Riemann-Hurwitz formula: Difference between revisions

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: <math>2 (\mbox{genus}(C)-1)=2d(\mbox{genus}(D)-1)+B. \, </math>
: <math>2 (\mbox{genus}(C)-1)=2d(\mbox{genus}(D)-1)+B. \, </math>


[[Image:Gludiag.png|400px|thumb|a triangulated gluing diagram for the Riemann sphere, and its pullback to a torus double cover, which is ramified over the vertices of the triangulation]]Over a [[field (algebra)|field]] in general [[Euler characteristic|characteristic]], this theorem is a consequence of the [[Riemann-Roch theorem]]. Over the [[complex numbers]], the theorem can be proved by choosing a [[triangulation]] of the curve ''D'' such that all the branch points of the map are nodes of the triangulation. One then considers the [[pullback]] of the triangulation to the curve ''C'' and computes the [[Euler characteristic]]s of both curves.
[[Image:Gludiag.png|400px|thumb|a triangulated gluing diagram for the Riemann sphere, and its pullback to a torus double cover, which is ramified over the vertices of the triangulation]]Over a [[field (algebra)|field]] in general [[Euler characteristic|characteristic]], this theorem is a consequence of the [[Riemann-Roch theorem]]. Over the [[complex numbers]], the theorem can be proved by choosing a [[triangulation]] of the curve ''D'' such that all the branch points of the map are nodes of the triangulation. One then considers the [[pullback]] of the triangulation to the curve ''C'' and computes the [[Euler characteristic]]s of both curves.[[Category:Suggestion Bot Tag]]

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In algebraic geometry the Riemann-Hurwitz formula, named after Bernhard Riemann and Adolf Hurwitz, states that if C, D are smooth algebraic curves, and is a finite map of degree d then the number of branch points of f, denoted by B, is given by

a triangulated gluing diagram for the Riemann sphere, and its pullback to a torus double cover, which is ramified over the vertices of the triangulation

Over a field in general characteristic, this theorem is a consequence of the Riemann-Roch theorem. Over the complex numbers, the theorem can be proved by choosing a triangulation of the curve D such that all the branch points of the map are nodes of the triangulation. One then considers the pullback of the triangulation to the curve C and computes the Euler characteristics of both curves.