Difference between revisions of "Forest UCM PnCP QuadAirRes"
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then <math>du = -2\frac{b}{m}v dv</math> | then <math>du = -2\frac{b}{m}v dv</math> | ||
− | :<math>y =\int_{v_i}^{v_f} \frac{-m}{2b} \frac{du}{u } = \frac{b}{m} \int_{v_f}^{v_i} \ln | + | :<math>y =\int_{v_i}^{v_f} \frac{-m}{2b} \frac{du}{u } = \frac{b}{m} \int_{v_f}^{v_i} \ln \left ( g -\frac{b}{m}v^2 \right ) =</math> |
:<math>y =\frac{m}{2b} \ln \left ( \frac {g -\frac{b}{m}v_i^2}{g -\frac{b}{m}v_f^2} \right ) </math> | :<math>y =\frac{m}{2b} \ln \left ( \frac {g -\frac{b}{m}v_i^2}{g -\frac{b}{m}v_f^2} \right ) </math> | ||
[[Forest_UCM_PnCP#quadratic_friction]] | [[Forest_UCM_PnCP#quadratic_friction]] |
Latest revision as of 11:54, 10 September 2014
Consider a ball falling under the influence of gravity and a frictional force that is proportion to its velocity squared
Find the fall distance
Here is a trick to convert the integral over time to one over distance so you don't need to integrate twice as inthe previous example
The integral becomes
let
then