The Whewell equation of a

plane curve In mathematics, a plane curve is a curve in a plane that may be either a Euclidean plane, an affine plane or a projective plane. The most frequently studied cases are smooth plane curves (including piecewise smooth plane curves), and algebraic ...

is an equation that relates the

tangential angle In geometry, the tangential angle of a curve in the Cartesian plane, at a specific point, is the angle between the tangent line to the curve at the given point and the -axis. (Some authors define the angle as the deviation from the direction of t ...

() with arclength (), where the tangential angle is the angle between the tangent to the curve and the -axis, and the arc length is the distance along the curve from a fixed point. These quantities do not depend on the coordinate system used except for the choice of the direction of the -axis, so this is an

intrinsic equation In geometry, an intrinsic equation of a curve is an equation that defines the curve using a relation between the curve's intrinsic properties, that is, properties that do not depend on the location and possibly the orientation of the curve. Ther ...

of the curve, or, less precisely, ''the'' intrinsic equation. If a curve is obtained from another by

translation Translation is the communication of the meaning of a source-language text by means of an equivalent target-language text. The English language draws a terminological distinction (which does not exist in every language) between ''transla ...

then their Whewell equations will be the same. When the relation is a function, so that tangential angle is given as a function of arclength, certain properties become easy to manipulate. In particular, the derivative of the tangential angle with respect to arclength is equal to the curvature. Thus, taking the derivative of the Whewell equation yields a

Cesàro equation In geometry, the Cesàro equation of a plane curve is an equation relating the curvature () at a point of the curve to the arc length () from the start of the curve to the given point. It may also be given as an equation relating the radius of curva ...

for the same curve. The concept is named after

William Whewell William Whewell ( ; 24 May 17946 March 1866) was an English polymath, scientist, Anglican priest, philosopher, theologian, and historian of science. He was Master of Trinity College, Cambridge. In his time as a student there, he achieved ...

, who introduced it in 1849, in a paper in the Cambridge Philosophical Transactions. In his conception, the angle used is the deviation from the direction of the curve at some fixed starting point, and this convention is sometimes used by other authors as well. This is equivalent to the definition given here by the addition of a constant to the angle or by rotating the curve.

Properties

If the curve is given parametrically in terms of the arc length , then is determined by :

\frac  = \begin \frac \\ \frac \end = \begin \cos \varphi \\ \sin \varphi \end \quad \text  \quad \left ,  \frac  \right ,  = 1 ,

which implies :

\frac = \tan \varphi.

Parametric equations for the curve can be obtained by integrating: :

\begin
x &= \int \cos \varphi \, ds \\
y &= \int \sin \varphi \, ds
\end

Since the curvature is defined by :

\kappa = \frac,

the

is easily obtained by differentiating the Whewell equation.

Examples

References

* Whewell, W. Of the Intrinsic Equation of a Curve, and its Application. Cambridge Philosophical Transactions, Vol. VIII, pp. 659-671, 1849
Google Books
* Todhunter, Isaac. William Whewell, D.D., An Account of His Writings, with Selections from His Literary and Scientific Correspondence. Vol. I. Macmillan and Co., 1876, London. Section 56: p. 317. * * Yates, R. C.: ''A Handbook on Curves and Their Properties'', J. W. Edwards (1952), "Intrinsic Equations" p124-5

External links

* {{MathWorld , title=Whewell Equation , urlname=WhewellEquation Curves