Eksperimentti: hyppykorkeuden määrittäminen impulssilla: Difference between revisions

From wikiluntti
(Created page with "== Introduction == thumb|Force exerted on the force plate Jumping on the force plate you can feel the force. We use time of flight method to estimate the height of the jump.")
 
 
(25 intermediate revisions by the same user not shown)
Line 4: Line 4:


Jumping on the force plate you can feel the force. We use time of flight method to estimate the height of the jump.
Jumping on the force plate you can feel the force. We use time of flight method to estimate the height of the jump.
== Theory ==
[[File:ForcePlate jumping2 Impulse Areas.svg|thumb]]
Impulse <math>J = \int F dt = \Delta p = m\Delta v</math>. Actually <math>\Delta v</math> is our takeoff speed because <math>v_1=0</math>, and we have <math>\Delta v = v_{0} = \frac{J}{m} = \frac1m \int F dt</math>.  Because <math>s = s_0 + v_0 t + \tfrac12 at^2</math> and thus we have <math>h = v_0 t - \tfrac12 gt^2</math> because <math>h_0=0</math> and <math>a=-g = -9.81m/s^2</math>. However, for the velocity we have <math>v = v_0 - gt</math> and at the maximum height we have that <math>v=0</math>, and thus <math>v_0 = gt</math> and <math>t=\frac{v_0}{g}</math>. Combining these two we have
<math>
\begin{align}
h &= v_0 t - \tfrac12 gt^2 \\
  &= v_0 \tfrac{v_0}g - \tfrac12 g\left( \frac{v_0}g \right)^2 \\
  &= \frac{v_0^2}{g} - \tfrac12 \frac{v_0^2}{g} \\
  &= \frac{v_0^2}{2g} \\
  &= \frac{J^2}{2gm^2} = \frac{1}{2g} \left( \frac Jm \right)^2
\end{align}
</math>
Note that <math>J/m = v_0</math>, and thus the equation gives the correct equation.
=== Example ===
The example gives
<math>
\begin{align}
m &= 880 N /9.81 = 89.7 kg \\
J &= 464 Ns - 89.7 kg \times 9.81 \times 0.2895 s = 464 Ns - 254.75 Ns = 209.25 Ns
\end{align}
</math>
and thus we have
<math>
\begin{align}
h &= \frac{J^2}{2gm^2} \\
  &= \frac{(209.25 Ns)^2}{2 \times 9.81 m/s^2 \times (89.7 kg)^2 } \\
  &= \frac{43785.5625}{315 728.5716} \\
  &= 0.139 m\\
\end{align}
</math>
The takeoff velocity is <math>v_0 = \frac Jm = \frac{209.25 Ns}{89.7 kg} = 2.33 m/s</math>.
== Example 2: Zero the force plate ==
== References ==
https://www.thehoopsgeek.com/the-physics-of-the-vertical-jump/
https://www.brunel.ac.uk/~spstnpl/LearningResources/VerticalJumpLab.pdf

Latest revision as of 18:16, 3 May 2022

Introduction

Force exerted on the force plate

Jumping on the force plate you can feel the force. We use time of flight method to estimate the height of the jump.

Theory

Impulse . Actually is our takeoff speed because , and we have . Because and thus we have because and . However, for the velocity we have and at the maximum height we have that , and thus and . Combining these two we have

Note that , and thus the equation gives the correct equation.

Example

The example gives

and thus we have

The takeoff velocity is .

Example 2: Zero the force plate

References

https://www.thehoopsgeek.com/the-physics-of-the-vertical-jump/

https://www.brunel.ac.uk/~spstnpl/LearningResources/VerticalJumpLab.pdf