Analysis and calculations of the ground plane inductance associated with a printed circuit board [[electronic resource] /] / Christopher L. Holloway, Edward F. Kuester |
Autore | Holloway Christopher L |
Pubbl/distr/stampa | [Boulder, Colo.] : , : U.S. Dept. of Commerce, National Telecommunications and Information Administration, , [1997] |
Descrizione fisica | 1 online resource (40 pages) : illustrations |
Altri autori (Persone) | KuesterEdward F |
Collana | NTIA report |
Soggetto topico |
Inductance
Printed circuits |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Record Nr. | UNINA-9910700768703321 |
Holloway Christopher L | ||
[Boulder, Colo.] : , : U.S. Dept. of Commerce, National Telecommunications and Information Administration, , [1997] | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
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A four terminal current shunt with calculable AC response / / O. B. Laug |
Autore | Laug O. B |
Pubbl/distr/stampa | Gaithersburg, MD : , : U.S. Dept. of Commerce, National Institute of Standards and Technology, , 2004 |
Descrizione fisica | 1 online resource |
Altri autori (Persone) | LaugO. B |
Collana | NIST technical note |
Soggetto topico |
Electric currents, Alternating
Electric resistance Inductance |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Record Nr. | UNINA-9910711203803321 |
Laug O. B | ||
Gaithersburg, MD : , : U.S. Dept. of Commerce, National Institute of Standards and Technology, , 2004 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Inductance : loop and partial / / Clayton R. Paul |
Autore | Paul Clayton R. |
Edizione | [1st edition] |
Pubbl/distr/stampa | Hoboken, New Jersey : , : J. Wiley, , c2010 |
Descrizione fisica | 1 online resource (395 p.) |
Disciplina |
537.6
621.3742 |
Soggetto topico |
Inductance
Induction coils |
ISBN |
1-118-21128-6
1-282-68659-3 9786612686597 0-470-56123-8 0-470-56122-X |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Preface -- 1 Introduction -- 1.1 Historical Background -- 1.2 Fundamental Concepts of Lumped Circuits -- 1.3 Outline of the Book -- 1.4 "Loop" Inductance vs. "Partial" Inductance -- 2 Magnetic Fields of DC Currents (Steady Flow of Charge) -- 2.1 Magnetic Field Vectors and Properties of Materials -- 2.2 Gauss's Law for the Magnetic Field and the Surface Integral -- 2.3 The Biot-Savart Law -- 2.4 Ampére's Law and the Line Integral -- 2.5 Vector Magnetic Potential -- 2.5.1 Leibnitz's Rule: Differentiate Before You Integrate -- 2.6 Determining the Inductance of a Current Loop: -- A Preliminary Discussion -- 2.7 Energy Stored in the Magnetic Field -- 2.8 The Method of Images -- 2.9 Steady (DC) Currents Must Form Closed Loops -- 3 Fields of Time-Varying Currents (Accelerated Charge) -- 3.1 Faraday's Fundamental Law of Induction -- 3.2 Ampère's Law and Displacement Current -- 3.3 Waves, Wavelength, Time Delay, and Electrical Dimensions -- 3.4 How Can Results Derived Using Static (DC) Voltages and Currents be Used in Problems Where the Voltages and Currents are Varying with Time? -- 3.5 Vector Magnetic Potential for Time-Varying Currents -- 3.6 Conservation of Energy and Poynting's Theorem -- 3.7 Inductance of a Conducting Loop -- 4 The Concept of "Loop" Inductance -- 4.1 Self Inductance of a Current Loop from Faraday's Law of Induction -- 4.1.1 Rectangular Loop -- 4.1.2 Circular Loop -- 4.1.3 Coaxial Cable -- 4.2 The Concept of Flux Linkages for Multiturn Loops -- 4.2.1 Solenoid -- 4.2.2 Toroid -- 4.3 Loop Inductance Using the Vector Magnetic Potential -- 4.3.1 Rectangular Loop -- 4.3.2 Circular Loop -- 4.4 Neumann Integral for Self and Mutual Inductances Between Current Loops -- 4.4.1 Mutual Inductance Between Two Circular Loops -- 4.4.2 Self Inductance of the Rectangular Loop -- 4.4.3 Self Inductance of the Circular Loop -- 4.5 Internal Inductance vs. External Inductance -- 4.6 Use of Filamentary Currents and Current Redistribution Due to the Proximity Effect -- 4.6.1 Two-Wire Transmission Line.
