Difference between revisions of "Matlab Primer"
(→Step 1: Make the model first order) |
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Now we have two equations: | Now we have two equations: | ||
− | <math> \begin{align} \dot\theta_0 & = \theta_1, | + | <math> \begin{align} \dot\theta_0 & = \theta_1, \\ |
\dot\theta_1 & = - \frac{g}{\ell} \sin\theta_0 \end{align} </math> | \dot\theta_1 & = - \frac{g}{\ell} \sin\theta_0 \end{align} </math> |
Revision as of 18:30, 3 November 2012
Today's lecture will be on MATLAB and PENDULA (plural of PENDULUM). Your next lab assignment motivated the topic.
My name is Sean Carver; I am a research scientist in Mechanical Engineering. I have been programming in MATLAB for almost 20 years and programming computers for almost 30 years.
This class is about MATLAB, not about deriving equations. So I am just going to give you the equations for the PENDULUM. There is still a lot to do to get it into MATLAB.
Pendulum on a movable support
This example comes from Wikipedia (copied legally). Consider a pendulum of mass m and length ℓ, which is attached to a support with mass M which can move along a line in the x-direction. Let x be the coordinate along the line of the support, and let us denote the position of the pendulum by the angle θ from the vertical.
See http://en.wikipedia.org/w/index.php?title=Lagrangian_mechanics&oldid=516894618 for a full derivation.
Your homework and class exercise for today is to implement this model.
Pendulum on a fixed support
Together we are going to implement a simpler model with support fixed and unmovable. You can see what the equations for this are easily. Just plug in
The second term drops out:
Step 1: Make the model first order
Define new variables
Now we have two equations: