patrick honner

Math teacher in Brooklyn, New York

Fun With Folding: Circumcenter

Here’s another entry from my Fun With Folding series:  folding the circumcenter of a triangle!  The circumcenter of a triangle is the center of the triangle’s circumscribing circle.

To fold your way to the circumcircle, use the perpendicular biscctor fold three times to construct the perpendicular bisector of each side of the triangle.  (Click here to find instructions for these basic folds.)

Like magic, all the perpendicular bisectors intersect at the circumcenter!

Be sure to try some other fun mathematical activities with folding!

Have more Fun With Folding!

By patrick honner, ago

Fun With Folding: Incenter

Here’s another entry from my Fun With Folding series:  folding the incenter of a triangle!  The incenter of a triangle has a lot of interesting properties, most of which are related to the fact that it is the center of the triangle’s unique inscribed circle.

To fold your way to the incenter, start with an arbitrary triangle and use the angle bisector fold on each angle.  (Click here to find instructions for the basic folds.)

Like magic, all the angle bisectors intersect at the incenter!

Be sure to try some other fun mathematical activities with folding!

Have more Fun With Folding!

By patrick honner, ago

A Curious Geometric Limit

Inspired by Alexander Bogomolny (@CutTheKnotMath) and his curious geometric limit, I offer this trigonometric approach.

Consider the following diagram in which we have circle X of radius 3 centered at (3,0) and circle O of radius k centered at the origin.  Call the intersection of the these circles in the first quadrant B.  Let A be the intersection of circle O with the y-axis, and extend line AB until it intersects the x-axis at E.  Our goal is to show that \lim_{kto}OE=12.

Consider the diagram below.

a-curious-geometric-limit

Let \angle{OXB} = \theta.  Some simple angle chasing, using properties of isosceles triangles and right triangles, gives us that \angle{OEA} = \frac{\theta}{4}.

Since AO = k by definition, we have tan(\frac{\theta}{4}) = \frac{k}{OE}, and so OE = \frac{k}{tan(\frac{\theta}{4}) }.

Since OB = k is the base of isosceles triangle OXB, we can drop an altitude from X to OB and find that sin(\frac{\theta}{2}) = \frac{\frac{k}{2}}{BX} = \frac{\frac{k}{2}}{3}.    This gives us k = 6sin(\frac{\theta}{2}) .

So OE =  \frac{k}{tan(\frac{\theta}{4}) } =  \frac{6sin(\frac{\theta}{2})}{tan(\frac{\theta}{4}) }.  By the double angle formula for sine, we have

sin(\frac{\theta}{2}) = 2sin(\frac{\theta}{4})cos(\frac{\theta}{4}),

Making this substitution, and by writing tangent as the quotient of sine and cosine, we get

OE = \frac{6sin(\frac{\theta}{2})}{tan(\frac{\theta}{4}) } = \frac{12sin(\frac{\theta}{4}) cos((\frac{\theta}{4}))}{\frac {sin(\frac{\theta}{4})}{cos(\frac{\theta}{4})} } = 12 {(cos(\frac{\theta}{4}))}^2.

Finally, since \theta\to 0 as k \to 0, we have

\lim_{k\to 0}OE = \lim_{\theta \to 0}12 {(cos(\frac{\theta}{4}))}^2 = 12\lim_{\theta \to 0} {(cos(\frac{\theta}{4}))}^2=12.

By patrick honner, ago

Fun With Folding: Basic Folds

Here’s a good place to start my Fun With Folding series.  Below are the instructions for four basic folds:  folding a linethrough two points; folding the midpoint of a line segment; folding the perpendicular bisector of a segment; and folding the angle bisector of an angle.  Get these all down and you’ll be ready to have lots of fun with folding!

First, let’s fold a line between two points.  The key here is to make sure that both points lie in the crease of the fold.

You can fold the midpoint of a line segment by folding in such a way that one endpoint of the line segment lies on top of the other.  The two halves of the line segment should be right on top of each other, and just pinch the fold at the midpoint.

To fold the perpendicular bisector of a segment, perform the same steps as above for a midpoint, but just complete the crease!

The last basic fold is an angle bisector.  Given an angle, make a fold that passes through the vertex of the angle so that the two sides of the angle lie on top of each other.

Once you’ve got these basic folds down, you’ve got everything you need to try some more advanced folding challenges!

Have more Fun With Folding!

By patrick honner, ago
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