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200 10$aMechanical Characterization of Materials and Wave Dispersion$b[electronic resource]
210   $aHoboken $cWiley$d2013
215   $a1 online resource (671 p.)
225 1 $aISTE ;$vv.79
300   $aDescription based upon print version of record.
311   $a1-84821-077-9 
327   $aCover; Mechanics of Viscoelastic Materials and Wave Dispersion; Title Page; Copyright Page; Table of Contents; Preface; Acknowledgements; PART A. CONSTITUTIVE EQUATIONS OF MATERIALS; Chapter 1. Elements of Anisotropic Elasticity and Complements on Previsional Calculations; 1.1. Constitutive equations in a linear elastic regime; 1.1.1. Symmetry applied to tensors sijkl and cijkl; 1.1.2. Constitutive equations under matrix form; 1.2. Technical elastic moduli; 1.2.1. Tension tests with one normal stress component ?; 1.2.2. Shear test; 1.3. Real materials with special symmetries
327   $a1.3.1. Change of reference axes1.3.2. Orthotropic materials possess two orthogonal planes of symmetry; 1.3.3. Quasi-isotropic transverse (tetragonal) material; 1.3.4. Transverse isotropic materials (hexagonal system); 1.3.5. Quasi-isotropic material (cubic system); 1.3.6. Isotropic materials; 1.4. Relationship between compliance Sij and stiffness Cij for orthotropic materials; 1.5. Useful inequalities between elastic moduli; 1.5.1. Orthotropic materials; 1.5.2. Quasi-transverse isotropic materials; 1.5.3. Transverse isotropic, quasi-isotropic, and isotropic materials
327   $a1.6. Transformation of reference axes is necessary in many circumstances1.6.1. Practical examples; 1.6.2. Components of stiffness and compliance after transformation; 1.6.3. Remarks on shear elastic moduli Gii (ij = 23, 31, 12) and stiffness constants Cii (with i = 4, 5, 6); 1.6.4. The practical consequence of a transformation of reference axes; 1.7. Invariants and their applications in the evaluation of elastic constants; 1.7.1. Elastic constants versus invariants; 1.7.2. Practical utilization of invariants in the evaluation of elastic constants; 1.8. Plane elasticity
327   $a1.8.1. Expression of plane stress stiffness versus compliance matrix1.8.2. Plane stress stiffness components versus three-dimensional stiffness components; 1.9. Elastic previsional calculations for anisotropic composite materials; 1.9.1. Long fibers regularly distributed in the matrix; 1.9.2. Stratified composite materials; 1.9.3. Reinforced fabric composite materials; 1.10. Bibliography; 1.11. Appendix; Appendix 1.A. Overview on methods used in previsional calculation of fiber-reinforced composite materials; Chapter 2. Elements of Linear Viscoelasticity
327   $a2.1. Time delay between sinusoidal stress and strain2.2. Creep and relaxation tests; 2.2.1. Creep test; 2.2.2. Relaxation test; 2.2.3. Ageing and non-ageing viscoelastic materials; 2.2.4. Viscoelastic materials with fading memory; 2.3. Mathematical formulation of linear viscoelasticity; 2.3.1. Linear system; 2.3.2. Superposition (or Boltzmann's) principle; 2.3.3. Creep function in a functional constitutive equation; 2.3.4. Relaxation function in functional constitutive equations; 2.3.5. Properties of relaxation and creep functions
327   $a2.4. Generalization of creep and relaxation functions to tridimensional constitutive equations
330   $aDynamic tests have proven to be as efficient as static tests and are often easier to use at lower frequency. Over the last 50 years, the methods of investigating dynamic properties have resulted in significant advances. This book explores dynamic testing, the methods used, and the experiments performed, placing a particular emphasis on the context of bounded medium elastodynamics.The discussion is divided into four parts. Part A focuses on the complements of continuum mechanics. Part B concerns the various types of rod vibrations: extensional, bending, and torsional. Part C is devoted to mecha
410  0$aISTE
606   $aDispersion -- Experiments
606   $aEngineering instruments
606   $aMaterials -- Mechanical properties -- Experiments
606   $aStructural engineering -- Materials -- Experiments
606   $aWave motion, Theory of -- Experiments
606   $aViscoelastic materials$xMechanical properties$xMathematical models
606   $aFlexible structures$xVibration$xMathematical models
606   $aStructural engineering$xMathematical models$xMaterials
606   $aWave-motion, Theory of$xMathematics
606   $aDispersion$xMathematical models
606   $aWave equation
606   $aChemical & Materials Engineering$2HILCC
606   $aEngineering & Applied Sciences$2HILCC
606   $aMaterials Science$2HILCC
615  4$aDispersion -- Experiments.
615  4$aEngineering instruments.
615  4$aMaterials -- Mechanical properties -- Experiments.
615  4$aStructural engineering -- Materials -- Experiments.
615  4$aWave motion, Theory of -- Experiments.
615  0$aViscoelastic materials$xMechanical properties$xMathematical models
615  0$aFlexible structures$xVibration$xMathematical models
615  0$aStructural engineering$xMathematical models$xMaterials
615  0$aWave-motion, Theory of$xMathematics
615  0$aDispersion$xMathematical models
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615  7$aChemical & Materials Engineering
615  7$aEngineering & Applied Sciences
615  7$aMaterials Science
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701   $aTuong$b Jean Vinh$0884192
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200 10$aForward-looking decision making $edynamic-programming models applied to health, risk, employment, and financial stability /$fRobert E. Hall
205   $aCourse Book
210   $aPrinceton, N.J. $cPrinceton University Press$dc2010
215   $a1 online resource (145 p.)
225 1 $aThe Gorman lectures in economics
300   $aDescription based upon print version of record.
311 08$a9780691142425 
311 08$a0691142424 
320   $aIncludes bibliographical references and index.
327   $t Frontmatter -- $tContents -- $tForeword / $rBlundell, Richard -- $tPreface -- $t1. Basic Analysis of Forward-Looking Decision Making -- $t2. Research on Properties of Preferences -- $t3. Health -- $t4. Insurance -- $t5. Employment -- $t6. Idiosyncratic Risk -- $t7. Financial Stability with Government-Guaranteed Debt -- $tReferences -- $tIndex -- $tThe Gorman Lectures in Economics / $rBlundell, Richard 
330   $aIndividuals and families make key decisions that impact many aspects of financial stability and determine the future of the economy. These decisions involve balancing current sacrifice against future benefits. People have to decide how much to invest in health care, exercise, their diet, and insurance. They must decide how much debt to take on, and how much to save. And they make choices about jobs that determine employment and unemployment levels. Forward-Looking Decision Making is about modeling this individual or family-based decision making using an optimizing dynamic programming model. Robert Hall first reviews ideas about dynamic programs and introduces new ideas about numerical solutions and the representation of solved models as Markov processes. He surveys recent research on the parameters of preferences--the intertemporal elasticity of substitution, the Frisch elasticity of labor supply, and the Frisch cross-elasticity. He then examines dynamic programming models applied to health spending, long-term care insurance, employment, entrepreneurial risk-taking, and consumer debt. Linking theory with data and applying them to real-world problems, Forward-Looking Decision Making uses dynamic optimization programming models to shed light on individual behaviors and their economic implications.
410  0$aGorman lectures in economics.
606   $aHouseholds$xDecision making$xEconometric models
606   $aFamilies$xDecision making$xEconometric models
606   $aDecision making$xEconometric models
615  0$aHouseholds$xDecision making$xEconometric models.
615  0$aFamilies$xDecision making$xEconometric models.
615  0$aDecision making$xEconometric models.
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