Doc Al said:There are two equations you can use.
First fill in these:
s = ?
v = ?
(You have enough information to fill in these values.)
grzz said:THINK!
What is the velocity at the max height?
Uniquebum said:Start with
v = v_0 + at
Where v = end velocity, v_0 initial velocity, a = g = gravity and t = time
If you consider v to be the velocity at the top of the throw then v = 0.
Thus 0 = v_0 + at
v_0 = -at, You know the acceleration and t = half the total time. So there you get the initial velocity and rest becomes simplier.
It looks like you are trying to use this equation: s=ut+1/2at^2TheGreenMarin said:0 = v_0 + 9.81x4.2 ? I am not sure I have done this correctly
so v_0 = -41.202
Doc Al said:It looks like you are trying to use this equation: s=ut+1/2at^2
But you left out a few things. Try again. (But yes, s = 0 for the round trip.)
OK, except that you have the wrong sign for the acceleration. Fix that first.TheGreenMarin said:0=u x 4.2 + 0.5 x 9.81 x 4.2^2
No it doesn't. Try again.gives me 0 = u x 90.7242
Doc Al said:OK, except that you have the wrong sign for the acceleration. Fix that first.
No it doesn't. Try again.
Good.TheGreenMarin said:-9.81 as its against gravity, rookie error
Show how you got that, step by step.I now got -82.3242 as my answer
OK.TheGreenMarin said:0=u x 4.2 + 0.5 x -9.81 x 4.2^2
Not OK.so 0 = u x -82.3242
Doc Al said:OK.
Not OK.
Try this:
0=u x 4.2 + 0.5 x -9.81 x 4.2^2
which I'll rewrite as:
0 = 4.2u -(0.5)(9.81)(4.2^2)
4.2u = (0.5)(9.81)(4.2^2)
And so on...
Starting with:TheGreenMarin said:Just confused on where the - sign has come from in the line: 0 = 4.2u -(0.5)(9.81)(4.2^2)
Doc Al said:Starting with:
0 = 4.2u +(0.5)(-9.81)(4.2^2)
You can move that minus sign from in front of the 9.81 and place it here:
0 = 4.2u -(0.5)(9.81)(4.2^2)
(1)(2)(-3) is the same as -(1)(2)(3).
Yes. (I'd round it off to no more than 3 sig figures.)TheGreenMarin said:Right OK, I see how you have done that. Is my answer of 20.601 correct?
Doc Al said:Yes. (I'd round it off to no more than 3 sig figures.)
SUVAT motion is a mathematical model used to describe the motion of an object in a straight line. It stands for displacement (S), initial velocity (U), final velocity (V), acceleration (A), and time (T).
In the case of a ball thrown vertically, SUVAT motion can be used to calculate the displacement, final velocity, and time of the ball. The initial velocity is usually given as the ball is thrown from a known height with no initial velocity in the vertical direction. The acceleration due to gravity is also known, and the time can be calculated using the formula t = √(2s/a) where s is the displacement and a is the acceleration.
Displacement refers to the change in position of an object in a specific direction, while distance is the total length traveled by the object regardless of direction. In SUVAT motion, displacement is represented by the letter S, while distance is represented by the letter D.
No, SUVAT motion is only applicable for objects moving in a straight line with constant acceleration. For non-uniform motion, more complex equations and models are needed to describe the motion accurately.
To determine the maximum height, we can use the formula V² = U² + 2as, where V is the final velocity (which would be 0 at the maximum height), U is the initial velocity, a is the acceleration due to gravity (usually -9.8 m/s²), and s is the displacement (which would be the maximum height). By solving for s, we can determine the maximum height reached by the ball.