Higher-Order Differential Equations - PowerPoint PPT Presentation

1 / 93
About This Presentation
Title:

Higher-Order Differential Equations

Description:

CHAPTER 3 Higher-Order Differential Equations Contents 3.1 Preliminary Theory: Linear Equations 3.3 Homogeneous Linear Equations with Constant Coefficients 3.4 ... – PowerPoint PPT presentation

Number of Views:4307
Avg rating:3.0/5.0
Slides: 94
Provided by: mm771
Category:

less

Transcript and Presenter's Notes

Title: Higher-Order Differential Equations


1
Higher-Order Differential Equations
  • CHAPTER 3

2
Contents
  • 3.1 Preliminary Theory Linear Equations
  • 3.3 Homogeneous Linear Equations with Constant
    Coefficients
  • 3.4 Undetermined Coefficients
  • 3.5 Variation of Parameters
  • 3.8 Linear Models Initial-Value Problems

3
3.1 Preliminary Theory Linear Equ.
  • Initial-value Problem An initial value problem
    for nth-order linear DE is with
    (1)as n initial conditions.

4
(No Transcript)
5
Example 1
  • The problem possesses the trivial solution y
    0. Since this DE with constant coefficients,
    from Theorem 3.1, hence y 0 is the only one
    solution on any interval containing x 1.

6
  • The following DE (6)is
    homogeneous (7)with g(x) 0, is
    nonhomogeneous.

7
Differential Operators
  • Let dy/dx Dy. This symbol D is called a
    differential operator. We define an nth-order
    differential operator as (8)In
    addition, we have (9)so the
    differential operator L is a linear operator.
  • Differential Equations We can simply write the
    n-th order linear DEs as L(y) 0 and L(y)
    g(x)

8
(No Transcript)
9
(No Transcript)
10
Linear Dependence and Independence

11
  • In other words, if the set is linearly
    independent, then c1f1(x) c2f2(x) cn
    fn(x) 0implies c1 c2 cn 0
  • Referring to Fig 3.3, neither function is a
    constant multiple of the other, then these two
    functions are linearly independent.

12
Fig 3.3
13
Example 5
  • The functions f1 cos2 x, f2 sin2 x, f3
    sec2 x, f4 tan2 x are linearly dependent on
    the interval (-?/2, ?/2) since c1 cos2 x c2
    sin2 x c3 sec2 x c4 tan2 x 0when c1 c2
    1, c3 -1, c4 1.

14
Example 6
  • The functions f1 x½ 5, f2 x½ 5x, f3
    x 1,f4 x2 are linearly dependent on the
    interval (0, ?), since f2 1? f1 5? f3 0?
    f4

15
(No Transcript)
16
(No Transcript)
17
(No Transcript)
18
(No Transcript)
19
Example 7
  • The functions y1 e3x, y2 e-3x are solutions
    of y 9y 0 on (-?, ?)Now for every x.
    So y c1y1 c2y2 is the general solution.

20
Example 8
  • The functions y 4 sinh 3x - 5e3x is a solution
    of example 7 (Verify it). Observe 4
    sinh 3x 5e-3x

21
Example 9
  • The functions y1 ex, y2 e2x , y3 e3x are
    solutions of y 6y 11y 6y 0 on (-?,
    ?). Since for every real value of x. So y
    c1ex c2 e2x c3e3x is the general solution
    on (-?, ?).

22
  • Complementary Function y y c1y1 c2y2
    cnyn yp yc yp complementary
    particular

23
Example 10
  • The function yp -(11/12) ½ x is a particular
    solution of (11)From previous
    discussions, the general solution of (11) is

24
(No Transcript)
25
Example 11
  • We find yp1 -4x2 is a particular solution
    of yp2 e2x is a particular solution of
    yp3 xex is a particular solution of
  • From Theorem 3.7, is a solution of

26
Note
  • If ypi is a particular solution of (12), then
    is also a particular solution of (12) when
    the right-hand member is

27
3.3 Homogeneous Linear Equation with Constant
Coefficients
  • Introduction (1)where ai are
    constants, an ? 0.
  • Auxiliary Equation (Characteristic Equation)For
    n 2, (2)Try y emx, then
    (3)is called an auxiliary equation
    or characteristic equation.

28
  • From (3) the two roots are(1) b2 4ac gt 0
    two distinct real numbers.(2) b2 4ac 0 two
    equal real numbers.(3) b2 4ac lt 0 two
    conjugate complex numbers.

