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Engineering field theory

By: Material type: TextTextSeries: The Commonwealth and international library. Applied electricity and electronics divisionPublisher: Oxford , New York: Pergamon Press, 1973Description: xiv, 253 p.: grafContent type:
  • Text
Media type:
  • computer
Carrier type:
  • online resource
ISBN:
  • 9781483187006 (
  • 1483187004 (
Subject(s): Genre/Form: Additional physical formats: Print version:: Engineering field theory.DDC classification:
  • 530.14  23
Contents:
Front Cover; Engineering Field Theory; Copyright Page; Table of Contents; Preface; Part I:Introduction; CHAPTER 1. INTRODUCTION; 1.1. Inverse square law; 1.2. Force at a distance; 1.3. Field theory; 1.4. Flux theory; 1.5. Systems of units and dimensions; 1.6. Vector quantities; 1.7. Mathematical basis; 1.8. Summary; Problems; Part II:Flux; CHAPTER 2. ELECTRIC FLUX; 2.1. An imaginary fluid; 2.2. Coulomb's law; 2.3. Electric flux; 2.4. Permittivity; 2.5. Flux density; 2.6. Field intensity; 2.7. Principle of superposition; 2.8. Gauss's law; 2.9. Field of a line charge
2.10. Field of a surface charge2.11. Two parallel surface charges; 2.12. Summary; Problems; CHAPTER 3. FLUX FUNCTION; 3.1. Introduction; 3.2. Flux tube and flux line; 3.3. Flux function; 3.4. Differential relationships; 3.5. Uniform field; 3.6. Line charge; 3.7. Line sink; 3.8. Line source and line sink; 3.9. Doublet; 3.10. Line source and uniform field; 3.11. Doublet and uniform field; 3.12. Summary; Problems; CHAPTER 4. ELECTRICAL MATERIALS; 4.1. Atomic properties; 4.2. A conducting medium in a uniform electric field; 4.3. Charge distribution on a conductor
4.4. Field intensity at the surface of a conductor4.5. Force on a charged surface; 4.6. An insulating medium in a uniform electric field; 4.7. Relative permittivity; 4.8. Summary; Problems; CHAPTER 5. GRAVITATION AND FLUID FLOW; 5.1. Gravitational flux; 5.2. Gravitational constant; 5.3. Gravitational field intensity; 5.4. Uniform sphere; 5.5. Fluid field; 5.6. Bernoulli's equation; 5.7. Ideal fluid; 5.8. Gauss's law; 5.9. Stream function; 5.10. Velocity; 5.11. Pressure; 5.12. Summary; Problems; CHAPTER 6. MAGNETIC FLUX; 6.1. Coulomb's law; 6.2. Flux density; 6.3. Gauss's law
6.4. Magnetic field of an electric current6.5. Force on an electric current; 6.6. Direction of magnetic forces; 6.7. Current loop and magnetic dipole; 6.8. Field intensity; 6.9. Magnetic materials; 6.10. Permeability; 6.11. Magnetization; 6.12. Summary; Problems; Part III:Potential; CHAPTER 7. ELECTRIC POTENTIAL; 7.1. Electric intensity; 7.2. Potential function; 7.3. Absolute potential; 7.4. Differential relationships; 7.5. Capacitance; 7.6. Boundary along an equipotential; 7.7. Capacitance with mixed dielectric; 7.8. Boundary along a flux line; 7.9. Energy; 7.10. Summary; Problems
CHAPTER 8. POTENTIAL FUNCTION8.1. Potential function calculations; 8.2. Point charge; 8.3. Dipole; 8.4. Line charge; 8.5. Line source and line sink; 8.6. Method of images; 8.7. Doublet; 8.8. Doublet and uniform field; 8.9. Dual; 8.10. Summary; Problems; CHAPTER 9. Other Fields; 9.1. GRAVITATIONAL POTENTIAL; 9.2. POTENTIAL ENERGY; 9.3. ELECTRIC CONDUCTION; 9.4. RESISTANCE; 9.5. POWER DISSIPATED; 9.6. CONDUCTIVE HEAT TRANSFER; 9.7. SURFACE HEAT TRANSFER; 9.8. FLUID FLOW THROUGH PERMEABLE MEDIA; 9.9. PERMEABILITY; 9.10. SUMMARY; PROBLEMS; CHAPTER 10. FLUID FLOW; 10.1. Velocity potential
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Holdings
Item type Home library Call number Status Notes Barcode
Books Books Centro de Información Eduardo Savino 530.14 B134 (Browse shelf(Opens below)) Available Donado por Manuel Gonzalez Rodriguez Diez 52816
Total holds: 0

