represented by the finite element and boundary element methods. This feature is particularly important when discontinuous Galerkin finite element methods are used. Error and stability analysis is presented for some of the methods. Numerical examples suggest that all three methods exhibit very similar convergence properties, consistent with available theoretical results.

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Ostrowski, Jörg. « Boundary element methods for inductive hardening ». [S.l. : s.n.], 2003. http://deposit.ddb.de/cgi-bin/dokserv?idn=973933941.

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Onyango, Thomas Tonny Mboya. « Boundary element methods for solving inverse boundary conditions identification problems ». Thesis, University of Leeds, 2008. http://etheses.whiterose.ac.uk/11283/.

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This thesis explores various features of the boundary element method (BEM) used in solving heat transfer boundary conditions identification problems. In particular, we present boundary integral equation (BIE) formulations and procedures of the numerical computation for the approximation of the boundary temperatures, heat fluxes and space, time or temperature dependent heat transfer coefficients. There are many practical heat transfer situations where such problems occur, for example in high temperature regions or hostile environments, such as in combustion chambers, steel cooling processes, etc., in which the actual method of heat transfer on the surface is unknown. In such situations the boundary condition relating the heat flux to the difference between the boundary temperature and that of the surrounding fluid is represented by an unknown function which may depend on space, time, or temperature. In these inverse heat conduction problems (IHCP), the BEM is formulated as a minimization of some functional that measures the discrepancy between the measured data, say the average temperature on a portion of the boundary or at an instant over the whole domain. The minimization provides solutions that are consistent with the data. This indicates that the BEM algorithms for the IRCP are robust, stable and predict reliable results. When the input data is noisy, we have used the truncated singular value decomposition and the Tikhonov regularisation methods to stabilise the solution of the IRCI' boundary conditions identification. Numerical approximations have been obtained and, where possible, the results obtained are compared to the analytical solutions.

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Shah, Nawazish A. « Boundary element methods for road vehicle aerodynamics ». Thesis, Loughborough University, 1985. https://dspace.lboro.ac.uk/2134/26942.

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The technique of the boundary element method consists of subdividing the boundary of the field of a function into a series of discrete elements, over which the function can vary. This technique offers important advantages over domain type solutions such as finite elements and finite differences. One of the most important features of the method is the much smaller system of equations and the considerable reduction in data required to run a program. Furthermore, the method is well-suited to problems with an infinite domain. Boundary element methods can be formulated using two different approaches called the ‘direct' and the ‘indirect' methods.

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Leon, Ernesto Pineda. « Dual boundary element methods for creep fracture ». Thesis, Queen Mary, University of London, 2006. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.435177.

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OLIVEIRA, MARIA FERNANDA FIGUEIREDO DE. « CONVENTIONAL, HYBRID AND SIMPLIFIED BOUNDARY ELEMENT METHODS ». PONTIFÍCIA UNIVERSIDADE CATÓLICA DO RIO DE JANEIRO, 2004. http://www.maxwell.vrac.puc-rio.br/Busca_etds.php?strSecao=resultado&nrSeq=5562@1.

