Kinematics in Two Dimensions Questions


A small block is placed at height  $h$ on a frictionless,  $30{}^\circ $ ramp.  Upon  being released (from rest), the  block  slides  down the  ramp  and  then falls  $1.0\ \mathrm{m}$ to  the  floor.  A small hole is located $1.0\ \mathrm{m}$ from the end of the ramp.  From what  height $h$ should the  block  be released  in  order to land  in  the  hole?

First, find the speed of the block at the bottom of ramp (from conservation of energy):
\[U_i+K_i=U_f+K_f\to \ \ mgh=\frac{1}{2}mv^2_1\to v_1=\sqrt{2gh}\] 
In the end of the ramp, block moving in two direction (projectile in plane):
The horizontal distance that the block hits the ground to the base is given by $\mathrm{\Delta }x=v_{1x}t+\frac{1}{2}a_xt^2$ but in $x$ direction there is a uniform motion i.e. $a_x=0$, so $t=\frac{\mathrm{\Delta }x}{v_{1x}}=\frac{\mathrm{\Delta }x}{v_1\,{\cos \theta \ }}$ .We know that in the projectiles motion the time traveled in horizontal direction is equal to that of in vertical direction. Then,
\Delta y &=v_{1y}t+\frac{1}{2}a_yt^2\\
&=v_1\,{\sin \theta \ }\frac{\mathrm{\Delta }x}{v_1\,{\cos \theta \ }}+\frac{1}{2}\left(-g\right){\left(\frac{\mathrm{\Delta }x}{v_1{\cos \theta \ }}\right)}^2
\[\mathrm{\Rightarrow }\mathrm{\ \ \ }\mathrm{\Delta }y=\mathrm{\Delta }x\,{\tan \theta \ }-\frac{g{\left(\mathrm{\Delta }x\right)}^2}{2v^2_1{{\cos}^{\mathrm{2}} \theta \ }}\] 
Solving for $v_1$, we get 
\frac{g{\left(\mathrm{\Delta }x\right)}^2}{2v^2_1{{\cos}^{\mathrm{2}} \theta \ }}=\mathrm{\Delta }x\,{\tan \theta \ }-\mathrm{\Delta }y\\
\Rightarrow \ v^2_1=\frac{g{\left(\mathrm{\Delta }x\right)}^2}{2{{\cos}^2 \theta \ }\left(-\mathrm{\Delta }y+\mathrm{\Delta }x{\tan \theta \ }\right)}=2gh
Then the desired height is obtained as
\[\therefore h=\frac{{\left(\mathrm{\Delta }x\right)}^2}{4{{\cos}^2 \theta \ }(-\mathrm{\Delta }y+\mathrm{\Delta }x\,{\tan \theta \ })}\] 
Consider the end of the ramp as the origin of coordinate system, so the coordinate of the landing point is $(x=1\mathrm{m,y=-1m)}$ and since the block exit the ramp at $30{}^\circ $ below the horizontal so $\theta =-30{}^\circ $. Substituting these values into the above relation for $h$, we obtain
\[h=\frac{{\left(1\right)}^2}{4{{\cos}^2 \left(-30{}^\circ \right)\ }\left(-\left(-1\right)+1{\tan \left(-30{}^\circ \right)\ }\right)}=0.788\ \mathrm{m}\] 

A missile is shot horizontally from the top of a $500\ \mathrm{m}$ cliff with an initial speed of $300\ \mathrm{m/s}$
(a) Find the time it takes for the missile to hit the ground.
(b) What is the range of the missile?
(c) Calculate the velocity of the missile just before it hits the ground.
(d) If the missile hits the ground and bounces up at an angle of $30{}^\circ$ with a speed of $\mathrm{200\ m/s}$, how far away from the point of impact will it land?

Projectile motion: in this motion without air resistance we have $a_x=0$ and $a_y=-g$. The kinematic relations for projectile are:
x=\underbrace{\left(v_0\,{\cos \alpha \ }\right)}_{v_{0x}}t\\
y=-\frac{1}{2}gt^2+\underbrace{\left(v_0\,{\sin \alpha \ }\right)}_{v_{0y}}t+y_0
v_x=\underbrace{v_0\,{\cos \alpha \ }}_{v_{0x}}\ \ ,\ \ v_y=\underbrace{v_0\,{\sin \alpha \ }}_{v_{0y}}-gt
(a) If we choose the initial position of the missile as the origin of the coordinate system (i.e. $x_0=y_0=0$)then the hitting position has coordinate ($x,y=-500\,\mathrm{m}$). Use the following kinematic relation to find the total flight time. 
y=-\frac{1}{2}gt^2+v_0t\,{\sin \alpha \ }+y_0\\
\to \ -500=-\frac{1}{2}\left(9.8\right)t^2+300\,t\,{\sin 0{}^\circ \ }+0
\[\Rightarrow t_{tot}=\sqrt{\frac{1000}{9.8}}=10.10\ \mathrm{s}\] 
Note: in horizontally shot $\alpha =0{}^\circ $
(b) To find the range of the projectile, we must find the total flight time of the motion then substitute it into $x=v_0t\,{\cos \alpha \ }$. 
In the previous part the total flight time is calculated as $t=10.10\,\mathrm{s}$, therefore 
R_1=x&=v_0t\,{\cos \alpha \ }\\
&=300\times 10.10\times {\cos 0{}^\circ \ }\\
&=3000.30\ \mathrm{m}
(c) In projectile motion first find the components of the velocity then use the $v=\sqrt{v^2_x+v^2_y}$ to determine the velocity of the missile at any moment (in this case the hitting position, $t_{tot}$). 
\[v_x=v_0\,{\cos \alpha \ }=300\times {\cos 0{}^\circ \ }=300\frac{\mathrm{m}}{\mathrm{s}}\] 
v_y&=v_0\,{\sin \alpha \ }-gt\\
&=300\times {\sin 0{}^\circ \ }-\left(9.8\times 10.10\right)\\
\[v=\sqrt{v^2_x+v^2_y}=\sqrt{{\left(300\right)}^2+{\left(-98.98\right)}^2}=315.9\ \mathrm{m/s}\] 
(d) In this part we have a separate projectile motion problem, hence we choose the launching point as the origin with the following information $x_0=y_0=0\ ,\ v_0=200\ \mathrm{m/s}$ , $\alpha =30{}^\circ $
. First by setting $y=0$ in the $y=-\frac{1}{2}gt^2+v_0t\,{\sin 30{}^\circ \ }+y_0$ find the total fight time, then substitute it into the $x=v_0t\,{\cos 30{}^\circ \ }$
\[0=-\frac{1}{2}\left(9.8\right)t^2+200\,t\left(\frac{1}{2}\right)+0\Rightarrow t\left(9.8t-200\right)=0\] 
\[\Rightarrow \left\{ \begin{array}{rcl}
t_1 & = & 0\ ,\ \ \ \mathrm{initial\ time} \\ 
t_2 & = & \frac{200}{9.8}=20.4\ \mathrm{s\ \ ,\ \ \ landing\ time} \end{array}
R_2=x &=v_0t_2\,{\cos 30{}^\circ \ }\\
&=200\times 20.4\times \left(\frac{\sqrt{3}}{2}\right)\\
&=3533.38\ \mathrm{m}


A baseball is thrown from the ground into the air with an initial velocity $\vec{v}=20\ \hat{i}+10\ \hat{j}\ (\frac{\mathrm{m}}{\mathrm{s}}\mathrm{)}$
(a) To what maximum height will the ball rise?
(b) What will be the total horizontal distance travelled by the ball?
(c) What is the velocity of the ball the instant before it hits the ground?

(a) From the given velocity we can determine the launch angle and the magnitude of initial velocity.
\alpha ={{\tan}^{-1} \frac{v_y}{y_x}\ }={{\tan}^{-1} \left(\frac{10}{20}\right)\ }=26.5{}^\circ\\
v_0=\sqrt{{10}^2+{20}^2}=22.36\ \frac{\mathrm{m}}{\mathrm{s}}
To find the maximum height we must calculate when the vertical component of velocity is zero $v_y=0$ then substitute it into the vertical distance relation.
v_y=v_0\,{\sin 26.5{}^\circ \ }-gt=0\\
\Rightarrow t=\frac{v_0\,{\sin 26.5{}^\circ \ }}{g}=\frac{22.36\times 0.44}{9.8}=1.01\ \mathrm{s}
y&=-\frac{1}{2}gt^2+v_0t\,{\sin \alpha \ }+y_0\\
&=-\frac{1}{2}\left(9.8\right){\left(1.01\right)}^2+22.36\left(1.01\right){\sin 26.5{}^\circ \ }+0\\
&=5.07\ \mathrm{m}
Alternative solution: without finding the angle and magnitude of the velocity we can find the maximum height!
\vec{v}=\underbrace{20}_{v_{0x}}\hat{i}+\underbrace{10}_{v_{0y}}\hat{\mathrm{j}}\ \left(\frac{\mathrm{m}}{\mathrm{s}}\right)\\
v_y=v_{0y}-gt=0\Rightarrow t=\frac{v_{0y}}{g}=\frac{10}{9.8}=1.01\ \mathrm{s}
y&=-\frac{1}{2}gt^2+\underbrace{v_0\,{\sin \alpha \ }}_{v_{0y}}t+y_0\\
&=5.10\ \mathrm{m}
Small difference between the two results is due to uncertainty in the magnitude of the angle and initial velocity of the projectile. 
(b) To find the horizontal distance, calculate the total flight time and then put it in the $x$ relation.
For finding the total flight time, substitute the location of hitting the projectile to the ground into $y=-\frac{1}{2}gt^2+v_{0y}t+y_0$. Because the launching and landing point are in the same level (choose this point as the origin $x_0=y_0=0$) set $y=0$.
\[0=-\frac{1}{2}\left(9.8\right)t^2_{tot}+10\,t_{tot}+0\Rightarrow t_{tot}\left(9.8\ t_{tot}-20\right)=0\] 
\[\Rightarrow t_{tot}=\left\{ \begin{array}{rcl}
0\ & , & \ \ \mathrm{initial\ time} \\ 
\frac{20}{9.8} & = & 2.04\ \mathrm{s\ ,\ \ landing\ time} \end{array}
x=v_0\, {\cos \alpha \ }t=v_{0x}t\\
\Rightarrow R=x_{tot}=v_{0x}t_{tot}=20\times 2.04=40.8\ \mathrm{m}
This is the maximum distance traveled in the horizontal direction or range of the projectile.
(c) First substitute the total flight time into the $v_y$ and $v_x$ then find the magnitude of the velocity.
\[\left\{ \begin{array}{c}
v_x=v_{0x}=20\frac{\mathrm{m}}{\mathrm{s}} \\ 
v_y=v_{0y}-gt_{tot}=10-\left(9.8\right)\left(2.04\right)=-9.992\frac{\mathrm{m}}{\mathrm{s}} \end{array}
\[\Rightarrow v=\sqrt{v^2_x+v^2_y}=\sqrt{{20}^2+{\left(-9.992\right)}^2}=22.35\frac{\mathrm{m}}{\mathrm{s}}\] 

A projectile is fired horizontally from a gun that is $45\ \mathrm{m}$ above the ground. The muzzle velocity is $250\ \mathrm{m/s}$. 
(a) How long does the projectile remains in air?
(b) At what horizontal distance from the firing point does it strike the ground?
(c) What is the magnitude of the vertical component of its velocity as it strikes the ground?

(a) Remains in air means that the total flight time. To find this time put the coordinate of the impact of the projectile into the $y=-\frac{1}{2}gt^2+v_0t\,{\sin \alpha \ }+y_0$ and then solve for the time $t_{tot}$. Let the origin of the coordinates to be the firing point. Therefore, the projectile hits the ground $-45\ \mathrm{m}$below the origin!
\[y=-\frac{1}{2}gt^2+v_0\,{\sin \alpha \ }\ t+y_0\] 
\[-45=-\frac{1}{2}\left(9.8\right)t^2+250\,t\,{\sin 0{}^\circ \ }+0\]
\[\Rightarrow t_{tot}=\sqrt{\frac{90}{9.8}}=3.03\mathrm{s}\] 
(b) Namely, find the range of the projectile. Hence substitute $t_{tot}$ into the $x$ component of the motion i.e.
\[R=x=v_0\,{\cos \alpha \ }t_{tot}=\left(250\right)\left(3.03\right){\cos 0{}^\circ \ }=757.5\ \mathrm{m}\] 
(c) The components of the velocity in a projectile motion at any moment in time are
\[v_x=v_{0x}=v_0\,{\cos \alpha \ }=250\,{\cos 0{}^\circ \ }=250\frac{\mathrm{m}}{\mathrm{s}}\] 
v_y&=v_{0y}-gt=v_0\,{\sin \alpha \ }-gt\\
&=250\,{\sin 0{}^\circ \ }-\left(9.8\right)\left(3.03\right)\\
&=29.69\ \frac{\mathrm{m}}{\mathrm{s}}
Where we have substitute the total time (the moment of impact on the ground).

A ball is thrown horizontally from the roof of a building $50\ \mathrm{m}$ tall and lands $45\,\mathrm{m}$ from the base. What was the ball's initial speed?

This is a projectile motion with launch angle $\alpha =0{}^\circ $, so use the projectile equations as 
x=v_{0x}t=v_0\,{\cos \alpha \ }t\ \ ,\ \ y=-\frac{1}{2}gt^2+\underbrace{v_0{\sin \alpha \ }}_{v_{0y}}t+y_0\\
v_x=v_0\,{\cos \alpha \ }\ \ ,\ \ v_y=\underbrace{v_0\,{\sin \alpha \ }}_{v_{0y}}-gt
If we choose the releasing point as the reference then the coordinate of the point of impact is $(x=45,y=-50\ \mathrm{m)}$. First find the total flight time then substitute it into the $x$ component of the projectile.
y=-\frac{1}{2}gt^2_{tot}+\underbrace{v_0{\sin \alpha \ }}_{v_{0y}}t_{tot}+y_0\\
\Rightarrow \ -50=-\frac{1}{2}\left(9.8\right)t^2_{tot}+v_0\,{\sin 0{}^\circ \ }t_{tot}+0\\
\Rightarrow t_{tot}=\sqrt{\frac{2\times 50}{9.8}}=3.19\ \mathrm{s\ }
\[x=v_0\,{\cos \alpha \ }t_{tot}\Rightarrow v_0=\frac{x}{{\cos 0{}^\circ \ }\,t_{tot}}=\frac{45}{3.19}=14.1\frac{\mathrm{m}}{\mathrm{s}}\] 


A $1\ \mathrm{kg}$ projectile is fired from a cannon with an initial kinetic energy of ${10}^4\ \mathrm{J}$. The cannon has an elevation angle of $45{}^\circ $. How far does the projectile go before striking the ground (neglect air resistance)? 

In the projectile language, the distance from the launching to striking point is called the range of the projectile which is found by substituting the total flight time into the $x$ component of the projectile motion that is $X=v_0\,{\cos \theta \ }\ t$. 
From the definition of the kinetic energy one can find the initial velocity of the projectile.
\[K=\frac{1}{2}mv^2_0\to {10}^4=\frac{1}{2}\left(1\right)v^2_0\] 
\[\Rightarrow v_0=\sqrt{2}\times {10}^2\frac{\mathrm{m}}{\mathrm{s}}\] 
Consider the starting and landing points to be in the same level. In this case, using the kinematic equation $v_y=v_0\,{\sin \theta \ }-gt$ and knowing the fact that at the highest point the vertical component of the projectile's velocity is zero i.e. $v_y=0$, find half of the total flight time that is $t_{tot}=2t$ (since there is no air resistance).
v_y=v_0\,{\sin \theta \ }-gt=0\\
\to t=\frac{v_0\,{\sin \theta \ }}{g}=\frac{\left(\sqrt{2}\times {10}^2\right){\sin 45{}^\circ \ }}{9.8}=10.2\ \mathrm{s}
This is the elapsed time to the highest point.
\[\Rightarrow t_{tot}=2t=20.4\ \mathrm{s}\] 
Range=X&=v_0t\,{\cos \theta \ }\\
&=\left(\sqrt{2}\times {10}^2\right){\cos 45{}^\circ \ }\times 20.4\\
&=2040\ \mathrm{m}

A particle is constrained to travel in a plane so that its position is described by
\[\vec{r}=\ \left(17\frac{m}{s^2}\right)t^2 \rm \hat i+\ \left[\left(20\frac{m}{s}\right)t\ -\ \left(6\frac{m}{s^4}\right)t^4\right]\hat{\mathrm{j}}\] 
(a) Consider the motion of the particle during the time interval from $t=0\,{\rm s}$ to $t=5\,{\rm s}$? What are the displacement, average velocity and average acceleration over this time interval.
(b) Find the position, velocity and acceleration at $t=8\,{\rm s}$.

(a) Displacement of an object as it moves from an initial position $\vec r_1$ to a final position $\vec r_2$ is defined as $\Delta \vec r=\vec r_2-\vec r_1$. So we must first find the position of the particle in the $0\,{\rm s}$ and  $5\,{\rm s}$ . substitute them in the $\vec{r}(t)$ so
\vec{r}\left(t=5\,{\rm s}\right)&=\ \left(17\frac{m}{s^2}\right){\left(5s\right)}^2\,\rm \hat i+\ \left[\left(20\frac{m}{s}\right)\left(5s\right)-\ \left(6\frac{m}{s^4}\right){\left(5s\right)}^4\right]\hat{\mathrm{j}}\\ 
&=425\ \rm \hat{i}+\left(100-3750\right)\rm \hat{j}=425\ \rm \hat{i}-3650\ \rm \hat{j}\ \ (m)
\[\vec{r}\left(t=0\,{\rm s}\right)=\ \left(17\frac{m}{s^2}\right){\left(0\,{\rm s}\right)}^2\rm \hat i+\ \left[\left(20\frac{m}{s}\right)\left(0\,{\rm s}\right)-\ \left(6\frac{m}{s^4}\right){\left(0s\right)}^4\right]\hat{\mathrm{j}}=0\] 
\[\Delta \vec{r}={\vec{r}}_2\left(t=5\,{\rm s}\right)-{\vec{r}}_1\left(t=0\right)=425\ \rm \hat{i}-3650\ \rm \hat{j}\] 
By definition, the average velocity is $\vec{v}=\mathrm{\Delta }\vec{r}/\mathrm{\Delta }t\ $ therefore
\[\vec{\overline{v}}=\frac{\Delta\vec{r}}{\Delta t}=\frac{425\ \hat{i}-3650\ \rm \hat{j}}{5-0}=85\,\rm\hat{i}-730\,\rm\hat{j}\left(\frac{m}{s}\right)\] 
Average acceleration is defined as $\vec{\overline{a}}=\Delta \vec{v}/\Delta t$ where $\vec{v}$ is the instantaneous velocity of the particle i.e. $\vec{v}=d\vec{r}/dt$
So first find the change in the instantaneous velocity of the particle during time interval $0$ to $5\mathrm{s}$ then calculate the average acceleration.
\vec{v}=\frac{d\vec{r}}{dt}&=\frac{d}{dt}\left(\left(17\frac{m}{s^2}\right)t^2\,\rm \hat i+\ \left[\left(20\frac{m}{s}\right)t\ -\ \left(6\frac{m}{s^4}\right)t^4\right]\hat{\mathrm{j}}\right)\\
&=34\,t\ \rm\hat{i}+\left[20-24t^3\right]\rm\hat{j}
\vec{v}\left(t=5\right)=34\left(5\right)\rm\hat i+\left[20-24{\left(5\right)}^3\right]\,\rm\hat j=170\,\rm\hat i-2980\,\rm\hat j\left(\frac{m}{s}\right)\\
\vec{v}\left(t=0\right)=20\,\rm\hat j\left(\frac{m}{s}\right)
&=170\,\rm\hat i+\left(-2980-20\right)\,\rm\hat j\\
&=170\,\rm\hat i-3000\,\rm\hat j
\[\vec{\vec{a}}=\frac{\Delta \vec{v}}{\Delta t}=\frac{170\,\rm\hat i-3000\,\rm\hat j}{5-0}=34\,\rm\hat i-600\,\rm\hat j\left(\frac{m}{s^2}\right)\] 
(b) Now we must calculate the instantaneous quantities in $t=8\mathrm{s}$
\[\vec r\left(t=8\,{\rm s}\right)=\left(17\frac{m}{s^2}\right)8^2 \rm \hat i +\ \left[\left(20\frac{m}{s}\right)8\ -\ \left(6\frac{m}{s^4}\right)8^4\right]\hat{\mathrm{j}}=1088\,\rm\hat i-24416\,\rm\hat j\] 
\[\vec v=\frac{d\vec r}{dt}=34t\,\rm\hat i+\left[20-24t^3\right]\,\rm\hat j=34\left(8\right)+\left[20-24{\left(8\right)}^3\right]\,\rm\hat j=272\,\rm\hat i-12268\,\rm\hat j\] 
\[\vec a=\frac{d\vec v}{dt}=34\,\rm\hat i-72t^2\,\rm\hat j=34\,\rm\hat i-72{\left(8\right)}^2\,\rm\hat j=34\,\rm\hat i-4608\,\rm\hat j\] 

The position of a particle as a function of time is given as:
\[\vec{r}\left(t\right)=R\,{\cos \omega t\ }\,\rm\hat i+R\,{\sin \omega t\ }\] 
(a) Instantaneous velocity vector, $\vec{v}(t)$
(b) The angle between $\vec{r}\left(t\right)$ and $\vec{v}(t)$
(c) Instantaneous acceleration vector
(d) What is the mathematical relation between $\left|\vec{a}\right|$ and $\left|\vec{v}\right|$?
(e) Using this relation (in part d), comment on the nature of this motion.

