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First_Order_Differential_Equations_PPT.ppt
- 1. First-Order Differential Equations By Dr. Summiya Parveen Department of Mathematics COLLOGE OF ENGINEERING ROORKE (COER) ROORKEE 247667, INDIA
- 2. Page 2 Outline Basic Concepts Separable Differential Equations substitution Methods Exact Differential Equations Integrating Factors Linear Differential Equations Bernoulli Equations
- 3. Page 3 Basic Concepts Differentiation x e x x x a a a e e nx x a a x x x x n n log ) (log 1 ) (ln ln ) ( ) ( ) ( 1 x x x x x x x x x x x x x x cot csc ) (csc tan sec ) (sec csc ) (cot sec ) (tan sin ) (cos cos ) (sin 2 2
- 4. Page 4 Basic Concepts Differentiation x x x x sinh ) (cosh cosh ) (sinh 2 1 2 1 2 1 2 1 1 1 ) (cot 1 1 ) (tan 1 1 ) (cos 1 1 ) (sin x x x x x x x x
- 5. Page 5 Basic Concepts Integration c a a dx a c e dx e c x dx x dx x c n x dx x x x x x n n ln ln 1 1 1 1 vdx u uv dx v u vdu uv udv udx c cudx vdx udx dx v u ) (
- 6. Page 6 Basic Concepts Integration c x x xdx c x x xdx c x xdx c x xdx c x xdx c x xdx cot csc ln csc tan sec ln sec sin ln cot cos ln tan sin cos cos sin
- 7. Page 7 Basic Concepts Integration c a x dx a x c a x dx a x c a x dx x a c a x a dx a x 1 2 2 1 2 2 1 2 2 1 2 2 cosh 1 sinh 1 sin 1 tan 1 1
- 8. Page 8 Basic Concepts ODE vs. PDE Dependent Variables vs. Independent Variables Order Linear vs. Nonlinear Solutions
- 9. Page 9 Basic Concepts Ordinary Differential Equations An unknown function (dependent variable) y of one independent variable x x dx dy y cos 0 4 y y 2 2 2 ) 2 ( 2 y x y e y y x x
- 10. Page 10 Basic Concepts Partial Differential Equations An unknown function (dependent variable) z of two or more independent variables (e.g. x and y) y x x z 4 6 y x y x z 2 2
- 11. Page 11 Basic Concepts The order of a differential equation is the order of the highest derivative that appears in the equation. 0 ) ( 2 2 3 y n x y x y x Order 2 2 2 1 y x dx dy Order 1 1 ) ( 4 3 2 2 y dx y d Order 2
- 12. Page 12 Basic Concept The first-order differential equation contain only y’ and may contain y and given function of x. A solution of a given first-order differential equation (*) on some open interval a<x<b is a function y=h(x) that has a derivative y’=h(x) and satisfies (*) for all x in that interval. ) , ( ' 0 ) ' , , ( y x F y y y x F or (*)
- 13. Page 13 Basic Concept Example : Verify the solution x 2 y 2y xy'
- 14. Page 14 Basic Concepts Explicit Solution Implicit Solution ) (x h y 0 ) , ( y x H
- 15. Page 15 Basic Concept General solution vs. Particular solution General solution arbitrary constant c Particular solution choose a specific c ,.... 2 , 3 ' c c sinx y cosx y
- 16. Page 16 Basic Concept Singular solutions Def : A differential equation may sometimes have an additional solution that cannot be obtained from the general solution and is then called a singular solution. Example The general solution : y=cx-c2 A singular solution : y=x2/4 0 ' y xy y' 2
- 17. Page 17 Basic Concepts General Solution Particular Solution for y(0)=2 (initial condition) kt ce t y ) ( kt e t y 2 ) ( ky y
