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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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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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