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Engineering Mechanics 3: Dynamics
Kategorie	Beschreibung
036a	XA-DE‡XD-US
037b	eng
077a	35314634X Buchausg. u.d.T.: ‡Engineering mechanics ; 3: Dynamics
087q	978-3-642-14018-1
100	Gross, Dietmar
104b	Hauger, Werner
108b	Schröder, Jörg
112b	Wall, Wolfgang
116b	Govindjee, Sanjay
331	Engineering Mechanics 3
335	Dynamics
410	Berlin, Heidelberg
412	Springer-Verlag Berlin Heidelberg
425	2011
425a	2011
433	Online-Ressource (IX, 359p. 160 illus. in color, digital)
451b	SpringerLink. Bücher
501	Includes index
517	""Preface""; ""Table of Contents""; ""Introduction""; ""Chapter 1""; ""1 Motion of a PointMass""; ""1.1 Kinematics""; ""1.1.1 Velocity and Acceleration""; ""1.1.2 Velocity and Acceleration in Cartesian Coordinates""; ""1.1.3 Rectilinear Motion""; ""1.1.4 Planar Motion, Polar Coordinates""; ""1.1.5 Three-Dimensional Motion, Serret-Frenet Frame""; ""1.2 Kinetics""; ""1.2.1 Newtonâ€?s Laws""; ""1.2.2 Free Motion, Projectiles""; ""1.2.3 Constrained Motion""; ""1.2.4 Resistance/Drag Forces""; ""1.2.5 Impulse Law and Linear Momentum, Impact""; ""1.2.6 Angular Momentum Theorem"". ""1.2.7 Work-Energy Theorem, Potential Energy, Conservation of Energy""""1.2.8 Universal Law of Gravitation, Planetary and Satellite Motion""; ""1.3 Supplementary Examples""; ""1.4 Summary""; ""Chapter 2""; ""2 Dynamics of Systems of Point Masses""; ""2.1 Fundamentals""; ""2.2 LinearMomentumfor a System of Point Masses""; ""2.3 Angular Momentum Theorem for a System of PointMasses""; ""2.4 Work-Energy Theorem and Conservation of Energy for a Systemof PointMasses""; ""2.5 Central Impact""; ""2.6 Bodies with VariableMass""; ""2.7 Supplementary Examples""; ""2.8 Summary""; ""Chapter 3"". ""3 Dynamics of Rigid Bodies""""3.1 Kinematics""; ""3.1.1 Translation""; ""3.1.2 Rotation""; ""3.1.3 General Motion""; ""3.1.4 Instantaneous Center of Rotation""; ""3.2 Kinetics of the Rotation about a Fixed Axis""; ""3.2.1 Principle of Angular Momentum""; ""3.2.2 Mass Moment of Inertia""; ""3.2.3 Work, Energy, Power""; ""3.3 Kinetics of a Rigid Body in Plane Motion""; ""3.3.1 Principles of Linear and Angular Momentum""; ""3.3.2 Impulse Laws, Work-Energy Theorem and Conservation of Energy""; ""3.3.3 Eccentric Impact""; ""3.4 Kinetics of a Rigid Body in Three DimensionalMotion"". ""3.4.1 Principles of Linear and Angular Momentum""""3.4.2 Angular Momentum, Inertia Tensor, Eulerâ€?s Equations""; ""3.4.3 Support Reactions in Plane Motion""; ""3.4.4 The Torque-Free Gyroscope""; ""3.5 Supplementary Examples""; ""3.6 Summary""; ""Chapter 4""; ""4 Principles of Mechanics""; ""4.1 Formal Reduction of Kinetics to Statics""; ""4.2 Dâ€?Alembertâ€?s Principle""; ""4.3 Lagrange Equations of the 2nd Kind""; ""4.4 Supplementary Examples""; ""4.5 Summary""; ""Chapter 5""; ""5 Vibrations""; ""5.1 Basic Concepts""; ""5.2 Free Vibrations""; ""5.2.1 Undamped Free Vibrations"". ""5.2.2 Spring Constants of Elastic Systems""""5.2.3 Damped Free Vibrations""; ""5.3 Forced Vibrations""; ""5.3.1 Undamped Forced Vibrations""; ""5.3.2 Damped Forced Vibrations""; ""5.4 Systems with two Degrees of Freedom""; ""5.4.1 Free Vibrations""; ""5.4.2 Forced Vibrations""; ""5.5 Supplementary Examples""; ""5.6 Summary""; ""Chapter 6""; ""6 Non-Inertial Reference Frames""; ""6.1 Kinematics of RelativeMotion""; ""6.1.1 Translating Reference Frames""; ""6.1.2 Translating and Rotating Reference Frames""; ""6.2 Kinetics of RelativeMotion""; ""6.3 Supplementary Examples""; ""6.4 Summary"". ""Chapter 7""
527	Buchausg. u.d.T.: ‡Engineering mechanics ; 3: Dynamics
540a	ISBN 978-3-642-14019-8
700	\|TGMD
700	\|TEC009070
700	\|SCI041000
