The system shown in figure are in equilibrium. If the spring balance is callibroated in newtons, what does it record in each case? `(g=10 m//s^(2))`

The systems shown in are in equilibrium if the spring balance is calibrated in newtons, what does it record in each case? (g=10m//s^(2))

In the arrangement shown, the 2 kg block is held to keep the system at rest. The string and pulley are ideal. When the 2kg block is set free, by what amount the tension in the string changes? [g=10m//s^(2)]

The system shown in the figure is initially in equilibrium. A is of mass 2 m and B,C D and E are of mass m Certain actions are performed on the system. Every action has been taken individually when the system is intact. Find the direction and magnitude of acceleration of the blocks after each action of the following actions has been taken {:((i)"Spting 1 is cut",(ii)"Spring 2 is cut"),((iii)"String between C and D is cut.",(iv)"String between B and C is cut."):}

In the diamram shown in figure , match the following (g=10m//s^(2))

A block of mass 1 kg falls freely on a spring form a height of 20 cm as shown in figure . Find the compression in the spring if its force constant is 10^(3) N/m . ( Take g = 10.0 m//s^(2) )

The system shown adjacent is in equilibrium. Find the acceleration of the blocks A,B &C all of equal masses m at the instant when (Assume springs to be ideal) (i) The spring between celling & A is cut. (ii) The spring (inextensible) between A&B is cut. (iii) The speing between B & C is cut. Also find the tension in the string when the system is at rest and in the above 3 cases.

In a given figure the acceleration of M is (g=10ms^(-2))

A block tied between two identical springs is in equilibrium. If upper spring is cut then the acceleration of the block just after cut is 6m//s^(2) downwards. Now, if instead of upper spring, lower spring is being cut then the acceleration of the block just after the cut will be.

A particle is projected from a tower as shown in figure, then find the distance from the foot of the tower where it will strike the ground. (g=10m//s^(2))

The pulley arrangements shown in figure are identical, the mass of the rope being negligible. In case I the mass m is lifted by attaching a mass 2m to the other end of rope with a constant downward force F =2mg , where g is acceleration due to gravity The acceleration of mass m in case I is .