Chapter 4, Problem 44AP

A projectile is launched from the point (x = 0, y = 0), with velocity $(12.0\hat{i}-19.0\hat{j})\text{m}/{\text{s}}^2$, at t = 0. (a) Make a table listing the projectile’s distance $\left|\stackrel{\to }{r}\right|$ from the origin at the end of each second thereafter, for 0 ≤ t ≤ 10 s. Tabulating the x and y coordinates and the components of velocity v_x and v_y will also be useful. (b) Notice that the projectile’s distance from its starting point increases with time, goes through a maximum, and starts to decrease. Prove that the distance is a maximum when the position vector is perpendicular to the velocity. Suggestion: Argue that if $\stackrel{\to }{v}$ is not perpendicular to $\stackrel{\to }{r}$, then $\left|\stackrel{\to }{r}\right|$ must lie increasing or decreasing. (c) Determine the magnitude of the maximum displacement. (d) Explain your method for solving part (c).

To determine

The values of the projectile distance $\left|\overrightarrow{\text{r}}\right|$ for each second for $0\le t\le 10\text{s}$ and tabulate the values for $0\le t\le 10\text{s}$.

Answer to Problem 44AP

The table for the values of $\left|\overrightarrow{\text{r}}\right|$ for $0\le t\le 10\text{s}$ is,

$t$ $\left(\sec \right)$	$\left|\overrightarrow{\text{r}}\right|$ $\left(\text{m}\right)$
0	0
1	45.7
2	82.0
3	109
4	127
5	136
6	138
7	133
8	124
9	117
10	120

Explanation of Solution

Given info: The initial position of the projectile is $\left(x=0,y=0\right)$, the velocity of the projectile at $t=0$ is $12.0\widehat{\text{i}}+49.0\widehat{\text{j}}$.

The value of the acceleration due to gravity is $9.8\text{m}/{\text{s}}^2$.

The formula to calculate the $x$ coordinate of the projectile is,

$x\left(t\right)=u_{\text{x}}t+\frac{1}{2}{a}_{\text{x}}{t}^2$

Here,

$u_{\text{x}}$ is the $x$ component of the initial velocity.

$a_{\text{x}}$ is the acceleration in the $x$ direction.

$t$ is the time.

In a vertical projectile the acceleration in $x$ direction is zero.

Substitute $12.0$ for $u_{\text{x}}$, $0$ for $a_{\text{x}}$ in the above equation.

$\begin{array}{c}x\left(t\right)=12.0t+\frac{1}{2}\left(0\right)t^2\\ =12.0t\end{array}$

Thus, the $x$ coordinate of the position vector is $12.0t$.

The formula to calculate the $y$ coordinate of the projectile is,

$y\left(t\right)=u_{\text{y}}t+\frac{1}{2}{a}_{\text{y}}{t}^2$

Here,

$u_{\text{y}}$ is the $y$ component of the initial velocity.

$a_{\text{y}}$ is the acceleration in the $y$ direction.

$t$ is the time.

For the vertical projectile the acceleration in $y$ direction is the acceleration due to gravity.

Substitute $49.0$ for $u_{\text{y}}$, $-9.8\text{m}/{\text{s}}^2$ for $a_{\text{y}}$ in the above equation.

$\begin{array}{c}y\left(t\right)=\left(49.0\right)t+\frac{1}{2}\left(-9.8{\text{m}/\text{s}}^2\right)t^2\\ =\left(49.0\right)t-\left(4.9{\text{m}/\text{s}}^2\right)t^2\end{array}$

Thus, the $y$ coordinate of the position vector is $\left(49.0\right)t-\left(4.9{\text{m}/\text{s}}^2\right)t^2$.

The formula to calculate the magnitude of the position vector is,

$\left|\overrightarrow{\text{r}}\right|=\sqrt{x^2+y^2}$

Substitute $12.0t$ for $x$ and $\left(49.0\right)t-\left(4.9{\text{m}/\text{s}}^2\right)t^2$ for $y$ in the above equation.

$\left|\overrightarrow{\text{r}}\right|=\sqrt{{\left(12.0t\right)}^2+{\left[\left(\left(49.0\right)t-\left(4.9{\text{m}/\text{s}}^2\right)t^2\right)\right]}^2}$

For $0\le t\le 10\text{s}$, the table of the values of $\left|\overrightarrow{\text{r}}\right|$ is shown in the table below.

$t$ $\left(\sec \right)$	$\left|\overrightarrow{\text{r}}\right|$ $\left(\text{m}\right)$
0	0
1	45.7
2	82.0
3	109
4	127
5	136
6	138
7	133
8	124
9	117
10	120

Conclusion:

Therefore, the table for the values of $\left|\overrightarrow{\text{r}}\right|$ for $0\le t\le 10\text{s}$ is,

$t$ $\left(\sec \right)$	$\left|\overrightarrow{\text{r}}\right|$ $\left(\text{m}\right)$
0	0
1	45.7
2	82.0
3	109
4	127
5	136
6	138
7	133
8	124
9	117
10	120

To determine

To show: The distance is maximum when the position vector is perpendicular to the velocity.