(a) Using the definition of the instantaneous velocity, we have $$\vec{v}\left(t\right)=\frac{d\vec{r}}{dt}=-\hat{x}\ R\omega {\sin \omega t\ }+\hat{y}\ R\omega {\cos \omega t\ }$$
(b) The angle between two vectors $\vec{A}$ and $\vec{B}$ is defined as ${\cos \alpha \ }=\frac{\vec{A}.\vec{B}}{\left|A\right|\left|B\right|}$. first compute the inner product of them: 
\vec{r}\left(t\right).\vec{v}\left(t\right) &=\left(R{\cos \omega t\ }\hat{x}+R{\sin \omega t\ }\hat{y}\right).\left(-\hat{x}\ R\omega \,{\sin R\omega \ }+\hat{y}\ R\omega \,{\cos R\omega \ }\right)\\
& =-R^2\omega \,{\sin \omega t\ }\,{\cos \omega t\ }\left(\hat{x}.\hat{x}\right)+R^2\omega \,{\sin \omega t\ }{\cos \omega t\ }\left(\hat{y}.\hat{y}\right)=0
Thus, ${\cos \alpha \ }=0\Rightarrow \ \alpha =90{}^\circ \ or\ 270{}^\circ $
(c) $$\vec{a}=\frac{d\vec{v}}{dt}=-\hat{x}R\,{\omega }^2{\cos \omega t\ }-\hat{y}R{\omega }^2{\sin \omega t\ }$$
(d) The magnitude of a vector $\vec{a}=a_x\hat{x}+a_y\,\rm\hat j$ is $\left|\vec{a}\right|=\sqrt{a^2_x+a^2_y}$. So 
\[\left|\vec{v}\right|=\sqrt{{\left(R\omega {\sin \omega t\ }\right)}^2+{\left(R\omega {\cos \omega t\ }\right)}^2}=R\omega \] 
\[\left|\vec{a}\right|=\sqrt{{\left(R{\omega }^2{\cos \omega t\ }\right)}^2+{\left(-R{\omega }^2{\sin \omega t\ }\right)}^2}=R{\omega }^2\] 
\[\therefore \ \left|\vec{a}\right|=\frac{{\left|\vec{v}\right|}^2}{R}\] 
(e) This is the defining equation for uniform circular motion. From the beginning, one can infer the nature of the circular motion from $\vec{r}\left(t\right)$ since it defines a circle!

A bullet is fired horizontally from the top of a cliff that is $80\ \mathrm{m}$ above a big lake. If the muzzle (initial) speed of the bullet is $400\ \mathrm{m/s}$, how far from the bottom of the cliff does the bullet strike the surface of the lake? Neglect air resistance. 

A pictorial representation of the problem is shown in the figure below.

Put a coordinate at the starting point. Since the hitting point of the bullet is $80\ \mathrm{m}$ below the coordinate so the coordinate of the landing point is $(x=?,y=-80\, \mathrm{m)}$. first using the equation $y=-\frac{1}{2}gt^2+v_{0y}t+y_0$ find the time required to reaches the bullet to the ground.
\[y=-\frac{1}{2}gt^2\to t=\sqrt{\frac{2y}{-g}}=\sqrt{2\times \frac{(-80)}{(-10)}}=4\ \mathrm{s}\] 
Now using the relation between uniform velocity and displacement i.e. $x=Vt$ we obtain
\[x=Vt=\left(400\right)\left(4\right)=1600\, \mathrm{m}\ \mathrm{\to }\mathrm{x=1 mile}\] 

A steel ball is dropped from the top of the Leaning Tower of Pizza, which is $56\ \mathrm{m}$ high. With air resistance neglected, approximately how long does it take the ball to hit the ground?

This is a free fall problem. So use the following kinematic equation to find the desired time
Where $v_0$ is the initial velocity of the ball and $y_0$ is initial height. In kinematic problems, we must first consider a reference point. Let the top of the tower be the origin of the coordinates so the hitting point has the coordinate $(x=0,y=-56\,\mathrm{m)}$. Since the ball is dropped so its initial velocity is zero ($v_0=0$).
\[-56=-\frac{1}{2}\left(9.8\right)t^2+0+0\Rightarrow t=\sqrt{\frac{2\times 56}{9.8}}=3.38\ \mathrm{s}\] 
$y_0=0$ since the ball has sat on the origin. 

Suppose that you are climbing the Leaning Tower, and you throw your cellphone to a friend on the ground, who catches it at a point $30\ \mathrm{m}$ below the point where you released it.
You throw it straight out, with an initial horizontal velocity of $10\ \mathrm{m/s}$ (and zero initial vertical velocity). By neglecting air resistance, what is the speed of the cellphone when your friend catches it? 
Find the components of the velocity at the hitting point then use the Pythagorean theorem to determine its magnitude.

Horizontal motion is uniform with speed $v_{0x}=v_x=10\ \mathrm{m/s}$ but vertical motion is accelerating. So use the following kinematic equation to find its velocity. 
\[v^2-v^2_0=2a\left(y-y_0\right) \to V^2_{y}-v^2_{0y}=2(-g)(y-y_0)\] 
\[v^2-0=2\left(-9.8\right)\left(-30-0\right) \Rightarrow v^2=588\frac{m^2}{s^2}\] 
\[\Rightarrow v=\sqrt{v^2_x+v^2_y}=\sqrt{{10}^2+588}=26\ \mathrm{m/s}\] 

A ball is thrown vertically upward with an initial speed of $20\ \mathrm{m/s}$. Neglect air resistance and assume constant acceleration. 
(a) How long does it take for the ball to reach its maximum height?
(b) What is that maximum height?
(c) At what height is the ball when its speed is $10\ \mathrm{m/s}$?
(d) How long does it take for the ball to return to the position at which it was released?
(e) What is its speed when it returns?

