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The Resource Engineering mathematics I : electromagnetics, fluid Mechanics, material physics and financial engineering, Sergei Silvestrov, Milica Rančić, editors
Engineering mathematics I : electromagnetics, fluid Mechanics, material physics and financial engineering, Sergei Silvestrov, Milica Rančić, editors
Resource Information
The item Engineering mathematics I : electromagnetics, fluid Mechanics, material physics and financial engineering, Sergei Silvestrov, Milica Rančić, editors represents a specific, individual, material embodiment of a distinct intellectual or artistic creation found in University of Oklahoma Libraries.This item is available to borrow from all library branches.
Resource Information
The item Engineering mathematics I : electromagnetics, fluid Mechanics, material physics and financial engineering, Sergei Silvestrov, Milica Rančić, editors represents a specific, individual, material embodiment of a distinct intellectual or artistic creation found in University of Oklahoma Libraries.
This item is available to borrow from all library branches.
 Summary
 This book highlights the latest advances in engineering mathematics with a main focus on the mathematical models, structures, concepts, problems and computational methods and algorithms most relevant for applications in modern technologies and engineering. In particular, it features mathematical methods and models of applied analysis, probability theory, differential equations, tensor analysis and computational modelling used in applications to important problems concerning electromagnetics, antenna technologies, fluid dynamics, material and continuum physics and financial engineering. The individual chapters cover both theory and applications, and include a wealth of figures, schemes, algorithms, tables and results of data analysis and simulation. Presenting new methods and results, reviews of cuttingedge research, and open problems for future research, they equip readers to develop new mathematical methods and concepts of their own, and to further compare and analyse the methods and results discussed. The book consists of contributed chapters covering research developed as a result of a focused international seminar series on mathematics and applied mathematics and a series of three focused international research workshops on engineering mathematics organised by the Research Environment in Mathematics and Applied Mathematics at Mälardalen University from autumn 2014 to autumn 2015: the International Workshop on Engineering Mathematics for Electromagnetics and Health Technology; the International Workshop on Engineering Mathematics, Algebra, Analysis and Electromagnetics; and the 1st SwedishEstonian International Workshop on Engineering Mathematics, Algebra, Analysis and Applications. It serves as a source of inspiration for a broad spectrum of researchers and research students in applied mathematics, as well as in the areas of applications of mathematics considered in the book
 Language
 eng
 Extent
 1 online resource.
 Contents

 Preface; Contents; Contributors; 1 Frequency Domain and Time Domain Response of the Horizontal Grounding Electrode Using the Antenna Theory Approach; 1.1 Introduction; 1.2 Frequency Domain Analysis; 1.2.1 Numerical Solution; 1.2.2 Computational Examples; 1.3 Time Domain Analysis; 1.3.1 BEM Procedure for Pocklington Equation; 1.3.2 Numerical Results for Grounding Electrode; 1.4 Concluding Remarks; References; 2 On the Use of Analytical Methods in Electromagnetic Compatibility and Magnetohydrodynamics; 2.1 Introduction; 2.2 Thin Wire Models in Antenna Theory
 2.2.1 Frequency Domain Formulation2.2.2 Time Domain Formulation; 2.3 Frequency Domain Applications of Analytical Methods; 2.3.1 Horizontal Wire Below Ground; 2.3.2 Horizontal Grounding Electrode; 2.4 Time Domain Applications of Analytical Methods; 2.4.1 Horizontal Wire Below Ground; 2.4.2 Horizontal Grounding Electrode; 2.5 Some Analytical Solutions to the Grad  Shafranov Equation; 2.5.1 Solution of the Homogeneous Equation; 2.5.2 The Solov'ev Equilibrium; 2.5.3 The Herrnegger  Maschke Solutions; 2.5.4 Mc Carthy's Solution; 2.5.5 Computational Example; 2.6 Concluding Remarks; References
 3 Analysis of Horizontal ThinWire Conductor Buried in Lossy Ground: New Model for Sommerfeld Type Integral3.1 Introduction; 3.2 Problem Formulation; 3.3 Sommerfeld Integral Approximations; 3.3.1 Transmission Coefficient (TC) Approach; 3.3.2 TwoImage Approximation  TIA; 3.4 Solution of the Integral Equation; 3.5 Numerical Results; 3.6 Conclusion; References; 4 Comparison of TL, PointMatching and Hybrid Circuit Method Analysis of a Horizontal Dipole Antenna Immersed in Lossy Soil; 4.1 Introduction; 4.2 Geometry Layout; 4.3 Transmission Line Model (TLM); 4.4 PointMatching Method (PMM)
 4.5 Hybrid Circuit Method (HCM)4.6 Numerical Results; 4.7 Conclusion; References; 5 Theoretical Study of Equilateral Triangular Microstrip Antenna and Its Arrays; 5.1 Introduction; 5.2 Types of Microstrip Antennas; 5.2.1 Theoretical Impedance Bandwidth; 5.3 Conclusion; References; 6 Green Function of the Point Source Inside/Outside Spherical Domain  Approximate Solution; 6.1 Introduction; 6.2 Theoretical Background; 6.2.1 Description of the Problem; 6.2.2 Exact ESP Solution According to [19]; 6.2.3 ESP Solution According to [20, pp. 97  98] and [21]; 6.2.4 ESP Solution Proposed in This Paper
 6.2.5 Analysis of the Presented ESP Solutions6.2.6 Error Estimation Using the Approximate Expressions for the ESP; 6.3 Numerical Results; 6.4 Technical Application; 6.5 Conclusion; References; 7 The Electromagnetic  Thermal Dosimetry Model of the Human Brain; 7.1 Introduction; 7.2 Electromagnetic Dosimetry Model; 7.2.1 Numerical Solution; 7.3 Thermal Dosimetry Model; 7.3.1 Finite Element Solution; 7.4 Computational Example; 7.5 Conclusion; References; 8 QuasiTEM Analysis of Multilayered Shielded Microstrip Lines Using Hybrid Boundary Element Method; 8.1 Introduction
 Isbn
 9783319420820
 Label
 Engineering mathematics I : electromagnetics, fluid Mechanics, material physics and financial engineering
 Title
 Engineering mathematics I
 Title remainder
 electromagnetics, fluid Mechanics, material physics and financial engineering
 Statement of responsibility
 Sergei Silvestrov, Milica Rančić, editors
 Subject

