1 / 42

Electrostatic Boundary-Value Problems

Electrostatic Boundary-Value Problems. 1. Figure 6.1 An electrohydrodynamic pump; for Example 6.1. Figure 6.2 For Example 6.2. Figure 6.3 Potential V ( f ) due to semi-infinite conducting planes. Figure 6.4 For Practice Exercise 6.3.

licia
Download Presentation

Electrostatic Boundary-Value Problems

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Electrostatic Boundary-Value Problems 1

  2. Figure 6.1 An electrohydrodynamic pump; for Example 6.1. Elements of Electromagnetics Fourth Edition Sadiku

  3. Figure 6.2 For Example 6.2. Elements of Electromagnetics Fourth Edition Sadiku

  4. Figure 6.3 Potential V(f) due to semi-infinite conducting planes. Elements of Electromagnetics Fourth Edition Sadiku

  5. Figure 6.4 For Practice Exercise 6.3. Elements of Electromagnetics Fourth Edition Sadiku

  6. Figure 6.5 Potential V(q) due to conducting cones. Elements of Electromagnetics Fourth Edition Sadiku

  7. Figure 6.6 For Practice Exercise 6.4. Elements of Electromagnetics Fourth Edition Sadiku

  8. Figure 6.7 Potential V(x, y) due to a conducting rectangular trough; for Example 6.5. Elements of Electromagnetics Fourth Edition Sadiku

  9. Figure 6.8 Sketch of cosh x andsinh x showing that sinh x =0 if and only if x =0; for Case 2 of Example 6.5. Elements of Electromagnetics Fourth Edition Sadiku

  10. Figure 6.9 Sketch of sin xshowing that sin x = 0 at infinite number of points; for Case 3 of Example 6.5. Elements of Electromagnetics Fourth Edition Sadiku

  11. Figure 6.10 For Example 6.5: (a) V(x, y) calculated at some points, (b) sketch of flux lines and equipotential lines. Elements of Electromagnetics Fourth Edition Sadiku

  12. Figure 6.11 Matlab program for Example 6.5. Elements of Electromagnetics Fourth Edition Sadiku

  13. Figure 6.12 A two-conductor capacitor. Elements of Electromagnetics Fourth Edition Sadiku

  14. Figure 6.13 (a) Parallel-plate capacitor. (b) Fringing effect due to a parallel-plate capacitor. Elements of Electromagnetics Fourth Edition Sadiku

  15. Figure 6.14 A coaxial capacitor. Elements of Electromagnetics Fourth Edition Sadiku

  16. Figure 6.15 A spherical capacitor. Elements of Electromagnetics Fourth Edition Sadiku

  17. Figure 6.16 Capacitors (a) in series and (b) in parallel. Elements of Electromagnetics Fourth Edition Sadiku

  18. Figure 6.17 Bent metal bar for Example 6.8. Elements of Electromagnetics Fourth Edition Sadiku

  19. Figure 6.18 Potential V(r) due to conducting spherical shells. Elements of Electromagnetics Fourth Edition Sadiku

  20. Figure 6.19 For Practice Exercises 6.9, 6.10, and 6.12. Elements of Electromagnetics Fourth Edition Sadiku

  21. Figure 6.20 For Example 6.12. Elements of Electromagnetics Fourth Edition Sadiku

  22. Figure 6.21 Image system: (a) charge configurations above a perfectly conducting plane, (b) image configuration with the conducting plane replaced by equipotential surface. Elements of Electromagnetics Fourth Edition Sadiku

  23. Figure 6.22 (a) Point charge and grounded conducting plane. (b) Image configuration and field lines. Elements of Electromagnetics Fourth Edition Sadiku

  24. Figure 6.23 Point charge between two semi-infinite conducting planes. Elements of Electromagnetics Fourth Edition Sadiku

  25. Figure 6.24 Determining (a) the potential at P and (b) the force on charge Q. Elements of Electromagnetics Fourth Edition Sadiku

  26. Figure 6.25 Point charge between two semi-infinite conducting walls inclined at f = 60° to each other. Elements of Electromagnetics Fourth Edition Sadiku

  27. Figure 6.26 Circular microstrip capacitor. Elements of Electromagnetics Fourth Edition Sadiku

  28. Figure 6.27 Capacitance of the circular microstrip capacitor. Elements of Electromagnetics Fourth Edition Sadiku

  29. Figure 6.28 For Problem 6.11. Elements of Electromagnetics Fourth Edition Sadiku

  30. Figure 6.29 Cylindrical capacitor of Problem 6.12. Elements of Electromagnetics Fourth Edition Sadiku

  31. Figure 6.30 Conducting cones of Problem 6.15. Elements of Electromagnetics Fourth Edition Sadiku

  32. Figure 6.31 For Problem 6.18. Elements of Electromagnetics Fourth Edition Sadiku

  33. Figure 6.32 For Problem 6.19. Elements of Electromagnetics Fourth Edition Sadiku

  34. Figure 6.33 For Problem 6.20. Elements of Electromagnetics Fourth Edition Sadiku

  35. Figure 6.34 For Problem 6.24. Elements of Electromagnetics Fourth Edition Sadiku

  36. Figure 6.35 For Problem 6.26. Elements of Electromagnetics Fourth Edition Sadiku

  37. Figure 6.36 For Problem 6.28. Elements of Electromagnetics Fourth Edition Sadiku

  38. Figure 6.37 For Problem 6.29. Elements of Electromagnetics Fourth Edition Sadiku

  39. Figure 6.38 For Problem 6.30. Elements of Electromagnetics Fourth Edition Sadiku

  40. Figure 6.39 For Problem 6.32. Elements of Electromagnetics Fourth Edition Sadiku

  41. Figure 6.40 Simplified geometry of an ink-jet printer; for Problem 6.41. Elements of Electromagnetics Fourth Edition Sadiku

  42. Figure 6.41 For Problem 6.43. Elements of Electromagnetics Fourth Edition Sadiku

More Related