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Electromagnetics and Transmission Lines
Textbook resource covering static electric and magnetic fields, dynamic electromagnetic fields, transmission lines, antennas, and signal integrity within a single course
Electromagnetics and Transmission Lines provides coverage of what every electrical engineer (not just the electromagnetic specialist) should know about electromagnetic fields and transmission lines. This work examines several fundamental electrical engineering concepts and components from an electromagnetic fields viewpoint, such as electric circuit laws, resistance, capacitance, and self and mutual inductances. The approach to transmission lines (T-lines), Smith charts, and scattering parameters establishes the underlying concepts of vector network analyzer (VNA) measurements. System-level antenna parameters, basic wireless links, and signal integrity are examined in the final chapters.
As an efficient learning resource, electromagnetics and transmission lines content is strategically modulated in breadth and depth towards a single semester objective. Extraneous, distracting topics are excluded. The wording style is somewhat more conversational than most electromagnetics textbooks in order to enhance student engagement and inclusivity while conveying the rigor that is essential for engineering student development. To aid in information retention, the authors also provide supplementary material, including a homework solutions manual, lecture notes, and VNA experiments.
Sample topics covered in Electromagnetics and Transmission Lines include:
* Vector algebra and coordinate systems, Coulomb's law, Biot-Savart law, Gauss's law, and solenoidal magnetic flux
* Electric potential, Ampere's circuital law, Faraday's law, displacement current, and the electromagnetic principles underlying resistance, capacitance, and self and mutual inductances
* The integral form of Maxwell's equations from a conceptual viewpoint that relates the equations to physical understanding (the differential forms are also included in an appendix)
* DC transients and AC steady-state waves, reflections, and standing waves on T-lines
* Interrelationships of AC steady-state T-line theory, the Smith chart, and scattering parameters
* Antenna basics and line-of-sight link analysis using the Friis equation
* An introduction to signal integrity
Electromagnetics and Transmission Lines is an authoritative textbook learning resource, suited perfectly for engineering programs at colleges and universities with a single required electromagnetic fields course. Student background assumptions are multivariable calculus, DC and AC electric circuits, physics of electromagnetics, and elementary differential equations.
Textbook resource covering static electric and magnetic fields, dynamic electromagnetic fields, transmission lines, antennas, and signal integrity within a single course
Electromagnetics and Transmission Lines provides coverage of what every electrical engineer (not just the electromagnetic specialist) should know about electromagnetic fields and transmission lines. This work examines several fundamental electrical engineering concepts and components from an electromagnetic fields viewpoint, such as electric circuit laws, resistance, capacitance, and self and mutual inductances. The approach to transmission lines (T-lines), Smith charts, and scattering parameters establishes the underlying concepts of vector network analyzer (VNA) measurements. System-level antenna parameters, basic wireless links, and signal integrity are examined in the final chapters.
As an efficient learning resource, electromagnetics and transmission lines content is strategically modulated in breadth and depth towards a single semester objective. Extraneous, distracting topics are excluded. The wording style is somewhat more conversational than most electromagnetics textbooks in order to enhance student engagement and inclusivity while conveying the rigor that is essential for engineering student development. To aid in information retention, the authors also provide supplementary material, including a homework solutions manual, lecture notes, and VNA experiments.
Sample topics covered in Electromagnetics and Transmission Lines include:
* Vector algebra and coordinate systems, Coulomb's law, Biot-Savart law, Gauss's law, and solenoidal magnetic flux
* Electric potential, Ampere's circuital law, Faraday's law, displacement current, and the electromagnetic principles underlying resistance, capacitance, and self and mutual inductances
* The integral form of Maxwell's equations from a conceptual viewpoint that relates the equations to physical understanding (the differential forms are also included in an appendix)
* DC transients and AC steady-state waves, reflections, and standing waves on T-lines
* Interrelationships of AC steady-state T-line theory, the Smith chart, and scattering parameters
* Antenna basics and line-of-sight link analysis using the Friis equation
* An introduction to signal integrity
Electromagnetics and Transmission Lines is an authoritative textbook learning resource, suited perfectly for engineering programs at colleges and universities with a single required electromagnetic fields course. Student background assumptions are multivariable calculus, DC and AC electric circuits, physics of electromagnetics, and elementary differential equations.
