In Euclidean geometry, the isodynamic points of a triangle are points associated with the triangle, with the properties that an inversion centered at one of these points transforms the given triangle into an equilateral triangle, and that the distances from the isodynamic point to the triangle vertices are inversely proportional to the opposite side lengths of the triangle. Triangles that are similar to each other have isodynamic points in corresponding locations in the plane, so the isodynamic points are triangle centers, and unlike other triangle centers the isodynamic points are also invariant under Möbius transformations. A triangle that is itself equilateral has a unique isodynamic point, at its centroid(as well as its orthocenter, its incenter, and its circumcenter, which are concurrent); every non-equilateral triangle has two isodynamic points. Isodynamic points were first studied and named by Joseph Neuberg (1885).[1]

  Circles of Apollonius; isodynamic points S and S' at their intersections
  Interior angle bisectors, used to construct the circles
  Exterior angle bisectors, also used to construct the circles

Distance ratios

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The isodynamic points were originally defined from certain equalities of ratios (or equivalently of products) of distances between pairs of points. If   and   are the isodynamic points of a triangle   then the three products of distances   are equal. The analogous equalities also hold for  [2] Equivalently to the product formula, the distances     and   are inversely proportional to the corresponding triangle side lengths     and  

  and   are the common intersection points of the three circles of Apollonius associated with triangle of a triangle   the three circles that each pass through one vertex of the triangle and maintain a constant ratio of distances to the other two vertices.[3] Hence, line   is the common radical axis for each of the three pairs of circles of Apollonius. The perpendicular bisector of line segment   is the Lemoine line, which contains the three centers of the circles of Apollonius.[4]

Transformations

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The isodynamic points   and   of a triangle   may also be defined by their properties with respect to transformations of the plane, and particularly with respect to inversions and Möbius transformations (products of multiple inversions). Inversion of the triangle   with respect to an isodynamic point transforms the original triangle into an equilateral triangle.[5] Inversion with respect to the circumcircle of triangle   leaves the triangle invariant but transforms one isodynamic point into the other one.[3] More generally, the isodynamic points are equivariant under Möbius transformations: the unordered pair of isodynamic points of a transformation of   is equal to the same transformation applied to the pair   The individual isodynamic points are fixed by Möbius transformations that map the interior of the circumcircle of   to the interior of the circumcircle of the transformed triangle, and swapped by transformations that exchange the interior and exterior of the circumcircle.[6]

Angles

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Three circles, each making angles of π/3 with the circumcircle and each other, meet at the first isodynamic point.

As well as being the intersections of the circles of Apollonius, each isodynamic point is the intersection points of another triple of circles. The first isodynamic point is the intersection of three circles through the pairs of points     and   where each of these circles intersects the circumcircle of triangle   to form a lens with apex angle 2π/3. Similarly, the second isodynamic point is the intersection of three circles that intersect the circumcircle to form lenses with apex angle π/3.[6]

The angles formed by the first isodynamic point with the triangle vertices satisfy the equations     and   Analogously, the angles formed by the second isodynamic point satisfy the equations    and  [6]

The pedal triangle of an isodynamic point, the triangle formed by dropping perpendiculars from   to each of the three sides of triangle   is equilateral,[5] as is the triangle formed by reflecting   across each side of the triangle.[7] Among all the equilateral triangles inscribed in triangle   the pedal triangle of the first isodynamic point is the one with minimum area.[8]

Additional properties

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The isodynamic points are the isogonal conjugates of the two Fermat points of triangle   and vice versa.[9]

The Neuberg cubic contains both of the isodynamic points.[4]

If a circle is partitioned into three arcs, the first isodynamic point of the arc endpoints is the unique point inside the circle with the property that each of the three arcs is equally likely to be the first arc reached by a Brownian motion starting at that point. That is, the isodynamic point is the point for which the harmonic measure of the three arcs is equal.[10]

Given a univariate polynomial   whose zeros are the vertices of a triangle   in the complex plane, the isodynamic points of   are the zeros of the polynomial   Note that   is a constant multiple of   where   is the degree of   This construction generalizes isodynamic points to polynomials of degree   in the sense that the zeros of the above discriminant are invariant under Möbius transformations. Here the expression   is the polar derivative of   with pole  [11]

Equivalently, with   and   defined as above, the (generalized) isodynamic points of   are the critical values of   Here   is the expression that appears in the relaxed Newton’s method with relaxation parameter   A similar construction exists for rational functions instead of polynomials.[11]

Construction

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Construction of the isodynamic point from reflected copies of the given triangle and inwards-pointing equilateral triangles.

The circle of Apollonius through vertex   of triangle   may be constructed by finding the two (interior and exterior) angle bisectors of the two angles formed by lines   and   at vertex   and intersecting these bisector lines with line   The line segment between these two intersection points is the diameter of the circle of Apollonius. The isodynamic points may be found by constructing two of these circles and finding their two intersection points.[3]

Another compass and straight-edge construction involves finding the reflection   of vertex   across line   (the intersection of circles centered at   and   through  ), and constructing an equilateral triangle inwards on side   of the triangle (the apex   of this triangle is the intersection of two circles having   as their radius). The line   crosses the similarly constructed lines   and   at the first isodynamic point. The second isodynamic point may be constructed similarly but with the equilateral triangles erected outwards rather than inwards.[12]

Alternatively, the position of the first isodynamic point may be calculated from its trilinear coordinates, which are[13]   The second isodynamic point uses trilinear coordinates with a similar formula involving   in place of  

Notes

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References

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