QA-Cu7: QA-Quasi Isogonal Cubic

QA-Cu7 is the locus of all points Q for which the 3 Reflections of the line Q.Si in the angle bisectors of Si concur, where Si = i^th vertex of the QA-Diagonal Triangle (i = 1,2,3). See also QG-Tf2 (Quasi Isogonal Conjugate).

The concurring point is also a point of the locus.

With the Reference Quadrangle as reference system this cubic can be seen as a circular isocubic invariant to the Involutary Conjugacy.

Construction: it is the locus of the intersection pint of the involutary conjugate of some line through QA-P4 and its perpendicular line through QA-P4 (note Eckart Schmidt). See QA-Cu-1, QA-Cubic Type 2.

QA-P4ic = Involutary Conjugate of QA-P4 = QA-P41,

Sic = Involutary Conjugate of S and the intersection of QA-P4.QA-P41 and perpendicular line in QA-P2 wrt QA-L2.

S is the intersection of QA-Cu7 and its asymptote

• or the intersection of the tangents in QA-P2, QA-P4, QA-P41
• or the diametral point of QA-P41 on the circumcircle of QA-P2, QA-P4, QA-P41 with Simson line QA-L2. See [34], Eckart Schmidt, QFG#1840.

Equation CT-notation:

– b² c² p² T_x (-q r x + p r y + p q z) x²

– a² c² q² T_y ( q r x – p r y + p q z) y²

– a² b² r² T_z ( q r x + p r y – p q z) z²

+ T_xyz x y z

where:

T_x = c² q² – a² q r + b² q r + c² q r + b² r²,

T_y = c² p² + a² p r – b² p r + c² p r + a² r²

T_z = b² p² + a² p q + b² p q – c² p q + a² q²

T_xyz = b² c² p⁴ + a² c² q⁴ – a² (a² – b² – c²) q³ r + a² (a² + b² + c²) q² r² – a² (a² – b² – c²) q r³ + a² b² r⁴ + p³ (c² (a² + b² – c²) q + b² (a² – b² + c²) r) + p² (c² (a² + b² + c²) q² + (a⁴ – a² b² – a² c² + 4 b² c²) q r + b² (a² + b² + c²) r²) + p (c² (a² + b² – c²) q³ + (-a² b² + b⁴ + 4 a² c² – b² c²) q² r + (4 a² b² – a² c² – b² c² + c⁴) q r² + b² (a² – b² + c²) r³)

Equation DT-notation:

((b² c² p⁴ + a⁴ q² r²) SA + p² (c² q² + b² r²) (S² + SB SC)) (r² y² + q² z²) x

+((a² c² q⁴ + b⁴ p² r²) SB + q² (c² p² + a² r²) (S² + SA SC)) (r² x² + p² z²) y

+((c⁴ p² q² + a² b² r⁴) SC + (b² p² + a² q²) r² (S² + SA SB)) (q² x² + p² y²) z

+(a² b² (b² p² + a² q²) r⁴ + a² c² q⁴ (c² p² + a² r²) + b² c² p⁴ (c² q² + b² r²)

+ 2 p² q² r² (3 SA SB SC + S² (SA + SB + SC))) x y z = 0

Properties

• • These points lie on QA-Cu7:
    • the vertices of the QA-Diagonal triangle,
    • QA-P2 (Euler-Poncelet Point),
    • QA-P4 (Isogonal Center)
    • QA-P41 (Involutary Conjugate of QA-P4)
    • the Involutary Conjugate of QA-P2 is the infinity point that represents the asymptote of the cubic.
    • the 3 QA-versions of QG-P18 (Quasi Isogonal Crosspoint)
    • the 3 QA-versions of QG-P19 (Quasi Isogonal Conjugate of QG-P1)
    • the circular points at infinity, which makes the cubic called circular.
  • The Asymptote is perpendicular to QA-L2 = QA-P2.QA-P4.
  • The Asymptote // 5^th Point tangent of QA-P2 (see QA-Tf9).
  • The Involutary Conjugate of every point on the cubic also lies on the cubic.
  • The cubic is “self-involutary”.
  • The tangents at QA-P2, QA-P4 and QA-P4ic pass through the intersection point S of the asymptote and the cubic.
  • QA-Cu7 is the locus of all pairs of involutary conjugated points for which the Thales circle passes through QA-P4 (note Eckart Schmidt).
  • Any line though Pi, Pj (Pi,Pj are two of the four points P1, P2, P3, P4) intersects QA-Cu7 in one of the QA-DT-vertices and a pair of points (T1, T2).
  • Now (T1, T2) are harmonic conjugated with (Pi, Pj).
  • Let (Pk, Pl) be the other pair of points of the Quadrangle. Again Pk.Pl intersects QA-Cu7 in one of the QA-DT-vertices and a pair of points (U1, U2). Similarly (U1, U2) are harmonic conjugated with (Pk, Pl).
  • Now T1.U1 ^ T2.U2 as well as T1.U2 ^ T2.U1 are points lying on QA-Cu7.
  • The intersection points of QA-Cu7 and the 3 diagonals of the Reference Quadrangle (unequal the vertices of QA-DT) are collinear. These intersection points are the perspectors of the three pairs of QA-triangle versions of QG-P1.QG-P18.QG-P19. See [34], Eckart Schmidt, QFG#1263.
  • QA-Cu7 is a pivotal isogonal cubic wrt reference triangle QA-P2.QA-P4.QA-P41, the isogonal conjugacy and pivot in the point at infinity of a perpendicular of QA-L2 = QA-P2.QA-P4. See [34], Eckart Schmidt, QFG#1840.

Quasi Isogonal Conjugate:

• An Isogonal Conjugate is defined in the environment of a Triangle.
• To construct an Isogonal Conjugate of a point P, reflections are made of the 3 P-cevians in the corresponding angle bisectors of the vertices of a triangle.
• The reflected P-cevians concur in a point P*. P* is called the Isogonal Conjugate.
• A Quasi Isogonal Conjugate (See QG-Tf2) is defined in the environment of a Diagonal Triangle of a Quadrangle.
• To construct a Quasi Isogonal Conjugate of a point P, reflections are made of the 3 P-cevians in a Diagonal Triangle in the corresponding angle bisectors of the 3 pairs of opposite lines of a quadrangle.
• The reflected cevians only concur in a point P* when P is situated on the Quasi Isogonal Cubic (QA-Cu7). P* is called the Quasi Isogonal Conjugate of P.

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