We describe four special families of ellipse-inscribed Poncelet triangles about the incircle which maintain certain triangle centers stationary and which also display interesting conservations.
Deep Dive into Four special Poncelet triangle families about the incircle.
We describe four special families of ellipse-inscribed Poncelet triangles about the incircle which maintain certain triangle centers stationary and which also display interesting conservations.
As special cases to [2], we introduce four special families of Poncelet triangles inscribed in an ellipse E and circumscribing their fixed incircle, let C be its center, i.e., the incenter X 1 (triangle center notation X k are after Kimberling [5]). Referring to Figure 1, the four Poncelet families are:
• focal-X 1 : the caustic is centered on a focus of E ; • iso-X 2 : caustic is centered on a special point on E ’s minor axis such that the barycenter X 2 is stationary;
• focal-X 4 : caustic is centered on a special point E ’s major axis such that the orthocenter X 4 is stationary on a focus of E ; • iso-X 7 : caustic is centered on a another special point on E ’s major axis such that the Gergonne point X 7 is stationary.
In the sections below, R, r, l i , i = 1, 2, 3 refer to a triangle’s circumradius, inradius, and sidelengths, respectively, see [14] for definitions.
Let E be given by (x/a) 2 + (y/b) 2 = 0. Referring to Figure 1 (top left): Proposition 1. The caustic centered at C 1 = [c, 0] admits a Poncelet family of triangles with r 1 given by:
Proof. This follows from [2, Prop. 2]: the radius r for a circular caustic (of Poncelet triangles) with center at [x c , y c ] is given by:
The focal-X 1 family is the polar image of the vertices of Chapple’s Porism (a porism of triangles interscribed between two circles [7]), with respect to the circumcircle, i.e., it is its tangential triangle. The former’s incenter X 1 coincides with the latter’s circumcenter X 3 .
Bicentric n-gons (a generalization of Chapple’s porism) conserve the sum of cosines of their internal angles θ i [10]. On the other hand, the polar family with respect to the circumcircle conserves ∑ n i=1 sin(θ i /2), for all n ≥ 3 [1, prop.26].
Proposition 2. For the focal-X 1 family, the sum of half-angle sines is invariant and given by:
Four families of ellipse-inscribed Poncelet triangles about the incircle. top-left: focal-X 1 (C at a focus of E ); top-right: iso-X 2 (C on minor axis of E , barycenter X 2 stationary); bot.-left: focal-X 4 (X 4 is a focus of E ); bot.-right: iso-X 7 (C on major axis of E , X 7 stationary). Video: youtu.be/nsHDfX6mA
Referring to Figure 1 (top right), it follows from the expressions for the center C 2 and semi-axis lengths a 2 , b 2 for the elliptic locus of the barycenter X 2 [2, Prop. 3] that: Proposition 3. For a circular caustic with center C 2 = 0, c b 2a and radius r 2 = b 2 , the barycenter X 2 is stationary at 0, c b 3a . Corollary 1. Over iso-X 2 triangles, Nagel’s point X 8 is stationary at E’s center.
Proof. Direct from the location of the stationary barycenter and the fact that
The Spieker center X 10 , incenter of the medial triangle and the midpoint of the incenter X 1 and Nagel’s point X 8 [5] will be stationary on E’s minor axis.
Observation 2. Since the barycenter X 2 is stationary, the family conserves |X 1 X 2 |, which for any triangle with sidelengths l i is given by [14,Triangle Centroid,eqn.11]:
Since foci of a triangle’s inconic are an isogonal conjugate pair [6] (see also Definition 2), the second focus must be the fixed orthocenter X 4 of the family (also within E ′ ), i.e., this is the MacBeath inconic.
Let K be the image of K ′ under A -1 . The the barycenter X 2 of the family in (E , K ) will be stationary because (i) by Lemma 1, the MacBeath’s centroid is stationary, and (ii) the centroid is the only triangle center which is equivariant with respect to affinities [5]. The barycenter X 2 must lie on OC because affinities preserve collinearities. Notice it will nevertheless not lie on the major axis of K (foci are not equivariant). □
Referring to Figure 3, experimental evidence suggests that for MacBeath-like Poncelet families of n-gons, n > 3, i.e., they are circle-inscribed and the caustic has a focus at the center of said circle, both vertex and area centroids C 0 and C 2 remain stationary on the caustic axis. When n = 4, C 0 lies at the caustic’s center. Corollary 3. Given an ellipse E centered at O and a point C in its interior, there is a caustic centered on C for which both c 0 and c 2 are stationary on OC. Indeed, over such families, the perimeter centroid, in general not expected to sweep a conic over Poncelet [11], is experimentally found to sweep an ellipse with major axis identical to the caustic’s.
Referring to Figure 1 (bottom left): Proposition 5. The orthocenter X 4 is stationary at a focus f = [±c, 0] of E for the circular caustic with center and radius given by:
Referring to Figure 4:
Observation 3. For the focal-X 4 family, the center (resp. other focus) of E is X 7952 (resp. X 18283 ). L 3 is an ellipse with a focus at E’s center. L 20 is twice as large, with a focus on E ’s distal focus.
Definition 3. A triangle’s polar circle is centered on the orthocenter X 4 and has squared radius given by [14, Polar circle]:
This quantity is positive (resp. negative) for obtuse (resp. acute triangles).
Proposition 6. The focal-X 4 family conserves the (neg
…(Full text truncated)…
This content is AI-processed based on ArXiv data.
