PlanetPhysics/Constant Acceleration Problems

Problem 1

At time ${\displaystyle t=0sec}$ we throw a stone from the ground level straight up with [[../Velocity/|speed]] of ${\displaystyle 20m/sec}$ (ignore air drag, and assume ${\displaystyle g=10m/se{c}^2}$).

a) At what time (in sec) will this stone reach its highest point, and how high is it then above the ground?

b) We now throw a second stone straight up 2 sec after the first. How many meters above the ground is the first stone at that moment?

c) At what speed should we throw this second stone from the ground if it is to hit the first stone 1 second after the second stone is thrown?

Ans a)

Let us choose the positive y axis extending into the air. Then the [[../Thrust/|force]] due to gravity is in the negative y direction

${\displaystyle F=-mg}$

applying [[../NewtonsLawsOfMotion/|Newton's 2nd law]]

${\displaystyle F=m\ddot{y}=-mg}$

Integrate this to get equation for [[../Velocity/|velocity]] of the stone

${\displaystyle \dot{y}(t)=-gt+C_1}$

At ${\displaystyle t=0,\dot{y}=20m/s}$, therefore

${\displaystyle \dot{y}(t)=-gt+20}$

Integrate again to get equation for [[../Position/|position]] of the stone

${\displaystyle y(t)=-\frac{1}{2}g{t}^2+20t+C_2}$

Once, again plug in the initial condition that at ${\displaystyle t=0,y=0}$ to get ${\displaystyle C_2}$

${\displaystyle 0=C_2}$

therefore

${\displaystyle y(t)=-\frac{1}{2}g{t}^2+20t}$

Next we know that at the stone's highest point ${\displaystyle h}$ its velocity will be ${\displaystyle 0}$. So from equation (1) we can then find the time ${\displaystyle t_h}$ at this point

${\displaystyle 0=-g{t}_h+20}$ ${\displaystyle t_h=20/g=20/10=2sec}$

Now we can plug this result into equation (2) to get the height

${\displaystyle h=-\frac{1}{2}g{t}_h^2+20t_h=-\frac{1}{2}(10)(2^2)+20(2)}$

Therefore

${\displaystyle h=20[m]}$

Ans b)

This is straight forward since equation 2 gives us the position of the first stone at some given time. So at ${\displaystyle t=2}$

${\displaystyle y(2)=-\frac{1}{2}g(2{)}^2+20(2)=40-20=20[m]}$

which, makes sense from question a.

Ans c)

The stones will hit when first stone is 3 seconds into its flight. Its height is then determined from equation 2

${\displaystyle y=-\frac{1}{2}(10)(3{)}^2+20(3)=-45+60=15[m]}$

If we now look back to see how we got the constant in equation (1), we see that ${\displaystyle C_1}$ is equal to the initial velocity ${\displaystyle v_0}$

${\displaystyle \dot{y}=-gt+v_0}$

Integrate to get position

${\displaystyle y=-\frac{1}{2}g{t}^2+v_{0}t}$

We want to find ${\displaystyle v_0}$ at 1 second into the second stone's flight which we know occurs at ${\displaystyle 15[m]}$. So set ${\displaystyle y=15}$ and solve for ${\displaystyle v_0}$ at ${\displaystyle t=1}$

${\displaystyle 15=-\frac{1}{2}(10)(1{)}^2+v_0(1)}$ ${\displaystyle 15=-5+v_0}$

So we see that the initial velocity needed for second stone is

${\displaystyle v_0=20[m/s]}$

There is another way of finding the speed without making any calculations. At ${\displaystyle t=3,}$ the first stone is at the same height as it was at ${\displaystyle t=1sec.}$ Since the stones have to collide at this height exactly 1 sec after the second stone is thrown, the second stone should also begin with a speed of 20 m/sec.

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References

This is a derivative [[../Work/|work]] from [1] a Creative Commons Attribution-Noncommercial-Share Alike 3.0 work.

[1] MIT OpenCourseWare, 8.01 Physics I: [[../NewtonianMechanics/|classical mechanics]], Fall 1999.

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