Tangent indicatrix

tantrix

The tangent indicatrix $ T $ of a regular curve $ \gamma : {[ a,b ] } \rightarrow {\mathbf R ^ {n} } $ is the curve of oriented unit vectors tangent to $ \gamma $.

More precisely, if $ \gamma : {[ a,b ] } \rightarrow {\mathbf R ^ {n} } $ is a differentiable curve whose velocity vector $ {\dot \gamma } = { {d \gamma } / {dt } } $ never vanishes, then

$$ T ( t ) = { \frac{ {\dot \gamma } ( t ) }{\left | { {\dot \gamma } ( t ) } \right | } } . $$

The tangent indicatrix $T$ of any regular curve in $\mathbf{R}^{n}$ thus traces out a curve on the unit sphere $S^{n-1} \in \mathbf{R}^{n}$ which, as a point set, is independent of the parametrization of $\gamma$. A direct computation shows that the "speeds" of $T$ and $\gamma$ relate via the curvature function $\kappa$ of $\gamma$ (cf. also Curvature):

$$ \left | { { \frac{dT }{dt } } } \right | = \kappa ( t ) \left | { { \frac{d \gamma }{dt } } } \right | . $$

It follows immediately that the length of the tangent indicatrix on $ S ^ {n - 1 } $ gives the total curvature (the integral of $ \kappa $ with respect to arc-length; cf. also Complete curvature) of the original curve $ \gamma $. Because of this, the tangent indicatrix has proven useful, among other things, in studying total curvature of closed space curves (see [a1], p. 29 ff).

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