Monodromy |
In of transformations acting on the data that codes what does happen as we run round .
These ideas were first made explicit in complex analysis. In the process of analytic continuation, a function that is an analytic function F ( z ) in some open subset E of the punctured disk D given
:0 < | z | < 1
may be continued back into E , but with different values. For example if we take
: F ( z ) = log z
and E to be defined by
: Re( z ) > 0
then analytic continuation anti-clockwise round the circle
:| z | = 0.5
will result in the return, not to F ( z ) but
: F ( z )+2π i .
In this case the monodromy group is infinite cyclic. One important application is to differential equations, where a single solution may give further linearly independent solutions by analytic continuation. Linear differential equations defined in an open, connected set S in the complex plane have a monodromy group, which (more precisely) is a linear representation of the fundamental group of S , summarising all the analytic continuations round loops within S . The inverse problem, of constructing the equation (with regular singularity), given a representation, is called the Riemann-Hilbert problem.
In the case of a covering map, we look at it as a special case of a Fibration, and use the homotopy lifting property to follow paths on the base space X (we assume it path-connected for simplicity) as they are lifted up into the cover C . If we follow round a loop based at x in X , which we lift to start at c above x , we ll end at some c* again above x ; it is quite possible that c ≠ c* , and to code this one considers the action of the fundamental group π1( X , x ) as a permutation group on the set of all c , as monodromy group in this context.
In differential geometry, an analogous role is played by parallel transport. In a principal bundle B over a smooth manifold M , a connection (mathematics) allows horizontal movement from fibers above m in M to adjacent ones. The effect when applied to loops based at m is to define a holonomy group of translations of the fiber at m ; if the structure group of B is G , it is a subgroup of G that measures the deviation of B from the product bundle M x G .
=Definition via Galois theory=
Let mathbb{F}(x) denote the field of fractions of the ring mathbb{F}[x] where mathbb{F} is also a field. An element f(y) in mathbb{F}(y) determines a finite field extension
:mathbb{F}(x) hookrightarrow mathbb{F}(y)
by setting
:f(y) = x
which is generally not Galois but which has Galois closure
:L_{f} , !.
The associated Galois group of the extension L_f/mathbb{F}(x) is called the monodromy group of the extension.
In the case of mathbb{F} = mathbb{C} Riemann surface theory enters and allows for the geometric interpretation given above. In the case that the extension mathbb{C}(y) is already Galois, the associated monodromy group is sometimes called a Covering map.
This has connections with the Grothendieck s Galois theory leading to the Riemann existence theorem.|
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