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COORDENAÇÃO DE APERFEIÇOAMENTO DO PESSOAL DE ENSINO SUPERIOR
Apresentam-se as formulações, consolidando a nomenclatura e os principais conceitos dos métodos de elementos de contorno: convencional (MCCEC), híbrido de tensões (MHTEC), híbrido de deslocamentos (MHDEC) e híbrido simplificado de tensões (MHSTEC). proposto o método híbrido simplificado de deslocamentos (MHSDEC), em contrapartida ao MHSTEC, baseando-se nas mesmas hipóteses de aproximação de tensões e deslocamentos do MHDEC e supondo que a solução fundamental em termos de tensões seja válida no contorno. Como decorrência do MHSTEC e do MHSDEC, é apresentado também o método híbrido de malha reduzida dos elementos de contorno (MHMREC), com aplicação computacionalmente vantajosa a problemas no domínio da freqüência ou envolvendo materiais não-homogêneos. A partir da investigação das equações matriciais desses métodos, são identificadas quatro novas relações matriciais, das quais uma verifica-se como válida para a obtenção dos elementos das matrizes de flexibilidade e de deslocamento que não podem ser determinados por integração ou avaliação direta. Também é proposta a correta consideração, ainda não muito bem explicada na literatura, de que forças de superfície devem ser interpoladas em função de atributos de superfície e não de atributos nodais. São apresentadas aplicações numéricas para problemas de potencial para cada método mencionado, em que é verificada a validade das novas relações matriciais.
A consolidated, unified formulation of the conventional (CCBEM), hybrid stress (HSBEM), hybrid displacement (HDBEM) and simplified hybrid stress (SHSBEM) boundary element methods is presented. As a counterpart of SHSBEM, the simplified hybrid displacement boundary element method (SHDBEM) is proposed on the basis of the same stress and displacement approximation hypotheses of the HDBEM and on the assumption that stress fundamental solutions are also valid on the boundary. A combination of the SHSBEM and the SHDBEM gives rise to a provisorily called mesh-reduced hybrid boundary element method (MRHBEM), which seems computationally advantageous when applied to frequency domain problems or non-homogeneous materials. Four new matrix relations are identified, one of which may be used to obtain the flexibility and displacement matrix coefficients that cannot be determined by integration or direct evaluation. It is also proposed the correct consideration, still not well explained in the technical literature, that traction forces should be interpolated as functions of surface and not of nodal attributes. Numerical examples of potential problems are presented for each method, in which the validity of the new matrix relations is verified.

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Zarco, Mark Albert. « Solution fo soil-structure interaction problems by coupled boundary element-finite element method / ». This resource online, 1993. http://scholar.lib.vt.edu/theses/available/etd-06062008-164808/.

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Vu, Thu Hang. « Enhancing the scaled boundary finite element method ». University of Western Australia. School of Civil and Resource Engineering, 2006. http://theses.library.uwa.edu.au/adt-WU2006.0068.

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[Truncated abstract] The scaled boundary finite element method is a novel computational method developed by Wolf and Song which reduces partial differential equations to a set of ordinary linear differential equations. The method, which is semi-analytical, is suitable for solving linear elliptic, parabolic and hyperbolic partial differential equations. The method has proved to be very efficient in solving various types of problems, including problems of potential flow and diffusion. The method out performs the finite element method when solving unbounded domain problems and problems involving stress singularities and discontinuities. The scaled boundary finite element method involves solution of a quadratic eigenproblem, the computational expense of which increases rapidly as the number of degrees of freedom increases. Consequently, to a greater extent than the finite element method, it is desirable to obtain solutions at a specified level of accuracy while using the minimum number of degrees of freedom necessary. In previous work, no systematic study had been performed so far into the use of elements of higher order, and no consideration made of p adaptivity. . . The primal problem is solved normally using the basic scaled boundary finite element method. The dual problem is solved by the new technique using the fundamental solution. A guaranteed upper error bound based on the Cauchy-Schwarz inequality is derived. A iv goal-oriented p-hierarchical adaptive procedure is proposed and implemented efficiently in the scaled boundary finite element method.

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Yan, Shu. « Efficient numerical methods for capacitance extraction based on boundary element method ». Texas A&M University, 2005. http://hdl.handle.net/1969.1/3230.

