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Finite element techniques in groundwater flow studies with applications in hydraulic and geotechnical engineering by Ivo Kazda

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Published by Elsevier in Amsterdam, New York .
Written in English

Subjects:

  • Groundwater flow -- Mathematical models.,
  • Finite element method.

Book details:

Edition Notes

Statementby Ivo Kazda ; [translation Zdeňka Jeniková].
SeriesDevelopments in geotechnical engineering ;, 61
Classifications
LC ClassificationsTC176 .K39 1990
The Physical Object
Paginationxiii, 313 p. :
Number of Pages313
ID Numbers
Open LibraryOL2197493M
ISBN 100444988106
LC Control Number89017215

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Get this from a library! Finite element techniques in groundwater flow studies: with applications in hydraulic and geotechnical engineering. [Ivo Kazda]. Get this from a library! Finite Element Techniques in Groundwater Flow Studies: With Applications in Hydraulic and Geotechnical Engineering.. [I Kazda] -- The finite element method (FEM) is one of those modern numerical methods whose rise and development was incited by the rapid development of computers. This method has found applications in all the. Finite Element Techniques in Groundwater Flow Studies The stimuli to write this book came from the results obtained in the solution of practical problems connected both with the construction and maintenance of fill-type dams and tailing dams and the utilization of groundwater in Czechoslovakia, and on the other hand from the experience. FINITE ELEMENT TECHNIQUES IN GROUNDWATER FLOW STUDIES WITH APPLICATIONS IN HYDRAULIC AND GEOTECHNICAL ENGINEERING by IVO KAZDA Department of Civil Engineering, Czech Technical University Prague, Czechoslovakia ELSEVIER Amsterdam Oxford New .

  Finite Element Techniques in Groundwater Flow Studies: With Applications in Hydraulic and Geotechnical Engineering (Developments in Geotechnical Engineering) by I. Kazda | . Introduction to Groundwater Modeling presents a broad, comprehensive overview of the fundamental concepts and applications of computerized groundwater modeling. The book covers both finite difference and finite element methods and includes practical sample programs that demonstrate theoretical points described in the by: A Modular Three-Dimensional Finite-Difference Ground-Water Flow Model. A Modular Three-Dimensional Finite-Difference Ground-Water Flow Model U.S. Geological Survey, Techniques of Water-Resources Investigations, Book 6, Chapter A1. by Michael G. McDonald and Arlen W. Harbaugh. About this book Published by the American Geophysical Union as part of the Water Resources Monograph Series, Volume The finite element method is now widely used to solve a variety of important problems in the field of groundwater hydrology.

Techniques of Water-Resources Investigations of the United States Geological Survey Chapter A4 A MODULAR FINITE-ELEMENT MODEL (MODFE) FOR AREAL AND AXISYMMETRIC GROUND-WATER FLOW PROBLEMS, PART 2: DERIVATION OF FINITE-ELEMENT EQUATIONS AND COMPARISONS WITH ANALYTICAL SOLUTIONS By Richard L. Cooley Book 6 Chapter A4 b. A numerical method is presented for analysing either steady state or transient three-dimensional groundwater flow problems. The governing equation is formulated in terms of the finite element process using the Galerkin approach, and cubic isoparametric elements are used to simulate the flow domain as these permit accurate modelling of curved boundaries. Finite Element Techniques in Groundwater Flow Studies: With Applications in Hydraulic and Geotechnical Engineering by Kazda, I. and Publisher Elsevier Science. Save up to 80% by choosing the eTextbook option for ISBN: , , The print version of this textbook is ISBN: , In the second the Galerkin finite element approximation is used in conjunction with a one‐dimensional finite difference approximation to handle flow in the fractures and matrix blocks, respectively. Both numerical techniques are shown to be readily amendable to the governing equations of the discrete fracture flow by: