Let A be a convex compact set in the plane (with a piecewise smooth boundary, say). We want to `inflate' it in such a way that the diameter does not increase. More accurately, we are looking for all sets C such that a) A is a subset of C; b) diam(A)=diam(C) Let now B is the largest possible set C which satisfies these two properties. By `largest' I mean either that it m(B) = max m(C), where m is the Lebesgue measure; or that B actually contains any C with these properties. Let us call B the *isodiametric hull* of A. The simplest example of A is of course the square: here B is the superscribed disc, and it is the isodiametric hull of A in the strong sense. Another example is the equilateral triangle, for which B is the [Reuleaux triangle][1]. Similarly, for any regular 2n-gon we have the disc, and for any regular (2n+1)-gon its isodiametric hull is a Reuleaux polygon. The first non-trivial example that comes to mind is an isosceles triangle that isn't equilateral. It is clear that the hull is always a set of constant diameter but how does one actually obtain it? It seems that its boundary - a curve of constant width - is not a finite union of circular arcs. I wonder if all this is well known (being such a natural question!). In particular, does the isodiametric hull of a set always exists in the strong sense? **Added:** of course, if there is no IDH in the strong sense, B may not be unique. Its area *is* unique, though. How does one find it? [1]: http://mathworld.wolfram.com/ReuleauxTriangle.html