1 / 72

PARTIAL DIFFERENTIAL EQUATIONS

PARTIAL DIFFERENTIAL EQUATIONS. Formation of Partial Differential equations Partial Differential Equation can be formed either by elimination of arbitrary constants or by the elimination of arbitrary functions from a relation involving three or more variables . SOLVED PROBLEMS

margot
Télécharger la présentation

PARTIAL DIFFERENTIAL EQUATIONS

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. PARTIAL DIFFERENTIAL EQUATIONS

  2. Formation of Partial Differential equations Partial Differential Equation can be formed either by elimination of arbitrary constants or by the elimination of arbitrary functions from a relation involving three or more variables . SOLVED PROBLEMS 1.Eliminate two arbitrary constants a and b from here R is known constant .

  3. (OR) Find the differential equation of all spheres of fixed radius having their centers in x y- plane. solution Differentiating both sides with respect to x and y

  4. By substituting all these values in (1) or

  5. 2. Find the partial Differential Equation by eliminating arbitrary functions from SOLUTION

  6. By

  7. 3.Find Partial Differential Equation by eliminating two arbitrary functions from SOLUTION Differentiating both sides with respect to x and y

  8. Again d . w .r. to x and yin equation (2)and(3)

  9. Different Integrals of Partial Differential Equation 1. Complete Integral (solution) Let be the Partial Differential Equation. The complete integral of equation (1) is given by

  10. 2. Particular solution A solution obtained by giving particular values to the arbitrary constants in a complete integral is called particular solution . 3.Singular solution The eliminant of a , b between when it exists , is called singular solution

  11. 4. General solution In equation (2) assume an arbitrary relation of the form . Then (2) becomes Differentiating (2) with respect to a, The eliminant of (3) and (4) if exists, is called general solution

  12. Standard types of first order equations TYPE-I The Partial Differential equation of the form has solution with TYPE-II The Partial Differential Equation of the form is called Clairaut’sform of pde , it’s solution is given by

  13. TYPE-III If the pdeis given by then assume that

  14. The given pdecan be written as .And also this can be integrated to get solution

  15. TYPE-IV The pdeof the form can be solved by assuming Integrate the above equation to get solution

  16. SOLVED PROBLEMS 1.Solve the pdeand find the complete and singular solutions Solution Complete solution is given by with

  17. d.w.r.to. a and c then Which is not possible Hence there is no singular solution 2.Solve the pdeand find the complete, general and singular solutions

  18. Solution The complete solution is given by with

  19. no singular solution To get general solution assume that From eq (1)

  20. Eliminate from (2) and (3) to get general solution 3.Solve the pde and find the complete and singular solutions Solution The pde is in Clairaut’s form

  21. complete solution of (1) is d.w.r.to “a” and “b”

  22. From (3)

  23. is required singular solution

  24. 4.Solve the pde Solution pde Complete solution of above pde is 5.Solve the pde Solution Assume that

  25. From given pde

  26. Integrating on both sides

  27. 6. Solve the pde Solution Assume Substituting in given equation

  28. Integrating on both sides 7.Solve pde (or) Solution

  29. Assume that Integrating on both sides

  30. 8. Solve the equation Solution integrating

  31. Equations reducible to the standard forms (i)If and occur in the pdeas in Or in Case (a) Put and if ;

  32. where Then reduces to Similarly reduces to

  33. case(b) If or put (ii)If and occur in pdeas in Or in

  34. Case(a) Put if where Given pde reduces to and

  35. Case(b) if Solved Problems 1.Solve Solution

  36. where

  37. (1)becomes

  38. 2. Solve the pde SOLUTION

  39. Eq(1) becomes

  40. Lagrange’s Linear Equation Def: The linear partial differenfial equation of first order is called as Lagrange’s linear Equation. This eq is of the form Where and are functions x,y and z The general solution of the partial differential equation is Where is arbitrary function of and

  41. Here and are independent solutions of the auxilary equations Solved problems 1.Find the general solution of Solution auxilary equations are

  42. Integrating on both sides Integrating on both sides

  43. The general solution is given by 2.solve solution Auxiliary equations are given by

  44. Integrating on both sides

  45. Integrating on both sides

  46. The general solution is given by HOMOGENEOUS LINEAR PDE WITH CONSTANT COEFFICIENTS Equations in which partial derivatives occurring are all of same order (with degree one ) and the coefficients are constants ,such equations are called homogeneous linear PDE with constant coefficient

  47. Assume that then order linear homogeneous equation is given by or

  48. The complete solution of equation (1) consists of two parts ,the complementary function and particular integral. The complementary function is complete solution of equation of Rules to find complementary function Consider the equation or

  49. The auxiliary equation for (A.E) is given by And by giving The A.E becomes Case 1 If the equation(3) has two distinct roots The complete solution of (2) is given by

More Related