In the diagrm shown, all pulleys are smooth and massless and strings are light.

`{:(,"Column I",,"Column II",),((A),1 kg "block",(P),"will remains tationary",),((B),2 kg "block",(Q),"will move down",),((C ),4 kg "block",(R ),"will move up",),((D),5 kg "block",(S),"has acceleration " 10 m//s^(2),),(,,(T),"has no acceleration",):}`

In the diagram shown in figure, all pulleys are smooth and massless and string are light. Match the following columns. {:("Column I","Column II"),("(A) 1kg block","(p) will remain stationary"),("(B) 2 kg block","(q) will move down"),("(C) 3 kg block","(r) will move up"),("(D) 4 kg block",(s) 5 ms^(-2)),(,(t) 10 ms^(-2)):}

In the diagram shown in figure, both pulleys and strings are massless. The acceleration of 2 kg block is

In the diagram shown in figure, match the following (g=10 m//s^(2)) {:(,"Column-I",,,"Coloumn-II"),((A),"Acceleration of 2kg block",,(P), "8 Si unit"),((B),"Net force on 3kg block",,(Q),"25 SI unit"),((C),"Normal reaction between 2 kg and 1kg",,(R),"2 SI unit"),((D),"Normal reaction between 3 kg and 2kg " ,,(S)," 45 SI unit"),(,,,(T)," None"):}

in the figure shown all surface are smooth. Find (a)acceleration of all the blocks, (b) net force on 4kg and 10kg blocks and , ( c) force acting between 4kg and 10kg blocks.

If pulleys shown in the diagram are smooth and massless and a_(1) and a_(2) are acceleration of blocks of mass 4 kg and 8 kg respectively, then -

In the figure ( g = 10 m//s^(2) ) .Acceleration of 2kg block is :

In the system shown in figure m_(B)=4kg , and m_(A)=2kg . The pulleys are massless and friction is absent everywhere. The acceleration of block A is.

In the arrangement shown the fixed pulley is massless and frictionless. If the acceleration of block of mass 1kg is (30)/(x)m//s^(2) . Find the value of x .

A 6kg block is kept on an inclined rought surface as shown in figure. Find the force F required to (a) keep the block stationary, (b) move the block downwards with constant velocity and (c ) move the block upwards with on acceleration of 4m//s^(2) . (Take =10m//g^(2))