Electromagnetics and Transmission Lines
Textbook resource covering static electric and magnetic fields, dynamic electromagnetic fields, transmission lines, antennas, and signal integrity within a single course
Electromagnetics and Transmission Lines provides coverage of what every electrical engineer (not just the electromagnetic specialist) should know about electromagnetic fields and transmission lines. This work examines several fundamental electrical engineering concepts and components from an electromagnetic fields viewpoint, such as electric circuit laws, resistance, capacitance, and self and mutual inductances. The approach to transmission lines (T-lines), Smith charts, and scattering parameters establishes the underlying concepts of vector network analyzer (VNA) measurements. System-level antenna parameters, basic wireless links, and signal integrity are examined in the final chapters.
As an efficient learning resource, electromagnetics and transmission lines content is strategically modulated in breadth and depth towards a single semester objective. Extraneous, distracting topics are excluded. The wording style is somewhat more conversational than most electromagnetics textbooks in order to enhance student engagement and inclusivity while conveying the rigor that is essential for engineering student development. To aid in information retention, the authors also provide supplementary material, including a homework solutions manual, lecture notes, and VNA experiments.
Sample topics covered in Electromagnetics and Transmission Lines include:
* Vector algebra and coordinate systems, Coulomb's law, Biot-Savart law, Gauss's law, and solenoidal magnetic flux
* Electric potential, Ampere's circuital law, Faraday's law, displacement current, and the electromagnetic principles underlying resistance, capacitance, and self and mutual inductances
* The integral form of Maxwell's equations from a conceptual viewpoint that relates the equations to physical understanding (the differential forms are also included in an appendix)
* DC transients and AC steady-state waves, reflections, and standing waves on T-lines
* Interrelationships of AC steady-state T-line theory, the Smith chart, and scattering parameters
* Antenna basics and line-of-sight link analysis using the Friis equation
* An introduction to signal integrity
Electromagnetics and Transmission Lines is an authoritative textbook learning resource, suited perfectly for engineering programs at colleges and universities with a single required electromagnetic fields course. Student background assumptions are multivariable calculus, DC and AC electric circuits, physics of electromagnetics, and elementary differential equations.
Textbook resource covering static electric and magnetic fields, dynamic electromagnetic fields, transmission lines, antennas, and signal integrity within a single course
Electromagnetics and Transmission Lines provides coverage of what every electrical engineer (not just the electromagnetic specialist) should know about electromagnetic fields and transmission lines. This work examines several fundamental electrical engineering concepts and components from an electromagnetic fields viewpoint, such as electric circuit laws, resistance, capacitance, and self and mutual inductances. The approach to transmission lines (T-lines), Smith charts, and scattering parameters establishes the underlying concepts of vector network analyzer (VNA) measurements. System-level antenna parameters, basic wireless links, and signal integrity are examined in the final chapters.
As an efficient learning resource, electromagnetics and transmission lines content is strategically modulated in breadth and depth towards a single semester objective. Extraneous, distracting topics are excluded. The wording style is somewhat more conversational than most electromagnetics textbooks in order to enhance student engagement and inclusivity while conveying the rigor that is essential for engineering student development. To aid in information retention, the authors also provide supplementary material, including a homework solutions manual, lecture notes, and VNA experiments.
Sample topics covered in Electromagnetics and Transmission Lines include:
* Vector algebra and coordinate systems, Coulomb's law, Biot-Savart law, Gauss's law, and solenoidal magnetic flux
* Electric potential, Ampere's circuital law, Faraday's law, displacement current, and the electromagnetic principles underlying resistance, capacitance, and self and mutual inductances
* The integral form of Maxwell's equations from a conceptual viewpoint that relates the equations to physical understanding (the differential forms are also included in an appendix)
* DC transients and AC steady-state waves, reflections, and standing waves on T-lines
* Interrelationships of AC steady-state T-line theory, the Smith chart, and scattering parameters
* Antenna basics and line-of-sight link analysis using the Friis equation
* An introduction to signal integrity
Electromagnetics and Transmission Lines is an authoritative textbook learning resource, suited perfectly for engineering programs at colleges and universities with a single required electromagnetic fields course. Student background assumptions are multivariable calculus, DC and AC electric circuits, physics of electromagnetics, and elementary differential equations.