- 18. Page 18 Basic Concept Def: A differential equation together with an initial condition is called an initial value problem 0 0) ( ), , ( ' y x y y x f y
- 19. Page 19 Separable Differential Equations Def: A first-order differential equation of the form is called a separable differential equation dx x f dy y g f(x) g(y)y ) ( ) ( '
- 20. Page 20 Separable Differential Equations Example : Sol: 0 4 9 x y y
- 21. Page 21 Separable Differential Equations Example : Sol: 2 1 y y
- 22. Page 22 Separable Differential Equations Example : Sol: ky y
- 23. Page 23 Separable Differential Equations Example : Sol: 1 ) 0 ( , 2 y xy y
- 24. Page 24 Separable Differential Equations Substitution Method: A differential equation of the form can be transformed into a separable differential equation ) ( x y g y
- 25. Page 25 Separable Differential Equations Substitution Method: ux y u x u y x dx u u g du u u g x u u g u x u ) ( ) ( ) (
- 26. Page 26 Separable Differential Equations Example : Sol: 2 2 2 x y y xy cx y x x c x y x c u c x c x u x dx u udu u u u x u y x x y xy x xy y y x y y xy 2 2 2 2 1 1 2 2 2 2 2 2 1 1 1 ln ln ) 1 ln( 1 2 ) 1 ( 2 1 ) ( 2 1 2 2 2
- 27. Page 27 Separable Differential Equations Exercise 1 2 01 . 0 1 y y 2 / xy y y y y x 2 2 ) 2 ( , 0 ' y y xy
- 28. Page 28 Exact Differential Equations Def: A first-order differential equation of the form is said to be exact if 0 ) , ( ) , ( dy y x N dx y x M x y x N y y x M ) , ( ) , (
- 29. Page 29 Exact Differential Equations Proof: 0 ) , ( ) , ( 0 ) , ( dy y x N dx y x M dy y u dx x u y x du x y x N y y x M y x y x u ) , ( ) , ( ) , (
- 30. Page 30 Exact Differential Equations Example : Sol: 0 ) 3 ( ) 3 ( 3 2 2 3 dy y y x dx xy x Exact xy x N y M xy x y y x xy y xy x , 6 6 3 6 3 3 2 2 3
- 31. Page 31 Exact Differential Equations Sol: ) ( 2 3 4 1 ) ( ) 3 ( ) ( 2 2 4 2 3 y k y x x y k dx xy x y k Mdx u 1 4 3 2 2 4 ) ( 3 ) ( 3 c y y k y y x N dy y dk y x y u
- 32. Page 32 Exact Differential Equations Sol: c y y x x y x u ) 6 ( 4 1 ) , ( 4 2 2 4
- 33. Page 33 Exact Differential Equations Example 3 ) 0 ( 0 ) sinh (cos ) cosh (sin y dy y x dx y x
- 34. Page 34 Non-Exactness Example : 0 xdy ydx
- 35. Page 35 Integrating Factor Def: A first-order differential equation of the form is not exact, but it will be exact if multiplied by F(x, y) then F(x,y) is called an integrating factor of this equation 0 ) , ( ) , ( dy y x Q dx y x P 0 ) , ( ) , ( ) , ( ) , ( dy y x Q y x F dx y x P y x F
- 36. Page 36 Exact Differential Equations How to find integrating factor Golden Rule x x y y FQ Q F FP P F Exact x FQ y FP FQdy FPdx , 0 ) ( 1 1 0 Let x y x y Q P Q dx dF F FQ Q dx dF FP P F(x) F
- 37. Page 37 Exact Differential Equations Example : Sol: 0 xdy ydx Exact x N x y M dy x dx x y x xdy ydx x F , 1 1 1 2 2 2 2
- 38. Page 38 Exact Differential Equations Sol: cx y c x y x y d dy x dx x y 0 ) ( 1 2
- 39. Page 39 Exact Differential Equations Example : 2 ) 2 ( 0 ) cos( ) sin( 2 2 2 y dy y xy dx y
- 40. Page 40 Exact Differential Equations Exercise 2 0 2 2 dy x xydx 0 ) ( 2 2 d r rdr e x e F ydy ydx , 0 cos sin b a y x F xdy b ydx a , 0 ) 1 ( ) 1 ( 0 ) 1 ( ) 1 ( dy x dx y
