QL-Cu2

QL-Cu2: Eckart’s Cubic

QL-Cu2 is the Cubic that passes through the 27 centers of Morley’s Multi Cardioids. See QL-27Qu1. It was discovered by Eckart Schmidt (April, 2013). See [34] Quadri-Figures Group, message # 37 (first notification), #52, #56 (asymptotes // axes Deltoid), #57 (QL-P1), #58 (27 Cardioid Centers).

It’s three asymptotes meet in one point QL-P1 (Miquel Center) at angles of 60°.

The asymptotes are parallel to the three axes of the Kantor-Hervey Deltoid QL-Qu2.

The construction of QL-Cu2can be found at [34], QFG message # 558.

Bernard Gibert made a detailed description at [17d] in a paper he wrote on the basis of this special cubic.

More information about the cubic also can be found at [43].

Equation in CT-notation

b² c² l (a² ( l m + l n – m n) – b² (m – l) (m – n) – c² (n – l) (n – m)) x³

+ a² c² m (b² ( l m – l n + m n) – c² (n – l) (n – m) – a² ( l – m) ( l – n)) y³

+ a² b² n (c² (-l m + l n + m n) – a² (l – m) ( l – n) – b² (m – l) (m – n)) z³

+ 3 a² b² c² (l x + m y) (m y+ n z) (n z + l x) = 0

Equation in DT-notation

(m⁴ Sa³ – 2 m² n² Sa³ + n⁴ Sa³ + 2 l² m² Sa² Sb + 2 l² n² Sa² Sb + 2 m² n² Sa² Sb + 2 n⁴ Sa² Sb + l⁴ Sa Sb² + 6 l² n² Sa Sb² + n⁴ Sa Sb² + 2 l² m² Sa² Sc + 2 m⁴ Sa² Sc + 2 l² n² Sa² Sc + 2 m² n² Sa² Sc + 2 l⁴ Sa Sb Sc + 6 l² m² Sa Sb Sc + 6 l² n² Sa Sb Sc + 2 m² n² Sa Sb Sc + 4 l⁴ Sb² Sc + 4 l² n² Sb² Sc + l⁴ Sa Sc² + 6 l² m² Sa Sc² + m⁴ Sa Sc² + 4 l⁴ Sb Sc² + 4 l² m² Sb Sc²) (l² x³ + 3 m² x y² + 3 n² x z²)

+ (m⁴ Sa² Sb + 6 m² n² Sa² Sb + n⁴ Sa² Sb + 2 l² m² Sa Sb² + 2 l² n² Sa Sb² + 2 m² n² Sa Sb² + 2 n⁴ Sa Sb² + l⁴ Sb³ – 2 l² n² Sb³ + n⁴ Sb³ + 4 m⁴ Sa² Sc + 4 m² n² Sa² Sc + 6 l² m² Sa Sb Sc + 2 m⁴ Sa Sb Sc + 2 l² n² Sa Sb Sc + 6 m² n² Sa Sb Sc + 2 l⁴ Sb² Sc + 2 l² m² Sb² Sc + 2 l² n² Sb² Sc + 2 m² n² Sb² Sc + 4 l² m² Sa Sc² + 4 m⁴ Sa Sc² + l⁴ Sb Sc² + 6 l² m² Sb Sc² + m⁴ Sb Sc²) ( m² y³ + 3 l² x² y + 3 n² y z²)

+ (4 m² n² Sa² Sb + 4 n⁴ Sa² Sb + 4 l² n² Sa Sb² + 4 n⁴ Sa Sb² + m⁴ Sa² Sc + 6 m² n² Sa² Sc + n⁴ Sa² Sc + 2 l² m² Sa Sb Sc + 6 l² n² Sa Sb Sc + 6 m² n² Sa Sb Sc + 2 n⁴ Sa Sb Sc + l⁴ Sb² Sc + 6 l² n² Sb² Sc + n⁴ Sb² Sc + 2 l² m² Sa Sc² + 2 m⁴ Sa Sc² + 2 l² n² Sa Sc² + 2 m² n² Sa Sc² + 2 l⁴ Sb Sc² + 2 l² m² Sb Sc² + 2 l² n² Sb Sc² + 2 m² n² Sb Sc² + l⁴ Sc³ – 2 l² m² Sc³ + m⁴ Sc³) (n² z³ + 3 l² x² z + 3 m² y² z)

+ 3 (m⁶ Sa³ – m⁴ n² Sa³ – m² n⁴ Sa³ + n⁶ Sa³ + 3 l² m⁴ Sa² Sb + 2 l² m² n² Sa² Sb + 3 m⁴ n² Sa² Sb + 3 l² n⁴ Sa² Sb + 2 m² n⁴ Sa² Sb + 3 n⁶ Sa² Sb + 3 l⁴ m² Sa Sb² + 3 l⁴ n² Sa Sb² + 2 l² m² n² Sa Sb² + 2 l² n⁴ Sa Sb² + 3 m² n⁴ Sa Sb² + 3 n⁶ Sa Sb² + l⁶ Sb³ – l⁴ n² Sb³ – l² n⁴ Sb³ + n⁶ Sb³ + 3 l² m⁴ Sa² Sc + 3 m⁶ Sa² Sc + 2 l² m² n² Sa² Sc + 2 m⁴ n² Sa² Sc + 3 l² n⁴ Sa² Sc + 3 m² n⁴ Sa² Sc + 6 l⁴ m² Sa Sb Sc + 6 l² m⁴ Sa Sb Sc + 6 l⁴ n² Sa Sb Sc – 4 l² m² n² Sa Sb Sc + 6 m⁴ n² Sa Sb Sc + 6 l² n⁴ Sa Sb Sc + 6 m² n⁴ Sa Sb Sc + 3 l⁶ Sb² Sc + 3 l⁴ m² Sb² Sc + 2 l⁴ n² Sb² Sc + 2 l² m² n² Sb² Sc + 3 l² n⁴ Sb² Sc + 3 m² n⁴ Sb² Sc + 3 l⁴ m² Sa Sc² + 2 l² m⁴ Sa Sc² + 3 m⁶ Sa Sc² + 3 l⁴ n² Sa Sc² + 2 l² m² n² Sa Sc² + 3 m⁴ n² Sa Sc² + 3 l⁶ Sb Sc² + 2 l⁴ m² Sb Sc² + 3 l² m⁴ Sb Sc² + 3 l⁴ n² Sb Sc² + 2 l² m² n² Sb Sc² + 3 m⁴ n² Sb Sc² + l⁶ Sc³ – l⁴ m² Sc³ – l² m⁴ Sc³ + m⁶ Sc³) x y z

Properties

These points lie on QL-Cu2:
- the 27 centers of Morley’s Multiple Cardioids QL-27Qu1.
It’s three asymptotes meet in QL-P1 (Miquel Center) at angles of 60°.
The asymptotes are parallel to the three axes of the Kantor-Hervey Deltoid QL-Qu2 (Eckart Schmidt, May 9, 2013).
The intersection points of QL-Cu2 with its three asymptotes lie collinear on a line parallel to QL-L1 (Newton Line) in 2/3 distance to QL-P1 (Miquel Point).
See [34], QFG message # 94 (Eckart Schmidt, June 29, 2013).

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