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Fast and accurate solvers for capacitance extraction are needed by the VLSI industry in order to achieve good design quality in feasible time. With the development of technology, this demand is increasing dramatically. Three-dimensional capacitance extraction algorithms are desired due to their high accuracy. However, the present 3D algorithms are slow and thus their application is limited. In this dissertation, we present several novel techniques to significantly speed up capacitance extraction algorithms based on boundary element methods (BEM) and to compute the capacitance extraction in the presence of floating dummy conductors. We propose the PHiCap algorithm, which is based on a hierarchical refinement algorithm and the wavelet transform. Unlike traditional algorithms which result in dense linear systems, PHiCap converts the coefficient matrix in capacitance extraction problems to a sparse linear system. PHiCap solves the sparse linear system iteratively, with much faster convergence, using an efficient preconditioning technique. We also propose a variant of PHiCap in which the capacitances are solved for directly from a very small linear system. This small system is derived from the original large linear system by reordering the wavelet basis functions and computing an approximate LU factorization. We named the algorithm RedCap. To our knowledge, RedCap is the first capacitance extraction algorithm based on BEM that uses a direct method to solve a reduced linear system. In the presence of floating dummy conductors, the equivalent capacitances among regular conductors are required. For floating dummy conductors, the potential is unknown and the total charge is zero. We embed these requirements into the extraction linear system. Thus, the equivalent capacitance matrix is solved directly. The number of system solves needed is equal to the number of regular conductors. Based on a sensitivity analysis, we propose the selective coefficient enhancement method for increasing the accuracy of selected coupling or self-capacitances with only a small increase in the overall computation time. This method is desirable for applications, such as crosstalk and signal integrity analysis, where the coupling capacitances between some conductors needs high accuracy. We also propose the variable order multipole method which enhances the overall accuracy without raising the overall multipole expansion order. Finally, we apply the multigrid method to capacitance extraction to solve the linear system faster. We present experimental results to show that the techniques are significantly more efficient in comparison to existing techniques.

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Hamina, M. (Martti). « Some boundary element methods for heat conduction problems ». Doctoral thesis, University of Oulu, 2000. http://urn.fi/urn:isbn:951425614X.

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Abstract This thesis summarizes certain boundary element methods applied to some initial and boundary value problems. Our model problem is the two-dimensional homogeneous heat conduction problem with vanishing initial data. We use the heat potential representation of the solution. The given boundary conditions, as well as the choice of the representation formula, yield various boundary integral equations. For the sake of simplicity, we use the direct boundary integral approach, where the unknown boundary density appearing in the boundary integral equation is a quantity of physical meaning. We consider two different sets of boundary conditions, the Dirichlet problem, where the boundary temperature is given and the Neumann problem, where the heat flux across the boundary is given. Even a nonlinear Neumann condition satisfying certain monotonicity and growth conditions is possible. The approach yields a nonlinear boundary integral equation of the second kind. In the stationary case, the model problem reduces to a potential problem with a nonlinear Neumann condition. We use the spaces of smoothest splines as trial functions. The nonlinearity is approximated by using the L2-orthogonal projection. The resulting collocation scheme retains the optimal L2-convergence. Numerical experiments are in agreement with this result. This approach generalizes to the time dependent case. The trial functions are tensor products of piecewise linear and piecewise constant splines. The proposed projection method uses interpolation with respect to the space variable and the orthogonal projection with respect to the time variable. Compared to the Galerkin method, this approach simplifies the realization of the discrete matrix equations. In addition, the rate of the convergence is of optimal order. On the other hand, the Dirichlet problem, where the boundary temperature is given, leads to a single layer heat operator equation of the first kind. In the first approach, we use tensor products of piecewise linear splines as trial functions with collocation at the nodal points. Stability and suboptimal L2-convergence of the method were proved in the case of a circular domain. Numerical experiments indicate the expected quadratic L2-convergence. Later, a Petrov-Galerkin approach was proposed, where the trial functions were tensor products of piecewise linear and piecewise constant splines. The resulting approximative scheme is stable and convergent. The analysis has been carried out in the cases of the single layer heat operator and the hypersingular heat operator. The rate of the convergence with respect to the L2-norm is also here of suboptimal order.

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Livres sur le sujet "Boundary element methods"

Sauter, Stefan A., et Christoph Schwab. Boundary Element Methods. Berlin, Heidelberg : Springer Berlin Heidelberg, 2011. http://dx.doi.org/10.1007/978-3-540-68093-2.

