In the above situation the block will have maximum velocity when :

A block of mass m is released from rest onto a spring. A having stiffness k_A=mg//2h as shown in figure. If the block compresses spring B through a distance h, find the: a. stiffness of the spring B b. equilibrium position of the block c. maximum velocity of the block d. maximum acceleration of the block

A block of mass m is released from rest onto a spring. A having stiffness k_A=mg//2h as shown in figure. If the block compresses spring B through a distance h, find the: a. stiffness of the spring B b. equilibrium position of the block c. maximum velocity of the block d. maximum acceleration of the block

A block of mass m is released from rest onto a spring. A having stiffness k_A=mg//2h as shown in figure. If the block compresses spring B through a distance h, find the: a. stiffness of the spring B b. equilibrium position of the block c. maximum velocity of the block d. maximum acceleration of the block

Block A of mass M = 2 kg is connected to another block B of mass m= 1 kg with a string and a spring of force constant k = 600 N//m as shown in Fig. Initially, spring is compressed to 10 cm and whole system is moving on a smooth surface with a velocity v = 1 m//s . At any time, thread is burnt, the velocity of block A , when B is having maximum velocity w.r.t. ground, is

A block of mass 'm' is pulled by a constant power 'p' placed on a rough horizontal plane . The coefficient of friction between the block and the surface is mu . Maximum velocity of the block will be

The maximum velocity of electrons emitted from a metal surface is v when the frequecny of light falling on it is f. The maximum velocity when the frequency becomes 4f is

The maximum velocity of electrons emitted from a metal surface is v when the frequecny of light falling on it is f. The maximum velocity when the frequency becomes 4f is