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ویرایش: 1
نویسندگان: Srinivasan Gopalakrishnan
سری:
ISBN (شابک) : 036763757X, 9780367637576
ناشر: CRC Press
سال نشر: 2022
تعداد صفحات: 430
زبان: English
فرمت فایل : PDF (درصورت درخواست کاربر به PDF، EPUB یا AZW3 تبدیل می شود)
حجم فایل: 24 مگابایت
در صورت تبدیل فایل کتاب Elastic Wave Propagation in Structures and Materials به فرمت های PDF، EPUB، AZW3، MOBI و یا DJVU می توانید به پشتیبان اطلاع دهید تا فایل مورد نظر را تبدیل نمایند.
توجه داشته باشید کتاب انتشار موج الاستیک در سازه ها و مواد نسخه زبان اصلی می باشد و کتاب ترجمه شده به فارسی نمی باشد. وبسایت اینترنشنال لایبرری ارائه دهنده کتاب های زبان اصلی می باشد و هیچ گونه کتاب ترجمه شده یا نوشته شده به فارسی را ارائه نمی دهد.
انتشار موج الاستیک در سازهها و مواد با مقدمهای کوتاه بر انتشار موج، معادلات امواج مختلف، تبدیلهای انتگرالی شامل مبانی تبدیل فوریه، تبدیل موجک، تبدیل لاپلاس و اجرای عددی آنها آغاز میشود. مفهوم تحلیل طیفی و روش محاسبه پارامترهای موج، انتشار موج در موجبرهای همسانگرد یک بعدی، پراکندگی موج در موجبرهای دو بعدی توضیح داده شده است. انتشار موج در محیطهای مختلف مانند کامپوزیتهای چند لایه، سازههای درجهبندی عملکردی، خاکهای دانهدار شامل مدلهای کشسانی غیرمحلی مورد بررسی قرار میگیرد. کل کتاب به صورت مدولار نوشته شده است و تجزیه و تحلیل در حوزه فرکانس انجام شده است.
ویژگی ها:
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هدف این کتاب برای دانشجویان ارشد و فارغ التحصیلان پیشرفته در تمام رشته های مهندسی به ویژه مهندسی مکانیک و هوافضا است.
Elastic Wave Propagation in Structures and Materials initiates with a brief introduction to wave propagation, different wave equations, integral transforms including fundamentals of Fourier Transform, Wavelet Transform, Laplace Transform and their numerical implementation. Concept of spectral analysis and procedure to compute the wave parameters, wave propagation in 1-D isotropic waveguides, wave dispersion in 2-D waveguides is explained. Wave propagation in different media such as laminated composites, functionally graded structures, granular soils including non-local elasticity models is addressed. The entire book is written in modular form and analysis is performed in frequency domain.
Features:
This book aims at Senior Undergraduates and Advanced Graduates in all streams of engineering especially Mechanical and Aerospace Engineering.
Cover Half Title Title Page Copyright Page Dedication Contents Preface Author Biography CHAPTER 1: Introduction to Wave Propagation 1.1. ESSENTIAL COMPONENTS OF A WAVE 1.2. INTERFERENCE OF WAVES 1.2.1. Interference of Two Similar Waves Propagating in the Same Direction 1.2.2. Standing Waves 1.3. NEED FOR WAVE PROPAGATION ANALYSIS IN STRUCTURES AND MATERIALS 1.4. SOME WAVE PROPAGATION PROBLEMS IN SCIENCE AND ENGINEERING 1.5. ORGANIZATION AND SCOPE OF THE BOOK CHAPTER 2: Introduction to Fourier Transforms 2.1. FOURIER TRANSFORMS 2.1.1. Continuous Fourier Transforms (CFT) 2.1.2. Fourier Series 2.1.3. Discrete Fourier Transform 2.2. COMPARATIVE MERITS AND DEMERITS OF FFT NOTE ON MATLAB® SCRIPTS PROVIDED IN THIS CHAPTER SUMMARY EXERCISES CHAPTER 3: Introduction to Wave Propagation in Structures 3.1. CONCEPT OF WAVENUMBER, GROUP SPEEDS AND PHASE SPEEDS 3.2. WAVE PROPAGATION TERMINOLOGIES 3.3. SPECTRAL ANALYSIS OF MOTION 3.3.1. Second-Order System 3.3.2. Fourth-Order System 3.4. GENERAL FORM OF WAVE EQUATION AND THEIR CHARACTERISTICS 3.4.1. General