(a) Given data are $v_0=20\ \mathrm{m/s}$ , $a=-g$ so use the following kinematic equation to find the desired time
At the maximum height, the velocity of the ball is zero i.e. $v=0$. Therefore, we obtain
\[0=20-9.8t\Rightarrow t=2.04\ \mathrm{s}\] 
(b) let the starting point as origin so $y_0=0$. Using the following kinematic relation we get
\[0-{20}^2=-2\left(9.8\right)\left(y-0\right)\Rightarrow y=\frac{400}{2\times 9.8}=20.4\ \mathrm{m}\] 
(c) Using the equation $v^2-v^2_0=-2g(y-y_0)$, we obtain
\[{10}^2-{20}^2=-2\left(9.8\right)\left(y-0\right)\Rightarrow y=\frac{300}{2\times 9.8}=15.3\ \mathrm{m}\] 
(d) Since there is no air resistance, we can multiply the result of part (a) by two and get $t_{tot}=2\times 2.04=4.08\ \mathrm{s}$ or use the relation $y=-\frac{1}{2}gt^2+v_0t+y_0$ as follows
\[0=-\frac{1}{2}\left(9.8\right)t^2+20t+0\Rightarrow t\left(9.8t-40\right)=0\] 
\[\Rightarrow \left\{ \begin{array}{lcl}
t=0\ \ & , & \ \ initial\ time\ \  \\ 
t=\frac{40}{9.8}=4.08\ {\rm s} \ \ & , &\ \ final\ time \end{array}
(e) Use the equation $v^2-v^2_0=-2g(y-y_0)$, between the throwing and landing points
\[v^2-v^2_0=-2g\left(y-y_0\right)\Rightarrow v^2-{20}^2=-2\times 9.8\times \left(0-0\right)\] 
\[\Rightarrow v=20\frac{\mathrm{m}}{\mathrm{s}}\] 

A boat travelling at $12\ \mathrm{miles/hr}$ goes due east for $30$ minutes and then turns $45{}^\circ $ toward the north and travels another $20$ minutes.
(a) What total distance does the boat travel?
(b) What is the magnitude of its displacement?
(c) What is the direction of its displacement?
(d) What is the magnitude of its average velocity?
(e) What is the direction of its average velocity?

(a) The boat has constant velocity so its acceleration is zero. Therefore, use the equation of the uniform motion as $x=vt$ where $x$ is the distance traveled. The sketch of the path is shown in the following



\[x_t=x_1+x_2=v_1t_1+v_2t_2=\left(12\frac{\mathrm{mile}}{\mathrm{hr}}\right)\left(\mathrm{30\ min+20\ min}\right)\left(1\frac{\mathrm{hr}}{\mathrm{60\ min}}\right)\] 
\[x_t=\ \left(12\frac{\mathrm{mile}}{\mathrm{hr}}\right)\left(\frac{1}{2}\mathrm{hr+}\frac{\mathrm{1}}{\mathrm{3}}\mathrm{hr}\right)\mathrm{=10\ mile}\] 
(b) Displacement is a vector that its initial position is at the first vector and its final position is at the final of the last vector. So as shown in the figure $x_t$ is the displacement vector. Use the Pythagorean theorem to find it as follows
$x^2_t={\left(x_1+x_2{\cos 45{}^\circ \ }\right)}^2+{\left(x_2{\sin 45{}^\circ \ }\right)}^2$
\[\Rightarrow x^2_t={\left(6+4{\cos 45{}^\circ \ }\right)}^2+{\left(4{\sin 45{}^\circ \ }\right)}^2\] 
\[\Rightarrow x_t=9.27\ \mathrm{mile}\] 
(c) The angle of the vector $\vec{R}=R_x\,\rm\hat i+R_y\,\rm\hat j$ with respect to the positive $x$ direction is determined by $\theta ={{\tan}^{-1} \left(\frac{\left|R_y\right|}{\left|R_x\right|}\right)\ }$. Therefore ,
\[{\tan \theta \ }=\frac{x_2{\sin 45{}^\circ \ }}{x_1+x_2{\cos 45{}^\circ \ }}=\frac{4{\sin 45{}^\circ \ }}{6+4{\cos 45{}^\circ \ }}\] 
\[\Rightarrow \theta =17.8{}^\circ \] 
So the resultant vector lies in the first quadrant of the coordinate system.
(d) Velocity is a vector quantity and defines as the displacement of the particle divided by the time interval that is $\vec{\overline{v}}=\Delta \vec{x}/\Delta t$so its magnitude is 
\[\left|\vec{\overline{v}}\right|=\frac{\left|{\vec{\mathrm{x}}}_{\mathrm{t}}\right|}{\Delta t}=\frac{9.27}{\left(\frac{1}{2}+\frac{1}{3}\right)}=11.1\frac{\mathrm{m}}{s}\] 
(e) As we see from the definition of the average velocity, it is a vector in the direction of the displacement vector so its angle relative to the positive $x$ axis is same as the displacement vector that is $\theta =17.8{}^\circ $.

