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Motion in Straight Line

Multiple Choice Questions

161. 'Parsec' is the unit of'

time
distance
frequency
angular acceleration

162.

When a ball is thrown up vertically with velocity v_o, it reaches a maximum height of h. If one wishes triple the maximum height then the ball should be thrown with velocity

$\sqrt{3}$ v_o
3v_o
9v_o
3/2 v_o

163.

A person is standing in an elevator. In which situation he finds his weight less?

When the elevator moves upward with constant acceleration
When the elevator moves downward with constant acceleration
When the elevator moves upward with uniform velocity
When the elevator moves downward with uniform velocity

164.

Using mass (M), length (L), time (T) and current (A) as fundamental quantities, the dimension of permittivity is

[ M L^-2 T² A ]
[ M^-1 L^-3 T⁴ A² ]
[ M L T^-2 A]
[ M L² T^-1 A² ]

165.

A body starting from rest moves along a straight line with a constant acceleration. The variation of speed (v) with distance ( s ) is represented by the graph

166.
A particle starts from rest and has an acceleration of 2 m/s² for 10 sec. After that, it travels for 30 sec with constant speed and then undergoes a retardation of 4 m/s² and comes back to rest. The total distance covered by the particle is

650 m

750 m

700 m

800 m

750 m

Initial velocity ( u ) = 0

Acceleration ( $α_{1}$ ) = 2 m/s²

time during acceleration (t₁) = 10 sec

Time during constant velocity (t₂ ) = 30 sec

and retardation ( $α_{2}$ ) = $-$ 4 m/s²

( negative sign due to retardation )

Distance covered by the particle during acceleration

s₁ = ut₁ + $\frac{1}{2}$ $α_{1}$ $t_{1}^{2}$

= ( 0 × 10 ) + $\frac{1}{2}$ × 2 × (10)²

s₁ = 100 m ......(i)

And velocity of the particle a the end of acceleration

v = u + $\frac{1}{2} α_{1} t_{1}^{2}$

= 0 + ( 2 × 10 )

v = 20 m/s

Therefore distance covered by the particle during constant velocity

s₂ = v × t₂

= 20 × 30⇒

s₂ = 600 m .....(ii)

Relation for the distance covered by the particle during retardation ( s₃) is

v² = u² + 2 $α_{2}$ s₃

⇒ ( 0 )² = ( 20 )² + 2 × ( $-$ 4 ) × s₃

⇒ 400 = 8 s₃

⇒ s₃ = $\frac{400}{8}$

⇒ s₃ = 50 m

Therefore total distance covered by the particle

s = s₁ + s₂ + s₃

= 100 +600 + 50

s = 750 m

167.

Speed in kilometre per hour in S.I unit is represented as

KMPH
Kmhr^-1
Kmh^-1
kilometre/hour

168.

S.I unit of velocity is

ms
m sec^-1
m hr^-1
m/hr

169.

A particle moving with velocity (1/10)th of light will cross a nucleus in about

10^-8 s
10^-12 s
10^-47 s
10^-21 s

170.

A coin is dropped in a lift. It takes time t₁ to reach the floor when the lift is stationary. It takes times t₂ when the lift is moving up with constant acceleration. Then:

t₁ > t₂
t₂ > t₁
t₁ = t₂
t₁ >> t₂

Previous Year Papers

Test Series

Test Yourself

Multiple Choice Questions

166. A particle starts from rest and has an acceleration of 2 m/s2 for 10 sec. After that, it travels for 30 sec with constant speed and then undergoes a retardation of 4 m/s2 and comes back to rest. The total distance covered by the particle is 650 m 750 m 700 m 800 m

166.
A particle starts from rest and has an acceleration of 2 m/s² for 10 sec. After that, it travels for 30 sec with constant speed and then undergoes a retardation of 4 m/s² and comes back to rest. The total distance covered by the particle is

650 m

750 m

700 m

800 m