In mathematics, a quadratic set is a set of points in a projective space that bears the same essential incidence properties as a quadric (conic section in a projective plane, sphere or cone or hyperboloid in a projective space).
Let
akP=({lP},{lG},\in)
{lQ}
{lP}
(QS1) Every line
g
{lG}
{lQ}
{lQ}
(
g
{lQ}
|g\cap{lQ}|=0
{lQ}
|g\cap{lQ}|=1
g\cap{lQ}=g
{lQ}
|g\cap{lQ}|=2
(QS2) For any point
P\in{lQ}
{lQ}P
P
{lP}
A quadratic set
{lQ}
P\in{lQ}
{lQ}P
A Pappian projective space is a projective space in which Pappus's hexagon theorem holds.
The following result, due to Francis Buekenhout, is an astonishing statement for finite projective spaces.
Theorem: Let be
akPn
n\ge3
{lQ}
akPn
{lQ}
\ge2
Ovals and ovoids are special quadratic sets:
Let
akP
\ge2
lO
The following equivalent definition of an oval/ovoid are more common:
Definition: (oval)A non-empty point set
ako
(o1) Any line meets
ako
(o2) For any point
P
ako
g
g\capako=\{P\}
g
|g\capako|=0
|g\capako|=1
|g\capako|=2
For finite planes the following theorem provides a more simple definition.
Theorem: (oval in finite plane) Let be
akP
n
ako
|ako|=n+1
ako
According to this theorem of Beniamino Segre, for Pappian projective planes of odd order the ovals are just conics: Theorem:Let be
akP
akP
Definition: (ovoid)A non-empty point set
lO
(O1) Any line meets
lO
(
g
|g\cap{lO}|=0, |g\cap{lO}|=1
|g\cap{lO}|=2
(O2) For any point
P\in{lO}
{lO}P
P
P
Example:
a) Any sphere (quadric of index 1) is an ovoid.
b) In case of real projective spaces one can construct ovoids by combining halves of suitable ellipsoids such that they are no quadrics.
For finite projective spaces of dimension
n
K
a) In case of
|K|<infty
akPn(K)
n=2
n=3
b) In case of
|K|<infty, \operatorname{char}K\ne2
akPn(K)
Counterexamples (Tits–Suzuki ovoid) show that i.g. statement b) of the theorem above is not true for
\operatorname{char}K=2