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Kobayashi, S., et N. Nishimura, dir. Boundary Element Methods. Berlin, Heidelberg : Springer Berlin Heidelberg, 1992. http://dx.doi.org/10.1007/978-3-662-06153-4.

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Gwinner, Joachim, et Ernst Peter Stephan. Advanced Boundary Element Methods. Cham : Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-92001-6.

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Cruse, Thomas A., dir. Advanced Boundary Element Methods. Berlin, Heidelberg : Springer Berlin Heidelberg, 1988. http://dx.doi.org/10.1007/978-3-642-83003-7.

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A, Brebbia C., et Aliabadi M. H, dir. Adaptive finite and boundary element methods. Southampton : Computational Mechanics Publications, 1993.

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Ying, Lung-an. Infinite element methods. Beijing : Peking University Press, 1995.

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Annigeri, Balkrishna S., et Kadin Tseng, dir. Boundary Element Methods in Engineering. Berlin, Heidelberg : Springer Berlin Heidelberg, 1990. http://dx.doi.org/10.1007/978-3-642-84238-2.

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Kythe, P. K. Introduction to boundary element methods. Boca Raton : CRC Press, 1995.

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Manolis, G. D. Boundary element methods in elastodynamics. London : Unwin Hyman, 1988.

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D, Ciskowski R., et Brebbia C. A, dir. Boundary element methods in acoustics. Southampton : Computational Mechanics Publications, 1991.

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Chapitres de livres sur le sujet "Boundary element methods"

Sauter, Stefan A., et Christoph Schwab. « Boundary Element Methods ». Dans Boundary Element Methods, 183–287. Berlin, Heidelberg : Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-540-68093-2_4.

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Sauter, Stefan A., et Christoph Schwab. « Cluster Methods ». Dans Boundary Element Methods, 403–65. Berlin, Heidelberg : Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-540-68093-2_7.

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Beer, Gernot, et Benjamin Marussig. « Boundary Element Methods ». Dans Isogeometric Methods for Numerical Simulation, 121–72. Vienna : Springer Vienna, 2015. http://dx.doi.org/10.1007/978-3-7091-1843-6_3.

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Aliabadi, Ferri M. H. « Boundary Element Methods ». Dans Encyclopedia of Continuum Mechanics, 1–12. Berlin, Heidelberg : Springer Berlin Heidelberg, 2018. http://dx.doi.org/10.1007/978-3-662-53605-6_18-1.

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Kythe, Prem K. « Boundary Element Methods ». Dans Fundamental Solutions for Differential Operators and Applications, 231–65. Boston, MA : Birkhäuser Boston, 1996. http://dx.doi.org/10.1007/978-1-4612-4106-5_11.

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Aliabadi, Ferri M. H. « Boundary Element Methods ». Dans Encyclopedia of Continuum Mechanics, 182–93. Berlin, Heidelberg : Springer Berlin Heidelberg, 2020. http://dx.doi.org/10.1007/978-3-662-55771-6_18.

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Wrobel, Luiz Carlos. « Boundary Element Methods ». Dans Encyclopedia of Applied and Computational Mathematics, 146–51. Berlin, Heidelberg : Springer Berlin Heidelberg, 2015. http://dx.doi.org/10.1007/978-3-540-70529-1_365.

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Sauter, Stefan A., et Christoph Schwab. « Introduction ». Dans Boundary Element Methods, 1–19. Berlin, Heidelberg : Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-540-68093-2_1.

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Sauter, Stefan A., et Christoph Schwab. « Elliptic Differential Equations ». Dans Boundary Element Methods, 21–100. Berlin, Heidelberg : Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-540-68093-2_2.

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Sauter, Stefan A., et Christoph Schwab. « Elliptic Boundary Integral Equations ». Dans Boundary Element Methods, 101–81. Berlin, Heidelberg : Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-540-68093-2_3.

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Actes de conférences sur le sujet "Boundary element methods"

Rajapakse, R. K. N. D. « Boundary element methods for piezoelectric solids ». Dans Smart Structures and Materials '97, sous la direction de Vasundara V. Varadan et Jagdish Chandra. SPIE, 1997. http://dx.doi.org/10.1117/12.276560.

