Question #8efea

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Question #8efea

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Answer 1 · 2016-08-03T17:18:54

The ball is $\frac{3 h}{4}$ $(3h)/4$ meters from the ground at $t = \frac{T}{2}$ $t = T/2$

Explanation:

I'm neglecting air resistance, but can add it in upon request. The body moves in only one dimension, which we shall call $y$ $y$ . We shall define the origin of our coordinate system at the ground ( $y = 0$ $y=0$ ) and the initial position of the body $y (0) = h$ $y(0) = h$ . As is the usual convention we define upwards as positive.

Without air resistance, the only force acting on the body will be gravity - this acts in the negative y direction to provide an unbalanced force which we can use Newton's second law on:

$m \frac{d^{2} y}{{d t}^{2}} = - m g$ $m(d^2y)/(dt^2) = -mg$

$\frac{d^{2} y}{{d t}^{2}}$ $(d^2y)/(dt^2)$ represents acceleration in the y direction.

If you are unfamiliar with using calculus to solve problems like this then skip to the blue heading, this is just the derivation of a formula common to introductory dynamics.

$therefore (d^2y)/(dt^2) = -g$

Integrating wrt t gives:

$(dy)/(dt) = -g t + C$

The body starts from rest so $y'(0) = 0$ .

$implies C =0$

$(dy)/(dt) = -g t$

Integrate again wrt t:

$y(t) = -1/2g t^2 + C$

$y(0)= h = C$

$implies y(t) = h - 1/2g t^2$

This is our expression for the displacement from the origin as a function of time. Notice it's very similar to the common expression

$s = v_0t + 1/2at^2$

which describes displacement under constant acceleration. This is because it is the exact same derivation, we have just accounted for the fact that initial speed is zero while doing it.

$color(blue)("Skip To Here")$

Anyway, onto solving the problem:

$y(t) = h - 1/2g t^2$

If it takes T seconds to reach the ground, $y(T) = 0$ .

$y(T) = 0 = h - 1/2gT^2$

$implies h = 1/2gT^2$

$T^2 = (2h)/g$

$T = sqrt((2h)/g)$

Note that we discard the negative solution from the square root because negative time doesn't really make sense.

$T/2 = 1/2sqrt((2h)/g) = sqrt(h/(2g))$

$y(T/2) = h - 1/2g (sqrt(h/(2g)))^2$

$y(T/2) = h - 1/2g(h/(2g)) = h - h/4 = (3h)/4$

Answer 2 · 2016-08-04T01:02:49

The body is at $h/4 m$ from the top of tower.

Explanation:

Kinematic equation for the body dropped from a height $h$ is
$h=ut+1/2g t^2$
where $u,g and t$ are initial velocity, acceleration due to gravity and time taken to reach ground respectively.
Inserting given values we get
$h=0xxT+1/2g T^2$
$=>h=1/2g T^2$ .......(1)

Similarly height $h_1$ dropped in time $T/2$ is
$h_1=1/2g (T/2)^2$
$=>h_1=1/8g T^2$ ......(2)
Dividing (2) by (1) we get
$h_1/h=1/4$

$=>h_1=h/4$

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