Difference between revisions of "Double perspective triangles"

(Two triangles in double perspective are in triple perspective)
(Two triangles in double perspective are in triple perspective)
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Let <math>BG = a, GE = b, AF = c, A = (0,0).</math> Then  
 
Let <math>BG = a, GE = b, AF = c, A = (0,0).</math> Then  
<cmath>B=(a, a), F = (0,c), BF: y= x (1 + \frac {c}{a})+c.</cmath>
+
<cmath>B = (-a, -a), F = (0,c), BF: y = x (1 + \frac {c}{a})+c.</cmath>
<cmath>E=(b, a),  AE: y = \frac {a}{b}x.</cmath>
+
<cmath>E=(b, -a),  AE: y = -\frac {a}{b}x.</cmath>
<cmath>D = (−a,0), C= (b,c), CD: y = c \frac {x+a}{a+b}.</cmath>
+
<cmath>D = (-a,0), C= (b,c), CD: y = c \frac {x+a}{a+b}.</cmath>
<math>X = CD \cap AE \cap BF = (− b, a) \frac {c}{a+b +{\frac {bc}{a}}</math> as desired.
+
<math>X = CD \cap AE \cap BF = (-bk, ak),</math> where k=  \frac {c} {a+b +{\frac {bc}{a}}}$ as desired.
  
 
'''vladimir.shelomovskii@gmail.com, vvsss'''
 
'''vladimir.shelomovskii@gmail.com, vvsss'''

Revision as of 13:48, 5 December 2022

Double perspective triangles

Two triangles in double perspective are in triple perspective

Exeter B.png

Let $\triangle ABC$ and $\triangle DEF$ be in double perspective, which means that triples of lines $AF, BD, CE$ and $AD, BE, CF$ are concurrent. Prove that lines $AE, BF,$ and $CD$ are concurrent (the triangles are in triple perspective).

Proof

Denote $G = AF \cap BE.$

It is known that there is projective transformation that maps any quadrungle into square.

We use this transformation for $BDFG$. We use the Claim for square and get the result: lines $AE, BF,$ and $CD$ are concurrent.

Claim for square Let $ADBG$ be the square, let $CEGF$ be the rectangle, $A \in FG, G \in BE.$ Prove that lines $BF, CD,$ and $AE$ are concurrent.

Proof

Let $BG = a, GE = b, AF = c, A = (0,0).$ Then \[B = (-a, -a), F = (0,c), BF: y = x (1 + \frac {c}{a})+c.\] \[E=(b, -a),  AE: y = -\frac {a}{b}x.\] \[D = (-a,0), C= (b,c), CD: y = c \frac {x+a}{a+b}.\] $X = CD \cap AE \cap BF = (-bk, ak),$ where k= \frac {c} {a+b +{\frac {bc}{a}}}$ as desired.

vladimir.shelomovskii@gmail.com, vvsss