## Abstract

The problem of partitioning the union of disks, which arises in theories of competition between plants, is analysed from a general point of view. Some simple and natural assumptions such as connectedness, invariance under translation, rotation and change of scale, and monotonicity and continuity properties of the partition sets are imposed. From these it is proved that the partition is specified by giving a boundary curve between two disks with the very explicit form: R$_{x}^{\alpha}$ - $|$r - x$|^{\alpha}$ = R$_{y}^{\alpha}$ - $|$r - y$|^{\alpha}$, $\alpha \geq $ 1, where R$_{x}$, R$_{y}$ are the radii of the disks, x, y are their centres and r is a point on the boundary. This includes the Johnson-Mehl construction ($\alpha $ = 1), the common chord ($\alpha $ = 2) and the perimeter of the larger disk ($\alpha \rightarrow \infty $). Larger disks dominate smaller ones if and only if $\alpha $ > 1, so that $\eta $ = 1 - 1/$\alpha $, 0 $\leq \eta $ < 1, is a natural index measuring the strength of domination. It is proved that a partition implies the existence of three-dimensional regions which are such that the projection on the plane of their exposed upper surface yields the partition (the reverse implication is trivial). Thus the partition implies, in a sense, the existence of a related three-dimensional crown shape. The partition rules make severe restrictions on these shapes. Making the further assumption that crowns of different sizes are 'similar' results in the specific crown surface (z/$\beta $R)$^{\alpha}$ + ($|$r - x$|$/R)$^{\alpha}$ = 1, where z > O, $\alpha \geq $ 1 and $\beta $ > 0. The obvious special cases are $\eta $ = 0 (cones, for conifers), $\eta $ = $\frac{1}{2}$ (ellipsoids of revolution, used by other authors for broadleaf trees) and $\eta $ = 1 (cylinders or umbrellas, perhaps for flat topped plants). The results apply equally to N-dimensional spheres, while some apply to more general shapes. The disk partitions also generate partitions of [Note: See the image of page 423 for this formatted text] R$^{2}$, giving a natural prescription for 'growing space' which is simpler than those of some other authors.