Homework SourseComplete Table 2 Describe each graph generated by the simula
Complete Table 2. Describe each graph generated by the simulation.
Table 2
| Fallen (m) | Describe | ||
|---|---|---|---|
| Distance Curve | Velocity Curve | Acceleration Curve | |
| 0 | |||
| 5 | ---Select--- horizontal line vertical line increasing straight line decreasing straight line increasing parabolic curve decreasing parabolic curve | ||
| 10 | ---Select--- horizontal line vertical line increasing straight line decreasing straight line increasing parabolic curve decreasing parabolic curve | ||
| 30 | ---Select--- horizontal line vertical line increasing straight line decreasing straight line increasing parabolic curve decreasing parabolic curve | ||
| 50 | ---Select--- horizontal line vertical line increasing straight line decreasing straight line increasing parabolic curve decreasing parabolic curve | ||
| 65 | ---Select--- horizontal line vertical line increasing straight line decreasing straight line increasing parabolic curve decreasing parabolic curve | ||
| 85 | ---Select--- horizontal line vertical line increasing straight line decreasing straight line increasing parabolic curve decreasing parabolic curve | ||
| 100 | ---Select--- horizontal line vertical line increasing straight line decreasing straight line increasing parabolic curve decreasing parabolic curve | ---Select--- horizontal line vertical line increasing straight line decreasing straight line increasing parabolic curve decreasing parabolic curve | ---Select--- horizontal line vertical line increasing straight line decreasing straight line increasing parabolic curve decreasing parabolic curve |
Solution
I did not totally understand the question asked , but attempt to give an answer.
Since the LHS column is titled \"Fallen\", im assuming that you are describing a free fall of the object.
Also, since the object mass and other simulation conditions are not given, ill assume it . At 100m it hits the ground and stays there(assumption)
Initially
At 0m distance : all graphs are at Zero.
CASE 1: No air resistance
As the object starts falling, then the equations of motion :
S=ut +1/2*at^2;
v=u+at
a=g (constant)
Here,
u=initial velocity (zero in our case)
v=final velocity (linearly dependant on time t)
s=distance (depends as t^2)
So all along the fall:
Distance: Increasing Parabolic curve
Velocity: Increasing straight line
accleration: constant horizontal straight line
and after it has fallen: (i.e at 100m)
Distance: horizontal line at 100m
Velocity: zero
accleration: zero
CASE 2: With air resistance
With air resistance accleration decreases with increasing velocity.
So Before terminal velocity (i.e a=0),
Distance: Increasing parabolic function (slowly tending to be linear)
Velocity: Increasing straight line (tending to be horizontal)
accleration: constant horizontal line slowly dipping to zero.
Once it reaches terminal velocity,
a=0
s=ut
v=constant
So
Distance: increasing straight line
Velocity: constant horizontal line
accleration: Zero
Hope ive answered your query..