Inhaltsverzeichnis
Preface xiii
Acknowledgments xvii
About the Authors xix
About the Companion Website xxi
1 Vectors, Vector Algebra, and Coordinate Systems 1
1.1 Vectors 1
1.2 Vector Algebra 4
1.2.1 Dot Product 4
1.2.2 Cross Product 7
1.3 Field Vectors 10
1.4 Cylindrical Coordinate System, Vectors, and Conversions 12
1.4.1 Cartesian (Rectangular) Coordinate System: Review 12
1.4.2 Cylindrical Coordinate System 13
1.5 Spherical Coordinate System, Vectors, and Conversions 19
1.6 Summary of Coordinate Systems and Vectors 25
1.7 Homework 27
Part 1 Static Electric and Magnetic Fields 31
2 The Superposition Laws of Electric and Magnetic Fields 33
2.1 Point Electric Charges, Coulomb's Law, and Electric Fields 34
2.2 Electric Charge Distributions and Charge Density 37
2.3 Coulomb's Law in Integral Form and Examples 38
2.4 Introduction to Magnetostatics and Current Density 47
2.5 Biot-Savart Law and Examples for Line Currents 50
2.6 Summary of Important Equations 56
2.7 Homework 56
3 The Flux Laws of Electric and Magnetic Fields 61
3.1 An Intuitive Development of Electric Flux and Gauss's Law 62
3.1.1 A First Look at Electric Flux Density 62
3.1.2 Electric Flux and Gauss's Law 63
3.2 Practical Determination of Electric Fields Using Gauss's Law 65
3.3 Determination of Charge from Electric Fields 73
3.4 Magnetic Flux 74
3.5 Summary of Important Equations 78
3.6 Homework 78
4 The Path Laws and Circuit Principles 83
4.1 Electric Potential (Voltage) and Kirchhoff's Voltage Law 84
4.1.1 Potential-Electric Field Relationship 84
4.1.2 Kirchhoff's Voltage Law (KVL) 86
4.1.3 Dielectric-Conductor Electric Field Boundary Conditions 86
4.2 Capacitance 87
4.2.1 Determination of Capacitance 88
4.2.2 Dielectrics and Permittivity 90
4.2.3 Energy Storage in Electric Fields 93
4.3 Resistance 94
4.4 Ampere's Circuital Law (ACL) 96
4.4.1 An Intuitive Development of ACL 96
4.4.2 Using ACL to Determine H 97
4.5 Inductance 100
4.5.1 Determination of Inductance 100
4.5.2 Magnetic Materials and Permeability 102
4.5.3 Magnetic Field Boundary Conditions 103
4.5.4 Energy Storage in a Magnetic Field 105
4.6 Summary of Important Equations 106
4.7 Appendices 106
Appendix 4.A Dielectric-Dielectric Electric Field Boundary Conditions 106
Appendix 4.B Development of Relative Permittivity 108
Appendix 4.C Development of Resistance 109
Appendix 4.D Introduction to Magnetic Circuits 111
4.8 Homework 113
Problems for Appendix 4.D 117
Part 2 Time-Changing Electric and Magnetic Fields 119
5 Maxwell's Equations 121
5.1 Introduction to Time-Changing Electromagnetic Fields 121
5.2 Faraday's Law 123
5.2.1 Lorentz Force Law and Induced Voltage 123
5.2.2 Time-Changing Magnetic Fields 125
5.2.3 Another Look at Kirchhoff's Voltage Law 127
5.2.4 Another Look at the Inductor 128
5.2.5 The Ideal Transformer 129
5.2.6 Mutual Inductors 130
5.3 Displacement Current 133
5.3.1 Time-Changing Electric Fields 133
5.3.2 Another Look at the Capacitor 134
5.3.3 Mutual Capacitance 135
5.4 Chapter Summary: Maxwell's Equations in Integral Form 136
5.5 Appendices
Acknowledgments xvii
About the Authors xix
About the Companion Website xxi
1 Vectors, Vector Algebra, and Coordinate Systems 1
1.1 Vectors 1
1.2 Vector Algebra 4
1.2.1 Dot Product 4
1.2.2 Cross Product 7
1.3 Field Vectors 10
1.4 Cylindrical Coordinate System, Vectors, and Conversions 12
