A particle is moving with kinetic energy E and momentum p. Which of the following graphs is possible between $\sqrt{E}$ and $\frac{1}{p}$?

1.  

2.  

3.  

4.  

Two vehicles are moving with the same kinetic energy. If the ratio of their masses is 1 : 3 then find the ratio of their stopping distances when both vehicles stop with the same retardation.

(1)  1: 1

(2)  3: 1

(3)  9: 1

(4)  1: 9

Two blocks having equal masses stick together after the collision. If their combined velocity after the collision is equal to the arithmetic mean velocity of them before the collision, then the coefficient of restitution is:

(1)  Zero

(2)  0.5

(3)  0.8

(4)  1

If the work done by the string on block A is W. Then work done by the string on the block B will be

(1)  -W

(2)  $-\frac{\mathrm{W}}{2}$

(3)  2W

(4)  Zero

If the pulley system with the ideal mechanical advantage of 4 requires a force of 15 N to lift a load of 45 N, then the efficiency of the pulley is

(1)  25%

(2)  30%

(3)  40%

(4)  75%

Choose incorrect statement about the oblique collision of two bodies.

(1)  The momentum of each body is conserved along the tangent.

(2)  The momentum of the system is conserved.

(3)  The momentum of each body is conserved along common normal.

(4)  Coefficient of restitution is considered along the common normal.

A small block of mass \(m\) is pulled by a light rope on a quarter circular track, having radius \(R\). If the force applied on the rope is \(F\) always directed horizontally, then the work done by the force till the block reaches from \(A\) to \(B\) is:

1. \(FR\)
2. \(FR\sqrt{2}\)
3. \(2\pi F R\)
4. zero

A stone of mass m is thrown from the earth's surface at an angle $\mathrm{\alpha }$ to the horizontal with an initial velocity ${\mathrm{v}}_0$. Ignoring the air drag, the power developed by gravitational force t second after the beginning of motion is:

(1)  $\mathrm{mg}\left(\mathrm{gt}<mspace\; width="1em"></mspace>-<mspace\; width="1em"></mspace>{\mathrm{v}}_0\mathrm{sin\alpha }\right)$

(2)  ${\mathrm{mgv}}_0\mathrm{sin\alpha }·\mathrm{t}$

(3)  $\mathrm{mg}\left(\mathrm{g}<mspace\; width="1em"></mspace>-<mspace\; width="1em"></mspace>\mathrm{vsin\alpha }·\mathrm{t}\right)$

(4)  Zero

An ideal horizontal spring has been compressed by two masses of 1 kg and 4 kg at its ends placed on a frictionless table. The stored energy is 40 joule. If the spring is released, the lighter mass will acquire a speed of:

(1)  2 m/s

(2)  4 m/s

(3)  8 m/s

(4)  16 m/s

A car of mass 100 kg and traveling at 20 m/s collides with a truck weighing 1 tonne traveling at 9 km/h in the same direction. The car bounces back at a speed of 5 m/s. The speed of the truck after the impact will be:

1.  11.5 m/s

2.  5 m/s

3.  18 m/s

4.  12 m/s