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Question: Natural frequency of a simple pendulum depends on- (A). it’s mass (B). its length (C). square ...

Natural frequency of a simple pendulum depends on-
(A). it’s mass
(B). its length
(C). square of its length
(D). square root of inverse of its length

Explanation

Solution

The motion of a simple pendulum is a periodic motion about its mean position. Its natural frequency is provided by the component of gravitational force acting on it. This means that in the absence of friction, it will continue to oscillate with its natural frequency. Applying Newton’s second law, we can find an equation for the motion of a simple pendulum.
Formulas Used:
τ=Iα\tau =I\alpha
τ=Fr\tau =Fr

Complete answer:
A simple pendulum is a system in which a point mass is suspended from a rod of negligible mass or a string. When displaced from its mean position, it swings and displaces about a mean position and follows a periodic motion. Applying Newton’s second law to the rotational motion of simple pendulum, we get,
τ=Iα\tau =I\alpha - (1)
Here,
τ\tau is the torque acting on the pendulum
IIis the moment of inertia
α\alpha is angular acceleration
Also,
τ=Fr\tau =Fr - (2)
Here, FFis the force acting on the body
rris distance from axis of rotation

Also torque is provided by the component of mg-mgcosθmg\,\cos \theta
Therefore, from eq (1) and eq (2), we get,
mL2d2θdt2=(mgsinθ)Lm{{L}^{2}}\dfrac{{{d}^{2}}\theta }{d{{t}^{2}}}=-(mg\,\sin \theta )L [I=mL2I=m{{L}^{2}} and α=d2θdt2\alpha =\dfrac{{{d}^{2}}\theta }{d{{t}^{2}}} ]
Rearranging the above equation as-
d2θdt2+gsinθL=0\dfrac{{{d}^{2}}\theta }{d{{t}^{2}}}+\dfrac{g\,\sin \theta }{L}=0
If θ<<1 sinθθ \begin{aligned} & \theta <<1 \\\ & \Rightarrow \,\sin \theta \approx \theta \\\ \end{aligned}
Therefore, the above equation will be-
d2θdt2+gθL=0\dfrac{{{d}^{2}}\theta }{d{{t}^{2}}}+\dfrac{g\,\theta }{L}=0 [Equation for simple harmonic motion]
the above equation reduces to the equation of simple harmonic motion
In simple harmonic motion, change in phase takes place as-
θ(t)=θ0cos(ωt+ϕ)\theta (t)={{\theta }_{0}}\cos (\omega t+\phi )
Here, θ\theta is the angle with which the pendulum gets displaced about its mean position
ω\omega is the angular velocity
ttis time taken
The angular velocity in simple harmonic motion is given by-

& \omega =\sqrt{\dfrac{g}{L}} \\\ & \therefore f=\dfrac{1}{2\pi }\sqrt{\dfrac{g}{L}} \\\ \end{aligned}$$ $$f=\dfrac{1}{2\pi }\sqrt{\dfrac{g}{L}}$$ is the natural frequency of the motion of a simple pendulum The natural frequency is $$f=\dfrac{1}{2\pi }\sqrt{\dfrac{g}{L}}$$ and it depends on square root of inverse of its length., **So the correct option is (D).** **Note:** Harmonic motion is the motion about an equilibrium position such that the maximum displacement on both sides of the mean position is equal. In this type of motion, the restoring force towards the equilibrium position is directly proportional to the negative of maximum displacement.