 Mathematics
 Maths for scientists
 Probability Theory and Stochastic Processes
 Mechanics of fluids
 Electronic books
 Statistics for Business/Economics/Mathematical Finance/Insurance
 TECHNOLOGY & ENGINEERING  Engineering (General)
 Applications of Mathematics
 Mathematical physics
 Numerical and Computational Physics, Simulation
 TECHNOLOGY & ENGINEERING  Reference
 Probability & statistics
 Engineering Fluid Dynamics
 Engineering mathematics
 Engineering mathematics
 Computational Science and Engineering
 Applied mathematics
 Language
 eng
 Summary
 This book highlights the latest advances in engineering mathematics with a main focus on the mathematical models, structures, concepts, problems and computational methods and algorithms most relevant for applications in modern technologies and engineering. In particular, it features mathematical methods and models of applied analysis, probability theory, differential equations, tensor analysis and computational modelling used in applications to important problems concerning electromagnetics, antenna technologies, fluid dynamics, material and continuum physics and financial engineering. The individual chapters cover both theory and applications, and include a wealth of figures, schemes, algorithms, tables and results of data analysis and simulation. Presenting new methods and results, reviews of cuttingedge research, and open problems for future research, they equip readers to develop new mathematical methods and concepts of their own, and to further compare and analyse the methods and results discussed. The book consists of contributed chapters covering research developed as a result of a focused international seminar series on mathematics and applied mathematics and a series of three focused international research workshops on engineering mathematics organised by the Research Environment in Mathematics and Applied Mathematics at Mälardalen University from autumn 2014 to autumn 2015: the International Workshop on Engineering Mathematics for Electromagnetics and Health Technology; the International Workshop on Engineering Mathematics, Algebra, Analysis and Electromagnetics; and the 1st SwedishEstonian International Workshop on Engineering Mathematics, Algebra, Analysis and Applications. It serves as a source of inspiration for a broad spectrum of researchers and research students in applied mathematics, as well as in the areas of applications of mathematics considered in the book
 Cataloging source
 YDX
 Dewey number
 620.001/51
 Index
 index present
 LC call number
 TA330
 Literary form
 non fiction
 Nature of contents

 dictionaries
 bibliography
 http://library.link/vocab/relatedWorkOrContributorName

 Silvestrov, Sergei
 Rancic, Milica
 Series statement
 Springer proceedings in mathematics & statistics,
 Series volume
 v. 178
 http://library.link/vocab/subjectName