29
  • Case 1 Distinct real rootsThe general solution
    is (why?) (4)
  • Case 2 Repeated real roots ,
    (why?) (5)The general solution is
    (why?) (6)

30
  • Case 3 Conjugate complex rootsWe write
    , a general solution is From Eulers
    formula and
    (7)
    and

31
  • Since is a solution then setC1
    C1 1 and C1 1, C2 -1 , we have two
    solutions So, e?x cos ?x and e?x sin ?x
    are a fundamental set of solutions, that is, the
    general solution is (8)

32
Example 1
  • Solve the following DEs
  • (a)
  • (b)
  • (c)

33
Example 2
  • Solve
  • Solution See Fig 3.4.

34
Fig 3.4
35
Higher-Order Equations
  • Given (12)we have (13)as
    an auxiliary equation (or characteristic
    equation).

36
Example 3
  • Solve
  • Solution

37
Example 4
  • Solve
  • Solution

38
Repeated complex roots
  • If m1 ? i? is a complex root of multiplicity
    k, then m2 ? - i? is also a complex root of
    multiplicity k. The 2k linearly independent
    solutions

39
3.4 Undetermined Coefficients
  • IntroductionIf we want to solve the
    nonhomogeneous linear DE (1)we have to
    find y yc yp. Thus we introduce the method of
    undetermined coefficients to solve for yp.

40
Example 1
  • Solve
  • Solution We can get yc as described in Sec 3.3.
    Now, we want to find yp.
  • Since the right side of the DE is a polynomial,
    we set After substitution, 2A 8Ax 4B
    2Ax2 2Bx 2C 2x2 3x 6

41
Example 1 (2)
  • Then

42
Example 2
  • Find a particular solution of
  • Solution Let yp A cos 3x B sin 3xAfter
    substitution,
  • Then

43
Example 3
  • Solve (3)
  • Solution We can find Let After
    substitution,
  • Then

44
Example 4
  • Find yp of
  • Solution First let yp AexAfter substitution,
    0 8ex, (wrong guess)
  • Let yp AxexAfter substitution, -3Aex 8ex
    Then A -8/3, yp (-8/3)xex

45
Rule of Case 1
  • No function in the assumed yp is part of ycTable
    3.1 shows the trial particular solutions.

46
Example 5
  • Find the form of yp of (a)
  • Solution We have and try There is
    no duplication between yp and yc .
  • (b) y 4y x cos x
  • Solution We try There is also no duplication
    between yp and yc .

47
Example 6
  • Find the form of yp of
  • Solution For 3x2 For -5 sin 2x For
    7xe6x
  • No term in duplicates a term in yc

48
Rule of Case 2
  • If any term in yp duplicates a term in yc, it
    should be multiplied by xn, where n is the
    smallest positive integer that eliminates that
    duplication.

49
Example 8
  • Solve
  • Solution First trial yp Ax B C cos x
    E sin x (5)However, duplication occurs. Then
    we try yp Ax B Cx cos x Ex sin x After
    substitution and simplification, A 4, B 0, C
    -5, E 0Then y c1 cos x c2 sin x 4x
    5x cos xUsing y(?) 0, y(?) 2, we have y
    9? cos x 7 sin x 4x 5x cos x

50
Example 9
  • Solve
  • Solution yc c1e3x c2xe3x After
    substitution and simplification, A 2/3, B
    8/9, C 2/3, E -6
  • Then

51
Example 10
  • Solve
  • Solution m3 m2 0, m 0, 0, -1 yc c1
    c2x c3e-x yp Aex cos x Bex sin xAfter
    substitution and simplification, A -1/10, B
    1/5
  • Then

52
Example 11
  • Find the form of yp of
  • Solution yc c1 c2x c3x2 c4e-x Normal
    trial Multiply A by x3 and (Bx2e-x Cxe-x
    Ee-x) by xThen yp Ax3 Bx3e-x Cx2e-x
    Exe-x

53
3.5 Variation of Parameters
  • Some Assumptions For the DE (1)we put
    (1) in the form (2)where P, Q, f are
    continuous on I. Let and be
    two linearly independent solutions of the
    associated homogeneous equation of (2).

54
Method of Variation of Parameters
  • We try (3) After we obtain yp,
    yp, we put them into (2), then
    (4)

55
  • Making further assumptions y1u1 y2u2 0,
    then from (4), y1u1 y2u2 f(x)Express
    the above in terms of determinants
  • and (5)where (6)

56
Example 1
  • Solve
  • Solution m2 4m 4 0, m 2, 2 y1 e2x,
    y2 xe2x,
  • Since f(x) (x 1)e2x, then

57
Example 1 (2)
  • From (5), Then u1 (-1/3)x3 ½ x2, u2
    ½ x2 xAnd

58
Example 2
  • Solve
  • Solution y 9y (1/4) csc 3x m2 9 0, m
    3i, -3i y1 cos 3x, y2 sin 3x, f (1/4)
    csc 3x
  • Since

59
Example 2 (2)
  • Then And

60
Example 3
  • Solve
  • Solution m2 1 0, m 1, -1 y1 ex, y2
    e-x, f 1/x, and W(ex, e-x) -2 ThenThe
    low and up bounds of the integral are x0 and x,
    respectively.

