Aaron Boyd's Assignment 8
I decided to use laplace transforms to solve a pendulum equation. A pendulum with a weight of mass m and a massless rod length L is released from an initial angle A0. Find a function to determine the angle at any time t. The summation of forces yields
Fx = T*sin(A)
Fy = T*cos(A) - mg = 0
Polar coordinates may be easier to use, lets try that.
now:
Fr = T- cos(A)*mg = 0
FA = sin(A)*mg = maL
now since Fr = 0 we can ignore it and look only at FA.
Since we know FA = maL and ma = mLa". We can conclude
sin(A)*mg = mLA"
canceling the common mass term and rearranging a bit we get.
A" - sin(A)(g/L) = 0
now we take the laplace transform of this. Unfortunately the laplace transform of that is horrible. Long, complicated, and nearly impossible to solve. So we use the approximation sin(A) = A where A is small.
(I tried to leave sin(A) in the equation. After 4 hours and many wolframalpha.com timeouts I gave up)
with this new equation we get:
g*A(t)/L +s^2*A(t) - s*A(0) - A'(0) = 0
we know that A(0) = A0 and A'(0) = 0
solving for A(t) we get
A(t) = s*A0/((-g/L)+S^2)
now we take the inverse laplace transform of that which yields
A(t) = cosh(t*(g/L)^(1/2))