# Calculating volumes of hollow three dimensional geometric objects

We've gotten a homework assignment in Java, which relates to inheritance. I don't have a problem with the programming in itself, but I'm a bit unsure about some of the math, and would like confirmation/corrections from someone a bit more knowledgable.

The assignment starts with a abstract class, GeometricObject, which is extended into three two-dimensional objects. A rectangle, a circle and a triangle. Those three are then extended into a cuboid for the rectangle, a cylinder and a sphere for the circle, and the triangle into a triangular prism.

Each of these three-dimensional objects are hollow, and has a defined thickness and is made of a special metal, so we are to calculate their weight. And herein lies the problem, since I'm a bit unsure as to how I find the "inner volume" on some of them.

• Cuboid: Here I assume that I can just subtract 2 * thickness from the width, height and depth, and then everything looks fine.
• Cylinder: Subtract thickness from the radius making up the base, and 2*thickness from the height
• Sphere: Subtract thickness from the radius
• Prism: This is where I'm a bit stuck. Each object gets passed a baseline, height of the triangle, and the height for the entire prism. How can I use this in order to find the "inner prism" representing the inner volume?

Update: Forgot to mention that when creating the object, we specify the outmost sizes, and the hollow part is inside of this. The other way around is not allowed.

Update again: The triangle is an isosceles triangle.

Update yet again: Mixed up radius and diameter for the circular. Corrected now.

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For cylinder and sphere: You mean subtract thickness from radius. (Or subtract 2*thickness from diameter.) –  Jason S Apr 2 '09 at 17:08
Yeah, of course. Got a bit mixed up –  PerfectlyNormal Apr 5 '09 at 15:31

I think you cannot get this result from the data you have (baseline length & triangle height). You have to get other information, like location of the points or the angles at the baseline.

Edit: since the triangle is isosceles:

As AnthonyWJones already pointed out, the inner triangle is similar to the outer triangle. Therefore, the only thing you need is find the ratio between the two.

You can find it easily from the height. Since triangles CQP and ACS are similar

``````h2 : |PQ| = |AC| : |AS|
``````

where

``````|PQ| = h1 (= the thickness of the metal)
|AC| = sqrt(base^2/4+height^2)
|AS| = base/2
``````

Then, you compute `h2` and the ratio `r = (height - h1 - h2)/height` is the ratio between the two triangles. The area of the inner triangle is then `r^2 * area of the outer triangle`.

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Might be helpful to mention that the triangle is an isosceles triangle, two sides are equal in length. Meaning that the two angles near the baseline is the same. Nothing more is given, and it is possible to calculate it –  PerfectlyNormal Apr 2 '09 at 10:08
+1. Nice illustration, better reasoning ;) –  AnthonyWJones Apr 3 '09 at 9:45

Get the volume of the shapes as if they were not hollow, then, get the volume of the hollow are only (Shape - Thickness)

subtract full volume from hollow volume to get the actual volume of the metal.

Example:

Cube:

``````Full Volume: Height * Width * Depth

hollow volume: (Height - Thickness) * ( Width - Thickness ) * ( Depth - Thickness)

Volume of the metal used: Full Volume - hollow Volume
``````

Work out the weight from the volume of the metal used..

Assuming your prism is triangular and the triangle is equilateral that the base line is the base of the triangle and the height is from the baseline to the opposite point (and the height line is at an right angle from the baseline).

Then the full volume would be

``````fv = (1/2 * baseLine * triangleHeight) * prismHeight
``````

the hollow volume would be

``````hv = (1/2 * (baseline - thickness) * (triangleHeight - thickness)) * (prismHeight - thickness)
``````

After reading you comment to jpaleck, it would seem your baseline is the Hypotenuse of the triangle, (the longest line), the above should still hold true with that.

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Yeah, that works for the cuboid, and is how I've done it there. But how would it work for the prism? Would it be correct to just shorten each of the lengths there ass well? –  PerfectlyNormal Apr 2 '09 at 9:36
Assuming your prism is triangular and the triangle is equilateral. Then the full volume would be fv = (1/2 * baseLine * triangleHeight) * prismHeight, the hollow volume would be (1/2 * (baseline - thickness) * (triangleHeight - thickness) * prismHeight –  Sekhat Apr 2 '09 at 10:24
you may have to multiple thickness by two so that you account for the changes of the line lengths on each side. As a thickness of 10, when drawing a shape shortened by 10 in each dimension actually only gives a metal thickness of 5 all the way around. –  Sekhat Apr 2 '09 at 10:35
@Killersponge: If the triangles were equilateral there would be no need to include the height of the prism as the question indicates. –  AnthonyWJones Apr 2 '09 at 10:37
Indeed. Though the above formula is sound anyway, Assuming the baseline is one side of the triangle and the triangle height is from the center of that line to the point opposite it. –  Sekhat Apr 2 '09 at 10:42

One thing you know about the inner prism is that it will have the same ratios as the outer prism. In other words given the height of the inner prism you can calculate the inner base length and from there the volume.

You know the base will have 1 unit thickness. So that leaves calculating the distance from the pinnacle of the inner prism to the pinnacle of the outer prism.

That distance is the hypontenuse of a right angled triangle. The angles in the triangle are known since they are function of the base length and height. One side of the triangle is of `thickness` length being the perpendicular from the inner edge at the inner pinnacle to the outer edge. (The final side of the triangle is where that perpendicular intersects the outer edge up to the outer pinnacle).

This is enough info to use standard trig to caclulate the hypotenuse length. This length plus 1 thickness (for the base) subtracted from the original height gives you the inner height. The ratio between the inner and outer heights can be applied to the base length.

There a probably cleverer ways to do this but this would be my common bloke approach.

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