Some calculations involving configuration spaces of distinct points
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== Introduction == | == Introduction == | ||
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− | .. | + | ‘The complement of the diagonal’ and ‘the Gauss map’ ideas play a greatrole in different branches of mathematics [Gl68, Va92]. The Haefliger-Wu invariant is amanifestation of these ideas in the theory of embeddings. The complement to the diagonalidea originated from two celebrated theorems: the Lefschetz Fixed Point Theorem andthe Borsuk-Ulam Antipodes Theorem |
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Revision as of 12:58, 2 April 2020
This page has not been refereed. The information given here might be incomplete or provisional. |
Contents |
1 Introduction
‘The complement of the diagonal’ and ‘the Gauss map’ ideas play a greatrole in different branches of mathematics [Gl68, Va92]. The Haefliger-Wu invariant is amanifestation of these ideas in the theory of embeddings. The complement to the diagonalidea originated from two celebrated theorems: the Lefschetz Fixed Point Theorem andthe Borsuk-Ulam Antipodes Theorem
2 Construction and examples
For a manifold , denotes the deleted product of , i.e. minus an open tubular neighborhood of the diagonal. It is a manifold with boundary and has the standard free involution.
Definition 2.1.[of the Haefliger-Wu invariant ]
The Haefliger-Wu invariant is induced by the Gauss map, also denoted by . The Gauss map assigns to an individual embedding an equivariant map defined by the formula
3 Invariants
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4 Classification/Characterization
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5 Further discussion
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