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Question
The surface density (mass/area) of a circular disc of radius a depends on the distance from the centre as [rholeft( r right) = A + Br.] Find its moment of inertia about the line perpendicular to the plane of the disc thorough its centre.
Solution
Consider a ring of thickness dx at a distance r from the centre of the disc.
Mass of the ring,
\[dm = \left( A + Br \right) \times 2\pi r \times dr\]
Therefore, moment of inertia about the centre,
\[I = \int_0^a r^2 dm\]
\[= \int_o^a d\left( A + Br \right) 2\pi r . dr \times r^2 \]
\[ = \int_o^a 2\pi A r^3 dr + \int_o^a 2\pi B r^4 dr\]
\[ = \left[ 2\pi A \left( \frac{r^4}{4} \right) + 2\pi B \left( \frac{r^5}{5} \right) \right]_0^a \]
\[ = 2\pi\left( \frac{A a^4}{4} + \frac{B a^5}{5} \right)\]
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