Answer to Problem 44AP

The distance is maximum when the position vector is perpendicular to the velocity.

Explanation of Solution

Given info: The initial position of the projectile is $\left(x=0,y=0\right)$, the velocity of the projectile at $t=0$ is $12.0\widehat{\text{i}}+49.0\widehat{\text{j}}$.

The velocity vector tells about the change in the position vector. If the velocity vector at particular point has a component along the position vector and the velocity vector makes an angle less than $90°$ with position vector, then the position vector is increasing in magnitude and if the angle is greater than $90°$ the magnitude of the position vector starts decreasing.

For the position vector to be maximum the distance from the origin must be momentarily at rest or constant and the only possible situation for this is that the velocity vector makes an angle $90°$ with the position vector.

Conclusion:

Therefore, the distance is maximum when the position vector is perpendicular to the velocity vector.

To determine

The magnitude of the maximum displacement.

Answer to Problem 44AP

The magnitude of the maximum displacement is $138\text{m}$.

Explanation of Solution

Given info: The initial position of the projectile is $\left(x=0,y=0\right)$, the velocity of the projectile at $t=0$ is $12.0\widehat{\text{i}}+49.0\widehat{\text{j}}$.

The expression for the position vector is,

$\left|\overrightarrow{\text{r}}\right|=\sqrt{{\left(12.0t\right)}^2+{\left[\left(\left(49.0\right)t-\left(4.9{\text{m}/\text{s}}^2\right)t^2\right)\right]}^2}$ (1)

Square both the sides of the above equation.

${\left|\overrightarrow{\text{r}}\right|}^2={\left(12.0t\right)}^2+{\left[\left(\left(49.0\right)t-\left(4.9{\text{m}/\text{s}}^2\right)t^2\right)\right]}^2$

Differentiate the above expression with respect to $t$ to calculate the maxima condition for $r^2$.

$\frac{d}{dt}{\left|\overrightarrow{\text{r}}\right|}^2=\frac{d}{dt}\left[{\left(12.0t\right)}^2+{\left[\left(\left(49.0\right)t-\left(4.9{\text{m}/\text{s}}^2\right)t^2\right)\right]}^2\right]$

For the maxima condition to calculate the value the value of $t$ for which $r^2$ is maximum substitute $0$ for $\frac{d}{dt}{\left|\overrightarrow{\text{r}}\right|}^2$.

$\begin{array}{c}0=\frac{d}{dt}\left[{\left(12.0t\right)}^2+{\left[\left(\left(49.0\right)t-\left(4.9\right)t^2\right)\right]}^2\right]\\ =24.0t+\left[\left(98.0t-\left(9.8t^2\right)\right)\left(49.0-9.8\text{t}\right)\right]\end{array}$

Further solve the above expression for $t$.

$\begin{array}{c}96.04{\text{t}}^3-1440.6t^2+4826t=0\\ 96.04{\text{t}}^2-1440.6t+4826=0\end{array}$

Further solving the above quadratic equation the values of $t$ are $5.70\text{s }$ and $9.9\text{s}$.

From the table in Part (a) it is evident that after $6\text{s}$ the distance starts to decrease therefore, for $t=9.9\text{s}$ the position vector does not has maximum magnitude.

Thus, the maximum value of $\overrightarrow{\text{r}}{\left(t\right)}^2$ is at $t=5.70\text{s}$, therefore the maximum value of $\overrightarrow{\text{r}}\left(t\right)$ is also at $t=5.70\text{s}$.

Substitute $5.70\text{s}$ for $t$ in equation (1).

$\begin{array}{c}{\left|\overrightarrow{\text{r}}\right|}_{\text{max}}=\sqrt{{\left(12.0\left(5.70\text{s}\right)\right)}^2+{\left[\left(\left(49.0\right)\left(5.70\text{s}\right)-\left(4.9{\text{m}/\text{s}}^2\right){\left(5.70\text{s}\right)}^2\right)\right]}^2}\\ =138.21\text{m}\\ \approx \text{138}\text{m}\end{array}$

Conclusion:

Therefore, the maximum distance is $\text{138}\text{m}$.

To determine

To write: The explanation for the method used in part (c) calculation.

Answer to Problem 44AP

The maxima and minima condition is used to calculate the maximum magnitude of the position vector.

Explanation of Solution

Given info: The initial position of the projectile is $\left(x=0,y=0\right)$, the velocity of the projectile at $t=0$ is $12.0\widehat{\text{i}}+49.0\widehat{\text{j}}$.

The maximum or minimum value of any function is easily calculated using the Maxima and Minima condition.

For the part (c) first calculate the critical points by equating the differential of $r^2$ to zero to find the values of $t$ for which has the maximum value.

$\frac{d}{dt}{r}^2=0$

The value of $t$ where $r^2$ is maximum has also the maximum value at the same $t$.

Substitute the maximum value of $r$ in the above expression to calculate the maximum magnitude of the position vector.

Conclusion:

Therefore, the maxima and minima condition is used to calculate the maximum magnitude of the position vector.