Pedal equation
For a plane curve C and a given fixed point O, the pedal equation of the curve is a relation between r and p where r is the distance from O to a point on C and p is the perpendicular distance from O to the tangent line to C at the point. The point O is called the pedal point and the values r and p are sometimes called the pedal coordinates of a point relative to the curve and the pedal point. Some curves have particularly simple pedal equations and knowing the pedal equation of a curve may simplify the calculation of certain of its properties such as curvature.
Equations
Cartesian coordinates
For C given in rectangular coordinates by f(x, y) = 0, and with O taken to be the origin, the pedal coordinates of the point (x, y) are given by:[1]
The pedal equation can be found by eliminating x and y from these equations and the equation of the curve.
The expression for p may be simplified if the equation of the curve is written in homogeneous coordinates by introducing a variable z, so that the equation of the curve is g(x, y, z) = 0. The value of p is then given by[2]
where the result is evaluated at z=1
Polar coordinates
For C given in polar coordinates by r = f(θ), then
where ψ is the polar tangential angle given by
The pedal equation can be found by eliminating θ from these equations.[3]
Pedal equations for specific curves
Sinusoidal spirals
For a sinusoidal spiral written in the form
the polar tangential angle is
which produces the pedal equation
The pedal equation for a number of familiar curves can be obtained setting n to specific values:[4]
n | Curve | Pedal point | Pedal eq. |
---|---|---|---|
1 | Circle with radius a | Point on circumference | pa = r2 |
−1 | Line | Point distance a from line | p = a |
1⁄2 | Cardioid | Cusp | p2a = r3 |
− 1⁄2 | Parabola | Focus | p2 = ar |
2 | Lemniscate of Bernoulli | Center | pa2 = r3 |
−2 | Rectangular hyperbola | Center | rp = a2 |
Epi- and hypocycloids
For a epi- or hypocycloid given by parametric equations
the pedal equation with respect to the origin is[5]
or[6]
with
Special cases obtained by setting b= a⁄n for specific values of n include:
n | Curve | Pedal eq. |
---|---|---|
1, − 1⁄2 | Cardioid | |
2, − 2⁄3 | Nephroid | |
−3, − 3⁄2 | Deltoid | |
−4, − 4⁄3 | Astroid |
Other curves
Other pedal equations are:[7]
Curve | Equation | Pedal point | Pedal eq. |
---|---|---|---|
Ellipse | Center | ||
Hyperbola | Center | ||
Ellipse | Focus | ||
Hyperbola | Focus | ||
Logarithmic spiral | Pole |
See also
References
- R.C. Yates (1952). "Pedal Equations". A Handbook on Curves and Their Properties. Ann Arbor, MI: J. W. Edwards. pp. 166 ff.
- J. Edwards (1892). Differential Calculus. London: MacMillan and Co. pp. 161 ff.