Form of Wave Equations 3.4.2. Characteristics of Waves in Anisotropic Media 3.4.3. Characteristics of Waves in Inhomogeneous Media 3.4.4. Characteristics of Waves in Non-local Waveguides 3.5. DIFFERENT METHODS OF COMPUTING WAVENUMBERS AND WAVE AMPLITUDES 3.5.1. Method - 1 : The Companion Matrix & the SVD Technique 3.5.2. Method - 2 : Linearization of Polynomial Eigenvalue Problem (PEP) SUMMARY EXERCISES CHAPTER 4: Wave Propagation in One-Dimensional Isotropic Structural Waveguides 4.1. WAVE PROPAGATION IN 1-D ELEMENTARY WAVEGUIDES 4.2. LONGITUDINAL WAVE PROPAGATION IN RODS 4.2.1. D’Alemberts Solution 4.2.2. Spectral Analysis 4.2.3. Propagation of Waves in an Infinite Longitudinal Waveguide 4.2.4. Interaction of Waves with Fixed and Free Boundaries 4.2.5. Reflection from an Elastic Boundary 4.2.6. Reection and Transmission from a Joint Having Concentrated Mass and Stepped Rod 4.3. FLEXURAL WAVE PROPAGATION IN BEAMS 4.3.1. Wave Propagation Analysis 4.3.2. Propagation of Waves in an Infinite Beam 4.3.3. Reflection from Boundaries 4.3.4. Reflection from Elastic Boundary 4.3.5. Reection and Transmission from a Stepped Beam and a Joint with Concentrated Mass 4.3.6. Wave Propagation in Beams with Pre-Tension or Pre-Compression 4.3.7. Wave Propagation in a Beam on Elastic Foundation 4.3.8. Wave Propagation in a Framed Structure 4.4. WAVE PROPAGATION IN HIGHER-ORDER WAVEGUIDES 4.4.1. Wave Propagation in Timoshenko Beam 4.4.2. Wave Propagation in Mindlin-Herrmann Rod 4.5. WAVE PROPAGATION IN ROTATING BEAMS 4.6. WAVE PROPAGATION IN TAPERED WAVEGUIDES 4.6.1. Wave Propagation in Tapered Rod Having Exponential Depth Variation 4.6.2. Wave Propagation in Tapered Rod Having Polynomial Depth Variation 4.6.3. Wave Propagation in Tapered Beam NOTE ON MATLAB® SCRIPTS PROVIDED IN THIS CHAPTER SUMMARY EXERCISES CHAPTER 5: Wave Propagation in Viscoelastic Waveguides 5.1. CONSTITUTIVE MODELS FOR VISCOELASTIC WAVEGUIDES 5.1.1. Two-Parameter Models 5.1.2. Three-Parameter Models 5.2. WAVE PROPAGATION IN VISCOELASTIC ROD 5.2.1. Wave Propagation in Two-Parameter Viscoelastic Rod 5.2.2. Wave Propagation in Three-Parameter Viscoelastic Rod 5.3. WAVE PROPAGATION IN VISCOELASTIC BEAMS NOTE ON MATLAB® SCRIPTS PROVIDED IN THIS CHAPTER SUMMARY EXERCISES CHAPTER 6: Signal Processing Aspects in Wave Propagation 6.1. SIGNAL PROCESSING ISSUES OF SAMPLED WAVEFORMS 6.1.1. Signal Aliasing 6.1.2. Spectral Leakage and Windowing 6.1.3. Signal Wraparound Problem 6.2. PROPAGATION AND RECONSTRUCTION OF SIGNALS 6.2.1. Integration of the Signals SUMMARY EXERCISES CHAPTER 7: Wave Propagation in Two-Dimensional Isotropic Waveguides 7.1. GOVERNING EQUATIONS OF MOTION 7.2. SOLUTION OF NAVIER’S EQUATION 7.3. PROPAGATION OF WAVES IN INFINITE 2-D MEDIA 7.3.1. Propagation of P-waves 7.3.2. Propagation of SV Waves 7.3.3. Propagation of SH Waves 7.4. WAVE PROPAGATION IN SEMI-INFINITE 2-D MEDIA 7.4.1. Fixed Boundary Condition 7.4.2. Mixed Boundary Condition 7.4.3. Traction Free Boundary Conditions: A Case of Rayleigh Surface Waves 7.5. WAVE PROPAGATION IN DOUBLY BOUNDED MEDIA 7.5.1. Symmetric Loading Case 7.5.2. Fixed Boundary Condition 7.5.3. Method of Solution of Dispersion Equations in a Doubly Bounded Media 7.5.4. Mixed Boundary Condition: Case I 7.5.5. Mixed Boundary Condition: Case II 7.5.6. Traction Free Surfaces: A Case of Lamb Wave Propagation 7.6. WAVE PROPAGATION IN