Difference between revisions of "Curvature"

(New page: Curvature is defined as the inverse of the radius length for circles. A line is treated as a circle with infinite radius, i.e. 0 curvature. The formula for curvature of an arbitrary functi...)
 
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Curvature is defined as the inverse of the radius length for circles. A line is treated as a circle with infinite radius, i.e. 0 curvature.
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'''Curvature''' is a a number associated with every point on a [[smooth curve]]s that describes "how curvy" the curve is at that point.  In particular, the "least curvy" curve is a [[line]], and fittingly lines have zero curvature.  For a [[circle]] of [[radius]] <math>r</math>, the curvature at every point is <math>\frac{1}{r}</math>. Intuitively, this grows smaller as <math>r</math> grows larger because one must turn much more sharply to follow the path of a circle of small radius than to follow the path of a circle with large radius.
The formula for curvature of an arbitrary function is
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<cmath>\dfrac{\frac{d^2y}{dx^2}}{((\frac{dy}{dx})^2+1)^{3/2}}</cmath>
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Given a twice-[[differentiable]] [[function]] <math>f(x)</math>, the curvature of the [[graph]] <math>y = f(x)</math> of the function at the point <math>(x, f(x))</math> is given by the formula
if y=f(x). A positive value indicates that the circle is above the function; a negative value, the circle is below.
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<cmath>\kappa(x) = \dfrac{f''(x)}{(f'(x)^2+1)^{3/2}}.</cmath>
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For a curve given in [[parametric]] form by the pair <math>(x(t), y(t))</math>, the curvature at a point is
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<cmath>\kappa(t) = \?.</cmath>
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This expression is invariant under positive-velocity reparametrizations, that is the curvature is a property of the curve and not the way in which you traverse it.
  
 
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[[Category:Calculus]]
 
[[Category:Calculus]]

Revision as of 11:21, 17 April 2008

Curvature is a a number associated with every point on a smooth curves that describes "how curvy" the curve is at that point. In particular, the "least curvy" curve is a line, and fittingly lines have zero curvature. For a circle of radius $r$, the curvature at every point is $\frac{1}{r}$. Intuitively, this grows smaller as $r$ grows larger because one must turn much more sharply to follow the path of a circle of small radius than to follow the path of a circle with large radius.

Given a twice-differentiable function $f(x)$, the curvature of the graph $y = f(x)$ of the function at the point $(x, f(x))$ is given by the formula \[\kappa(x) = \dfrac{f''(x)}{(f'(x)^2+1)^{3/2}}.\]

For a curve given in parametric form by the pair $(x(t), y(t))$, the curvature at a point is

\[\kappa(t) = \?.\] (Error compiling LaTeX. Unknown error_msg)

This expression is invariant under positive-velocity reparametrizations, that is the curvature is a property of the curve and not the way in which you traverse it.

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