 Engineering mathematics
 TECHNOLOGY & ENGINEERING
 TECHNOLOGY & ENGINEERING
 Engineering mathematics
 Mathematics
 Computational Science and Engineering
 Applications of Mathematics
 Numerical and Computational Physics, Simulation
 Engineering Fluid Dynamics
 Probability Theory and Stochastic Processes
 Statistics for Business/Economics/Mathematical Finance/Insurance
 Applied mathematics
 Mathematical physics
 Mechanics of fluids
 Probability & statistics
 Maths for scientists
 Label
 Engineering mathematics I : electromagnetics, fluid Mechanics, material physics and financial engineering, Sergei Silvestrov, Milica Rančić, editors
 Bibliography note
 Includes bibliographical references at the end of each chapters and index
 Carrier category
 online resource
 Carrier category code

 cr
 Carrier MARC source
 rdacarrier
 Content category
 text
 Content type code

 txt
 Content type MARC source
 rdacontent
 Contents

 Preface; Contents; Contributors; 1 Frequency Domain and Time Domain Response of the Horizontal Grounding Electrode Using the Antenna Theory Approach; 1.1 Introduction; 1.2 Frequency Domain Analysis; 1.2.1 Numerical Solution; 1.2.2 Computational Examples; 1.3 Time Domain Analysis; 1.3.1 BEM Procedure for Pocklington Equation; 1.3.2 Numerical Results for Grounding Electrode; 1.4 Concluding Remarks; References; 2 On the Use of Analytical Methods in Electromagnetic Compatibility and Magnetohydrodynamics; 2.1 Introduction; 2.2 Thin Wire Models in Antenna Theory
 2.2.1 Frequency Domain Formulation2.2.2 Time Domain Formulation; 2.3 Frequency Domain Applications of Analytical Methods; 2.3.1 Horizontal Wire Below Ground; 2.3.2 Horizontal Grounding Electrode; 2.4 Time Domain Applications of Analytical Methods; 2.4.1 Horizontal Wire Below Ground; 2.4.2 Horizontal Grounding Electrode; 2.5 Some Analytical Solutions to the Grad  Shafranov Equation; 2.5.1 Solution of the Homogeneous Equation; 2.5.2 The Solov'ev Equilibrium; 2.5.3 The Herrnegger  Maschke Solutions; 2.5.4 Mc Carthy's Solution; 2.5.5 Computational Example; 2.6 Concluding Remarks; References
 3 Analysis of Horizontal ThinWire Conductor Buried in Lossy Ground: New Model for Sommerfeld Type Integral3.1 Introduction; 3.2 Problem Formulation; 3.3 Sommerfeld Integral Approximations; 3.3.1 Transmission Coefficient (TC) Approach; 3.3.2 TwoImage Approximation  TIA; 3.4 Solution of the Integral Equation; 3.5 Numerical Results; 3.6 Conclusion; References; 4 Comparison of TL, PointMatching and Hybrid Circuit Method Analysis of a Horizontal Dipole Antenna Immersed in Lossy Soil; 4.1 Introduction; 4.2 Geometry Layout; 4.3 Transmission Line Model (TLM); 4.4 PointMatching Method (PMM)
 4.5 Hybrid Circuit Method (HCM)4.6 Numerical Results; 4.7 Conclusion; References; 5 Theoretical Study of Equilateral Triangular Microstrip Antenna and Its Arrays; 5.1 Introduction; 5.2 Types of Microstrip Antennas; 5.2.1 Theoretical Impedance Bandwidth; 5.3 Conclusion; References; 6 Green Function of the Point Source Inside/Outside Spherical Domain  Approximate Solution; 6.1 Introduction; 6.2 Theoretical Background; 6.2.1 Description of the Problem; 6.2.2 Exact ESP Solution According to [19]; 6.2.3 ESP Solution According to [20, pp. 97  98] and [21]; 6.2.4 ESP Solution Proposed in This Paper
 6.2.5 Analysis of the Presented ESP Solutions6.2.6 Error Estimation Using the Approximate Expressions for the ESP; 6.3 Numerical Results; 6.4 Technical Application; 6.5 Conclusion; References; 7 The Electromagnetic  Thermal Dosimetry Model of the Human Brain; 7.1 Introduction; 7.2 Electromagnetic Dosimetry Model; 7.2.1 Numerical Solution; 7.3 Thermal Dosimetry Model; 7.3.1 Finite Element Solution; 7.4 Computational Example; 7.5 Conclusion; References; 8 QuasiTEM Analysis of Multilayered Shielded Microstrip Lines Using Hybrid Boundary Element Method; 8.1 Introduction
 Dimensions
 unknown
 Extent
 1 online resource.
 Form of item
 online
 Isbn
 9783319420820
 Media category
 computer
 Media MARC source
 rdamedia
 Media type code

 c
 Note
 SpringerLink
 Other control number
 10.1007/9783319420820
 Specific material designation
 remote
 System control number

