Matched asymptotic expansion
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IPSA Institut Polytechnique des Sciences Avancées |
PIRI |
Matching of Asymptotic expansions |
Senthan Thayaparan 07/06/2017 |
Resume
Remerciement
Introduction
Exercise 1 :
We consider the following Cauchy problem for nonlinear ordinary differential equation :
[pic 1]
With is a non-negative small parameter.[pic 2]
- We want to find such as is a solution of (1).[pic 3][pic 4]
is solution of [pic 5][pic 6]
[pic 7]
Finally, we find the following result:
[pic 8]
- We want to find the exact solution of the equation (1) :
If we use the characteristic equation, we can say that the exact solution would be of the following form :
[pic 9]
With C1 and C2 which are representing real constants.
After that, we are using the initial conditions, and we can obtain the exact solution :
[pic 10]
[pic 11]
- We are looking for a second order asymptotic expansion of in the form :[pic 12]
[pic 13]
We want to show that :
[pic 14]
We first obtain the following equations :
[pic 15]
We can identify the following problems:
[pic 16]
[pic 17]
[pic 18]
We have these systems :
[pic 19]
[pic 20]
Now we use the initial conditions to obtain:
[pic 21]
[pic 22]
Using the initial conditions, we have:
[pic 23]
[pic 24]
Then:
[pic 25]
Finally, we have:
[pic 26]
We have the following initial conditions :
[pic 27]
So finally, we obtain :
[pic 28]
We can write the following equation to find the solution using Matlab :
[pic 29]
Chapter 1: Regulier
[pic 30]
We start by taking in account the equation (1):
[pic 31]
We write all the equation in function of :[pic 32]
[pic 33]
By rewriting we get:
[pic 34]
Then we integer this equation
[pic 35]
An other time:
[pic 36]
We assume the characteristic equation:
[pic 37]
So:
[pic 38]
Now we are going to determine a particular solution of (1) on the form:
[pic 39]
[pic 40]
[pic 41]
Then we introduce this new equations (3) and (4) on the first one, and we get:
[pic 42]
so
[pic 43]
And finnaly we obtain:
[pic 44]
By identification:
[pic 45]
So we have:
[pic 46]
Then we obtain the exact solution using the general solution (2) and the particular one (5) :
[pic 47]
Then by using the boundary conditions we have:
[pic 48]
[pic 49]
[pic 50]
Then we do (7)-(6):
[pic 51]
and:
[pic 52]
Finally
[pic 53]
Outer-limit
[pic 54]
So:
[pic 55]
And
[pic 56]
We put into the equation (1), the equations (8) and (9):
[pic 57]
And we rearrange:
[pic 58]
Then we can easily identify:
[pic 59]
And by using the boundary conditions[pic 60]
...