1.4.1 Cartesian (Rectangular) Coordinate System: Review 12
1.4.2 Cylindrical Coordinate System 13
1.5 Spherical Coordinate System, Vectors, and Conversions 19
1.6 Summary of Coordinate Systems and Vectors 25
1.7 Homework 27
Part 1 Static Electric and Magnetic Fields 31
2 The Superposition Laws of Electric and Magnetic Fields 33
2.1 Point Electric Charges, Coulomb's Law, and Electric Fields 34
2.2 Electric Charge Distributions and Charge Density 37
2.3 Coulomb's Law in Integral Form and Examples 38
2.4 Introduction to Magnetostatics and Current Density 47
2.5 Biot-Savart Law and Examples for Line Currents 50
2.6 Summary of Important Equations 56
2.7 Homework 56
3 The Flux Laws of Electric and Magnetic Fields 61
3.1 An Intuitive Development of Electric Flux and Gauss's Law 62
3.1.1 A First Look at Electric Flux Density 62
3.1.2 Electric Flux and Gauss's Law 63
3.2 Practical Determination of Electric Fields Using Gauss's Law 65
3.3 Determination of Charge from Electric Fields 73
3.4 Magnetic Flux 74
3.5 Summary of Important Equations 78
3.6 Homework 78
4 The Path Laws and Circuit Principles 83
4.1 Electric Potential (Voltage) and Kirchhoff's Voltage Law 84
4.1.1 Potential-Electric Field Relationship 84
4.1.2 Kirchhoff's Voltage Law (KVL) 86
4.1.3 Dielectric-Conductor Electric Field Boundary Conditions 86
4.2 Capacitance 87
4.2.1 Determination of Capacitance 88
4.2.2 Dielectrics and Permittivity 90
4.2.3 Energy Storage in Electric Fields 93
4.3 Resistance 94
4.4 Ampere's Circuital Law (ACL) 96
4.4.1 An Intuitive Development of ACL 96
4.4.2 Using ACL to Determine H 97
4.5 Inductance 100
4.5.1 Determination of Inductance 100
4.5.2 Magnetic Materials and Permeability 102
4.5.3 Magnetic Field Boundary Conditions 103
4.5.4 Energy Storage in a Magnetic Field 105
4.6 Summary of Important Equations 106
4.7 Appendices 106
Appendix 4.A Dielectric-Dielectric Electric Field Boundary Conditions 106
Appendix 4.B Development of Relative Permittivity 108
Appendix 4.C Development of Resistance 109
Appendix 4.D Introduction to Magnetic Circuits 111
4.8 Homework 113
Problems for Appendix 4.D 117
Part 2 Time-Changing Electric and Magnetic Fields 119
5 Maxwell's Equations 121
5.1 Introduction to Time-Changing Electromagnetic Fields 121
5.2 Faraday's Law 123
5.2.1 Lorentz Force Law and Induced Voltage 123
5.2.2 Time-Changing Magnetic Fields 125
5.2.3 Another Look at Kirchhoff's Voltage Law 127
5.2.4 Another Look at the Inductor 128
5.2.5 The Ideal Transformer 129
5.2.6 Mutual Inductors 130
5.3 Displacement Current 133
5.3.1 Time-Changing Electric Fields 133
5.3.2 Another Look at the Capacitor 134
5.3.3 Mutual Capacitance 135
5.4 Chapter Summary: Maxwell's Equations in Integral Form 136
5.5 Appendices
Details
| Erscheinungsjahr: | 2022 |
|---|---|
| Fachbereich: | Nachrichtentechnik |
| Genre: | Technik |
| Rubrik: | Naturwissenschaften & Technik |
| Medium: | Buch |
| Seiten: | 304 |
| Inhalt: | 304 S. |
| ISBN-13: | 9781119881902 |
| ISBN-10: | 1119881900 |
| Sprache: | Englisch |
| Herstellernummer: | 1W119881900 |
| Autor: |
Strangeway, Robert Alan
Holland, Steven Sean Richie, James Elwood |
| Auflage: | 2. Aufl. |
| Hersteller: |
Wiley
Wiley & Sons |
| Maße: | 254 x 203 x 18 mm |
| Von/Mit: | Robert Alan Strangeway (u. a.) |
| Erscheinungsdatum: | 27.10.2022 |
| Gewicht: | 0,751 kg |
Inhaltsverzeichnis
Preface xiii
