Difference between revisions of "Van Aubel's Theorem"
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= Theorem = | = Theorem = | ||
On each side of quadrilateral <math>ABCD</math>, construct an external square and its center: (<math>ABA'B'</math>, <math>BCB'C'</math>, <math>CDC'D'</math>, <math>DAD'A'</math>; yielding centers <math>P_{AB}, P_{BC}, P_{CD}, P_{DA}</math>). Van Aubel's Theorem states that the two line segments connecting opposite centers are perpendicular and equal length: | On each side of quadrilateral <math>ABCD</math>, construct an external square and its center: (<math>ABA'B'</math>, <math>BCB'C'</math>, <math>CDC'D'</math>, <math>DAD'A'</math>; yielding centers <math>P_{AB}, P_{BC}, P_{CD}, P_{DA}</math>). Van Aubel's Theorem states that the two line segments connecting opposite centers are perpendicular and equal length: | ||
− | <math>P_{AB}P_{CD} = P_{BC}P_{DA}</math>, and <math>\overline{P_{AB}P_{CD | + | <math>P_{AB}P_{CD} = P_{BC}P_{DA}</math>, and <math>\overline{P_{AB}P_{CD}} \perp \overline{P_{BC}P_{DA}}</math>. |
= Proofs = | = Proofs = |
Revision as of 14:54, 21 February 2023
Theorem
On each side of quadrilateral , construct an external square and its center: (, , , ; yielding centers ). Van Aubel's Theorem states that the two line segments connecting opposite centers are perpendicular and equal length: , and .
Proofs
Proof 1: Complex Numbers
Putting the diagram on the complex plane, let any point be represented by the complex number . Note that and that , and similarly for the other sides of the quadrilateral. Then we have
From this, we find that Similarly,
Finally, we have , which implies and , as desired.