Difference between revisions of "Riemann-Hurwitz formula"

Hurwitz formula, Hurwitz theorem

A formula that connects the genus and other invariants in a covering of Riemann surfaces (cf. Riemann surface). Let $ T $ and $ R $ be closed Riemann surfaces, and let $ f: T \rightarrow R $ be a surjective holomorphic mapping. Suppose this is an $ m $- sheeted covering, and suppose that $ f $ is branched in the points $ Q _ {1} \dots Q _ {s} \in T $ with multiplicities $ k _ {1} \dots k _ {s} $. Suppose that $ g = \textrm{ genus } ( T) $ and $ h = \textrm{ genus } ( R) $. Then the following (Riemann–Hurwitz) formula holds:

$$ \tag{* } 2 g - 2 = m( 2h - 2) + \sum _ {i= 1 } ^ { s } ( k _ {i} - 1). $$

In particular, if $ R $ is the Riemann sphere, i.e. $ h = \textrm{ genus } ( R) = 0 $, then

$$ g = 1 + \sum _ {i= 1 } ^ { s } \frac{k _ {i} - 1 }{2} . $$

Formula (*) was stated by B. Riemann [1] and proved by A. Hurwitz [2].

In the case of coverings of complete curves over a field, an analogous formula can be derived in case the covering mapping $ f $ is separable (cf. Separable mapping). In that case

$$ 2g - 2 = m ( 2h- 2) + \mathop{\rm deg} ( \delta ( f ) ) , $$

where $ \delta ( f ) $ is the different of $ f $. In this case one speaks of the Riemann–Hurwitz–Hasse formula. In case a branching multiplicity $ k _ {i} $ is divisible by the characteristic of the base field, one speaks of wild ramification, and the degree of $ \delta ( f ) $ at that point is larger than $ k _ {i} - 1 $.

References

Comments

The different of a mapping $ f $ is the different of the extension of algebraic function fields determined by $ f $. For the latter notion cf. (the editorial comments to) Discriminant.

References