A small ball of mass m is thrown upward with velocity u from the ground. The ball experiences a resistive force `mkv^(2)` where v is its speed. The maximum height attained by the ball is :

A ball is thrown with velocity V_0 from ground in vertical upward direction, if particle experiences resistance force mkv^2 . where v is the speed of particle, m mass of the particle and k is a positive constant. Find maximum height reached.

A ball is thrown with velocity V_0 from ground in vertical upward direction, if particle experiences resistance force mkv^2 . where v is the speed of particle, m mass of the particle and k is a positive constant. Find maximum height reached.

A ball is thrown vertically upwards with a velocity of 10 ms^(-1) . It returns to the ground with a velocity of 9 ms^(-1) . If g=9.8 ms^(-2) , then the maximum height attained by the ball is nearly (assume air resistance to be uniform)

A ball is thrown vertically upwards with a velocity of 10 ms^(-1) . It returns to the ground with a velocity of 9 ms^(-1) . If g=9.8 ms^(-2) , then the maximum height attained by the ball is nearly (assume air resistance to be uniform)

A ball is thrown vertically upward with speed 10 m//s and it returns to the ground with speed 8 m//s . A constant air resistance acts. The minimum height attained by the ball is

A ball of mass m is thrown upward with a velocity upsilon . If air exerts an average resisting force F, the velocity with which the ball returns to the thrower is

A ball of mass m is thrown upward with a velocity upsilon . If air exerts an average resisting force F, the velocity with which the ball returns to the thrower is

A ball is thrown upward with an initial velocity of 100 ms^(-1) . After how much time will it return ? Draw velocity -time graph for the ball and find the maximum height attained by the ball. [Assume, g = - 10 ms ^ { - 2 } ]