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Rott, Relindis, et Martin Schanz. « EFFICIENT BOUNDARY ELEMENT FORMULATION OF THERMOELASTICITY ». Dans VII European Congress on Computational Methods in Applied Sciences and Engineering. Athens : Institute of Structural Analysis and Antiseismic Research School of Civil Engineering National Technical University of Athens (NTUA) Greece, 2016. http://dx.doi.org/10.7712/100016.2025.7178.

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Yan, Shu, Jianguo Liu et Weiping Shi. « Improving boundary element methods for parasitic extraction ». Dans the 2003 conference. New York, New York, USA : ACM Press, 2003. http://dx.doi.org/10.1145/1119772.1119823.

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Santana, Andre Pereira, Eder Lima de Albuquerque et Vania Maria Costa Sousa. « Boundary element method to analysis nonlinear in elasticity ». Dans XXXVIII Iberian-Latin American Congress on Computational Methods in Engineering. Florianopolis, Brazil : ABMEC Brazilian Association of Computational Methods in Engineering, 2017. http://dx.doi.org/10.20906/cps/cilamce2017-1188.

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Ptaszny, Jacek. « Parallel fast multipole boundary element method applied to computational homogenization ». Dans COMPUTER METHODS IN MECHANICS (CMM2017) : Proceedings of the 22nd International Conference on Computer Methods in Mechanics. Author(s), 2018. http://dx.doi.org/10.1063/1.5019145.

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Zhang, Zhiyuan, et Ashok V. Kumar. « Modal Analysis Using Implicit Boundary Finite Element Methods ». Dans ASME 2014 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. American Society of Mechanical Engineers, 2014. http://dx.doi.org/10.1115/detc2014-35100.

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Modal analysis is widely used for linear dynamic analysis of structures. The finite element method is used to numerically compute stiffness and mass matrices and the corresponding eigenvalue problem is solved to determine the natural frequencies and mode shapes of vibration. Implicit boundary method was developed to use equations of the boundary to apply boundary conditions and loads so that a background mesh can be used for analysis. A background mesh is easier to generate because the elements do not have to conform to the given geometry and therefore uniform regular shaped elements can be used. In this paper, we show that this approach is suitable for modal analysis and modal superposition techniques as well. Furthermore, the implicit boundary method also allows higher order elements that use B-spline approximations. Several test examples are studied for verification.

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Dargush, Gary, et Mikhail Grigoriev. « Boundary Element Methods for Unsteady Convective Heat Diffusion ». Dans 36th AIAA Thermophysics Conference. Reston, Virigina : American Institute of Aeronautics and Astronautics, 2003. http://dx.doi.org/10.2514/6.2003-4204.

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Sivak, Sergey A., Mikhail E. Royak et Ilya M. Stupakov. « Coupling of Vector and Scalar Boundary Element Methods ». Dans 2021 XV International Scientific-Technical Conference on Actual Problems Of Electronic Instrument Engineering (APEIE). IEEE, 2021. http://dx.doi.org/10.1109/apeie52976.2021.9647694.

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Beer, Gernot. « ADVANCES IN THE BOUNDARY ELEMENT METHOD IN GEOMECHANICS ». Dans VII European Congress on Computational Methods in Applied Sciences and Engineering. Athens : Institute of Structural Analysis and Antiseismic Research School of Civil Engineering National Technical University of Athens (NTUA) Greece, 2016. http://dx.doi.org/10.7712/100016.2021.4408.

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Peixoto, Rodrigo Guerra, Samuel Silva Penna, Gabriel de Oliveira Ribeiro et Roque Luiz da Silva Pitangueira. « Non-local constitutive modelling by the boundary element method ». Dans XXXVIII Iberian-Latin American Congress on Computational Methods in Engineering. Florianopolis, Brazil : ABMEC Brazilian Association of Computational Methods in Engineering, 2017. http://dx.doi.org/10.20906/cps/cilamce2017-0187.