700	\|*70-01
700b	\|620.1
700b	\|620.104
700c	\|TA349-359
750	Dynamics is the third volume of a three-volume textbook on Engineering Mechanics. It was written with the intention of presenting to engineering students the basic concepts and principles of mechanics in as simple a form as the subject allows. A second objective of this book is to guide the students in their efforts to solve problems in mechanics in a systematic manner. The simple approach to the theory of mechanics allows for the different educational backgrounds of the students. Another aim of this book is to provide engineering students as well as practising engineers with a basis to help them bridge the gaps between undergraduate studies, advanced courses on mechanics and practical engineering problems. The book contains numerous examples and their solutions. Emphasis is placed upon student participation in solving the problems. The contents of the book correspond to the topics normally covered in courses on basic engineering mechanics at universities and colleges. Volume 1 deals with Statics; Volume 2 contains Mechanics of Materials. Dietmar Gross received his Engineering Diploma in Applied Mechanics and his Doctor of Engineering degree at the University of Rostock. He was Research Associate at the University of Stuttgart and since 1976 he is Professor of Mechanics at the University of Darmstadt. His research interests are mainly focused on modern solid mechanics on the macro and micro scale, including advanced materials. Werner Hauger studied Applied Mathematics and Mechanics at the University of Karlsruhe and received his Ph.D. in Theoretical and Applied Mechanics from Northwestern University in Evanston. He worked in industry for several years, was a Professor at the Helmut-Schmidt-University in Hamburg and went to the University of Darmstadt in 1978. His research interests are, among others, theory of stability, dynamic plasticity and biomechanics. Jörg Schröder studied Civil Engineering, received his doctoral degree at the University of Hannover and habilitated at the University of Stuttgart. He was Professor of Mechanics at the University of Darmstadt and went to the University of Duisburg-Essen in 2001. His fields of research are theoretical and computer-oriented continuum mechanics, modeling of functional materials as well as the further development of the finite element method. Wolfgang A. Wall studied Civil Engineering at Innsbruck University and received his doctoral degree from the University of Stuttgart. Since 2003 he is Professor of Mechanics at the TU München and Head of the Institute for Computational Mechanics. His research interests cover broad fields in computational mechanics, including both solid and fluid mechanics. His recent focus is on multiphysics and multiscale problems as well as computational biomechanics. Sanjay Govindjee received his SB from MIT and an MS and PhD from Stanford University in mechanical engineering.He was an engineering analyst at the Lawrence Livermore National Laboratory (1991-93) and Professor of Mechanics at ETH Zurich (2006-08). Currently he is a Chancellor's Professor and Professor of Civil Engineering at the University of California Berkeley (1993-2006, 2008-present). His expertise lies in computational mechanics and the modeling of materials based upon molecular and atomic structure with a particular emphasis upon polymeric based materials, large deformations, and inelastic phenomena.
012	339783435
081	Gross, Dietmar <P>: Engineering Mechanics 3
100	Springer E-Book
125a	Elektronischer Volltext - Campuslizenz
655e	$uhttp://dx.doi.org/10.1007/978-3-642-14019-8