Front Cover; Engineering Field Theory; Copyright Page; Table of Contents; Preface; Part I:Introduction; CHAPTER 1. INTRODUCTION; 1.1. Inverse square law; 1.2. Force at a distance; 1.3. Field theory; 1.4. Flux theory; 1.5. Systems of units and dimensions; 1.6. Vector quantities; 1.7. Mathematical basis; 1.8. Summary; Problems; Part II:Flux; CHAPTER 2. ELECTRIC FLUX; 2.1. An imaginary fluid; 2.2. Coulomb's law; 2.3. Electric flux; 2.4. Permittivity; 2.5. Flux density; 2.6. Field intensity; 2.7. Principle of superposition; 2.8. Gauss's law; 2.9. Field of a line charge

2.10. Field of a surface charge2.11. Two parallel surface charges; 2.12. Summary; Problems; CHAPTER 3. FLUX FUNCTION; 3.1. Introduction; 3.2. Flux tube and flux line; 3.3. Flux function; 3.4. Differential relationships; 3.5. Uniform field; 3.6. Line charge; 3.7. Line sink; 3.8. Line source and line sink; 3.9. Doublet; 3.10. Line source and uniform field; 3.11. Doublet and uniform field; 3.12. Summary; Problems; CHAPTER 4. ELECTRICAL MATERIALS; 4.1. Atomic properties; 4.2. A conducting medium in a uniform electric field; 4.3. Charge distribution on a conductor

4.4. Field intensity at the surface of a conductor4.5. Force on a charged surface; 4.6. An insulating medium in a uniform electric field; 4.7. Relative permittivity; 4.8. Summary; Problems; CHAPTER 5. GRAVITATION AND FLUID FLOW; 5.1. Gravitational flux; 5.2. Gravitational constant; 5.3. Gravitational field intensity; 5.4. Uniform sphere; 5.5. Fluid field; 5.6. Bernoulli's equation; 5.7. Ideal fluid; 5.8. Gauss's law; 5.9. Stream function; 5.10. Velocity; 5.11. Pressure; 5.12. Summary; Problems; CHAPTER 6. MAGNETIC FLUX; 6.1. Coulomb's law; 6.2. Flux density; 6.3. Gauss's law

6.4. Magnetic field of an electric current6.5. Force on an electric current; 6.6. Direction of magnetic forces; 6.7. Current loop and magnetic dipole; 6.8. Field intensity; 6.9. Magnetic materials; 6.10. Permeability; 6.11. Magnetization; 6.12. Summary; Problems; Part III:Potential; CHAPTER 7. ELECTRIC POTENTIAL; 7.1. Electric intensity; 7.2. Potential function; 7.3. Absolute potential; 7.4. Differential relationships; 7.5. Capacitance; 7.6. Boundary along an equipotential; 7.7. Capacitance with mixed dielectric; 7.8. Boundary along a flux line; 7.9. Energy; 7.10. Summary; Problems

CHAPTER 8. POTENTIAL FUNCTION8.1. Potential function calculations; 8.2. Point charge; 8.3. Dipole; 8.4. Line charge; 8.5. Line source and line sink; 8.6. Method of images; 8.7. Doublet; 8.8. Doublet and uniform field; 8.9. Dual; 8.10. Summary; Problems; CHAPTER 9. Other Fields; 9.1. GRAVITATIONAL POTENTIAL; 9.2. POTENTIAL ENERGY; 9.3. ELECTRIC CONDUCTION; 9.4. RESISTANCE; 9.5. POWER DISSIPATED; 9.6. CONDUCTIVE HEAT TRANSFER; 9.7. SURFACE HEAT TRANSFER; 9.8. FLUID FLOW THROUGH PERMEABLE MEDIA; 9.9. PERMEABILITY; 9.10. SUMMARY; PROBLEMS; CHAPTER 10. FLUID FLOW; 10.1. Velocity potential

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