In the diagram shown in figure, match the following columns (take `g=10 ms^(-2)`)

`{:("Column I","Column II"),("(A) Normal reaction","(p) 12 SI unit"),("(B) Force of friction","(q) 20 SI unit"),("(C) Acceleration of block","(r) zero"),(,"(s) 2 SI unit"):}`

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 diagram shown in figure. Match the following columns. {:("Colmun I","Column II"),("(A) Absolute acceleration of 1 kg block",(p) 11 ms^(-2)),("(B) Absolute acceleration of 2 kg block",(q)6 ms^(-2)),("(C) Relative acceleration between the two",(r) 17 ms^(-2)),(,(s) "None"):}

A balloon rises up with constant net acceleration of 10 m//s^(2) . After 2 s a particle drops from the balloon. After further 2 s match the following : ("Take" g=10 m//s^(2)) {:(,"Column I",,,"Column II"),((A),"Height of perticle from ground",,(p),"Zero"),((B),"Speed of particle",,(q),10 SI "units"),((C),"Displacement of Particle",,(r),40 SI "units"),((D),"Acceleration of particle",,(s),20 SI "units"):}

Match the following columns. {:("Column I","Column II"),("(A) Force of friction","(p) Oppose motion"),("(B) Normal reaction on a block kept on horizontal ground","(q) Oppose relative motion"),(,"(r) Is always mg"),(,"(s) May be equal to mg"),(,"(t) None"):}

For the velocity -time graph shown in figure, in a time interval from t=0 to t=6 s , match the following: {:(,"Column I",,,"Column II"),((A),"Change in velocity",,(p),-5//3 SI "unit"),((B),"Average acceleration",,(q),-20 SI "unit"),((C),"Total displacement",,(r),-10 SI "unit"),((D),"Acceleration ay t=3s",,(s),-5 SI "unit"):}

A particle of mass 1 kg is projected upwards with velocity 60ms^(-1) . Another particle of mass 2kg is just dropped from a certain height. After 2s, match the following. [Take, g =10 ms^(-2)] {:("column1","column2"),("Accelertion of CM","P Zero"),("B Velocity of CM","Q 10 SI unit"),("C Displacement of CM","R 20 SI unit"),("-","S None"):}

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 s-t equation (s=10+20 t-5t^(2)) match the following columns. |{:(,"Column I",,"Column II"),((A),"Distancec travelled in 3s",(p),-20" units"),((B),"Displacement 1 s",(q),15" units"),((C ),"Initial acceleration",(r ),25" units"),((D),"Velocity at 4 s",(s),-10" units"):}|

In the diamram shown in figure , match the following (g=10m//s^(2)) Column I Column II (P) Acceleration of 2 k g block (in m / s 2 ) (1) 5 (Q) Acceleration of 3 k g block (in m / s 2 ) (2) 50 (R) Normal reaction between 2 k g and 3 k g (in N) (3) 45 (S) Normal reaction between 3 k g and 5 k g (in N) (4) 60

In the arrangement shown in figure match the following {:("column1","column2"),("A Velocities of center of mass","P 2SI unit"),("B Velocity of combined mass when compression in the spring is maximum","Q 1 SI unit"),("C Maximum compression in the spring","R 4 SIunit"),("D Maximum potential energy stored in the spring","S 0.5SI unit"):}