# Evolute The evolute of a curve (in this case, an ellipse) is the envelope of its normals.

In the differential geometry of curves, the evolute of a curve is the locus of all its centers of curvature. That is to say that when the center of curvature of each point on a curve is drawn, the resultant shape will be the evolute of that curve. The evolute of a circle is therefore a single point at its center. Equivalently, an evolute is the envelope of the normals to a curve.

The evolute of a curve, a surface, or more generally a submanifold, is the caustic of the normal map. Let M be a smooth, regular submanifold in Rn. For each point p in M and each vector v, based at p and normal to M, we associate the point p + v. This defines a Lagrangian map, called the normal map. The caustic of the normal map is the evolute of M.

Evolutes are closely connected to involutes: A curve is the evolute of any of its involutes.

## History

Apollonius (c. 200 BC) discussed evolutes in Book V of his Conics. However, Huygens is sometimes credited with being the first to study them (1673). Huygens formulated his theory of evolutes sometime around 1659 to help solve the problem of finding the tautochrone curve, which in turn helped him construct an isochronous pendulum. This was because the tautochrone curve is a cycloid, and the cycloid has the unique property that its evolute is also a cycloid. The theory of evolutes, in fact, allowed Huygens to achieve many results that would later be found using calculus.

## Evolute of a parametric curve

If ${\vec {x}}={\vec {c}}(t),\;t\in [t_{1},t_{2}]$ is the parametric representation of a regular curve in the plane with its curvature nowhere 0 and $\rho (t)$ its curvature radius and ${\vec {n}}(t)$ the unit normal pointing to the curvature center, then

${\vec {E}}(t)={\vec {c}}(t)+\rho (t){\vec {n}}(t)$ describes the evolute of the given curve.

For ${\vec {c}}(t)=(x(t),y(t))^{\mathsf {T}}$ and ${\vec {E}}=(X,Y)^{\mathsf {T}}$ one gets

$X(t)=x(t)-{\frac {y'(t){\Big (}x'(t)^{2}+y'(t)^{2}{\Big )}}{x'(t)y''(t)-x''(t)y'(t)}}$ and
$Y(t)=y(t)+{\frac {x'(t){\Big (}x'(t)^{2}+y'(t)^{2}{\Big )}}{x'(t)y''(t)-x''(t)y'(t)}}.$ ## Properties of the evolute

In order to derive properties of a regular curve it is advantageous to use the arc length $s$ of the given curve as its parameter, because of ${\textstyle \left|{\vec {c}}'\right|=1}$ and ${\textstyle {\vec {n}}'=-{\vec {c}}'/\rho }$ (see Frenet–Serret formulas). Hence the tangent vector of the evolute ${\textstyle {\vec {E}}={\vec {c}}+\rho {\vec {n}}}$ is:

${\vec {E}}'={\vec {c}}'+\rho '{\vec {n}}+\rho {\vec {n}}'=\rho '{\vec {n}}\ .$ From this equation one gets the following properties of the evolute:

• At points with $\rho '=0$ the evolute is not regular. That means: at points with maximal or minimal curvature (vertices of the given curve) the evolute has cusps. (See the diagrams of the evolutes of the parabola, the ellipse, the cycloid and the nephroid.)
• For any arc of the evolute that does not include a cusp, the length of the arc equals the difference between the radii of curvature at its endpoints. This fact leads to an easy proof of the Tait–Kneser theorem on nesting of osculating circles.
• The normals of the given curve at points of nonzero curvature are tangents to the evolute, and the normals of the curve at points of zero curvature are asymptotes to the evolute. Hence: the evolute is the envelope of the normals of the given curve.
• At sections of the curve with $\rho '>0$ or $\rho '<0$ the curve is an involute of its evolute. (In the diagram: The blue parabola is an involute of the red semicubic parabola, which is actually the evolute of the blue parabola.)

Proof of the last property:
Let be $\rho '>0$ at the section of consideration. An involute of the evolute can be described as follows:

${\vec {C}}_{0}={\vec {E}}-{\frac {{\vec {E}}'}{\left|{\vec {E}}'\right|}}\left(\int _{0}^{s}\left|{\vec {E}}'(w)\right|\mathrm {d} w+l_{0}\right),$ where $l_{0}$ is a fixed string extension (see Involute of a parameterized curve ).
With ${\vec {E}}={\vec {c}}+\rho {\vec {n}}\;,\;{\vec {E}}'=\rho '{\vec {n}}$ and $\rho '>0$ one gets
${\vec {C}}_{0}={\vec {c}}+\rho {\vec {n}}-{\vec {n}}\left(\int _{0}^{s}\rho '(w)\;\mathrm {d} w\;+l_{0}\right)={\vec {c}}+(\rho (0)-l_{0})\;{\vec {n}}\,.$ That means: For the string extension $l_{0}=\rho (0)$ the given curve is reproduced.

• Parallel curves have the same evolute.

Proof: A parallel curve with distance $d$ off the given curve has the parametric representation ${\vec {c}}_{d}={\vec {c}}+d{\vec {n}}$ and the radius of curvature $\rho _{d}=\rho -d$ (see parallel curve). Hence the evolute of the parallel curve is

${\vec {E}}_{d}={\vec {c}}_{d}+\rho _{d}{\vec {n}}={\vec {c}}+d{\vec {n}}+(\rho -d){\vec {n}}={\vec {c}}+\rho {\vec {n}}={\vec {E}}\;.$ ## Examples

### Evolute of a parabola

For the parabola with the parametric representation $(t,t^{2})$ one gets from the formulae above the equations:

$X=\cdots =-4t^{3}$ $Y=\cdots ={\frac {1}{2}}+3t^{2}\,,$ which describes a semicubic parabola

### Evolute of an ellipse

For the ellipse with the parametric representation $(a\cos t,b\sin t)$ one gets:

$X=\cdots ={\frac {a^{2}-b^{2}}{a}}\cos ^{3}t$ $Y=\cdots ={\frac {b^{2}-a^{2}}{b}}\sin ^{3}t\;.$ These are the equations of a non symmetric astroid. Eliminating parameter $t$ leads to the implicit representation
$(aX)^{\tfrac {2}{3}}+(bY)^{\tfrac {2}{3}}=(a^{2}-b^{2})^{\tfrac {2}{3}}\ .$ ### Evolute of a cycloid

For the cycloid with the parametric representation $(r(t-\sin t),r(1-\cos t))$ the evolute will be:

$X=\cdots =r(t+\sin t)$ $Y=\cdots =r(\cos t-1)$ which describes a transposed replica of itself.

## Evolutes of some curves

The evolute

$(X,Y)=\left(-y'{\frac {{x'}^{2}+{y'}^{2}}{x'y''-x''y'}}\;,\;x'{\frac {{x'}^{2}+{y'}^{2}}{x'y''-x''y'}}\right).$ 