Vector Fields Acting on a Curve

1. VC.04-VC.08 Redux Vector Fields Acting on a Curve

2. VC.04: Find a surface with the given gradient (Ex 1 From VC.04 Notes)

3. VC.04: Gradient Fields

4. VC.04: Gradient Fields

5. VC.04: Breaking Field Vectorsinto Two Components

8. VC.04: Flow Along and Flow Across

9. VC.05: Measuring the Flow of a Vector Field ALONG a Curve These integrals are usually called line integrals or path integrals.

10. VC.05: Measuring the Flow of a Vector Field ALONG a Curve

11. VC.05: Measuring the Flow of a Vector Field Along Another Closed Curve

12. VC.05: Measuring the Flow of a Vector Field Along Another Closed Curve  Counterclockwise

13. VC.05: Measuring the Flow of a Vector Field ACROSS a Curve

14. VC.05: Measuring the Flow of a Vector Field Across Another Closed Curve  Counterclockwise

15. VC.05: The Gradient Test

16. VC.05: The Flow of a Gradient Field Along a Closed Curve

17. VC.05: Path Independence: The Flow of a Gradient Field Along an Open Curve

18. VC.06: The Gauss-Green Formula

19. VC.06: Measuring the Flow of a Vector Field ALONG a Closed Curve Let C be a closed curve with a counterclockwise parameterization. Then the net flow of the vector field ALONG the closed curve is measured by: Let region R be the interior of C. If the vector field has no singularities in R, then we can use Gauss-Green:

20. VC.06: Summary: The Flow of A Vector Field ALONG a Closed Curve: • Let C be a closed curve parameterized counterclockwise. Let Field(x,y) be a vector field with no singularities on the interior region R of C. Then: • This measures the net flow of the vector field ALONG the closed curve.

21. VC.06: Measuring the Flow of a Vector Field ACROSS a Closed Curve Let C be a closed curve with a counterclockwise parameterization. Then the net flow of the vector field ACROSS the closed curve is measured by: Let region R be the interior of C. If the vector field has no singularities in R, then we can use Gauss-Green:

22. VC.06: Summary: The Flow of A Vector Field ACROSS a Closed Curve: • Let C be a closed curve parameterized counterclockwise. Let Field(x,y) be a vector field with no singularities on the interior region R of C. Then: • This measures the net flow of the vector field ACROSS the closed curve.

23. VC.06: The Divergence Locates Sources and Sinks Let C be a closed curve with a counterclockwise parameterization with no singularities on the interior of the curve. Then:

24. VC.06: The Rotation Helps You Find Clockwise/Counterclockwise Swirl Let C be a closed curve with a counterclockwise parameterization with no singularities on the interior of the curve. Then:

25. VC.06: Avoiding Computation Altogether

26. VC.06: Find the Net Flow of a Vector Field ACROSS Closed Curve

27. VC.06: A Flow Along Measurement With a Singularity

28. VC.06: A Flow Along Measurement With a Singularity

29. VC.06: A Flow Along With Multiple Singularities? No Problem!

30. VC.06: Flow Along When rotField(x,y)=0

31. VC.06: Flow Along When divField(x,y)=0

32. VC.07: The Area Conversion Factor:

33. VC.07: The Area Conversion Factor:

34. VC.07: : Fixing Example 2

35. VC.07: Mathematica-Aided Change of Variables (Parallelogram Region)

36. VC.07: Mathematica-Aided Change of Variables (Parallelogram Region)

37. VC.07: Mathematica-Aided Change of Variables (Parallelogram Region)

38. VC.08: 3D Integrals:

39. VC.08: A 3D-Change of Variables with an Integrand