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Consider a set of points $P=\{p_1,p_2,\ldots,p_n\}$ in the plane. Define $x_1$ (resp. $x_2$) to be the minimal (resp. maximal) $x$ coordinate of the points in $P$.

Now, let $c(P)$ be any curve, with differentiable curvature, that passes through all points in $P$, and is restricted to the domain $[x_1, x_2]$. Note that the restriction ensures that $c(P)$ does not extrapolate the $p_i$'s. Also, define $\kappa(c(P))$ to be the maximal curvature of $c(P)$ in its domain.

Can the $|\kappa(c(P))|$ be arbitrarily small, or does it have a lower bound? Does this change if $c(P)$ has continuous, but not necessarily differentiable, curvature in its domain?

Plausible answer (Updated after Rahul's comment:) Suppose not all $p_i$'s lie in a straight line. It seems to me that $\kappa$ is bounded below by the radius of the minimal circle that encloses all points in $P$.I don't know enough differential geometry to prove or refute this. Note that differentiable curvature is key; otherwise we could draw straight lines segments between the points, where the curvature is undefined as we switch from one segment to another . Side note this question is a variant of my older question.

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    Well, instead of addressing many super-special cases, I'll just say that my intuition could be wrong2012-04-07

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