7.) Determine the initial velocity v so that its maximum height reached will be exactly 400 feet.

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asked Aug 1, 2019 49.7k views

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Lionet Chen · Answer 1 · 2019-08-01T19:46:32+0000

totally different way by using kinematic eqns

height = init vel * t + 1/2 * accel * t^2

and

final vel ^2 = init vel ^2 + 2 * accel * height

given h(t) = vt - 16t^2

accel = -16*2 = -32

at max height=400, final vel = 0

0 = v^2 + 2 * (-32) * 400

v^2 = 25600

v = 160 feet per second

Monte · Answer 2 · 2019-08-06T15:53:44+0000

The derivative of height with respect to time is
h'(t) = -32t +v
This will be zero when
0 = -32t +v
t = v/32

The height at this time is
h(v/32) = -16(v/32)² + v(v/32) = (v²)(-1/(2·32) +1/32) = v²/64
Setting this to 400, we get
400 = v²/64
v = √(64·400) = 160

The initial velocity required so that the maximum height is exactly 400 feet is
160 ft/s.

7.) Determine the initial velocity v so that its maximum height reached will be exactly-example-1

7.) Determine the initial velocity v so that its maximum height reached will be exactly 400 feet.

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