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Multiphysics Modeling Using COMSOL5 and MATLAB [ OP]: Using Comsol 5 and Matlab [Kõva köide]

  • Formaat: Hardback, 700 pages, kaal: 1129 g
  • Sari: Multiphysics Modeling
  • Ilmumisaeg: 29-Sep-2015
  • Kirjastus: Mercury Learning & Information
  • ISBN-10: 1938549988
  • ISBN-13: 9781938549984
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Multiphysics Modeling Using COMSOL5 and MATLAB [ OP]: Using Comsol 5 and MatlabSuurem pilt
  • Formaat: Hardback, 700 pages, kaal: 1129 g
  • Sari: Multiphysics Modeling
  • Ilmumisaeg: 29-Sep-2015
  • Kirjastus: Mercury Learning & Information
  • ISBN-10: 1938549988
  • ISBN-13: 9781938549984
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9781938549984.html
Pryor introduces hands-on model building and solving with COMSOL Multiphysics software version five to scientists, engineers, and others interested in exploring the behavior of physical device structures built on a computer before going to the workshop or laboratory and trying to build it, that is to create a virtual prototype before creating a physical prototype. His topics include materials properties, one-dimensional modeling, two-dimensional axisymmetric modeling, two-dimensional simple and complex mixed mode modeling, perfectly matched layer models, and bioheat models. Distributed in North America by Stylus Publishing and Distribution. Annotation ©2015 Ringgold, Inc., Portland, OR (protoview.com)


Preface ix
Introduction xi
Chapter 1 Modeling Methodology Using COMSOL Multiphasics 5.x
1(64)
Guidelines for New COMSOL Multiphysics 5.x Modelers
1(12)
Hardware Considerations
2(2)
Simple Model Setup Overview
4(8)
Basic Problem Formulation and Implicit Assumptions
12(1)
1D Window Heat Flow Models
13(48)
1D 1 Pane Window Heat Flow Model
13(24)
1D 2 Pane Window Heat Flow Model
37(13)
1D 3 Pane Window Heat Flow Model
50(11)
First Principles as Applied to Model Definition
61(1)
Some Common Sources of Modeling Errors
62(1)
References
63(1)
Suggested Modeling Exercises
64(1)
Chapter 2 Materials Properties Using COMSOL Multiphysics 5.x
65(22)
Materials Properties Guidelines and Considerations
65(1)
COMSOL Materials Properties Sources
66(2)
Other Materials Properties Sources
68(1)
Material Property Entry Techniques
68(17)
Multipane Window Model
68(15)
Set Boundary Conditions
83(2)
References
85(2)
Chapter 3 OD Electrical Circuit Interface Modeling Using COMSOL Multiphysics 5.x
87(40)
Guidelines for Electrical Circuit Interface Modeling in 5.x
88(14)
Electrical / Electronic Circuit Considerations
88(9)
Simple Electrical Circuit Interface Model Setup Overview
97(4)
Basic Problem Formulation and Implicit Assumptions
101(1)
0D Basic Circuit Models
102(22)
0D Resistor-Capacitor Series Circuit Model
102(7)
0D Inductor-Resistor Series Circuit Model
109(6)
0O Series-Resistor Parallel-Inductor-Capacitor Circuit Model
115(8)
0D Basic Circuit Models Analysis and Conclusions
123(1)
First Principles as Applied to 0D Model Definition
124(1)
References
125(1)
Suggested Modeling Exercises
126(1)
Chapter 4 1D Modeling Using COMSOL Multiphysics 5.x
127(60)
Guidelines for ID Modeling in 5.x
127(1)
1D Modeling Considerations
128(1)
1D Basic Models
128(56)
1D KdV Equation Model
128(18)
1D Telegraph Equation Model
146(19)
1D Telegraph Equation Model Summary and Conclusions
165(1)
1D Spherically Symmetric Transport Model
165(17)
1D Spherically Symmetric Transport Model Animation
182(2)
First Principles as Applied to ID Model Definition
184(1)
References
185(1)
Suggested Modeling Exercises
185(2)
