Minkowski-Steiner formula

In mathematics, the Minkowski-Steiner formula is a formula relating the surface area and volume of compact subsets of Euclidean space. More precisely, it defines the surface area as the "derivative" of enclosed volume in an appropriate sense.

The Minkowski-Steiner formula is used, together with the Brunn-Minkowski theorem, to prove the isoperimetric inequality. It is named after the Lithuanian mathematician Hermann Minkowski.

tatement of the Minkowski-Steiner formula

Let $n geq 2$ , and let $A subsetneq mathbb{R}^{n}$ be a compact set. Let $mu (A)$ denote the Lebesgue measure (volume) of $A$ . Define the quantity $lambda (partial A)$ by the Minkowski-Steiner formula

: $lambda (partial A) := liminf_{delta o 0} frac{mu left( A + overline{B_{delta
ight) - mu (A)}{delta},$

where

: $overline{B_{delta := left{ x = (x_{1}, dots, x_{n}) in mathbb{R}^{n} left| | x | := sqrt{x_{1}^{2} + dots + x_{n}^{2 leq delta
ight.
ight}$

denotes the closed ball of radius $delta > 0$ , and

: $A + overline{B_{delta := left{ a + b in mathbb{R}^{n} left| a in A, b in overline{B_{delta
ight.
ight}$

is the Minkowski sum of $A$ and $overline{B_{delta$ , so that

: $A + overline{B_{delta = left{ x in mathbb{R}^{n} left| | x - a | leq delta mbox{ for some } a in A
ight.
ight}.$

Remarks

urface measure

For "sufficiently regular" sets $A$ , the quantity $lambda (partial A)$ does indeed correspond with the $(n - 1)$ -dimensional measure of the boundary $partial A$ of $A$ . See Federer (1969) for a full treatment of this problem.

Convex sets

When the set $A$ is a convex set, the lim-inf above is a true limit, and one can show that

: $mu left( A + overline{B_{delta
ight) = mu (A) + lambda (partial A) delta + sum_{i = 2}^{n - 1} lambda_{i} (A) delta^{i} + omega_{n} delta^{n},$

where the $lambda_{i}$ are some continuous functions of $A$ and $omega_{n}$ denotes the measure (volume) of the unit ball in $mathbb{R}^{n}$ :

: $omega_{n} = frac{2 pi^{n / 2{n Gamma (n / 2)},$

where $Gamma$ denotes the Gamma function.

Example: volume and surface area of a ball

Taking $A = overline{B_{R$ gives the following well-known formula for the surface area of the sphere of radius $R$ , $S_{R} := partial B_{R}$ :

: $lambda (S_{R}) = lim_{delta o 0} frac{mu left( overline{B_{R + overline{B_{delta
ight) - mu left( overline{B_{R
ight)}{delta}$ :: $= lim_{delta o 0} frac{ [ (R + delta)^{n} - R^{n} ] omega_{n{delta}$ :: $= n R^{n - 1} omega_{n},$

where $omega_{n}$ is as above.

References

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