4.6.2 One Wire Above a Ground Plane -- 4.7 Energy Storage Method for Computing Loop Inductance -- 4.7.1 Internal Inductance of a Wire -- 4.7.2 Two-Wire Transmission Line -- 4.7.3 Coaxial Cable -- 4.8 Loop Inductance Matrix for Coupled Current Loops -- 4.8.1 Dot Convention -- 4.8.2 Multiconductor Transmission Lines -- 4.9 Loop Inductances of Printed Circuit Board Lands -- 4.10 Summary of Methods for Computing Loop Inductance -- 4.10.1 Mutual Inductance Between Two Rectangular Loops -- 5 The Concept of "Partial" Inductance -- 5.1 General Meaning of Partial Inductance -- 5.2 Physical Meaning of Partial Inductance -- 5.3 Self Partial Inductance of Wires -- 5.4 Mutual Partial Inductance Between Parallel Wires -- 5.5 Mutual Partial Inductance Between Parallel Wires that are Offset -- 5.6 Mutual Partial Inductance Between Wires at an Angle to Each Other -- 5.7 Numerical Values of Partial Inductances and Significance of Internal Inductance -- 5.8 Constructing Lumped Equivalent Circuits with Partial Inductances -- 6 Partial Inductances of Conductors of Rectangular Cross Section -- 6.1 Formulation for the Computation of the Partial Inductances of PCB Lands -- 6.2 Self Partial Inductance of PCB Lands -- 6.3 Mutual Partial Inductance Between PCB Lands -- 6.4 Concept of Geometric Mean Distance -- 6.4.1 Geometrical Mean Distance Between a Shape and Itself and the Self Partial Inductance of a Shape -- 6.4.2 Geometrical Mean Distance and Mutual Partial Inductance Between Two Shapes -- 6.5 Computing the High-Frequency Partial Inductances of Lands and Numerical Methods -- 7 "Loop" Inductance vs. "Partial" Inductance -- 7.1 Loop Inductance vs. Partial Inductance: Intentional Inductors vs. Nonintentional Inductors -- 7.2 To Compute "Loop" Inductance, the "Return Path" for the Current Must be Determined -- 7.3 Generally, There is no Unique Return Path for all Frequencies, Thereby Complicating the Calculation of a "Loop" Inductance -- 7.4 Computing the "Ground Bounce" and "Power Rail Collapse" of a Digital Power Distribution System Using "Loop" Inductances. 7.5 Where Should the "Loop" Inductance of the Closed Current Path be Placed When Developing a Lumped-Circuit Model of a Signal or Power Delivery Path? -- 7.6 How Can a Lumped-Circuit Model of a Complicated System of a Large Number of Tightly Coupled Current Loops be Constructed Using "Loop" Inductance? -- 7.7 Modeling Vias on PCBs -- 7.8 Modeling Pins in Connectors -- 7.9 Net Self Inductance of Wires in Parallel and in Series -- 7.10 Computation of Loop Inductances for Various Loop Shapes -- 7.11 Final Example: Use of Loop and Partial Inductance to Solve a Problem -- Appendix A: Fundamental Concepts of Vectors -- A.1 Vectors and Coordinate Systems -- A.2 Line Integral -- A.3 Surface Integral -- A.4 Divergence -- A.4.1 Divergence Theorem -- A.5 Curl -- A.5.1 Stokes's Theorem -- A.6 Gradient of a Scalar Field -- A.7 Important Vector Identities -- A.8 Cylindrical Coordinate System -- A.9 Spherical Coordinate System -- Table of Identities, Derivatives, and Integrals Used in this Book -- References and Further Readings -- Index. |
