Evolute

of a plane curve

The set $ \widetilde \gamma $ of the centres of curvature of the given curve $ \gamma $. If $ \mathbf r = \mathbf r ( s) $( where $ s $ is the arc length parameter of $ \gamma $) is the equation of $ \gamma $, then the equation of its evolute has the form

$$ \widetilde{\mathbf r} = \mathbf r + \frac{1}{k} {\pmb\nu } , $$

where $ k $ is the curvature and $ {\pmb\nu } $ the unit normal to $ \gamma $. The figures shows the construction of the evolute in three typical cases:

a) if along the entire curve $ k ^ \prime $ has a fixed sign and $ k $ does not vanish;

Figure: e036670a

Figure: e036670b

b) if along the entire curve $ k ^ \prime $ has a fixed sign and $ k $ vanishes for $ s = s _ {0} $; and

c) if $ k ^ \prime > 0 $ for $ s < s _ {0} $; $ k ^ \prime ( s) < 0 $ for $ s > s _ {0} $; $ k ^ \prime ( s _ {0} ) = 0 $, and $ k $ does not vanish (the point of the evolute corresponding to $ s = s _ {0} $ is a cusp).

Figure: e036670c

The length of the arc of the evolute corresponding to the segment $ s _ {1} \leq s \leq s _ {2} $ of $ \gamma $ is

$$ \widetilde{s} ( s _ {1} , s _ {2} ) = \left | \frac{1}{k ( s _ {2} ) } - \frac{1}{k ( s _ {1} ) } \right | . $$

The evolute is the envelope of the normals to $ \gamma $. The curve $ \gamma $ is called the evolvent of its evolute (cf. Evolvent of a plane curve).

Comments

The evolvent is also called the involute; thus, if $ \gamma ^ \prime $ is the evolute of $ \gamma $, then $ \gamma $ is the involute of $ \gamma ^ \prime $, cf. Evolvent of a plane curve.

References