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Lecture Notes for Exam 3 Lecture Notes on Material for Exam III--Not all the theory is here but it will give you an idea of what was covered in class. Variation of Parameters Given that we are somehow able to find the complimentary solution (solution to the corresponding homogeneous equation) to an equation of the form given below, we want to find a particular solution in cases where our previous annihilator method using undetermined coefficients cannot be applied to produce a form for yp. (1) Divide each side of (1) by (2) Rewrite this as (3) Suppose we somehow find that (4) It turns out to be possible (subject to being able to do the required
integration) to find a
We need to substitute this form for
To avoid dealing with the second derivatives of A(x) and B(x) we will look for A and B satisfying the following condition:
Thus
Substituting (5) Since
To find A and B we need to solve the system
Cramer’s Rule produces
As an alternative you could use the reduction in order option for finding yp. This formula often (but not always) leads to more complex integration. The variation of parameters formula can be extended to find particular solutions to linear differential equations of order higher than two but you will not be expected to do so in this class. It is possible to find yp through an integration formula for a first order linear differential equation in a manner similar to what you see demonstrated above as follows:
Laplace Transform The Laplace Transform is an integral transform that transforms a function of some independent variable, say t, into a function of s. The function g(s,t) is called the kernel function for the Laplace Transform.
The Laplace Transform of some additional functions can be found without the need to evaluate improper integrals by differentiating transforms that have already been established.
We can also pretty quickly find the Laplace Transform of functions of the form eatf(t) if we already know the Laplace Transform of f(t).
To use the Laplace Transform to solve a differential equation we are going to need to be able to represent the Laplace Transform of the derivative of a function in terms of the Laplace Transform of the original function under the assumption that the Laplace Transform of the original function exists (i.e., the limit that defines the improper integral that defines the Laplace Transform exists).
To use the Laplace Transform to solve an initial value problem, we need to take the Laplace Transform of each side of the equation, implement the initial conditions, algebraically solve for the Laplace Transform of the solution function we are looking for, L{y}, and then use the Inverse Laplace Transform, L-1, to find y.
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This site contains links to other Internet sites. These links are not endorsements of any products or services in such sites, and no information in such site has been endorsed or approved by this site. Lane Vosbury, Mathematics, Seminole State College email: vosburyl@seminolestate.edu This page was last updated on 08/21/14 Copyright 2002 webstats |
to get
.
.
where 
is the general solution to
.
of the form
.
and 
.
into (3) yields
is a solution to (4) the terms in red
above must add up to 0. Similarly, since 
is a
solution to (4) the terms in blue must add up to 0.
Thus (5) becomes
.
