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4
Advanced/Geometry of Masses/main.tex
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@ -28,7 +28,7 @@
\input{parts/0 balance 1d.tex}
\input{parts/1 balance 2d.tex}
%\input{parts/1 continuous}
%\input{parts/2 pappus}
\input{parts/1 continuous}
\input{parts/2 pappus}
\end{document}

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Advanced/Geometry of Masses/parts/2 pappus.tex
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@ -7,25 +7,31 @@
\label{pappus1}
\end{figure}
\remark{}
\textit{Centroids} are closely related to, and often synonymous with, centres of mass. A centroid is the geometric centre of an object, regardless of the mass distribution. Thus, the centroid and centre of mass coincide when the mass is uniformly distributed.
\remark{}
Figure \ref{pappus1} depicts three different surfaces constructed by revolving a line segment (in red) about a central axis. These are often called \textit{surfaces of revolution}.
\problem{}
\textit{Pappus's First Centroid Theorem} allows you to determine the area of a surface of revolution using information about the line segment and the axis of rotation.
Can you intuitively come up with Pappus's First Centroid Theorem for yourself? Figure \ref{pappus1} is very helpful. It may also help to draw from surface area formulae you already know. What limitations are there on the theorem?
Can you intuitively come up with Pappus's First Centroid Theorem for yourself? Figure \ref{pappus1} is very helpful. It may also help to draw from surface area formulae you already know. What limitations are there on the theorem?
\vfill
\pagebreak
\problem{}
\textit{Pappus's Second Centroid Theorem} simply extends this concept to \textit{solids of revolution}, which are exactly what you think they are.
Now that you've done the first theorem, what do you think Pappus's Second Centroid Theorem states?
\problem{}
Now that you've done the first theorem, what do you think Pappus's Second Centroid Theorem states?
\vfill
The centroid of a semi-circular line segment is already given in Figure \ref{pappus1}, but what about the centroid of a filled semi-circle? (Hint: For a sphere of radius $r$, $V=\frac{4}{3}\pi r^3$)
\problem{}
The centroid of a semi-circular line segment is already given in Figure \ref{pappus1}, but what about the centroid of a filled semi-circle? (Hint: For a sphere of radius $r$, $V=\frac{4}{3}\pi r^3$)
\begin{figure}[htp]
\centering
@ -40,18 +46,21 @@ Figure \ref{pappus1} depicts three different surfaces constructed by revolving a
\pagebreak
Using your answers from Problem \ref{isosceles centroid} and Problem \ref{arc centroid}. Where is the centroid of the \textit{sector} of the circle in Figure \ref{arc}. (Hint: Cut it up.)
\problem{}
Using your answers from Problem \ref{isosceles centroid} and Problem \ref{arc centroid}. Where is the centroid of the \textit{sector} of the circle in Figure \ref{arc}. (Hint: Cut it up.)
\vfill
Seeing your success with his linear staff, the wizard challenges you with another magical staff to balance. It looks identical to the first one, but you're told that the density decreases from $\lambda_0$ to $0$ according to the function $\lambda(x) = \lambda_0\sqrt{1-x^2}$.
\problem{}
Seeing your success with his linear staff, the wizard challenges you with another magical staff to balance. It looks identical to the first one, but you're told that the density decreases from $\lambda_0$ to $0$ according to the function $\lambda(x) = \lambda_0\sqrt{1-x^2}$.
\vfill
\problem{}
Infinitely many masses $m_i$ are placed at $x_i$ along the positive $x$-axis, starting with $m_0 = 1$ placed at $x_0 = 1$. Each successive mass is placed twice as far from the origin compared to the previous one. But also, each successive mass has a quarter the weight of the previous one. Find the CoM if it exists.
\vfill
Infinitely many masses $m_i$ are placed at $x_i$ along the positive $x$-axis, starting with $m_0 = 1$ placed at $x_0 = 1$. Each successive mass is placed twice as far from the origin compared to the previous one. But also, each successive mass has a quarter the weight of the previous one. Find the CoM if it exists.
\vfill
(Bonus) Try to actually find $h$ from Problem \ref{3D soda}. Good luck.
\problem{}
(Bonus) Try to actually find $h$ from Problem \ref{3D soda}. Good luck.
%\item (Bonus, not related to the packet) Spongebob, Patrick, and Squidward are all hiding from the Sea Bear. Initially, Spongebob and Patrick are keeping watch 100 yards apart with Squidward halfway in between them. When Spongebob gets scared, he runs to hide halfway between Squidward and Patrick. Then Patrick, not wanting to be the farthest from the centre, runs to be halfway between Squidward and Patrick. Squidward, seeing this, quickly finds the new halfway point between Spongebob and Patrick. This pattern keeps repeating until all three of them are pointlessly clambering on top of each other. Where do they end up relative to their initial positions?