How to Find the Moment of Inertia of a Semicircular Rod?

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Homework Help Overview

The discussion revolves around finding the moment of inertia of a semicircular rod with constant density when revolved around the x-axis. The original poster expresses uncertainty about how to start the problem, particularly in visualizing the shape and applying the relevant concepts.

Discussion Character

  • Exploratory, Conceptual clarification, Mathematical reasoning

Approaches and Questions Raised

  • Participants discuss the definition of moment of inertia and its application to a thin rod, questioning how it differs for a curved rod. There are inquiries about the integration process needed to find the moment of inertia for the semicircular shape.

Discussion Status

Some participants have provided guidance on starting points, including the definition of moment of inertia and the suggestion to visualize the shape. There is an ongoing exploration of the integration required and the use of polar coordinates for the problem.

Contextual Notes

Participants note the need for a clearer understanding of the shape and the integration process, with some uncertainty about the appropriate expressions for mass and radius in this context.

sunniexdayzz
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Find the moment of inertia when the wire of constant density shaped like the semicircle
y=sqrt(r^2-x^2)
where r is the radius
is revolved around the x-axis

I don't even know where to begin =[
 
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sunniexdayzz said:
Find the moment of inertia when the wire of constant density shaped like the semicircle
y=sqrt(r^2-x^2)
where r is the radius
is revolved around the x-axis

I don't even know where to begin =[

Welcome to the PF. Start with the definition of the Moment of Inertia. What is it in the general case?

I'm also having a little trouble visualizing the shape... is there any way you can sketch it?
 
the general case for a thin rod is I=\int(mr^2)
with m=mass and r=radius

but I don't know what it is for a curved rod. The rod in the problem is a semi circle about the origin in quadrants I and II with radius r
 
You have to do the integration from the definition of moment of inertia.

<br /> I\ =\ \int dm\ r^2\ <br />

Some tips: dm can be expressed in terms of linear density dm\ = \rho d\theta, with theta in play due to it being easier in this case to use polar co-ordinates.
 

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