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Math 260

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Math 3120 Differential Equations with Boundary Value Problems Chapter 4: Higher-Order Differential Equations Section 4-1: Preliminary Theory-Linear Equations – PowerPoint PPT presentation

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Title: Math 260


1
Math 3120 Differential Equations withBoundary
Value Problems
Chapter 4 Higher-Order Differential
Equations Section 4-1 Preliminary Theory-Linear
Equations
2
Initial-Value and Boundary-Value Problems
  • Theorem 4.1.1 An initial value problem for a
    nth order Linear DE has the general form
  • subject to the initial conditions
  • If the functions P0,, Pn, and G are continuous
    on an open interval I (?, ? ), and that P0 is
    nowhere zero on I. If t t0 is any point in I,
    then there exists exactly one solution y ?(t)
    that satisfies the initial value problem. This
    solution exists throughout the interval I .

3
Example 1
  • Verify that is a
    unique solution to the IVP

4
Boundary-Value Problems
  • Is a linear DE of order two or greater in which
    the dependent variable y or its derivative is
    specified at different points. For example,
  • The values are
    called boundary conditions.
  • A solution to Eq. (1) is a function y ?(x) that
    satisfies the differential equation on the
    interval ? lt x lt ? and that takes on the
    specified values y0 and y1 at the endpoints.

5
Example 2 BVP has a unique solution
  • Consider the boundary value problem
  • The general solution of the differential equation
    is
  • The first boundary condition requires that c1
    1.
  • From the second boundary condition, we have
  • Thus the solution to the boundary value problem
    is
  • This is an example of a nonhomogeneous boundary
    value problem with a unique solution.

6
Example 3 BVP has No solution
  • Consider the boundary value problem
  • The general solution of the differential equation
    is
  • The first boundary condition requires that c1
    1, while the second requires c1 - a. Thus
    there is no solution.

7
Example 4 BVP has Infinite solution
  • Consider the boundary value problem
  • The general solution of the differential equation
    is
  • However, if a -1, then there are infinitely
    many solutions
  • This example illustrates that a non homogeneous
    boundary value problem may have no solution, and
    also that under special circumstances it may have
    infinitely many solutions.

8
Homogeneous Equations
  • An nth order homogenous Linear DE is of the form
  • An nth order nonhomogenous Linear DE is of the
    form
  • When we talk about Linear equations of form (1),
    we will assume that the coefficient functions
    Pi(t), i 0,1,n and G(t) are continuous and
    P0(t) ? 0 for every t in the interval.

9
Differential Operator
  • We can denote differentiation by the Capital
    letter D, i.e.,
  • This symbol D is called the Differential
    operator. Higher-Order derivatives can also be
    expressed in terms of D. For example,
  • An nth order differential operator or polynomial
    operator is defined as
  • L is a linear operator, i.e., Laf(x)ßg(x)
    aL(f(x))ßL(g(x))

10
Theorem 4.1.2 Superposition Principle
  • If y1,, yn are solutions of the homogeneous nth
    order linear differential equation on an interval
    I
  • Then the linear combination
  • where the ci , i 0,1,,n are arbitrary
    constants is also a solution on the interval I.

11
Linear Independence and Linear Dependence
  • A set of functions f1(x), f2(x),., fn(x) is said
    to be linearly dependent on an interval I if
    there exist constants c1, c2,,cn, not all zero,
    such that
  • for every x in the interval.
  • If the set of functions is not linearly dependent
    on the interval I, then it is said to be linearly
    independent.

12
Wronskian
  • Suppose each of the functions f1(x), f2(x),.,
    fn(x) possesses at least n-1 derivatives. The
    determinant
  • where the primes denote derivatives, is called
    the Wronskian of the functions.

13
Homogeneous Equations Wronskian
  • If y1,, yn are solutions of the homogeneous nth
    order linear differential equation on an interval
    I , then the set of solutions is Linearly
    independent iff Wronskian, is nonzero at t0 in
    the interval I.
  • Since t0 can be any point in the interval I, the
    Wronskian determinant needs to be nonzero at
    every point in I.
  • As before, it turns out that the Wronskian is
    either zero for every point in I, or it is never
    zero on I.

14
Fundamental Solutions Linear Independence
  • Consider the nth order homogenous LDE
  • A set y1,, yn of solutions of Eq. (3) with
    W(y1,, yn) ? 0 on I is called a fundamental set
    of solutions.
  • If y1,, yn are fundamental solutions, then
    W(y1,, yn) ? 0 on I. It can be shown that this
    is equivalent to saying that y1,, yn are
    linearly independent

15
General Solution of Homogenous Equations
  • Since all solutions can be expressed as a linear
    combination of the fundamental set of solutions,
    the general solution of the equation on the
    interval is
  • where cis are arbitrary constants

16
Example 5
  • Verify that the given functions are solutions of
    the differential equation, and determine their
    Wronskian.

17
Nonhomogeneous Equations
  • Consider the non homogeneous equation
  • Any function yp that has no arbitrary parameters
    and satisfies the Eq. (4) is said to be a
    particular solution of the non homogeneous
    equation.
  • The general solution to the non homogeneous
    equation (4) is
  • where yp is any particular solution and y1,, yn
    are the fundamental solutions of the associated
    homogeneous differential equation (3) on the
    interval I and where cis are arbitrary constants.

18
Theorem 4.1.7 Superposition Principle Non
Homogenous Equations
  • If yp1,, ypk be k particular solutions of the
    non homogeneous nth order linear differential
    equation (4) on an interval I corresponding, in
    turn, to k distinct functions g1,, gk, i.e.,
  • where i1,.,k. Then
  • is a particular solution of (5).
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