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Repeated Roots | Calculus - Mathematics PDF Download

In this section we will be looking at the last case for the constant coefficient, linear, homogeneous second order differential equations. In this case we want solutions to
ay′′+by′+cy=0
where solutions to the characteristic equation
ar2+br+c=0
are double roots r1=r2=r.
This leads to a problem however. Recall that the solutions are

Repeated Roots | Calculus - Mathematics

These are the same solution and will NOT be “nice enough” to form a general solution. We do promise that we’ll define “nice enough” eventually! So, we can use the first solution, but we’re going to need a second solution.
Before finding this second solution let’s take a little side trip. The reason for the side trip will be clear eventually. From the quadratic formula we know that the roots to the characteristic equation are,
Repeated Roots | Calculus - Mathematics
In this case, since we have double roots we must have
b2−4ac=0
This is the only way that we can get double roots and in this case the roots will be

Repeated Roots | Calculus - Mathematics

So, the one solution that we’ve got is 

Repeated Roots | Calculus - Mathematics

To find a second solution we will use the fact that a constant times a solution to a linear homogeneous differential equation is also a solution. If this is true then maybe we’ll get lucky and the following will also be a solution

Repeated Roots | Calculus - Mathematics (1)

with a proper choice of v(t).  To determine if this in fact can be done, let’s plug this back into the differential equation and see what we get.  We’ll first need a couple of derivatives.

Repeated Roots | Calculus - Mathematics

We dropped the (t) part on the v to simplify things a little for the writing out of the derivatives.  Now, plug these into the differential equation. 

Repeated Roots | Calculus - Mathematics

We can factor an exponential out of all the terms so let’s do that.  We’ll also collect all the coefficients of v and its derivatives. 

Repeated Roots | Calculus - Mathematics

Now, because we are working with a double root we know that that the second term will be zero. Also exponentials are never zero. Therefore, (1) will be a solution to the differential equation provided v(t) is a function that satisfies the following differential equation.
av′′=0 OR v′′=0
We can drop the a because we know that it can’t be zero. If it were we wouldn’t have a second order differential equation! So, we can now determine the most general possible form that is allowable for v(t).

Repeated Roots | Calculus - Mathematics

This is actually more complicated than we need and in fact we can drop both of the constants from this. To see why this is let’s go ahead and use this to get the second solution. The two solutions are then

Repeated Roots | Calculus - Mathematics

Eventually you will be able to show that these two solutions are “nice enough” to form a general solution. The general solution would then be the following.

Repeated Roots | Calculus - Mathematics

Notice that we rearranged things a little. Now, c, k, c1, and c2 are all unknown constants so any combination of them will also be unknown constants. In particular, c1+c2k and c2c are unknown constants so we’ll just rewrite them as follows.

Repeated Roots | Calculus - Mathematics

So, if we go back to the most general form for v(t) we can take c=1 and k=0 and we will arrive at the same general solution.
Let’s recap. If the roots of the characteristic equation are r1=r2=r, then the general solution is then

Repeated Roots | Calculus - Mathematics
Now, let’s work a couple of examples. 

Example 1 Solve the following IVP.

Repeated Roots | Calculus - Mathematics

Solution:
The characteristic equation and its roots are.
r2−4r+4=(r−2)2=0  r1,2=2
The general solution and its derivative are 

Repeated Roots | Calculus - Mathematics

Don’t forget to product rule the second term! Plugging in the initial conditions gives the following system.
12=y(0)=c1
−3=y′(0)=2c1+c2
This system is easily solved to get c1=12 and c2=−27. The actual solution to the IVP is then.

Repeated Roots | Calculus - Mathematics

Example 2 Solve the following IVP.

Repeated Roots | Calculus - Mathematics    

Solution:
The characteristic equation and its roots are.

Repeated Roots | Calculus - Mathematics    

The general solution and its derivative are 

Repeated Roots | Calculus - Mathematics

Don’t forget to product rule the second term!  Plugging in the initial conditions gives the following system. 

Repeated Roots | Calculus - Mathematics

This system is easily solve to get c1=3 and c2=−6. The actual solution to the IVP is then.

Repeated Roots | Calculus - Mathematics

Example 3 Solve the following IVP 

Repeated Roots | Calculus - Mathematics

Solution:
The characteristic equation and its roots are.

Repeated Roots | Calculus - Mathematics

The general solution and its derivative are 

Repeated Roots | Calculus - Mathematics

Plugging in the initial conditions gives the following system of equations. 

Repeated Roots | Calculus - Mathematics

Solving this system gives the following constants. 

Repeated Roots | Calculus - Mathematics

The actual solution to the IVP is then.

Repeated Roots | Calculus - Mathematics

The document Repeated Roots | Calculus - Mathematics is a part of the Mathematics Course Calculus.
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