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===소스===
 
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==메타데이터==
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===위키데이터===
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* ID :  [https://www.wikidata.org/wiki/Q662830 Q662830]
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===Spacy 패턴 목록===
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* [{'LOWER': 'fundamental'}, {'LEMMA': 'group'}]

2021년 2월 17일 (수) 01:18 기준 최신판

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말뭉치

  1. D. K. Biss (Topology and its Applications 124 (2002) 355-371) introduced the topological fundamental group and presented some interesting basic properties of the notion.[1]
  2. one sometimes loosely speaks of ‘the’ fundamental group of a connected space.[2]
  3. There is a relation to universal covers: Under suitable conditions the group of cover automorphisms of a universal cover is isomorphic to the fundamental group of the covered space.[2]
  4. In particular in algebraic geometry and arithmetic geometry this essentially identifies the concept of fundamental group with that of Galois groups.[2]
  5. For this reason one also speaks of the algebraic fundamental group in this context.[2]
  6. In the mathematical field of algebraic topology, the fundamental group of a topological space is the group of the equivalence classes under homotopy of the loops contained in the space.[3]
  7. This set (with the group structure described below) is called the fundamental group of the topological space X at the base point x 0 {\displaystyle x_{0}} .[3]
  8. It becomes a group (and therefore deserves the name fundamental group) using the concatenation of loops.[3]
  9. The fundamental group of the plane punctured at n points is also the free group with n generators.[3]
  10. In fact, the fundamental group only depends on the homotopy type of .[4]
  11. A space with a trivial fundamental group (i.e., every loop is homotopic to the constant loop), is called simply connected.[4]
  12. The underlying set of the fundamental group of is the set of based homotopy classes from the circle to , denoted .[4]
  13. When is a continuous map, then the fundamental group pushes forward.[4]
  14. Exercise (i) Show that the fundamental group of the circle S(1) is Z, the additive group of the integers.[5]
  15. A Hopf space is a space in which the proof given above for the statement that the fundamental group of a topological group is Abelian still works.[5]
  16. The definition of the fundamental group as the space of path components of gives a topology on the fundamental group.[6]
  17. It turns out, though, that if the path component of in is a locally path-connected space, then so is , in which case the fundamental group has a discrete topology.[6]
  18. Moreover, any path between these two points yields an isomorphism, and any two such isomorphisms have quotient equal to an inner automorphism of the fundamental group at one point.[6]
  19. All loops based at , up to homotopies where the intermediaries must be loops but need not be based at conjugacy class set of fundamental group ?[6]
  20. \pi _{1}(X,x_0)\rightarrow \check{\pi }_1(X,x_0)\) from the fundamental group to the first shape group is injective (See Sect.[7]
  21. The fundamental group is the first of what are known as the homotopy groups of a topological space.[8]
  22. An easy way to approach the concept of fundamental group is to start with a concrete example.[9]
  23. This type of approach constitutes the base of the definition of fundamental group and explains essential differences between different kinds of topological spaces.[9]
  24. Now, in a fundamental group, we will work with loops.[9]
  25. This section is dedicated to the calculation of the fundamental group of S 1 {\displaystyle S^{1}} that we can consider contained in the complex topological space.[9]
  26. I want to show the fundamental group of a topological group is abelian.[10]
  27. I have just learned the fundamental group.[10]
  28. For well-behaved topological spaces, there are several equivalent definitions for the fundamental group.[11]
  29. On the other hand, we will find that the fundamental group is too unwieldy to compute (and for deep reasons).[12]
  30. Since we want to be able to readily compute the number of holes in twisted and tied-up spaces, we will need to scrap the fundamental group and try something else.[12]
  31. For now, we will develop the idea of homotopy and the fundamental group.[12]
  32. Although we have not proved it here, the fundamental group is a topological invariant.[12]
  33. Note that the fundamental group is not in general abelian.[13]
  34. In order for the fundamental group to be a useful topological concept, any two spaces that are topologically "the same" must have the same fundamental group.[13]
  35. Daniel K. Biss, The topological fundamental group and generalized covering spaces , Topology and its Applications, Vol.[14]

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Spacy 패턴 목록

  • [{'LOWER': 'fundamental'}, {'LEMMA': 'group'}]