Isoperimetric point
In
Isoperimetric points in the sense of Veldkamp exist only for triangles satisfying certain conditions. The isoperimetric point of △ABC in the sense of Veldkamp, if it exists, has the following trilinear coordinates.[3]
Given any triangle △ABC one can associate with it a point P having trilinear coordinates as given above. This point is a triangle center and in Clark Kimberling's Encyclopedia of Triangle Centers (ETC) it is called the isoperimetric point of the triangle △ABC. It is designated as the triangle center X(175).[4] The point X(175) need not be an isoperimetric point of triangle △ABC in the sense of Veldkamp. However, if isoperimetric point of triangle △ABC in the sense of Veldkamp exists, then it would be identical to the point X(175).
The point P with the property that the triangles △PBC, △PCA, △PAB have equal perimeters has been studied as early as 1890 in an article by
Existence of isoperimetric point in the sense of Veldkamp
Let △ABC be any triangle. Let the sidelengths of this triangle be a, b, c. Let its circumradius be R and inradius be r. The necessary and sufficient condition for the existence of an isoperimetric point in the sense of Veldkamp can be stated as follows.[1]
- The triangle △ABC has an isoperimetric point in the sense of Veldkamp if and only if
For all acute angled triangles △ABC we have a + b + c > 4R + r, and so all acute angled triangles have isoperimetric points in the sense of Veldkamp.
Properties
Let P denote the triangle center X(175) of triangle △ABC.[4]
- P lies on the line joining the Gergonne pointof △ABC.
- If P is an isoperimetric point of △ABC in the sense of Veldkamp, then the excirclesof triangles △PBC, △PCA, △PAB are pairwise tangent to one another and P is their radical center.
- If P is an isoperimetric point of △ABC in the sense of Veldkamp, then the perimeters of △PBC, △PCA, △PAB are equal to
Soddy circles
Given a triangle △ABC one can draw circles in the plane of △ABC with centers at A, B, C such that they are tangent to each other externally. In general, one can draw two new circles such that each of them is tangential to the three circles with A, B, C as centers. (One of the circles may degenerate into a straight line.) These circles are the
The triangle center X(175), the isoperimetric point in the sense of Kimberling, is the outer Soddy point of △ABC.
References
- ^ JSTOR 2323159.
- S2CID 122898960.
- ^ Kimberling, Clark. "Isoperimetric Point and Equal Detour Point". Retrieved 27 May 2012.
- ^ a b c Kimberling, Clark. "X(175) Isoperimetric Point". Archived from the original on 19 April 2012. Retrieved 27 May 2012.
- ^ The article by Emile Lemoine can be accessed in Gallica. The paper begins at page 111 and the point is discussed in page 126.Gallica
- ^ a b Nikolaos Dergiades (2007). "The Soddy Circles" (PDF). Forum Geometricorum. 7: 191–197. Retrieved 29 May 2012.
- ^ "Soddy Circles". Retrieved 29 May 2012.
External links
- isoperimetric and equal detour points - interactive illustration on Geogebratube