A simple pendulum performs simple harmonic motion about X = 0 with an amplitude A and time period T. The speed of the pendulum at

Q: A simple pendulum performs simple harmonic motion about $X = 0$ with an amplitude $A$ and time period $T$. The speed of the pendulum at $X = \frac{A}{2}$ will be

a (a)Velocity of a particle executing $S.H.M.$ is given by $v = \omega \sqrt {{a^2} - {x^2}} $ $= \frac{{2\pi }}{T}\sqrt {{A^2} - \frac{{{A^2}}}{4}} $ $= \frac{{2\pi }}{T}\sqrt {\frac{{3{A^2}}}{4}}$ $= \frac{{\pi A\sqrt 3 }}{T}$.

SECTION - A [PHYSICS - MCQ]

GSEB - English Medium

A simple pendulum performs simple harmonic motion about $X = 0$ with an amplitude $A$ and time period $T$. The speed of the pendulum at $X = \frac{A}{2}$ will be

A$\frac{{\pi A\sqrt 3 }}{T}$
B$\frac{{\pi A}}{T}$
C$\frac{{\pi A\sqrt 3 }}{{2T}}$
D$\frac{{3{\pi ^2}A}}{T}$

Medium

STD 11 Science
NEET
STD 11 - 13. oscillations
Physics

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