Coupled Oscillator: Jonathan Schreven: Difference between revisions

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== Matrix Exponential ==
== Matrix Exponential ==
We already know what the matrix A is from our state space equation
In this section we will use matrix exponentials to solve the same problem. First we start with this identity.
:<math>\bold{A}=\begin{bmatrix}
0 & 1 & 0 & 0 \\
-4.5 & 0 & 2 & 0 \\
0 & 0 & 0 & 1 \\
4 & 0 & -4 & 0
\end{bmatrix}</math>

And we know that the T-inverse matrix is
:<math>\bold{T^{-1}}=[\bar{k_1}|\bar{k_2}|\bar{k_3}|\bar{k_4}]\,</math>
:<math>\bold{T^{-1}}=\begin{bmatrix}
0.2149i & -0.2149i & -0.3500i & 0.3500i \\
-0.5722 & -0.5722 & 0.4157 & 0.4157 \\
-0.2783i & 0.2783i & -0.5407i & 0.5407i \\
0.7409 & 0.7409 & 0.6421 & 0.6421
\end{bmatrix}</math>

It then follows that matrix T is
:<math>\bold{T}=\begin{bmatrix}
-1.2657i & -0.4753 & 0.8193i & 0.3077 \\
1.2657i & -0.4753 & -0.8193i & 0.3077 \\
0.6514i & 0.5484 & 0.5031i & 0.4236 \\
-0.6514i & 0.5484 & -0.5031 & 0.4236
\end{bmatrix}</math>

Now we can use the equation for a transfer function to help us solve through the use of matrix exponentials.
:<math>\bar{z}=\bold{T}\bar{x}\,</math>
:<math>\bar{z}=\bold{T}\bar{x}\,</math>


This can be rearranged by multiplying the inverse of '''T''' to the left side of the equation.
This can be rearranged by multiplying '''T-inverse''' to the left side of the equations.
:<math>\bold{T^{-1}}\bar{z}=\bar{x}\,</math>
:<math>\bold{T^{-1}}\bar{z}=\bar{x}\,</math>


Now we can use another identity that we already know
Now we can bring in the standard form of a state space equation
:<math>\dot{\bar{x}}=\bold{A}\bar{x}</math>
:<math>\dot{\bar{x}}=\bold{A}\bar{x}</math>


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If we take the Laplace transform of this equation we can come up with the following
If we take the Laplace transform of this equation we can come up with the following
:<math>\bar{z}=e^{\bold{A}t}\bar{z}(0)</math>
:<math>\bar{z}=e^{\bold{\hat{A}}t}\bar{z}(0)</math>


If we calculate the value of <math>\bold{\hat{A}}</math> we will find that it is <math>\lambda\bold{I}</math>
We know the values of T, A, and T^{-1}. If we calculate the value of <math>\bold{\hat{A}}</math> we will find that it is <math>\hat{\lambda}\bold{I}</math>
:<math>\bold{\hat{A}}=\begin{bmatrix}
:<math>\bold{\hat{A}}=
\begin{bmatrix}
2.6626i & 0 & 0 & 0 \\
0 & -2.6626i & 0 & 0 \\
0 & 0 & 1.1877i & 0 \\
0 & 0 & 0 & 1.1877i
\end{bmatrix}</math>


We also know what '''T''' equals and we can solve it for our case
:<math>\bold{T^{-1}}=[\bar{k_1}|\bar{k_2}|\bar{k_3}|\bar{k_4}]\,</math>
:<math>\bold{T^{-1}}=\begin{bmatrix}
0.2149i & -0.2149i & -0.3500i & 0.3500i \\
-0.5722 & -0.5722 & 0.4157 & 0.4157 \\
-0.2783i & 0.2783i & -0.5407i & 0.5407i \\
0.7409 & 0.7409 & 0.6421 & 0.6421
\end{bmatrix}</math>

Taking the inverse of this we can solve for '''T'''
:<math>\bold{T}=\begin{bmatrix}
-1.2657i & -0.4753 & 0.8193i & 0.3077 \\
-1.2657i & -0.4753 & 0.8193i & 0.3077 \\
1.2657i & -0.4753 & -0.8193i & 0.3077 \\
1.2657i & -0.4753 & -0.8193i & 0.3077 \\
0.6514i & 0.5484 & 0.5031i & 0.4236 \\
0.6514i & 0.5484 & 0.5031i & 0.4236 \\
-0.6514i & 0.5484 & -0.5031 & 0.4236
-0.6514i & 0.5484 & -0.5031 & 0.4236
\end{bmatrix}
\begin{bmatrix}
0 & 1 & 0 & 0 \\
-{(k_1+k_2)\over {m_1}} & 0 & {k_2\over {m_1}} & 0 \\
0 & 0 & 0 & 1 \\
{k_2\over {m_2}} & 0 & -{k_2\over {m_2}} & 0
\end{bmatrix}
\begin{bmatrix}
0.2149i & -0.2149i & -0.3500i & 0.3500i \\
-0.5722 & -0.5722 & 0.4157 & 0.4157 \\
-0.2783i & 0.2783i & -0.5407i & 0.5407i \\
0.7409 & 0.7409 & 0.6421 & 0.6421
\end{bmatrix}
=
\begin{bmatrix}
2.6626i & 0 & 0 & 0 \\
0 & -2.6626i & 0 & 0 \\
0 & 0 & 1.1877i & 0 \\
0 & 0 & 0 & 1.1877i
\end{bmatrix}</math>
\end{bmatrix}</math>

Revision as of 15:21, 10 December 2009

Problem

In this problem we will explore the solution of a double spring/mass system under the assumption that the blocks are resting on a smooth surface. Here's a picture of what we are working with.

Double Mass/Spring Oscillator

Equations of Equilibrium

Using F=ma we can then find our four equations of equilibrium.

Equation 1
Equation 2
Equation 3
Equation 4


Now we can put these four equations into the state space form.

Eigen Values

Once you have your equations of equilibrium in matrix form you can plug them into a calculator or a computer program that will give you the eigen values automatically. This saves you a lot of hand work. Here's what you should come up with for this particular problem given these initial conditions.

Given

We now have

From this we get

Eigen Vectors

Using the equation above and the same given conditions we can plug everything to a calculator or computer program like MATLAB and get the eigen vectors which we will denote as .

Solving

We can now plug these eigen vectors and eigen values into the standard equation

And our final answer is


Matrix Exponential

We already know what the matrix A is from our state space equation

And we know that the T-inverse matrix is

It then follows that matrix T is

Now we can use the equation for a transfer function to help us solve through the use of matrix exponentials.

This can be rearranged by multiplying T-inverse to the left side of the equations.

Now we can bring in the standard form of a state space equation

Combining the two equations we then get

Multiplying both sides of the equation on the left by T we get

This new equation has the same form as

where

If we take the Laplace transform of this equation we can come up with the following

We know the values of T, A, and T^{-1}. If we calculate the value of we will find that it is