Record Nr. | UNINA-9910139472603321 |
Paul Clayton R. | ||
Hoboken, New Jersey : , : J. Wiley, , c2010 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Inductance : loop and partial / / Clayton R. Paul |
Autore | Paul Clayton R. |
Edizione | [1st edition] |
Pubbl/distr/stampa | Hoboken, New Jersey : , : J. Wiley, , c2010 |
Descrizione fisica | 1 online resource (395 p.) |
Disciplina |
537.6
621.3742 |
Soggetto topico |
Inductance
Induction coils |
ISBN |
1-118-21128-6
1-282-68659-3 9786612686597 0-470-56123-8 0-470-56122-X |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Preface -- 1 Introduction -- 1.1 Historical Background -- 1.2 Fundamental Concepts of Lumped Circuits -- 1.3 Outline of the Book -- 1.4 "Loop" Inductance vs. "Partial" Inductance -- 2 Magnetic Fields of DC Currents (Steady Flow of Charge) -- 2.1 Magnetic Field Vectors and Properties of Materials -- 2.2 Gauss's Law for the Magnetic Field and the Surface Integral -- 2.3 The Biot-Savart Law -- 2.4 Ampére's Law and the Line Integral -- 2.5 Vector Magnetic Potential -- 2.5.1 Leibnitz's Rule: Differentiate Before You Integrate -- 2.6 Determining the Inductance of a Current Loop: -- A Preliminary Discussion -- 2.7 Energy Stored in the Magnetic Field -- 2.8 The Method of Images -- 2.9 Steady (DC) Currents Must Form Closed Loops -- 3 Fields of Time-Varying Currents (Accelerated Charge) -- 3.1 Faraday's Fundamental Law of Induction -- 3.2 Ampère's Law and Displacement Current -- 3.3 Waves, Wavelength, Time Delay, and Electrical Dimensions -- 3.4 How Can Results Derived Using Static (DC) Voltages and Currents be Used in Problems Where the Voltages and Currents are Varying with Time? -- 3.5 Vector Magnetic Potential for Time-Varying Currents -- 3.6 Conservation of Energy and Poynting's Theorem -- 3.7 Inductance of a Conducting Loop -- 4 The Concept of "Loop" Inductance -- 4.1 Self Inductance of a Current Loop from Faraday's Law of Induction -- 4.1.1 Rectangular Loop -- 4.1.2 Circular Loop -- 4.1.3 Coaxial Cable -- 4.2 The Concept of Flux Linkages for Multiturn Loops -- 4.2.1 Solenoid -- 4.2.2 Toroid -- 4.3 Loop Inductance Using the Vector Magnetic Potential -- 4.3.1 Rectangular Loop -- 4.3.2 Circular Loop -- 4.4 Neumann Integral for Self and Mutual Inductances Between Current Loops -- 4.4.1 Mutual Inductance Between Two Circular Loops -- 4.4.2 Self Inductance of the Rectangular Loop -- 4.4.3 Self Inductance of the Circular Loop -- 4.5 Internal Inductance vs. External Inductance -- 4.6 Use of Filamentary Currents and Current Redistribution Due to the Proximity Effect -- 4.6.1 Two-Wire Transmission Line.
