Nine-point hyperbola

Template:Short description

In Euclidean geometry with triangle △ABCScript error: No such module "Check for unknown parameters"., the nine-point hyperbola is an instance of the nine-point conic described by American mathematician Maxime Bôcher in 1892. The celebrated nine-point circle is a separate instance of Bôcher's conic:

Given a triangle △ABCScript error: No such module "Check for unknown parameters". and a point Template:Mvar in its plane, a conic can be drawn through the following nine points:

the midpoints of the sides of △ABCScript error: No such module "Check for unknown parameters".,

the midpoints of the lines joining Template:Mvar to the vertices, and

the points where these last named lines cut the sides of the triangle.

The conic is an ellipse if Template:Mvar lies in the interior of △ABCScript error: No such module "Check for unknown parameters". or in one of the regions of the plane separated from the interior by two sides of the triangle; otherwise, the conic is a hyperbola. Bôcher notes that when Template:Mvar is the orthocenter, one obtains the nine-point circle, and when Template:Mvar is on the circumcircle of △ABCScript error: No such module "Check for unknown parameters"., then the conic is an equilateral hyperbola.

Allen

An approach to the nine-point hyperbola using the analytic geometry of split-complex numbers was devised by E. F. Allen in 1941.^[1] Writing ${\displaystyle z=a+bj}$, j² = 1Script error: No such module "Check for unknown parameters"., he uses split-complex arithmetic to express a hyperbola as

${\displaystyle z{z}^{*}=a^2.}$

It is used as the circumconic of triangle ${\displaystyle t_1,t_2,t_3.}$ Let ${\displaystyle s=t_1+t_2+t_3.}$ Then the nine-point conic is

${\displaystyle (z-\frac{s}{2})(z^{*}-\frac{s^{*}}{2})=\frac{a^2}{4}.}$

Allen's description of the nine-point hyperbola followed a development of the nine-point circle that Frank Morley and his son published in 1933. They requisitioned the unit circle in the complex plane as the circumcircle of the given triangle.

In 1953 Allen extended his study to a nine-point conic of a triangle inscribed in any central conic.^[2]

Yaglom

For Yaglom, a hyperbola is a Minkowskian circle as in the Minkowski plane. Yaglom's description of this geometry is found in the "Conclusion" chapter of a book that initially addresses Galilean geometry.^[3] He considers a triangle inscribed in a "circumcircle" which is in fact a hyperbola. In the Minkowski plane the nine-point hyperbola is also described as a circle:

… the midpoints of the sides of a triangle △ABCScript error: No such module "Check for unknown parameters". and the feet of its altitudes (as well as the midpoints of the segments joining the orthocenter of △ABCScript error: No such module "Check for unknown parameters". to its vertices) lie on a [Minkowskian] circle Template:Mvar whose radius is half the radius of the circumcircle of the triangle. It is natural to refer to S as the six- (nine-) point circle of the (Minkowskian) triangle △ABCScript error: No such module "Check for unknown parameters".; if △ABCScript error: No such module "Check for unknown parameters". has an incircle Template:Mvar, then the six- (nine-) point circle Template:Mvar of △ABCScript error: No such module "Check for unknown parameters". touches its incircle Template:Mvar (Fig.173).

Others

In 2005 J. A. Scott^[4] used the unit hyperbola as the circumconic of triangle ABC and found conditions for it to include six triangle centers: the centroid X(2), the orthocenter X(4), the Fermat points X(13) and X(14), and the Napoleon points X(17) and X(18) as listed in the Encyclopedia of Triangle Centers. Scott’s hyperbola is a Kiepert hyperbola of the triangle.

Christopher Bath^[5] describes a nine-point rectangular hyperbola passing through these centers: incenter X(1), the three excenters, the centroid X(2), the de Longchamps point X(20), and the three points obtained by extending the triangle medians to twice their cevian length.

References

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• Maxime Bôcher (1892) Nine-point Conic, Annals of Mathematics, link from Jstor.
• Maud A. Minthorn (1912) The Nine Point Conic, Master's dissertation at University of California, Berkeley, link from HathiTrust. Maude Ellen Minthorn, born 1883, LeMars, Iowa, died 1966, St. Petersburg, Florida. Dau. of Pennington Minthorn, 1856-1939, (brother of Hulda Minthorn Hoover, mother of Pres. Herbert Hoover) and Anna Mary Heald, 1887-1940, (sister of Franklin Herman Heald, founder of Lake Elsinore, California (WRH) Maud Minthorn also taught at Fresno, Cal, High School 1935-1940
• Bjørn Felsager (2004) Minkowski geometry, Part 1, Minkowski geometry, Part 2 ICME-10 Copenhagen.