Partial geometry

An incidence structure ${\displaystyle C=(P,L,I)}$ consists of points ${\displaystyle P}$, lines ${\displaystyle L}$, and flags ${\displaystyle I\subseteq P\times L}$ where a point ${\displaystyle p}$ is said to be incident with a line ${\displaystyle l}$ if ${\displaystyle (p,l)\in I}$. It is a (finite) partial geometry if there are integers ${\displaystyle s,t,\alpha \geq 1}$ such that:

• For any pair of distinct points ${\displaystyle p}$ and ${\displaystyle q}$, there is at most one line incident with both of them.
• Each line is incident with ${\displaystyle s+1}$ points.
• Each point is incident with ${\displaystyle t+1}$ lines.
• If a point ${\displaystyle p}$ and a line ${\displaystyle l}$ are not incident, there are exactly ${\displaystyle \alpha }$ pairs ${\displaystyle (q,m)\in I}$, such that ${\displaystyle p}$ is incident with ${\displaystyle m}$ and ${\displaystyle q}$ is incident with ${\displaystyle l}$.

A partial geometry with these parameters is denoted by ${\displaystyle pg(s,t,\alpha )}$.

Properties

• The number of points is given by ${\displaystyle {\frac {(s+1)(st+\alpha )}{\alpha }}}$ and the number of lines by ${\displaystyle {\frac {(t+1)(st+\alpha )}{\alpha }}}$.
• The point graph of a ${\displaystyle pg(s,t,\alpha )}$ is a strongly regular graph : ${\displaystyle srg((s+1){\frac {(st+\alpha )}{\alpha }},s(t+1),s-1+t(\alpha -1),\alpha (t+1))}$.
• Partial geometries are dual structures : the dual of a ${\displaystyle pg(s,t,\alpha )}$ is simply a ${\displaystyle pg(t,s,\alpha )}$.

Special case

• The generalized quadrangles are exactly those partial geometries ${\displaystyle pg(s,t,\alpha )}$ with ${\displaystyle \alpha =1}$.
• The Steiner systems are precisely those partial geometries ${\displaystyle pg(s,t,\alpha )}$ with ${\displaystyle \alpha =s+1}$.

Generalisations

A partial linear space ${\displaystyle S=(P,L,I)}$ of order ${\displaystyle s,t}$ is called a semipartial geometry if there are integers ${\displaystyle \alpha \geq 1,\mu }$ such that:

• If a point ${\displaystyle p}$ and a line ${\displaystyle \ell }$ are not incident, there are either ${\displaystyle 0}$ or exactly ${\displaystyle \alpha }$ pairs ${\displaystyle (q,m)\in I}$, such that ${\displaystyle p}$ is incident with ${\displaystyle m}$ and ${\displaystyle q}$ is incident with ${\displaystyle \ell }$.
• Every pair of non-collinear points have exactly ${\displaystyle \mu }$ common neighbours.

A semipartial geometry is a partial geometry if and only if ${\displaystyle \mu =\alpha (t+1)}$.

It can be easily shown that the collinearity graph of such a geometry is strongly regular with parameters ${\displaystyle (1+s(t+1)+s(t+1)t(s-\alpha +1)/\mu ,s(t+1),s-1+t(\alpha -1),\mu )}$.

A nice example of such a geometry is obtained by taking the affine points of ${\displaystyle PG(3,q^{2})}$ and only those lines that intersect the plane at infinity in a point of a fixed Baer subplane; it has parameters ${\displaystyle (s,t,\alpha ,\mu )=(q^{2}-1,q^{2}+q,q,q(q+1))}$.

See also

• Maximal arc

References

• Brouwer, A.E.; van Lint, J.H. (1984), "Strongly regular graphs and partial geometries", in Jackson, D.M.; Vanstone, S.A. (eds.), Enumeration and Design, Toronto: Academic Press, pp. 85–122
• Bose, R. C. (1963), "Strongly regular graphs, partial geometries and partially balanced designs", Pacific J. Math, 13: 389–419
• De Clerck, F.; Van Maldeghem, H. (1995), "Some classes of rank 2 geometries", Handbook of Incidence Geometry, Amsterdam: North-Holland, pp. 433–475
• Thas, J.A. (2007), "Partial Geometries", in Colbourn, Charles J.; Dinitz, Jeffrey H. (eds.), Handbook of Combinatorial Designs (2nd ed.), Boca Raton: Chapman & Hall/ CRC, pp. 557–561, ISBN 1-58488-506-8
• Debroey, I.; Thas, J. A. (1978), "On semipartial geometries", Journal of Combinatorial Theory Ser. A, 25: 242–250