An object is launched at 20 m/s from a height of 65 m. The equation for the height (h) in terms of time (t) is given by h(t) = -4.9t² + 20t + 65. What is the object's maximum height? the numeric answer only, rounded to the nearest meter.

To answer the question above,first you have to take the derivative of the h(t) function and set it equal to zero , then solve for t to find the time when the object is at its maximum height :

h ' (t) = - 9.8 t + 20

- 9.8 t + 20 = 0

- 9.8 t = - 20

t = ( - 20 / - 9.8 ) = 2.04 seconds

(I will round that to 2.0 seconds, which is acceptable because of the significant figures used in the question, but I won't go into that.)

So the object reaches max. height at t = 2

Put that value of t into the original h(t) function to find the height at time t = 2 :

h(2) = ( - 4.9 * 2 ) + ( 20 * 2 ) + 65

h(2) = ( - 9.8 + 40 + 65 ) = 95.2 meters.

aristocles aristocles · Answer 2 · 2019-07-16T02:42:51+02:00

Answer:

Maximum height will be 85 meter

Explanation:

given that height of an object is function of time and it is given as

[tex]h(t) = -4.9 t^2 + 20t + 65[/tex]

here we can write it as

[tex]h(t) - 65 = 20 t + \frac{1}{2}(-9.8) t^2[/tex]

now we can compare it with the kinematics equation

[tex]y(t) - y_o = v_i t + \frac{1}{2}at^2[/tex]

now if we compare the two equations then we will have

initial height of object = 65 m

initial velocity of projection = 20 m/s

acceleration = - 9.8 m/s/s

now for the maximum height at which its final speed will become zero is given as

[tex]v_f^2 - v_i^2 = 2a(h - h_o)[/tex]

[tex]0 - 20^2 = 2(-9.8)(h - 65)[/tex]

[tex]-400 = -19.6(h - 65)[/tex]

[tex]h = 85.4 m[/tex]

So maximum height in meter in nearest integer will be 85 m