Chapter 5 2D Modeling Using COMSOL Multiphysics 5.x
187(48)
Guidelines for 2D Modeling in 5.x
187(6)
2D Modeling Considerations
188(5)
2D Basic Models
193(38)
2D Electrochemical Polishing Model
193(23)
2D Hall Effect Model
216(15)
First Principles as Applied to 2D Model Definition
231(1)
References
232(1)
Suggested Modeling Exercises
233(2)
Chapter 6 2D Axisymmetric Modeling Using COMSOL Multiphysics 5.x
235(32)
Guidelines for 2D Axisymmetric Modeling in 5.x
235(5)
2D Axisymmetric Modeling Considerations
236(4)
2D Axisymmetric Heat Conduction in a Cylinder Model
240(1)
2D Axisymmetric Basic Models
240(25)
2D Axisymmetric Cylinder Conduction Model
240(12)
2D Axisymmetric Transient Heat Transfer Model
252(13)
First Principles as Applied to 2D Axisymmetric Model Definition
265(1)
References
265(1)
Suggested Modeling Exercises
266(1)
Chapter 7 2D Simple Mixed Mode Modeling Using COMSOL Multiphysics 5.x
267(46)
Guidelines for 2D Simple Mixed Mode Modeling in 5.x
267(7)
2D Simple Mixed Mode Modeling Considerations
268(6)
2D Simple Mixed Mode Models
274(35)
2D Electric Impedance Sensor Model
274(17)
2D Metal Layer on a Dielectric Block Model
291(12)
Heat Transfer 2 (ht2) Interface
303(6)
First Principles as Applied to 2D Simple Mixed Mode Model Definition
309(1)
References
310(1)
Suggested Modeling Exercises
311(2)
Chapter 8 2D Complex Mixed Mode Modeling Using COMSOL Multiphysics 5.x
313(74)
Guidelines for 2D Complex Mixed Mode Modeling in 5.x
313(9)
2D Complex Mixed Mode Modeling Considerations
314(8)
2D Complex Mixed Mode Models
322(62)
2D Copper Electroplating Model
322(26)
2D Copper Electroplating Model Summary and Conclusions
348(1)
2D Electrocoalescence Oil/Water Separation Model
349(28)
Time-Dependent Solver 2
377(7)
2D Electrocoalescence Oil/Water Separation Model Summary and Conclusions
384(1)
First Principles as Applied to 2D Complex Mixed Mode Model Definition
384(1)
References
385(1)
Suggested Modeling Exercises
386(1)
Chapter 9 3D Modeling Using COMSOL Multiphysics 5.x
387(60)
Guidelines for 3D Modeling in 5.x
387(6)
3D Modeling Considerations
388(5)
3D Models
393(50)
3D Spiral Coil Microinductor Model
393(17)
3D Spiral Coil Microinductor Model Summary and Conclusions
410(1)
3D Linear Microresistor Beam Model
410(20)
Multiphysics Thermal Linear Elastic 1 (tel)
430(1)
Heat Transfer in Solids (ht)
431(12)
First Principles as Applied to 3D Model Definition
443(1)
References
443(1)
Suggested Modeling Exercises
444(3)
Chapter 10 Perfectly Matched Layer Models Using COMSOL Multiphysics 5.x
447(50)
Guidelines for Perfectly Matched Layer (PML) Modeling in 5.x
447(4)
Perfectly Matched Layer (PML) Modeling Guidelines and Coordinate Considerations
448(3)
Perfectly Matched Layer Models
451(42)
Building the 2D Concave Metallic Mirror PML Model
451(21)
Building the 2D Energy Concentrator PML Model
472(21)
First Principles as Applied to PML Model Definition
493(1)
References
494(1)
Suggested Modeling Exercises
494(3)
Chapter 11 Bioheat Models Using COMSOL Multiphysics 5.x
497(64)
Guidelines for Bioheat Modeling in 5.x
497(61)
Bioheat Modeling Considerations
498(3)
Bioheat Transfer Models
501(31)
2D Axisymmetric Microwave Cancer Therapy Model
532(26)
First Principles as Applied to Bioheat Model Definition
558(1)
References
558(1)
Suggested Modeling Exercises
559(2)
Appendix A A Brief Introduction to LiveLink™ for MATLAB® 561(12)
Appendix B A Brief Introduction to COMSOL Application Builder 573(12)
Index 585
Pryor Roger W. : Roger W. Pryor, PhD, is a COMSOL Certified Consultant and VP of Research for Pryor Knowledge Systems, Inc. He has been granted 23 US Patents.