 (OCoLC)964652823
 (OCoLC)ocn964652823
 Label
 Engineering mathematics I : electromagnetics, fluid Mechanics, material physics and financial engineering, Sergei Silvestrov, Milica Rančić, editors
 Bibliography note
 Includes bibliographical references at the end of each chapters and index
 Carrier category
 online resource
 Carrier category code

 cr
 Carrier MARC source
 rdacarrier
 Content category
 text
 Content type code

 txt
 Content type MARC source
 rdacontent
 Contents

 Preface; Contents; Contributors; 1 Frequency Domain and Time Domain Response of the Horizontal Grounding Electrode Using the Antenna Theory Approach; 1.1 Introduction; 1.2 Frequency Domain Analysis; 1.2.1 Numerical Solution; 1.2.2 Computational Examples; 1.3 Time Domain Analysis; 1.3.1 BEM Procedure for Pocklington Equation; 1.3.2 Numerical Results for Grounding Electrode; 1.4 Concluding Remarks; References; 2 On the Use of Analytical Methods in Electromagnetic Compatibility and Magnetohydrodynamics; 2.1 Introduction; 2.2 Thin Wire Models in Antenna Theory
 2.2.1 Frequency Domain Formulation2.2.2 Time Domain Formulation; 2.3 Frequency Domain Applications of Analytical Methods; 2.3.1 Horizontal Wire Below Ground; 2.3.2 Horizontal Grounding Electrode; 2.4 Time Domain Applications of Analytical Methods; 2.4.1 Horizontal Wire Below Ground; 2.4.2 Horizontal Grounding Electrode; 2.5 Some Analytical Solutions to the Grad  Shafranov Equation; 2.5.1 Solution of the Homogeneous Equation; 2.5.2 The Solov'ev Equilibrium; 2.5.3 The Herrnegger  Maschke Solutions; 2.5.4 Mc Carthy's Solution; 2.5.5 Computational Example; 2.6 Concluding Remarks; References
 3 Analysis of Horizontal ThinWire Conductor Buried in Lossy Ground: New Model for Sommerfeld Type Integral3.1 Introduction; 3.2 Problem Formulation; 3.3 Sommerfeld Integral Approximations; 3.3.1 Transmission Coefficient (TC) Approach; 3.3.2 TwoImage Approximation  TIA; 3.4 Solution of the Integral Equation; 3.5 Numerical Results; 3.6 Conclusion; References; 4 Comparison of TL, PointMatching and Hybrid Circuit Method Analysis of a Horizontal Dipole Antenna Immersed in Lossy Soil; 4.1 Introduction; 4.2 Geometry Layout; 4.3 Transmission Line Model (TLM); 4.4 PointMatching Method (PMM)
 4.5 Hybrid Circuit Method (HCM)4.6 Numerical Results; 4.7 Conclusion; References; 5 Theoretical Study of Equilateral Triangular Microstrip Antenna and Its Arrays; 5.1 Introduction; 5.2 Types of Microstrip Antennas; 5.2.1 Theoretical Impedance Bandwidth; 5.3 Conclusion; References; 6 Green Function of the Point Source Inside/Outside Spherical Domain  Approximate Solution; 6.1 Introduction; 6.2 Theoretical Background; 6.2.1 Description of the Problem; 6.2.2 Exact ESP Solution According to [19]; 6.2.3 ESP Solution According to [20, pp. 97  98] and [21]; 6.2.4 ESP Solution Proposed in This Paper
 6.2.5 Analysis of the Presented ESP Solutions6.2.6 Error Estimation Using the Approximate Expressions for the ESP; 6.3 Numerical Results; 6.4 Technical Application; 6.5 Conclusion; References; 7 The Electromagnetic  Thermal Dosimetry Model of the Human Brain; 7.1 Introduction; 7.2 Electromagnetic Dosimetry Model; 7.2.1 Numerical Solution; 7.3 Thermal Dosimetry Model; 7.3.1 Finite Element Solution; 7.4 Computational Example; 7.5 Conclusion; References; 8 QuasiTEM Analysis of Multilayered Shielded Microstrip Lines Using Hybrid Boundary Element Method; 8.1 Introduction
 Dimensions
 unknown
 Extent
 1 online resource.
 Form of item
 online
 Isbn
 9783319420820
 Media category
 computer
 Media MARC source
 rdamedia
 Media type code

 c
 Note
 SpringerLink
 Other control number
 10.1007/9783319420820
 Specific material designation
 remote
 System control number

 (OCoLC)964652823
 (OCoLC)ocn964652823
Subject
 Applications of Mathematics
 Applied mathematics
 Computational Science and Engineering
 Electronic books
 Engineering Fluid Dynamics
 Engineering mathematics
 Engineering mathematics
 Mathematical physics
 Mathematics
 Maths for scientists
 Mechanics of fluids
 Numerical and Computational Physics, Simulation
 Probability & statistics
 Probability Theory and Stochastic Processes
 Statistics for Business/Economics/Mathematical Finance/Insurance
 TECHNOLOGY & ENGINEERING  Engineering (General)
 TECHNOLOGY & ENGINEERING  Reference
Genre
Member of
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