000 03419nam a22005535i 4500
001 978-3-642-36101-2
003 DE-He213
005 20200420220224.0
007 cr nn 008mamaa
008 130125s2013 gw | s |||| 0|eng d
020 _a9783642361012
_9978-3-642-36101-2
024 7 _a10.1007/978-3-642-36101-2
_2doi
050 4 _aTA329-348
050 4 _aTA640-643
072 7 _aTBJ
_2bicssc
072 7 _aMAT003000
_2bisacsh
082 0 4 _a519
_223
100 1 _aAlotto, Piergiorgio.
_eauthor.
245 1 4 _aThe Cell Method for Electrical Engineering and Multiphysics Problems
_h[electronic resource] :
_bAn Introduction /
_cby Piergiorgio Alotto, Fabio Freschi, Maurizio Repetto, Carlo Rosso.
264 1 _aBerlin, Heidelberg :
_bSpringer Berlin Heidelberg :
_bImprint: Springer,
_c2013.
300 _aXII, 129 p.
_bonline resource.
336 _atext
_btxt
_2rdacontent
337 _acomputer
_bc
_2rdamedia
338 _aonline resource
_bcr
_2rdacarrier
347 _atext file
_bPDF
_2rda
490 1 _aLecture Notes in Electrical Engineering,
_x1876-1100 ;
_v230
505 0 _aTonti diagrams.-Topological equations -- Constitutive equations -- Classical physical problems -- Multiphysics problems -- Implementation.
520 _aThis book presents a numerical scheme for the solution of field problems governed by partial differential equations: the cell method. The technique lends itself naturally to the solution of multiphysics problems with several interacting phenomena. The Cell Method, based on a space-time tessellation, is intimately related to the work of Tonti and to his ideas of classification diagrams or, as they are nowadays called, Tonti diagrams: a graphical representation of the problem's equations made possible by a suitable selection of a space-time framework relating physical variables to each other. The main features of the cell method are presented and links with many other discrete numerical methods (finite integration techniques, finite difference time domain, finite volumes, mimetic finite differences, etc.) are discussed. After outlining the theoretical basis of the method, a set of physical problems which have been solved with the cell method is described. These single and multiphysics problems stem from the authors' research experience in the fields of electromagnetism, elasticity, thermo-elasticity and others. Finally, the implementation of the numerical technique is described in all its main components: space-time discretization, problem formulation, solution and representation of the resulting physical fields.  .
650 0 _aEngineering.
650 0 _aPhysics.
650 0 _aApplied mathematics.
650 0 _aEngineering mathematics.
650 0 _aElectrical engineering.
650 1 4 _aEngineering.
650 2 4 _aAppl.Mathematics/Computational Methods of Engineering.
650 2 4 _aElectrical Engineering.
650 2 4 _aNumerical and Computational Physics.
700 1 _aFreschi, Fabio.
_eauthor.
700 1 _aRepetto, Maurizio.
_eauthor.
700 1 _aRosso, Carlo.
_eauthor.
710 2 _aSpringerLink (Online service)
773 0 _tSpringer eBooks
776 0 8 _iPrinted edition:
_z9783642361005
830 0 _aLecture Notes in Electrical Engineering,
_x1876-1100 ;
_v230
856 4 0 _uhttp://dx.doi.org/10.1007/978-3-642-36101-2
912 _aZDB-2-ENG
942 _cEBK
999 _c52056
_d52056