61
Example 3 (2)
62
Higher-Order Equations
  • For the DEs of the form (8)then yp
    u1y1 u2y2 unyn, where yi , i 1, 2, ,
    n, are the elements of yc. Thus we
    have (9)and uk Wk/W, k 1,
    2, , n.

63
  • For the case n 3, (10)

64
3.8 Linear Models IVP
  • Newtons LawSee Fig 3.18, we have (1)

65
Fig 3.18
66
Fig3.19
67
Free Undamped Motion
  • From (1), if and f(t)0, we
    have (2)where ? k/m. (2) is called a
    simple harmonic motion, or free undamped motion.

68
Solution and Equation of Motion
  • From (2), the general solution is
    (3)Period T 2?/?, frequency f 1/T ?/2?.

69
Example 1
  • A mass weighing 2 pounds stretches a spring 6
    inches. At t 0, the mass is released from a 8
    inches below the equilibrium position with an
    upward velocity 4/3 ft/s. Determine the equation
    of motion.
  • SolutionUnit convert 6 in 1/2 ft 8 in
    2/3 ft, m W/g 1/16 slugFrom Hookes Law,
    2 k(1/2), k 4 lb/ft Hence (1) gives

70
Example 1 (2)
  • together with x(0) 2/3, x(0) -4/3.Since ?2
    64, ? 8, the solution is x(t) c1 cos 8t
    c2 sin 8t (4)Applying the initial condition,
    we have (5)

71
Alternate form of x(t)
  • (4) can be written as x(t) A sin(?t ?)
    (6)where and ? is a phase angle,
    (7) (8)
    (9)

72
Fig 3.20
73
Example 2
  • Solution (5) is x(t) (2/3) cos 8t - (1/6) sin
    8t A sin(?t ?)Then However it is not
    the solution, since we know tan-1 (/-) will
    locate in the second quadrantThen
    so (9)The period is T 2?/8 ?/4.

74
Fig 3.21
  • Fig 3.21 shows the motion.

75
Free Damped Motion
  • If and f(t)0, the DE is as
    (10)where ? is a positive damping
    constant. Then x(t) (?/m)x (k/m)x 0 can
    be written as (11)where 2? ?/m, ?2
    k/m (12)The auxiliary equation is m2 2?m
    ?2 0, and the roots are

76
Case 1
  • ?2 ?2 gt 0. Let then (13)It
    is said to be overdamped. See Fig 3.23.

77
Fig3.23
78
Case 2
  • ?2 ?2 0. then (14)It is said to
    be critically damped. See Fig 3.24.

79
Fig3.24
80
Case 3
  • ?2 ?2 lt 0. Let then (15)It
    is said to be underdamped. See Fig 3.25.

81
Fig 3.25
82
Example 3
  • The solution of is (16)See Fig
    3.26.

83
Fig 3.26
84
Example 4
  • A mass weighing 8 pounds stretches a spring 2
    feet. Assuming a damping force equal to 2 times
    the instantaneous velocity exists. At t 0, the
    mass is released from the equilibrium position
    with an upward velocity 3 ft/s. Determine the
    equation of motion.
  • SolutionFrom Hookes Law, 8 k (2), k 4
    lb/ft, and m W/g 8/32 ¼ slug, hence
    (17)

85
Example 4 (2)
  • m2 8m 16 0, m -4, -4 x(t) c1 e-4t
    c2t e-4t (18)Initial conditions x(0) 0,
    x(0) -3, then x(t) -3t e-4t (19)See
    Fig 3.27.

86
Fig 3.27
87
Example 5
  • A mass weighing 16 pounds stretches a spring from
    5 feet to 8.2 feet. t. Assuming a damping force
    is equal to the instantaneous velocity exists. At
    t 0, the mass is released from rest at a point
    2 feet above the equilibrium position. Determine
    the equation of motion.
  • SolutionFrom Hookes Law, 16 k (3.2), k 5
    lb/ft, and m W/g 16/32 ½ slug, hence
    (20) m2 2m 10 0, m -3 3i,
    -3 - 3i

88
Example 5 (2)
  • (21)Initial conditions x(0) -2,
    x(0) 0, then (22)

89
Alternate form of x(t)
  • (22) can be written as (23)where
    and

90
LRC-Series Circuits
  • The following equation is the DE of forced motion
    with damping (32)If i(t) denotes the
    current shown in Fig 3.32, then
    (33)Since i , we
    have (34)

91
Fig 3.32
92
Forced Undamped and Damped
  • If R0, (34) is forced undamped.
  • If R 0, (34) is forced damped.
  • Q Can you find the relationship between R, L, C
    to
  • distinguish the cases of forced overdamped,
    forced
  • critically damped and forced underdamped?

93

Thank You !
Write a Comment
User Comments (0)
About PowerShow.com