Strophoid


In geometry, a strophoid is a curve generated from a given curve and points and as follows: Let be a variable line passing through and intersecting at. Now let and be the two points on whose distance from is the same as the distance from to . The locus of such points and is then the strophoid of with respect to the pole and fixed point. Note that and are at right angles in this construction.
In the special case where is a line, lies on, and is not on, then the curve is called an oblique strophoid. If, in addition, is perpendicular to then the curve is called a right strophoid, or simply strophoid by some authors. The right strophoid is also called the logocyclic curve or foliate.

Equations

Polar coordinates

Let the curve be given by where the origin is taken to be. Let be the point. If is a point on the curve the distance from to is
The points on the line have polar angle, and the points at distance from on this line are distance from the origin. Therefore, the equation of the strophoid is given by

Cartesian coordinates

Let be given parametrically by. Let be the point and let be the point. Then, by a straightforward application of the polar formula, the strophoid is given parametrically by:
where

An alternative polar formula

The complex nature of the formulas given above limits their usefulness in specific cases. There is an alternative form which is sometimes simpler to apply. This is particularly useful when is a sectrix of Maclaurin with poles and.
Let be the origin and be the point. Let be a point on the curve, the angle between and the -axis, and the angle between and the -axis. Suppose can be given as a function, say Let be the angle at so We can determine in terms of using the law of sines. Since
Let and be the points on that are distance from, numbering so that and is isosceles with vertex angle, so the remaining angles, and are The angle between and the -axis is then
By a similar argument, or simply using the fact that and are at right angles, the angle between and the -axis is then
The polar equation for the strophoid can now be derived from and from the formula above:
is a sectrix of Maclaurin with poles and when is of the form in that case and will have the same form so the strophoid is either another sectrix of Maclaurin or a pair of such curves. In this case there is also a simple polar equation for the polar equation if the origin is shifted to the right by.

Specific cases

Strophoids of lines are actually expressible as singular cubics in the projective plane.

Oblique strophoids

Let be a line through. Then, in the notation used above, where is a constant. Then and The polar equations of the resulting strophoid, called an oblique strphoid, with the origin at are then
and
It's easy to check that these equations describe the same curve.
Moving the origin to and replacing with produces
and rotating by in turn produces
In rectangular coordinates, with a change of constant parameters, this is
This is a cubic curve and, by the expression in polar coordinates it is rational. It has a crunode at and the line is an asymptote.

The right strophoid

Putting in
gives
This is called the right strophoid and corresponds to the case where is the -axis, is the origin, and is the point.
The Cartesian equation is
The curve resembles the Folium of Descartes and the line is an asymptote to two branches. The curve has two more asymptotes, in the plane with complex coordinates, given by
This curve passes through the two circular points at infinity and is a special case of a focal circular Van Rees cubic.

Circles

Let be a circle through and, where is the origin and is the point. Then, in the notation used above, where is a constant. Then and The polar equations of the resulting strophoid, called an oblique strophoid, with the origin at are then
and
These are the equations of the two circles which also pass through and and form angles of with at these points.