Difference between revisions of "Forest UCM Energy Line1D"
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:<math> \theta = \omega t + \theta_0 </math> | :<math> \theta = \omega t + \theta_0 </math> | ||
:<math> \sin \theta = \sin {\left (\omega t + \theta_0 \right )}</math> | :<math> \sin \theta = \sin {\left (\omega t + \theta_0 \right )}</math> | ||
− | :<math>\sqrt{\frac{2E}{m}} \sin \theta = \sqrt{\frac{2E}{m}} \sin {\omega t + \theta_0}</math> | + | :<math>\sqrt{\frac{2E}{m}} \sin \theta = \sqrt{\frac{2E}{m}} \sin {\left (\omega t + \theta_0 \right )}</math> |
− | :<math>x = \sqrt{\frac{2E}{m}} \sin {\omega t + \theta_0}</math> | + | :<math>x = \sqrt{\frac{2E}{m}} \sin {\left (\omega t + \theta_0 \right )}</math> |
− | |||
[[Forest_UCM_Energy#Energy_for_Linear_1-D_systems]] | [[Forest_UCM_Energy#Energy_for_Linear_1-D_systems]] |
Revision as of 12:43, 26 September 2014
The equation of motion for a system restricted to 1-D is readily solved from conservation of energy when the force is conservative.
- cosntant
The ambiguity in the sign of the above relation, due to the square root operation, is easily resolved in one dimension by inspection and more difficult to resolve in 3-D.
The velocity can change direction (signs) during the motion. In such cases it is best to separte the inegral into a part for one direction of the velocity and a second integral for the case of a negative velocity.
spring example
Consider the problem of a mass attached to a spring in 1-D.
The potential is given by
let
- and
then