Intersection theorem

In projective geometry, an intersection theorem or incidence theorem is an incidence structure consisting of points, lines, and possibly higher-dimensional objects and their incidences, together with a pair of nonincident objects A and B (for instance, a point and a line). The "theorem" states that, whenever a set of objects satisfies the incidences (i.e. can be matched up with the objects of the incidence structure in a way that preserves incidence), then the objects corresponding to A and B must also be incident. An intersection theorem is not necessarily true in all projective geometries; it is rather a property which some geometries satisfy but not others.

For example, Desargues' theorem can be stated using the following incidence structure:

Points: $\{A,B,C,a,b,c,P,Q,R,O\}$
Lines: $\{AB,AC,BC,ab,ac,bc,Aa,Bb,Cc,PQ\}$
Incidences (in addition to obvious ones such as $(A,AB)$ : $\{(O,Aa),(O,Bb),(O,Cc),(P,BC),(P,bc),(Q,AC),(Q,ac),(R,AB),(R,ab)\}$

The implication is then $(R,PQ)$ —that point R is incident with line PQ.

Famous examples

Desargues' theorem holds in a projective plane P iff P is the projective plane over some division ring D— $P=\mathbb {P} _{2}D$ . The projective plane is then called desarguian. A theorem of Amitsur's and Bergman's states that, in the context of desarguian projective planes, for every intersection theorem there is a rational identity such that the plane P satisfies the intersection theorem iff the division ring D satisfies the rational identity.

Pappus's hexagon theorem holds in a desarguian projective plane $\mathbb {P} _{2}D$ iff D is a field; it corresponds to the identity $\forall a,b\in D,a\cdot b=b\cdot a$ .
Fano's theorem holds in $\mathbb {P} _{2}D$ iff D has characteristic $\neq 2$ ; it corresponds to the identity a+a=0.

References

L. H. Rowen; Polynomial Identities in Ring Theory. Academic Press: New York, 1980.
S. A. Amitsur; "Rational Identities and Applications to Algebra and Geometry", Journal of Algebra 3 (1996), 304–359.