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CL061 is the class of isogonal nKs passing through the centroid G and the Lemoine point K. They form a net of cubics that contains many special cubics. If the root R is u:v:w, the equation of the cubic is : ∑ u x (y  z) (c^2 y  b^2 z) = 0 or ∑ a^2 y z [v (x  z) + w (x  y)] = 0. See the related CL062. The table gives a selection of these cubics with root R and centers other than G, K. 





Classification by type When the root lies on a certain locus (L), the cubic (K) = nK(X6, R, X2) has a specific characterization as shown in the next table and the figure below. L(M) denotes the trilinear polar of M. 



Remarks : • the line L(X1016) and its extraversions (green lines) are the four common tangents to the circumcircle and the Steiner ellipse. • for any R on the (dashed red) line X107X110, the cubic (K) contains X(3) and X(4) and the tangents at these points concur at X(6). • for any R on the (dashed blue) line X110X523, the cubic (K) contains X(13), X(14), X(15), X(16). Further details below. • when R is one of the intersections Ro, Ra, Rb, Rc of L(X598) with L(X1016) and extraversions, the cubic is a strophoid with node X(1) and excenters respectively. *** For any R on the (red) cubic (C), (K) has three concurring asymptotes. No ETC center was found on (C). 



Classification by centers Any cubic (K) = nK(X6, R, X2) that contains a center P (which is not G, K or an in/excenter) must contain the isogonal conjugate P* of P, P1 = GP /\ KP*, P2 = KP /\ GP* = P1*. It follows that the cubics passing through P have 9 common points hence they belong to a same pencil whose root R lies on a certain line (L). (L) contains the trilinear poles of the lines GP, GP* (on the Steiner ellipse) and KP, KP* (on the circumcircle) giving in general four decomposed cubics of the pencil. When R traverses (L), the tangents at P, P* to (K) intersect on the circumconic passing through P and P*. Note that the four points P, P*, P1, P2 are not necessarily all distinct : • P = P1 (therefore P* = P2) if and only if P lies on the Grebe cubic K102, in which case the tangents at P, P* concur at G. • P = P2 (therefore P* = P1) if and only if P lies on the Thomson cubic K002, in which case the tangents at P, P* concur at K. In both cases, (K) has fixed tangents at P and P* for any root R on (L). This occurs in the yellow lines of the table. 



Note : the cubics corresponding to the first line of the table are also members of the class CL062. *** The transformations f1 : P > P1 = GP /\ KP* and f2 : P > P2 = KP /\ GP* = P1* are closely related to the CundyParry transformations as in CL037. Indeed, these are also involutions with singular points A, B, C, G, K. f1 leaves any nK(X6, R, X2) globally invariant and fixes the Thomson cubic K002 and the Grebe cubic K102. Moreover, any cubic of the pencil generated by K002, K102 is transformed into another cubic of the same pencil. These two cubics are isogonal pKs and their pivots are harmonically conjugated with respect to G and K. f1 transforms a line (L) not passing through G and K into a nodal circumcubic (K) with node G passing through K and f2 transforms the same line (L) into the isogonal transform of the cubic. For example, when (L) is the line at infinity, these two cubics are K280 and K281. If S is the trilinear pole of (L), then • (K) is a K0 when S lies on the circumhyperbola through G and K in which case (L) contains X(512) i.e. (L) is perpendicular to the Brocard axis. • (K) is a nK when S lies on the circumcircle or on the Steiner ellipse (these two giving decomposed nKs) or on the circumconic with perspector X(39). In this case, (K) is an isotomic nK with root on the line passing through X99, X670, X804, X874, X880, X887, X1632, X1634. In particular, with S = X(694), the cubic is cK0(#X2, X804), the only cubic of this type. • (K) is a cuspidal cubic when S lies on the isogonal transform of the Kiepert parabola in which case (L) is tangent to the circumhyperbola through G and K. • the nodal tangents are perpendicular when the X(1992isoconjugate of S lies on the line X(2), X(39). • there is only one point S for which (K) is circular (resp. equilateral). In both cases, S is complicated and (K) is not particularly interesting. 
