Difference between revisions of "Some retraction problems"
(Created page with "Scale calculus was developed to make reparametrization actions on function spaces smooth. All the key issues and ideas can already be seen at the example of <math>S^1=\R/\Z</...") |
|||
Line 1: | Line 1: | ||
+ | |||
+ | |||
+ | == A useful toy retraction == | ||
+ | |||
+ | 1. State | ||
+ | 2. Investigate smooth paths | ||
+ | 3. Investigate Tangent space at strange point | ||
+ | |||
+ | == The model lemmas == | ||
+ | |||
+ | == Retractions instead of sc-Banach manifolds == | ||
+ | |||
+ | 1. Transversal constraint construction as retraction | ||
+ | 2. Target manifold as <math>\mathbb{R}^N</math> | ||
+ | 3. Retractions on retracts | ||
+ | |||
+ | == The <math>\overline{\partial_J}</math> operator as sc-Fredholm == | ||
+ | |||
+ | 1. Use the original definition of HWZ for sc-Fredholm to prove dbar is. | ||
+ | 2. Show that the linearized d-bar operator at a constant solution is an isomorphism | ||
+ | |||
+ | |||
+ | |||
Scale calculus was developed to make reparametrization actions on function spaces smooth. | Scale calculus was developed to make reparametrization actions on function spaces smooth. | ||
All the key issues and ideas can already be seen at the example of <math>S^1=\R/\Z</math> acting on a space of nonconstant functions on <math>S^1</math>, for example the shift action | All the key issues and ideas can already be seen at the example of <math>S^1=\R/\Z</math> acting on a space of nonconstant functions on <math>S^1</math>, for example the shift action | ||
Line 17: | Line 40: | ||
the structure of a scale-smooth manifold ... and to see that classical Banach space topologies fail at giving it a differentiable Banach manifold structure. | the structure of a scale-smooth manifold ... and to see that classical Banach space topologies fail at giving it a differentiable Banach manifold structure. | ||
− | == | + | == A subtitle == |
Compute the directional derivatives of the shift map <math>\sigma</math>, | Compute the directional derivatives of the shift map <math>\sigma</math>, | ||
Line 31: | Line 54: | ||
− | == | + | == Another subtitle == |
Verify that <math>\mathcal{B}</math> has local Banach manifold charts modeled on | Verify that <math>\mathcal{B}</math> has local Banach manifold charts modeled on |
Revision as of 07:50, 12 June 2017
Contents
A useful toy retraction
1. State 2. Investigate smooth paths 3. Investigate Tangent space at strange point
The model lemmas
Retractions instead of sc-Banach manifolds
1. Transversal constraint construction as retraction 2. Target manifold as 3. Retractions on retracts
The operator as sc-Fredholm
1. Use the original definition of HWZ for sc-Fredholm to prove dbar is. 2. Show that the linearized d-bar operator at a constant solution is an isomorphism
Scale calculus was developed to make reparametrization actions on function spaces smooth. All the key issues and ideas can already be seen at the example of acting on a space of nonconstant functions on , for example the shift action
The purpose of the following exercises is to give the quotient of S^1-valued functions homotopic to the identity, modulo reparametrization by shifts, the structure of a scale-smooth manifold ... and to see that classical Banach space topologies fail at giving it a differentiable Banach manifold structure.
A subtitle
Compute the directional derivatives of the shift map , first at , then at .
Next, understand how to identify , and write down a conjectural formula for the differential .
Then recall the definition of differentiability in terms of uniform linear approximation and see whether it can be satisfied at any base point .
YOUR SOLUTION WANTS TO BE HERE
Another subtitle
Verify that has local Banach manifold charts modeled on . To set up a chart near a given point, pick a representative with and consider the map
YOUR SOLUTION WANTS TO BE HERE