From the top of a tower, a ball is thrown vertically upward which reaches the ground in 6 s. A second ball thrown vertically downward from the same position with the same speed reaches the ground in 1.5 s. A third ball released, from the rest from the same location, will reach the ground in ____ s.
From the top of a tower, a ball is thrown vertically upward which reaches the ground in 6 s. A second ball thrown vertically downward from the same position with the same speed reaches the ground in 1.5 s. A third ball released, from the rest from the same location, will reach the ground in ____ s.
Correct Answer: 3
Solution and Explanation
For case-I : 2nd equations=ut+\(\frac{1}{2}at^2\)
H=−u(6)+\(\frac{1}{2}\)g(6)2 H=−6u+18g…(i)
For case-II : h=u(1.5)+\(\frac{1}{2}\)g(1.5)2h=1.5u+\(\frac{2.25g}{2}\)…(ii)Multiplying equation (ii) by 4 we get 4h=6u+4.5 g…(iii)
equation (i) + equation (iii)
we get 5h = 22.5gh=4.5 g… (iv)
For case-III :h=0+\(\frac{1}{2}\)gt2…(v)Using equation (4) & equation (5) 4.5g=\(\frac{1}{2}\)gt2 t2=9⇒t=3s
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Concepts Used:
Relative Velocity
The velocity with which one object moves with respect to another object is the relative velocity of an object with respect to another. By relative velocity, we can further understand the time rate of change in the relative position of one object with respect to another.
It is generally used to describe the motion of moving boats through water, airplanes in the wind, etc. According to the person as an observer inside the object, we can compute the velocity very easily.
The velocity of the body A – the velocity of the body B = The relative velocity of A with respect to B
V_{AB} = V_{A} – V_{B}
Where,
The relative velocity of the body A with respect to the body B = V_{AB}
The velocity of the body A = V_{A}
The velocity of body B = V_{B}