Acknowledgments xvii
About the Authors xix
About the Companion Website xxi
1 Vectors, Vector Algebra, and Coordinate Systems 1
1.1 Vectors 1
1.2 Vector Algebra 4
1.2.1 Dot Product 4
1.2.2 Cross Product 7
1.3 Field Vectors 10
1.4 Cylindrical Coordinate System, Vectors, and Conversions 12
1.4.1 Cartesian (Rectangular) Coordinate System: Review 12
1.4.2 Cylindrical Coordinate System 13
1.5 Spherical Coordinate System, Vectors, and Conversions 19
1.6 Summary of Coordinate Systems and Vectors 25
1.7 Homework 27
Part 1 Static Electric and Magnetic Fields 31
2 The Superposition Laws of Electric and Magnetic Fields 33
2.1 Point Electric Charges, Coulomb's Law, and Electric Fields 34
2.2 Electric Charge Distributions and Charge Density 37
2.3 Coulomb's Law in Integral Form and Examples 38
2.4 Introduction to Magnetostatics and Current Density 47
2.5 Biot-Savart Law and Examples for Line Currents 50
2.6 Summary of Important Equations 56
2.7 Homework 56
3 The Flux Laws of Electric and Magnetic Fields 61
3.1 An Intuitive Development of Electric Flux and Gauss's Law 62
3.1.1 A First Look at Electric Flux Density 62
3.1.2 Electric Flux and Gauss's Law 63
3.2 Practical Determination of Electric Fields Using Gauss's Law 65
3.3 Determination of Charge from Electric Fields 73
3.4 Magnetic Flux 74
3.5 Summary of Important Equations 78
3.6 Homework 78
4 The Path Laws and Circuit Principles 83
4.1 Electric Potential (Voltage) and Kirchhoff's Voltage Law 84
4.1.1 Potential-Electric Field Relationship 84
4.1.2 Kirchhoff's Voltage Law (KVL) 86
4.1.3 Dielectric-Conductor Electric Field Boundary Conditions 86
4.2 Capacitance 87
4.2.1 Determination of Capacitance 88
4.2.2 Dielectrics and Permittivity 90
4.2.3 Energy Storage in Electric Fields 93
4.3 Resistance 94
4.4 Ampere's Circuital Law (ACL) 96
4.4.1 An Intuitive Development of ACL 96
4.4.2 Using ACL to Determine H 97
4.5 Inductance 100
4.5.1 Determination of Inductance 100
4.5.2 Magnetic Materials and Permeability 102
4.5.3 Magnetic Field Boundary Conditions 103
4.5.4 Energy Storage in a Magnetic Field 105
4.6 Summary of Important Equations 106
4.7 Appendices 106
Appendix 4.A Dielectric-Dielectric Electric Field Boundary Conditions 106
Appendix 4.B Development of Relative Permittivity 108
Appendix 4.C Development of Resistance 109
Appendix 4.D Introduction to Magnetic Circuits 111
4.8 Homework 113
Problems for Appendix 4.D 117
Part 2 Time-Changing Electric and Magnetic Fields 119
5 Maxwell's Equations 121
5.1 Introduction to Time-Changing Electromagnetic Fields 121
5.2 Faraday's Law 123
5.2.1 Lorentz Force Law and Induced Voltage 123
5.2.2 Time-Changing Magnetic Fields 125
5.2.3 Another Look at Kirchhoff's Voltage Law 127
5.2.4 Another Look at the Inductor 128
5.2.5 The Ideal Transformer 129
5.2.6 Mutual Inductors 130
5.3 Displacement Current 133
5.3.1 Time-Changing Electric Fields 133
5.3.2 Another Look at the Capacitor 134
5.3.3 Mutual Capacitance 135
5.4 Chapter Summary: Maxwell's Equations in Integral Form 136
5.5 Appendices
Acknowledgments xvii
About the Authors xix
About the Companion Website xxi
1 Vectors, Vector Algebra, and Coordinate Systems 1
1.1 Vectors 1
1.2 Vector Algebra 4
1.2.1 Dot Product 4
1.2.2 Cross Product 7
1.3 Field Vectors 10
1.4 Cylindrical Coordinate System, Vectors, and Conversions 12
1.4.1 Cartesian (Rectangular) Coordinate System: Review 12