- 41. Page 41 Linear Differential Equations Def: A first-order differential equation is said to be linear if it can be written If r(x) = 0, this equation is said to be homogeneous ) ( ) ( x r y x p y
- 42. Page 42 Linear Differential Equations How to solve first-order linear homogeneous ODE ? Sol: 0 ) ( y x p y dx x p c dx x p c dx x p ce e e e y c dx x p y dx x p y dy y x p dx dy ) ( ) ( ) ( 1 1 1 ) ( ln ) ( 0 ) (
- 43. Page 43 Linear Differential Equations Example : Sol: 0 y y x c x c x dx dx x p e c e ce ce ce ce x y 2 ) 1 ( ) ( 1 1 ) (
- 44. Page 44 Linear Differential Equations How to solve first-order linear nonhomogeneous ODE ? Sol: ) ( ) ( x r y x p y ) ( )) ( ) ( ( ) ( 1 1 0 )) ( ) ( ( ) ( ) ( x p x r y x p y Q P Q dx dF F dy dx x r y x p x r y x p dx dy x y
- 45. Page 45 Linear Differential Equations Sol: dx x p e x F ) ( ) ( c dx r e e x y c dx r e y e r e y e py y e dx x p dx x p dx x p dx x p dx x p dx x p dx x p ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( ) (
- 46. Page 46 Linear Differential Equations Example : Sol: x e y y 2 x x x x x x x x dx dx dx x p dx x p e ce c e e c dx e e e c dx e e e c dx r e e x y 2 2 2 ) 1 ( ) 1 ( ) ( ) ( ) (
- 47. Page 47 Linear Differential Equations Example : ) 2 cos 2 2 sin 3 ( 2 x x e y y x '
- 48. Page 48 Linear Differential Equations Def: Bernoulli equations If a = 0, Bernoulli Eq. => First Order Linear Eq. If a <> 0, let u = y1-a a y x g y x p y ) ( ) ( g a pu a u ) 1 ( ) 1 (
- 49. Page 49 Linear Differential Equations Example : Sol: 2 By Ay y A B ce u y A B ce c dx e A B e c dx Be e u B Au u Ay B Ay By y y y u y y y u Ax Ax Ax Ax Ax Ax a 1 1 ) ( 1 2 2 2 1 2 1 1
- 50. Page 50 Linear Differential Equations Exercise 3 4 y y kx e ky y 2 2 y y y 1 xy xy y ) 2 ( , sin 3 y x y y
- 51. Page 51 Summary Separable Substitution Exact Integrating Factor Linear dx x f dy y g ) ( ) ( dx x f du u g ) ( ) ( 0 ) , ( ) , ( dy y x N dx y x M 0 FQdy FPdx ) ( ) ( x r y x p y
- 52. Page 52 Orthogonal Trajectories of Curves Angle of intersection of two curves is defined to be the angle between the tangents of the curves at the point of intersection How to use differential equations for finding curves that intersect given curves at right angles ?
- 53. Page 53 How to find Orthogonal Trajectories 1st Step: find a differential equation for a given cure 2nd Step: the differential equation of the orthogonal trajectories to be found 3rd step: solve the differential equation as above ( in 2nd step) ) , ( y x f y ) , ( y x f y' ) , ( 1 y x f y'
- 54. Page 54 Orthogonal Trajectories of Curves Example: given a curve y=cx2, where c is arbitrary. Find their orthogonal trajectories. Sol:
- 55. Page 55 Existance and Uniqueness of Solution An initial value problem may have no solutions, precisely one solution, or more than one solution. Example 1 ) 0 ( , 0 ' y y y 1 ) 0 ( , ' y x y 1 ) 0 ( , 1 ' y y xy No solutions Precisely one solutions More than one solutions
- 56. Page 56 Existence and uniqueness theorems Problem of existence Under what conditions does an initial value problem have at least one solution ? Existence theorem, see page 53 Problem of uniqueness Under what conditions does that the problem have at most one solution ? Uniqueness theorem, see page54