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Rapports d'organisations sur le sujet "Boundary element methods"

GRIFFITH, RICHARD O., et KENNETH K. MURATA. Proposed Extension of FETI Methods to the Boundary Element Technique. Office of Scientific and Technical Information (OSTI), octobre 2001. http://dx.doi.org/10.2172/787646.

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Gray, L. J. (Environmental and geophysical modeling, fracture mechanics, and boundary element methods). Office of Scientific and Technical Information (OSTI), novembre 1990. http://dx.doi.org/10.2172/6369024.

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Babuska, I., B. Q. Guo et E. P. Stephan. On the Exponential Convergence of the h-p Version for Boundary Element Galerkin Methods on Polygons. Fort Belvoir, VA : Defense Technical Information Center, mai 1989. http://dx.doi.org/10.21236/ada215814.

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Cox, J. V. A Preliminary Study on Finite Element-Hosted Couplings with the Boundary Element Method. Fort Belvoir, VA : Defense Technical Information Center, avril 1988. http://dx.doi.org/10.21236/ada197539.

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Zhao, George, Grang Mei, Bulent Ayhan, Chiman Kwan et Venu Varma. DTRS57-04-C-10053 Wave Electromagnetic Acoustic Transducer for ILI of Pipelines. Chantilly, Virginia : Pipeline Research Council International, Inc. (PRCI), mars 2005. http://dx.doi.org/10.55274/r0012049.

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In this project, Intelligent Automation, Incorporated (IAI) and Oak Ridge National Lab (ORNL) propose a novel and integrated approach to inspect the mechanical dents and metal loss in pipelines. It combines the state-of-the-art SH wave Electromagnetic Acoustic Transducer (EMAT) technique, through detailed numerical modeling, data collection instrumentation, and advanced signal processing and pattern classifications, to detect and characterize mechanical defects in the underground pipeline transportation infrastructures. The technique has four components: (1) thorough guided wave modal analysis, (2) recently developed three-dimensional (3-D) Boundary Element Method (BEM) for best operational condition selection and defect feature extraction, (3) ultrasonic Shear Horizontal (SH) waves EMAT sensor design and data collection, and (4) advanced signal processing algorithm like a nonlinear split-spectrum filter, Principal Component Analysis (PCA) and Discriminant Analysis (DA) for signal-to-noise-ratio enhancement, crack signature extraction, and pattern classification. This technology not only can effectively address the problems with the existing methods, i.e., to detect the mechanical dents and metal loss in the pipelines consistently and reliably but also it is able to determine the defect shape and size to a certain extent.

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Paulino, G. H., L. J. Gray et V. Zarikian. A posteriori pointwise error estimates for the boundary element method. Office of Scientific and Technical Information (OSTI), janvier 1995. http://dx.doi.org/10.2172/42836.

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Hong, S. W., W. W. Schultz et W. P. Graebel. An Alternative Complex Boundary Element Method for Nonlinear Free Surface Problems. Fort Belvoir, VA : Defense Technical Information Center, février 1988. http://dx.doi.org/10.21236/ada250817.

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Babuska, Ivo, Victor Nistor et Nicolae Tarfulea. Approximate Dirichlet Boundary Conditions in the Generalized Finite Element Method (PREPRINT). Fort Belvoir, VA : Defense Technical Information Center, février 2006. http://dx.doi.org/10.21236/ada478502.

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Driessen, B. J., et J. L. Dohner. A finite element-boundary element method for advection-diffusion problems with variable advective fields and infinite domains. Office of Scientific and Technical Information (OSTI), août 1998. http://dx.doi.org/10.2172/677125.

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Andraka, C. E., G. A. Knorovsky et C. A. Drewien. Boundary element method applied to a gas-fired pin-fin-enhanced heat pipe. Office of Scientific and Technical Information (OSTI), février 1998. http://dx.doi.org/10.2172/672137.

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