1.4.2 Cylindrical Coordinate System 13
1.5 Spherical Coordinate System, Vectors, and Conversions 19
1.6 Summary of Coordinate Systems and Vectors 25
1.7 Homework 27
Part 1 Static Electric and Magnetic Fields 31
2 The Superposition Laws of Electric and Magnetic Fields 33
2.1 Point Electric Charges, Coulomb's Law, and Electric Fields 34
2.2 Electric Charge Distributions and Charge Density 37
2.3 Coulomb's Law in Integral Form and Examples 38
2.4 Introduction to Magnetostatics and Current Density 47
2.5 Biot-Savart Law and Examples for Line Currents 50
2.6 Summary of Important Equations 56
2.7 Homework 56
3 The Flux Laws of Electric and Magnetic Fields 61
3.1 An Intuitive Development of Electric Flux and Gauss's Law 62
3.1.1 A First Look at Electric Flux Density 62
3.1.2 Electric Flux and Gauss's Law 63
3.2 Practical Determination of Electric Fields Using Gauss's Law 65
3.3 Determination of Charge from Electric Fields 73
3.4 Magnetic Flux 74
3.5 Summary of Important Equations 78
3.6 Homework 78
4 The Path Laws and Circuit Principles 83
4.1 Electric Potential (Voltage) and Kirchhoff's Voltage Law 84
4.1.1 Potential-Electric Field Relationship 84
4.1.2 Kirchhoff's Voltage Law (KVL) 86
4.1.3 Dielectric-Conductor Electric Field Boundary Conditions 86
4.2 Capacitance 87
4.2.1 Determination of Capacitance 88
4.2.2 Dielectrics and Permittivity 90
4.2.3 Energy Storage in Electric Fields 93
4.3 Resistance 94
4.4 Ampere's Circuital Law (ACL) 96
4.4.1 An Intuitive Development of ACL 96
4.4.2 Using ACL to Determine H 97
4.5 Inductance 100
4.5.1 Determination of Inductance 100
4.5.2 Magnetic Materials and Permeability 102
4.5.3 Magnetic Field Boundary Conditions 103
4.5.4 Energy Storage in a Magnetic Field 105
4.6 Summary of Important Equations 106
4.7 Appendices 106
Appendix 4.A Dielectric-Dielectric Electric Field Boundary Conditions 106
Appendix 4.B Development of Relative Permittivity 108
Appendix 4.C Development of Resistance 109
Appendix 4.D Introduction to Magnetic Circuits 111
4.8 Homework 113
Problems for Appendix 4.D 117
Part 2 Time-Changing Electric and Magnetic Fields 119
5 Maxwell's Equations 121
5.1 Introduction to Time-Changing Electromagnetic Fields 121
5.2 Faraday's Law 123
5.2.1 Lorentz Force Law and Induced Voltage 123
5.2.2 Time-Changing Magnetic Fields 125
5.2.3 Another Look at Kirchhoff's Voltage Law 127
5.2.4 Another Look at the Inductor 128
5.2.5 The Ideal Transformer 129
5.2.6 Mutual Inductors 130
5.3 Displacement Current 133
5.3.1 Time-Changing Electric Fields 133
5.3.2 Another Look at the Capacitor 134
5.3.3 Mutual Capacitance 135
5.4 Chapter Summary: Maxwell's Equations in Integral Form 136
5.5 Appendices
Details
| Erscheinungsjahr: | 2022 |
|---|---|
| Fachbereich: | Nachrichtentechnik |
| Genre: | Technik |
| Rubrik: | Naturwissenschaften & Technik |
| Medium: | Buch |
| Seiten: | 304 |
| Inhalt: | 304 S. |
| ISBN-13: | 9781119881902 |
| ISBN-10: | 1119881900 |
| Sprache: | Englisch |
| Herstellernummer: | 1W119881900 |
| Autor: |
Strangeway, Robert Alan
Holland, Steven Sean Richie, James Elwood |
| Auflage: | 2. Aufl. |
| Hersteller: |
Wiley
Wiley & Sons |
| Maße: | 254 x 203 x 18 mm |
| Von/Mit: | Robert Alan Strangeway (u. a.) |
| Erscheinungsdatum: | 27.10.2022 |
| Gewicht: | 0,751 kg |
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