Hofstadter points

In triangle geometry, a Hofstadter point is a special point associated with every plane triangle. In fact there are several Hofstadter points associated with a triangle. All of them are triangle centers. Two of them, the Hofstadter zero-point and Hofstadter one-point, are particularly interesting.^[1] They are two transcendental triangle centers. Hofstadter zero-point is the center designated as X(360) and the Hofstafter one-point is the center denoted as X(359) in Clark Kimberling's Encyclopedia of Triangle Centers. The Hofstadter zero-point was discovered by Douglas Hofstadter in 1992.^[1]

Hofstadter triangles

Let ABC be a given triangle. Let r be a positive real constant.

Rotate the line segment BC about B through an angle rB towards A and let L_BC be the line containing this line segment. Next rotate the line segment BC about C through an angle rC towards A. Let L'_BC be the line containing this line segment. Let the lines L_BC and L'_BC intersect at A(r). In a similar way the points B(r) and C(r) are constructed. The triangle whose vertices are A(r), B(r), C(r) is the Hofstadter r-triangle (or, the r-Hofstadter triangle) of triangle ABC.^[2]^[1]

Special case

The Hofstadter 1/3-triangle of triangle ABC is the first Morley's triangle of triangle ABC. Morley's triangle is always an equilateral triangle.
The Hofstadter 1/2-triangle is simply the incentre of the triangle.

Trilinear coordinates of the vertices of Hofstadter triangles

The trilinear coordinates of the vertices of the Hofstadter r-triangle are given below:

A(r) = ( 1 , sin rB / sin (1 − r)B , sin rC / sin (1 − r)C )

B(r) = ( sin rA / sin (1 − r)A , 1 , sin rC / sin (1 − r)C )

C(r) = ( sin rA / sin (1 − r)A , sin (1 − r)B / sin rB , 1 )

Hofstadter points

Animation showing various Hofstadter points. H₀ is the Hofstadter zero-point. H₁ is the Hofstadter one-point. The little red arc in the center of the triangle is the locus of the Hofstadter r-points for 0 < r < 1. This locus passes through the incenter I of the triangle.

For a positive real constant r > 0, let A(r) B(r) C(r) be the Hofstadter r-triangle of triangle ABC. Then the lines AA(r), BB(r), CC(r) are concurrent.^[3] The point of concurrence is the Hofstdter r-point of triangle ABC.

Trilinear coordinates of Hofstadter r-point

The trilinear coordinates of Hofstadter r-point are given below.

( sin rA / sin ( A − rA) , sin rB / sin ( B − rB ) , sin rC / sin ( C − rC) )

Hofstadter zero- and one-points

The trilinear coordinates of these points cannot be obtained by plugging in the values 0 and 1 for r in the expressions for the trilinear coordinates for the Hofstdter r-point.

Hofstadter zero-point is the limit of the Hofstadter r-point as r approaches zero.

Hofstadter one-point is the limit of the Hofstadter r-point as r approaches one.

Trilinear coordinates of Hofstadter zero-point

= lim _{r → 0} ( sin rA / sin ( A − rA) , sin rB / sin ( B − rB ) , sin rC / sin ( C − rC) )

= lim _{r → 0} ( sin rA / r sin ( A − rA) , sin rB / r sin ( B − rB ) , sin rC / r sin ( C − rC) )

= lim _{r → 0} ( A sin rA / rA sin ( A − rA) , B sin rB / rB sin ( B − rB ) , C sin rC / rC sin ( C − rC) )

= ( A / sin A , B / sin B , C / sin C ) ), as lim _{r → 0} sin rA / rA = 1, etc.

= ( A / a, B / b, C / c )

Trilinear coordinates of Hofstadter one-point

= lim _{r → 1} ( sin rA / sin ( A − rA) , sin rB / sin ( B − rB ) , sin rC / sin ( C − rC) )

= lim _{r → 1} ( ( 1 − r ) sin rA / sin ( A − rA) , ( 1 - r ) sin rB / sin ( B − rB ) , ( 1 − r )sin rC / sin ( C − rC) )

= lim _{r → 1} ( ( 1 − r ) A sin rA / A sin ( A − rA) , ( 1 − r ) B sin rB / B sin ( B − rB ) , ( 1 − r ) C sin rC / C sin ( C − rC) )

= ( sin A / A , sin B / B , sin C / C ) ) as lim _{r → 1} ( 1 − r ) A / sin ( A − rA ) = 1, etc.

= ( a / A, b / B, c / C )

References

1 2 3 Kimberling, Clark. "Hofstadter points". Retrieved 11 May 2012.
↑ Weisstein, Eric W. "Hofstadter Triangle". MathWorld--A Wolfram Web Resource. Retrieved 11 May 2012.
↑ C. Kimberling (1994). "Hofstadter points". Nieuw Archief voor Wiskunde. 12: 109–114.

Douglas Hofstadter

Books	Gödel, Escher, Bach (1979) The Mind's I (1981)¹ Metamagical Themas (1985) Fluid Concepts and Creative Analogies (1995)² Le Ton beau de Marot (1997) I Am a Strange Loop (2007) Surfaces and Essences (2013)

Concepts and projects	BlooP and FlooP Copycat Hofstadter's butterfly Hofstadter's law Hofstadter points MU puzzle Platonia dilemma Six nines in pi Strange loop Superrationality

Related topics	Egbert B. Gebstadter Robert Hofstadter Indiana University Bloomington Victim of the Brain

¹ Edited by Hofstadter and Daniel C. Dennett ² By Hofstadter and the Fluid Analogies Research Group

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