Pole and polar
For a given circle, reciprocation in a circle means the transformation of each point in the plane into its polar line and each line in the plane into its pole.
Poles and polars have several useful properties:
- If a point P lies on a line l, then the pole L of the line l lies on the polar p of point P.
- If a point P moves along a line l, its polar p rotates about the pole L of the line l.
- If two tangent lines can be drawn from a pole to the conic section, then its polar passes through both tangent points.
- If a point lies on the conic section, its polar is the tangent through this point to the conic section.
- If a point P lies on its own polar line, then P is on the conic section.
- Each line has, with respect to a non-degenerated conic section, exactly one pole.
Special case of circlesEdit
The pole of a line L in a circle C is a point P that is the inversion in C of the point Q on L that is closest to the center of the circle. Conversely, the polar line (or polar) of a point P in a circle C is the line L such that its closest point Q to the center of the circle is the inversion of P in C.
The relationship between poles and polars is reciprocal. Thus, if a point A lies on the polar line q of a point Q, then the point Q must lie on the polar line a of the point A. The two polar lines a and q need not be parallel.
There is another description of the polar line of a point P in the case that it lies outside the circle C. In this case, there are two lines through P which are tangent to the circle, and the polar of P is the line joining the two points of tangency (not shown here). This shows that pole and polar line are concepts in the projective geometry of the plane and generalize with any nonsingular conic in the place of the circle C.
Reciprocation and projective dualityEdit
The concepts of a pole and its polar line were advanced in projective geometry. For instance, the polar line can be viewed as the set of projective harmonic conjugates of a given point, the pole, with respect to a conic. The operation of replacing every point by its polar and vice versa is known as a polarity.
General conic sectionsEdit
The concepts of pole, polar and reciprocation can be generalized from circles to other conic sections which are the ellipse, hyperbola and parabola. This generalization is possible because conic sections result from a reciprocation of a circle in another circle, and the properties involved, such as incidence and the cross-ratio, are preserved under all projective transformations.
Calculating the polar of a pointEdit
where Axx, Axy, Ayy, Bx, By, and C are the constants defining the equation. For such a conic section, the polar line to a given pole point (ξ, η) is defined by the equation
where D, E and F are likewise constants that depend on the pole coordinates (ξ, η)
Calculating the pole of a lineEdit
The pole of the line , relative to the non-degenerated conic section
can be calculated in two steps.
First, calculate the numbers x, y and z from
Now, the pole is the point with coordinates
In planar dynamics a pole is a center of rotation, the polar is the force line of action and the conic is the mass–inertia matrix. The pole–polar relationship is used to define the center of percussion of a planar rigid body. If the pole is the hinge point, then the polar is the percussion line of action as described in planar screw theory.
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- "Apollonius' Problem: A Study of Solutions and Their Connections" (PDF). Retrieved 2013-06-04.
- John Alexiou Thesis, Chapter 5, pp. 80–108 Archived 2011-07-19 at the Wayback Machine
|Wikimedia Commons has media related to Poles and polars.|
- Interactive animation with multiple poles and polars at Cut-the-Knot
- Interactive animation with one pole and its polar
- Interactive 3D with coloured multiple poles/polars - open source
- Weisstein, Eric W. "Polar". MathWorld.
- Weisstein, Eric W. "Reciprocation". MathWorld.
- Weisstein, Eric W. "Inversion pole". MathWorld.
- Weisstein, Eric W. "Reciprocal curve". MathWorld.
- Tutorial at Math-abundance