Difference between revisions of "3D Geometry"

 
(Making 3D Problems 2D)
 
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'''3D Geometry''' deals with objects in 3 [[dimension]]s.  For example, a drawing on a piece of paper is 2 dimensional since it has lenght and width.  But a baseball, on the other hand, is three dimensional because it not only has lenght and width but also depth.
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'''3D Geometry''' deals with objects in 3 [[dimension]]s.  For example, a drawing on a piece of paper is 2-dimensional since it has length and width.  A baseball, on the other hand, is three-dimensional because it not only has length and width, but also depth.
  
== Making 3D Problems 2D ==
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= Making 3D Problems 2D =
A very common technique for approaching 3D Geometry problems is to make it 2D.  We can do this by looking at certain cross-sections of the diagram one at a time.
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A very common technique for approaching 3D Geometry problems is to make it 2D.  We can do this by looking at certain cross-section(s) of the diagram one at a time. Another common solution is to try the 2D analogous problem first.
  
=== Example ===
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== Example Problem ==
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=== Problem ===
 
On a sphere with a radius of 2 units, the points <math> A </math> and <math> B </math> are 2 units away from each other.  Compute the distance from the center of the sphere to the line segment <math> AB. </math>
 
On a sphere with a radius of 2 units, the points <math> A </math> and <math> B </math> are 2 units away from each other.  Compute the distance from the center of the sphere to the line segment <math> AB. </math>
  
==== Solution ====
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=== Solution ===
First we note that the distance of a point to a line is usually meant to be the ''shortest'' distance between the point and the line.  This occurs when the perpendicular to the line segment through the point is drawn.
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First, we note that the distance of a point to a line is the ''shortest'' distance between the point and the line.  This occurs when the perpendicular to the line segment through the point is drawn.
  
Now we know what we are looking for, we can choose an appropriate cross-section to look at.  We choose to look at the cross-section containing <math> A, B </math> and the center of the sphere as shown in the following diagram:
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Now that we know what we are looking for, we can choose an appropriate cross-section to look at.  We choose to look at the cross-section containing <math>A</math>, <math>B</math>, and the center of the sphere as shown in the following diagram:
  
 
<center>[[Image:sphere3d.PNG]]</center>
 
<center>[[Image:sphere3d.PNG]]</center>
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<center>[[Image:sphere3dtriangle.PNG]]</center>
 
<center>[[Image:sphere3dtriangle.PNG]]</center>
  
From here, we can note the 30-60-90 triangle or the Pythagorean Theorem to find that <math> x = \sqrt{3} </math> units.
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From here, we can note the 30-60-90 triangle, or the Pythagorean Theorem, to find that <math> x = \sqrt{3} </math> units.
  
 
== See also ==
 
== See also ==
* [[Geometry]]
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* [[Solid Angle]]
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* [[Sphere]]
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* [[Cylinder]]
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* [[Cone]]
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* [[Cube (geometry) | Cube]]
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* [[Platonic solids]]
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* [[Tetrahedron]]
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* [[Octahedron]]
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* [[Dodecahedron]]
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* [[Icosahedron]]
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* [[Rhombic dodecahedron]]

Latest revision as of 21:45, 27 August 2024

3D Geometry deals with objects in 3 dimensions. For example, a drawing on a piece of paper is 2-dimensional since it has length and width. A baseball, on the other hand, is three-dimensional because it not only has length and width, but also depth.

Making 3D Problems 2D

A very common technique for approaching 3D Geometry problems is to make it 2D. We can do this by looking at certain cross-section(s) of the diagram one at a time. Another common solution is to try the 2D analogous problem first.

Example Problem

Problem

On a sphere with a radius of 2 units, the points $A$ and $B$ are 2 units away from each other. Compute the distance from the center of the sphere to the line segment $AB.$

Solution

First, we note that the distance of a point to a line is the shortest distance between the point and the line. This occurs when the perpendicular to the line segment through the point is drawn.

Now that we know what we are looking for, we can choose an appropriate cross-section to look at. We choose to look at the cross-section containing $A$, $B$, and the center of the sphere as shown in the following diagram:

Sphere3d.PNG

We now draw in the perpendicular to $AB$:

Sphere3dtriangle.PNG

From here, we can note the 30-60-90 triangle, or the Pythagorean Theorem, to find that $x = \sqrt{3}$ units.

See also