Unsolved problem in mathematics :
For how many points is it always possible to projectively transform the points into convex position?
The McMullen problem is an open problem in discrete geometry named after Peter McMullen .
Statement
In 1972, David G. Larman wrote about the following problem:[ 1]
Determine the largest number
ν ν -->
(
d
)
{\displaystyle \nu (d)}
such that for any given
ν ν -->
(
d
)
{\displaystyle \nu (d)}
points in
general position in the
d
{\displaystyle d}
-dimensional affine space
R
d
{\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.
Using the Gale transform , this problem can be reformulated as:
Determine the smallest number
μ μ -->
(
d
)
{\displaystyle \mu (d)}
such that for every set of
μ μ -->
(
d
)
{\displaystyle \mu (d)}
points
X
=
{
x
1
,
x
2
,
… … -->
,
x
μ μ -->
(
d
)
}
{\displaystyle X=\{x_{1},x_{2},\dots ,x_{\mu (d)}\}}
in linearly general position on the sphere
S
d
− − -->
1
{\displaystyle S^{d-1}}
it is possible to choose a set
Y
=
{
ε ε -->
1
x
1
,
ε ε -->
2
x
2
,
… … -->
,
ε ε -->
μ μ -->
(
d
)
x
μ μ -->
(
d
)
}
{\displaystyle Y=\{\varepsilon _{1}x_{1},\varepsilon _{2}x_{2},\dots ,\varepsilon _{\mu (d)}x_{\mu (d)}\}}
where
ε ε -->
i
=
± ± -->
1
{\displaystyle \varepsilon _{i}=\pm 1}
for
i
=
1
,
2
,
… … -->
,
μ μ -->
(
d
)
{\displaystyle i=1,2,\dots ,\mu (d)}
, such that every open hemisphere of
S
d
− − -->
1
{\displaystyle S^{d-1}}
contains at least two members of
Y
{\displaystyle Y}
.
The numbers
ν ν -->
{\displaystyle \nu }
of the original formulation of the McMullen problem and
μ μ -->
{\displaystyle \mu }
of the Gale transform formulation are connected by the relationships
μ μ -->
(
k
)
=
min
{
w
∣ ∣ -->
w
≤ ≤ -->
ν ν -->
(
w
− − -->
k
− − -->
1
)
}
ν ν -->
(
d
)
=
max
{
w
∣ ∣ -->
w
≥ ≥ -->
μ μ -->
(
w
− − -->
d
− − -->
1
)
}
{\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
Also, by simple geometric observation, it can be reformulated as:
Determine the smallest number
λ λ -->
(
d
)
{\displaystyle \lambda (d)}
such that for every set
X
{\displaystyle X}
of
λ λ -->
(
d
)
{\displaystyle \lambda (d)}
points in
R
d
{\displaystyle \mathbb {R} ^{d}}
there exists a
partition of
X
{\displaystyle X}
into two sets
A
{\displaystyle A}
and
B
{\displaystyle B}
with
conv
-->
(
A
∖ ∖ -->
{
x
}
)
∩ ∩ -->
conv
-->
(
B
∖ ∖ -->
{
x
}
)
≠
∅ ∅ -->
,
∀ ∀ -->
x
∈ ∈ -->
X
.
{\displaystyle \operatorname {conv} (A\backslash \{x\})\cap \operatorname {conv} (B\backslash \{x\})\not =\varnothing ,\forall x\in X.\,}
The relation between
μ μ -->
{\displaystyle \mu }
and
λ λ -->
{\displaystyle \lambda }
is
μ μ -->
(
d
+
1
)
=
λ λ -->
(
d
)
,
d
≥ ≥ -->
1
{\displaystyle \mu (d+1)=\lambda (d),\qquad d\geq 1\,}
Projective duality
An arrangement of lines dual to the regular pentagon. Every five-line projective arrangement, like this one, has a cell touched by all five lines. However, adding the line at infinity produces a six-line arrangement with six pentagon faces and ten triangle faces; no face is touched by all of the lines. Therefore, the solution to the McMullen problem for d = 2 is ν = 5.
The equivalent projective dual statement to the McMullen problem is to determine the largest number
ν ν -->
(
d
)
{\displaystyle \nu (d)}
such that every set of
ν ν -->
(
d
)
{\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
This problem is still open. However, the bounds of
ν ν -->
(
d
)
{\displaystyle \nu (d)}
are in the following results:
David Larman proved in 1972 that[ 1]
2
d
+
1
≤ ≤ -->
ν ν -->
(
d
)
≤ ≤ -->
(
d
+
1
)
2
.
{\displaystyle 2d+1\leq \nu (d)\leq (d+1)^{2}.}
Michel Las Vergnas proved in 1986 that[ 2]
ν ν -->
(
d
)
≤ ≤ -->
(
d
+
1
)
(
d
+
2
)
2
.
{\displaystyle \nu (d)\leq {\frac {(d+1)(d+2)}{2}}.}
Jorge Luis Ramírez Alfonsín proved in 2001 that[ 3]
ν ν -->
(
d
)
≤ ≤ -->
2
d
+
⌈
d
+
1
2
⌉
.
{\displaystyle \nu (d)\leq 2d+\left\lceil {\frac {d+1}{2}}\right\rceil .}
The conjecture of this problem is that
ν ν -->
(
d
)
=
2
d
+
1
{\displaystyle \nu (d)=2d+1}
. This has been proven for
d
=
2
,
3
,
4
{\displaystyle d=2,3,4}
.[ 1] [ 4]
References
^ a b c Larman, D. G. (1972), "On sets projectively equivalent to the vertices of a convex polytope", The Bulletin of the London Mathematical Society , 4 : 6–12, doi :10.1112/blms/4.1.6 , MR 0307040
^ Las Vergnas, Michel (1986), "Hamilton paths in tournaments and a problem of McMullen on projective transformations in
R
d
{\displaystyle \mathbb {R} ^{d}}
", The Bulletin of the London Mathematical Society , 18 (6): 571–572, doi :10.1112/blms/18.6.571 , MR 0859948
^ Ramírez Alfonsín, J. L. (2001), "Lawrence oriented matroids and a problem of McMullen on projective equivalences of polytopes", European Journal of Combinatorics , 22 (5): 723–731, doi :10.1006/eujc.2000.0492 , MR 1845496
^ Forge, David; Las Vergnas, Michel ; Schuchert, Peter (2001), "10 points in dimension 4 not projectively equivalent to the vertices of a convex polytope", Combinatorial geometries (Luminy, 1999), European Journal of Combinatorics , 22 (5): 705–708, doi :10.1006/eujc.2000.0490 , MR 1845494