THIN PLATES 7.6.1. Spectral Analysis 7.6.2. Plate Edge Wave Propagation Wavenumber Transform Solution NOTE ON MATLAB® SCRIPTS PROVIDED IN THIS CHAPTER SUMMARY EXERCISES CHAPTER 8: Wave Propagation in Laminated Composite Waveguides 8.1. INTRODUCTION TO COMPOSITE MATERIALS 8.2. THEORY OF LAMINATED COMPOSITES 8.2.1. Micro-mechanical Analysis of Composites 8.2.2. Macro-mechanical Analysis of Composites 8.3. CLASSICAL LAMINATION PLATE THEORY 8.4. WAVE PROPAGATION IN 1-D THIN LAMINATED COMPOSITE WAVEGUIDE 8.4.1. Computation of Wavenumbers 8.5. WAVE PROPAGATION IN THICK 1-D LAMINATED COMPOSITE WAVEGUIDES 8.5.1. Governing Equation for a Thick Composite Beam 8.5.2. Wave Propagation in a Thick Beam Model with Both Shear Deformation and Lateral Contraction Included 8.5.3. Wave Propagation in a Thick Beams Model That Includes Only the Shear Deformation 8.6. WAVE PROPAGATION IN TWO-DIMENSIONAL COMPOSITE WAVEGUIDES 8.6.1. Formulation of Governing Equations and Computation of Wavenumbers 8.7. WAVE PROPAGATION IN 2-D LAMINATED COMPOSITE PLATES 8.7.1. Governing Equations and Wavenumber Computations NOTE ON MATLAB® SCRIPTS PROVIDED IN THIS CHAPTER SUMMARY EXERCISES CHAPTER 9: Wave Propagation in Graded Material Waveguides 9.1. INTRODUCTION TO FUNCTIONALLY GRADED MATERIALS (FGM) 9.2. MODELING OF FGM STRUCTURES 9.3. WAVE PROPAGATION IN LENGTHWISE GRADED RODS 9.4. WAVE PROPAGATION IN DEPTHWISE GRADED FGM BEAM 9.4.1. Reduction to FSDT 9.5. WAVE PROPAGATION ON LENGTHWISE GRADED BEAM 9.6. WAVE PROPAGATION IN 2-D FUNCTIONALLY GRADED STRUCTURES NOTE ON MATLAB® SCRIPTS PROVIDED IN THIS CHAPTER SUMMARY EXERCISES CHAPTER 10: Wave Propagation in Granular Medium 10.1. MECHANICAL PROPERTIES EVALUATION FOR DRY SANDS 10.2. WAVE PROPAGATION CHARACTERISTICS IN DIFFERENT TYPES OF DRY SANDS 10.3. DESIGN CONCEPT FOR SAND BUNKERS FOR EFFICIENT BLAST MITIGATION 10.4. RESPONSE OF SAND BUNKERS SUBJECTED TO BLAST LOADING 10.4.1. Estimation of Blast Pressure Profile on the Sand Bunker SUMMARY EXERCISES CHAPTER 11: Wave Propagation in Non-Local One-Dimensional Waveguides 11.1. ERINGEN’S STRESS GRADIENT THEORY 11.2. STRAIN GRADIENT THEORY 11.3. WAVE PROPAGATION IN NO-NLOCAL WAVEGUIDES 11.3.1. Wave Propagation in Eringen Stress Gradient Rod (ESGR) 11.3.2. Wave Propagation in Second-Order Strain Gradient Rod (SOSGR-P) Model 11.3.3. Wave Propagation in Second-Order Strain Gradient Rod (SOSGR-N) Model 11.3.4. Wave Propagation in Fourth-Order Strain Gradient Rod (FOSGR) Model 11.3.5. Wave Propagation in Euler-Bernoulli Eringen Stress Gradient Beam (ESGB) NOTE ON MATLAB® SCRIPTS PROVIDED IN THIS CHAPTER SUMMARY EXERCISES CHAPTER 12: Introduction to Spectral Finite Element Formulation 12.1. FUNDAMENTAL PRINCIPLES OF SPECTRAL FINITE ELEMENT FORMULATION 12.2. GENERAL FORMULATION PROCEDURE OF SFEM 12.3. SPECTRAL FINITE ELEMENT FORMULATION 12.3.1. Spectral Rod Element 12.3.2. Spectrally Formulated Elementary Beam Element 12.3.3. Higher-Order 1-D Composite Waveguides 12.3.4. Spectral Element for Framed Structures 12.3.5. 2-D Layer Element for Isotropic Solids One Noded or Throw-off Element Two Noded or Finite Length Element 12.3.6. Composite Layer Element Finite Layer Element (FLE) Infinite Layer Element (ILE) 12.3.7. Determination of Lamb Wave Modes in Laminated Composites 12.4. MERITS AND DEMERITS OF FOURIER SPECTRAL FINITE ELEMENT METHOD SUMMARY EXERCISES Bibliography Index