4.6.2 One Wire Above a Ground Plane -- 4.7 Energy Storage Method for Computing Loop Inductance -- 4.7.1 Internal Inductance of a Wire -- 4.7.2 Two-Wire Transmission Line -- 4.7.3 Coaxial Cable -- 4.8 Loop Inductance Matrix for Coupled Current Loops -- 4.8.1 Dot Convention -- 4.8.2 Multiconductor Transmission Lines -- 4.9 Loop Inductances of Printed Circuit Board Lands -- 4.10 Summary of Methods for Computing Loop Inductance -- 4.10.1 Mutual Inductance Between Two Rectangular Loops -- 5 The Concept of "Partial" Inductance -- 5.1 General Meaning of Partial Inductance -- 5.2 Physical Meaning of Partial Inductance -- 5.3 Self Partial Inductance of Wires -- 5.4 Mutual Partial Inductance Between Parallel Wires -- 5.5 Mutual Partial Inductance Between Parallel Wires that are Offset -- 5.6 Mutual Partial Inductance Between Wires at an Angle to Each Other -- 5.7 Numerical Values of Partial Inductances and Significance of Internal Inductance -- 5.8 Constructing Lumped Equivalent Circuits with Partial Inductances -- 6 Partial Inductances of Conductors of Rectangular Cross Section -- 6.1 Formulation for the Computation of the Partial Inductances of PCB Lands -- 6.2 Self Partial Inductance of PCB Lands -- 6.3 Mutual Partial Inductance Between PCB Lands -- 6.4 Concept of Geometric Mean Distance -- 6.4.1 Geometrical Mean Distance Between a Shape and Itself and the Self Partial Inductance of a Shape -- 6.4.2 Geometrical Mean Distance and Mutual Partial Inductance Between Two Shapes -- 6.5 Computing the High-Frequency Partial Inductances of Lands and Numerical Methods -- 7 "Loop" Inductance vs. "Partial" Inductance -- 7.1 Loop Inductance vs. Partial Inductance: Intentional Inductors vs. Nonintentional Inductors -- 7.2 To Compute "Loop" Inductance, the "Return Path" for the Current Must be Determined -- 7.3 Generally, There is no Unique Return Path for all Frequencies, Thereby Complicating the Calculation of a "Loop" Inductance -- 7.4 Computing the "Ground Bounce" and "Power Rail Collapse" of a Digital Power Distribution System Using "Loop" Inductances. 7.5 Where Should the "Loop" Inductance of the Closed Current Path be Placed When Developing a Lumped-Circuit Model of a Signal or Power Delivery Path? -- 7.6 How Can a Lumped-Circuit Model of a Complicated System of a Large Number of Tightly Coupled Current Loops be Constructed Using "Loop" Inductance? -- 7.7 Modeling Vias on PCBs -- 7.8 Modeling Pins in Connectors -- 7.9 Net Self Inductance of Wires in Parallel and in Series -- 7.10 Computation of Loop Inductances for Various Loop Shapes -- 7.11 Final Example: Use of Loop and Partial Inductance to Solve a Problem -- Appendix A: Fundamental Concepts of Vectors -- A.1 Vectors and Coordinate Systems -- A.2 Line Integral -- A.3 Surface Integral -- A.4 Divergence -- A.4.1 Divergence Theorem -- A.5 Curl -- A.5.1 Stokes's Theorem -- A.6 Gradient of a Scalar Field -- A.7 Important Vector Identities -- A.8 Cylindrical Coordinate System -- A.9 Spherical Coordinate System -- Table of Identities, Derivatives, and Integrals Used in this Book -- References and Further Readings -- Index. |
Record Nr. | UNINA-9910830602103321 |
Paul Clayton R. | ||
Hoboken, New Jersey : , : J. Wiley, , c2010 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
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Superconductive dust cores for inductive elements / / by Russell J. Jirberg |
Autore | Jirberg Russell J. |
Pubbl/distr/stampa | Washington, D.C. : , : National Aeronautics and Space Administration, , April 1969 |
Descrizione fisica | 1 online resource (ii, 36 pages) : illustrations |
Collana | NASA/TN |
Soggetto topico |
Superconductors (materials)
Impedance Impedance (Electricity) - Measurement Inductance Superconductors - Magnetic properties |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Record Nr. | UNINA-9910716046203321 |
Jirberg Russell J. | ||
Washington, D.C. : , : National Aeronautics and Space Administration, , April 1969 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
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