McMullen problem

The McMullen problem is an open problem in discrete geometry named after Peter McMullen.

Statement[edit]

In 1972, David G. Larman wrote about the following problem:^[1]

Determine the largest number ${\displaystyle \nu (d)}$ such that for any given ${\displaystyle \nu (d)}$ points in general position in the ${\displaystyle d}$-dimensional affine space ${\displaystyle \mathbb {R} ^{d}}$ there is a projective transformation mapping these points into convex position (so they form the vertices of a convex polytope).

Larman credited the problem to a private communication by Peter McMullen.

Equivalent formulations[edit]

Gale transform[edit]

Using the Gale transform, this problem can be reformulated as:

Determine the smallest number ${\displaystyle \mu (d)}$ such that for every set of ${\displaystyle \mu (d)}$ points ${\displaystyle X=\{x_{1},x_{2},\dots ,x_{\mu (d)}\}}$ in linearly general position on the sphere ${\displaystyle S^{d-1}}$ it is possible to choose a set ${\displaystyle Y=\{\varepsilon _{1}x_{1},\varepsilon _{2}x_{2},\dots ,\varepsilon _{\mu (d)}x_{\mu (d)}\}}$ where ${\displaystyle \varepsilon _{i}=\pm 1}$ for ${\displaystyle i=1,2,\dots ,\mu (d)}$, such that every open hemisphere of ${\displaystyle S^{d-1}}$ contains at least two members of ${\displaystyle Y}$.

The numbers ${\displaystyle \nu }$ of the original formulation of the McMullen problem and ${\displaystyle \mu }$ of the Gale transform formulation are connected by the relationships

$${\displaystyle {\begin{aligned}\mu (k)&=\min\{w\mid w\leq \nu (w-k-1)\}\\\nu (d)&=\max\{w\mid w\geq \mu (w-d-1)\}\end{aligned}}}$$

Partition into nearly-disjoint hulls[edit]

Also, by simple geometric observation, it can be reformulated as:

Determine the smallest number ${\displaystyle \lambda (d)}$ such that for every set ${\displaystyle X}$ of ${\displaystyle \lambda (d)}$ points in ${\displaystyle \mathbb {R} ^{d}}$ there exists a partition of ${\displaystyle X}$ into two sets ${\displaystyle A}$ and ${\displaystyle B}$ with

$${\displaystyle \operatorname {conv} (A\backslash \{x\})\cap \operatorname {conv} (B\backslash \{x\})\not =\varnothing ,\forall x\in X.\,}$$

The relation between ${\displaystyle \mu }$ and ${\displaystyle \lambda }$ is

$${\displaystyle \mu (d+1)=\lambda (d),\qquad d\geq 1\,}$$

Projective duality[edit]

The equivalent projective dual statement to the McMullen problem is to determine the largest number ${\displaystyle \nu (d)}$ such that every set of ${\displaystyle \nu (d)}$ hyperplanes in general position in d-dimensional real projective space form an arrangement of hyperplanes in which one of the cells is bounded by all of the hyperplanes.

Results[edit]

This problem is still open. However, the bounds of ${\displaystyle \nu (d)}$ are in the following results:

• David Larman proved in 1972 that^[1]
  $${\displaystyle 2d+1\leq \nu (d)\leq (d+1)^{2}.}$$

  
• Michel Las Vergnas proved in 1986 that^[2]
  $${\displaystyle \nu (d)\leq {\frac {(d+1)(d+2)}{2}}.}$$

  
• Jorge Luis Ramírez Alfonsín proved in 2001 that^[3]
  $${\displaystyle \nu (d)\leq 2d+\left\lceil {\frac {d+1}{2}}\right\rceil .}$$

  

The conjecture of this problem is that ${\displaystyle \nu (d)=2d+1}$. This has been proven for ${\displaystyle d=2,3,4}$.^[1][4]

References[edit]