QA-Cu-1: Circumscribed QA-Cubics

Here 3 types of Quadrangle Cubics are mentioned:

QA-Cubic Type 1

QA-Cubic Type 1 is a cubic that can be constructed as follows:

Let P1, P2, P3, P4 be the vertices of the Reference Quadrangle.

Let V (u:v:w) be a variable point.

Let Lv be some line through V.

Let IC(Lv) be the Involutary Conjugate (QA-Tf2) of Line Lv.

IC(Lv) is a conic since QA-Tf2 is a transformation of the 2^nd degree.

The locus of the intersection IC(Lv) ^ Lv is a QA-Cubic Type 1.

Because of its function V is called the Pivot Point of the QA-Cubic Type 1.

Examples: QA-Cu1 – QA-Cu5, where resp. V = QA-P4, QA-P5, QA-P10, QA-P19, QA-P1

The general equation in CT-notation is:

q r x² (v z – w y) + p r y² (w x – u z) + p q z² ( u y – v x) = 0

The general equation in DT-notation is:

p² y z (v z – w y) + q² x z (w x – u z) + r² x y (u y – v x) = 0

This QA-Cubic Type 1 has some interesting general properties:

• The tangents at P1, P2, P3, P4 are concurrent in the Pivot Point V on the cubic.
• The tangents at DT1, DT2, DT3 are concurrent in a point W on the cubic, which is the Involutary Conjugate of V.
• The vertices of the Cevian Triangle of Pivot Point V wrt the QA-Diagonal Triangle QA-Tr1 lie on the cubic.
• V.W is the only line through V for which Q1 is Doublepoint itself wrt the created QA-Line Involution, whilst W is the 2^nd Doublepoint on this line.
• V.W is tangent in V at the cubic and also at the conic (P1,P2,P3,P4,V)
• These cubics can all be seen as “pivotal isocubics” like described by Bernard Gibert [17b]. The reference system here is not a triangle but a quadrangle. The Isoconjugation here is the Involutary Conjugation. Point V is the pivot.
• Cubic QA-Cu1 is also a circular cubic because the imaginary circular infinity points lies on this cubic.

QA-Cubic Type 2

QA-Cubic Type 1 is a cubic that can be constructed as follows:

• Let P1, P2, P3, P4 be the vertices of the Reference Quadrangle.
• Let V (u:v:w) be a variable point.
• Let Lv be some line through V.
• Let IC(Lv) be the Involutary Conjugate (QA-Tf2) of Line Lv.
• IC(Lv) is a conic since QA-Tf2 is a transformation of the 2^nd degree.
• The locus of the intersection of IC (Lv) ^ the perpendicular at V to Lv is a QA-Cubic Type-2.

Example: QA-Cu7 (QA-Quasi Isogonal Cubic) with V = QA-P4.

Cubic QA-Cu7 is also a circular cubic because the imaginary circular infinity points lies on this cubic.

The general equation in CT-notation is:

(-a² v w + c² v (v + w) + b² w (v + w )) (q r x³ – p r x² y – p q x² z)

+ (-b² u w + c² u (u + w) + a² w (u + w)) (p r y³ – p q y² z – q r x y²)

+ (-c² u v + b² u (u + v) + a² v (u + v )) (p q z³ – q r x z² – p r y z²)

+ (a² (q r u² – p r u v + q r u v – p r v² – p q u w + q r u w + p q v w + p r v w + 2 q r v w – p q w²)

+ b² (-q r u² + p r u v – q r u v + p r v² + p q u w + 2 p r u w + q r u w – p q v w + p r v w – p q w²)

+ c² (-q r u² + 2 p q u v + p r u v + q r u v – p r v² + p q u w – q r u w + p q v w – p r v w + p q w²)) x y z = 0

The general equation in DT-notation is:

(-Sa u² + Sb v (u + w) + Sc (u + v) w) (r² y² + q² z²) x

+(Sa u (v + w) – Sb v² + Sc (u + v) w) (r² x² + p² z²) y

+(Sa u (v + w) + Sb v (u + w) – Sc w²) (q² x² + p² y²) z

-(r² (b² u² + 2 Sc u v + a² v²) + q² (c² u² + 2 Sb u w + a² w²) + p² (c² v² + 2 Sa v w + b² w²)) x y z = 0

QA-Cubic Type 3

QA-Cubic Type 3 is a cubic that can be constructed as follows:

• Let P1, P2, P3, P4 be the vertices of the Reference Quadrangle.
• Let V (u:v:w) be a variable point.
• Let Lv be some line through V.
• Let IC(Lv) be the Involutary Conjugate (QA-Tf2) of Line Lv.
• IC(Lv) is a conic since QA-Tf2 is a transformation of the 2^nd degree.
• The intersection of IC(Lv) with Lv results in 2 intersection points.
• The locus of the Midpoint of these 2 intersection points (which is the Involution Center of the QA-Line Involution on line Lv) produces a QA-Cubic Type 3.

Example: QA-Cu6, where V = QA-P1

The general equation in CT-notation is:

r w ((p u + q u + p w) y – (p v + q v + q w) x) x y

+ q v ((r v + p w + r w) x – (p u + r u + p v) z) x z

+ p u ((q u + q v + r v) z – (r u + q w + r w) y) y z

+ (q r u (w – v) + p r v (u – w) + p q w (v – u)) x y z = 0

The general equation in DT-notation is:

p² (w y – v z) (-2 u y z + v z (x – y + z) + w y (x + y – z))

+q² (u z – w x) (u z (-x + y + z) – 2 v x z + w x (x + y – z))

+r² (v x – u y) (u y (-x + y + z) + v x (x – y + z) – 2 w x y) = 0

Properties

• The vertices of the Reference Quadrangle lie on this cubic.
• The intersection point of the line through V parallel to the side Pi.Pj intersected with the opposite side Pk.Pl is a point on this cubic for all instances of (i,j,k,l) ∊ (1,2,3,4).

Notes from Bernard Gibert (2012, January 22):

Type 1 cubics are pK(P x Q, P) wrt ABC, in particular :

• QACu1 = pK(P x igP, P), circular cubic see CL035 and SITP 4.2.1
• QACu2 = pK(W1, P), central cubic see CL017 and SITP 3.1
• QACu3 = pK(P x X2P, P), where X2P is the centroid of the cevian triangle of P, see CL007
• QACu4 = pK(cP x ccP x ct(P²),P), seems complicated…
• QACu5 = pK(W4, P), a K+, see CL017 and CL049

Type 2 cubics are nK isocubics wrt the cevian triangle of P. See SITP 1.5.3.

• It is the locus of M such that P/M lies on the tangent at Q to the circle with center M passing through Q.
• QACu7 is obtained with Q = igP. It is a focal cubic with focus P/igP, passing through the center S of the rectangular circum-hyperbola through P and P/S which is the infinite real point.

Type 3 cubics are spK(P, Midpoint PQ) cubics with pole P x Q. See CL055.

• These are nodal cubics with node Q.
• QACu6 is obtained with Q = ccP. It is a K+.
• notations : c, g, t, i mean complement, isogonal, isotomic, inverse as usual.
• SITP = Special Isocubics…

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