A ball is thrown horizontally off the edge of a cliff with an initial speed of $15\ \mathrm{m/s}$ and hits the ground $3$ seconds later.
(a) How high is the cliff?
(b) How far does the ball travel horizontally before it hits the ground?
(c) What is the magnitude of the ball's displacement?
(d) What is the speed of the ball when it hits the ground?
(e) At what angle from the vertical is the ball moving when it hits the ground?

(a) In the kinematic problems, first consider an origin then use the kinematic equations to find the desired parameters. Let the point of throw as the origin. This is projectile motion. In projectile motions, the horizontal motion is under constant velocity and vertical is under uniform acceleration $a=-g$. So in the vertical stage use the kinematic equation $y=-\frac{1}{2}gt^2+v_{0y}t+y_0$ where $y_0$ is the initial height and solve for the landing point $-y$ ( since the ball hits the ground below the origin)
\[-y=-\frac{1}{2}\left(9.8\right){\left(3\right)}^2+0\left(3\right)+0\Rightarrow y=44.1\ \mathrm{m}\] 
(b) Use the following kinematic equation, we have $x=vt=15\times 3=45\ \mathrm{m}$
(c) Use the Pythagorean theorem and find the ball's displacement as shown in the figure.
\[{\left(\Delta r\right)}^2=x^2+y^2={45}^2+{\left(44.1\right)}^2=63\ \mathrm{m}\] 
(d) First calculate its components at the moment that the ball hits the ground then use the Pythagorean theorem to find its magnitude as follows
\[v=v_0+at\to \ \left\{ \begin{array}{c}
v_x=v_{0x}=15\frac{\mathrm{m}}{\mathrm{s}} \\ 
v_y=v_{0y}-gt=0-\left(9.8\right)\left(3\right)=-29.4\frac{\mathrm{m}}{\mathrm{s}} \end{array}
\[\Rightarrow \left|v\right|=\sqrt{v^2_x+v^2_y}=\sqrt{{15}^2+{\left(-29.4\right)}^2}=33\frac{\mathrm{m}}{\mathrm{s}}\] 
(e) The angle with respect to the positive $x$ axis is determined by the following relation 
\[\theta ={{\tan}^{-1} \left(\frac{\left|v_y\right|}{\left|v_x\right|}\right)\ }={{\tan}^{-1} \left(\frac{15}{29.4}\right)\ }=27.03{}^\circ \] 
Since $v_y$ is a negative number and $v_x>0$, so the final velocity directed $27.03\,^\circ$ below the +x axis.

Kinematics in Two Dimensions
Category : Kinematics in Two Dimensions


Position vector $\vec r$ points from the origin of the coordinate system to the particle.
\[\vec r=x\hat i+y\hat j+z\hat k\]
Average velocity:
\[\vec v_{ave}=\frac{\vec r_2-\vec r_1}{t_2-t_1}=\frac{\Delta \vec r}{\Delta t}\]
Instantaneous velocity:
\[\vec v=\lim_{\Delta t \to 0} \frac {\Delta \vec r}{\Delta t}=\frac{d\vec r}{dt}\]
Average acceleration:
\[\vec a_{ave}=\frac{\vec v_2-\vec v_1}{t_2-t_1}=\frac{\Delta \vec v}{\Delta t}\]
Instantaneous acceleration:
\[\vec a=\lim_{\Delta t \to 0} \frac {\Delta \vec v}{\Delta t}=\frac{d\vec v}{dt}\]

Projectile motion:
\[a_x=0 \quad , \quad a_y=-g\]
Coordinate components:
\[x=\left(v_0\,\cos \alpha\right)t \quad , \quad y=\left(v_0\,\sin \alpha \right)t-\frac 1 2 gt^2\]
velocity components:
\[v_x=v_0\,\cos \alpha\ \quad , \quad v_y=v_0\,\sin \alpha -gt\]

Number Of Questions : 14