A block of mass `2 kg` is connected with a spring of natural length `40 cm` of force constant `K=200 N//m`. The cofficient of friction is `mu=0.5`. When released from the given position, acceleration of block will be

A 2kg block is connected with two springs of force constants K_(1)=100 N/m and K_(2)=300 N/m as shown in figure. The block is released from rest with the springs unstretched. Find the acceleration of the block in its lowest position (g=10 m//s^(2))

A smooth block of mass m is connected with a spring of stiffness k(=20Nm^(-1) )and natural length l_(0)=0.25 m . If the block is pulled such that the new length of the spring becomes l=0.3m , find the acceleration of the block at the moment when it is released from given positon.

A smooth block of mass m is connected with a spring of stiffness k(=20Nm^(-1) )and natural length l_(0)=0.25 m . If the block is pulled such that the new length of the spring becomes l=0.3m , find the acceleration of the block at the moment when it is released from given positon.

A 2 kg block is connected with two springs of force constants k_(1)=100 N//m and k_(2)=300 N//m as shown in figure. The block is released from rest with the springs unstretched. The acceleration of the block in its lowest postion is (g=10 m//s^(2))

A 2 kg block is connected with two springs of force constants k_(1)=100 N//m and k_(2)=300 N//m as shown in figure. The block is released from rest with the springs unstretched. The acceleration of the block in its lowest postion is (g=10 m//s^(2))

A block of mass m=5kg is resting on a rough horizontal surface for which the coefficient of friction is 0.2 . When a force F=40N is applied, the acceleration of the block will be (g=10m//s^(2)) .

A block of mass m=5kg is resting on a rough horizontal surface for which the coefficient of friction is 0.2 . When a force F=40N is applied, the acceleration of the block will be (g=10m//s^(2)) .