In algebraic geometry, Behrend's formula is a generalization of the Grothendieck–Lefschetz trace formula to a smooth algebraic stack over a finite field, conjectured in 1993 and proven in 2003 by Kai Behrend. Unlike the classical one, the formula counts points in the "stacky way"; it takes into account the presence of nontrivial automorphisms.
Contents
The desire for the formula comes from the fact that it applies to the moduli stack of principal bundles on a curve over a finite field (in some instances indirectly, via the Harder–Narasimhan stratification, as the moduli stack is not of finite type.) See the moduli stack of principal bundles and references therein for the precise formulation in this case.
Deligne found an example that shows the formula may be interpreted as a sort of the Selberg trace formula.
A proof of the formula in the context of the six operations formalism developed by Laszlo and Olsson is given by Shenghao Sun.
Formulation
By definition, if C is a category in which each object has finitely many automorphisms, the number of points in
with the sum running over representatives p of all isomorphism classes in C. (The series may diverge in general.) The formula states: for a smooth algebraic stack X of finite type over a finite field
Here, it is crucial that the cohomology of a stack is with respect to the smooth topology (not etale).
When X is a variety, the smooth cohomology is the same as etale one and, via the Poincaré duality, this is equivalent to Grothendieck's trace formula. (But the proof relies on Grothendieck's formula, so this does not subsume Grothendieck's.)
Simple example
Consider
On the other hand, we may compute the l-adic cohomology of
Note that