Misplaced Pages

Regular homotopy

Article snapshot taken from Wikipedia with creative commons attribution-sharealike license. Give it a read and then ask your questions in the chat. We can research this topic together.
(Redirected from Whitney–Graustein theorem)

In the mathematical field of topology, a regular homotopy refers to a special kind of homotopy between immersions of one manifold in another. The homotopy must be a 1-parameter family of immersions.

Similar to homotopy classes, one defines two immersions to be in the same regular homotopy class if there exists a regular homotopy between them. Regular homotopy for immersions is similar to isotopy of embeddings: they are both restricted types of homotopies. Stated another way, two continuous functions f , g : M N {\displaystyle f,g:M\to N} are homotopic if they represent points in the same path-components of the mapping space C ( M , N ) {\displaystyle C(M,N)} , given the compact-open topology. The space of immersions is the subspace of C ( M , N ) {\displaystyle C(M,N)} consisting of immersions, denoted by Imm ( M , N ) {\displaystyle \operatorname {Imm} (M,N)} . Two immersions f , g : M N {\displaystyle f,g:M\to N} are regularly homotopic if they represent points in the same path-component of Imm ( M , N ) {\displaystyle \operatorname {Imm} (M,N)} .

Examples

Any two knots in 3-space are equivalent by regular homotopy, though not by isotopy.

This curve has total curvature 6π, and turning number 3.

The Whitney–Graustein theorem classifies the regular homotopy classes of a circle into the plane; two immersions are regularly homotopic if and only if they have the same turning number – equivalently, total curvature; equivalently, if and only if their Gauss maps have the same degree/winding number.

Smale's classification of immersions of spheres shows that sphere eversions exist, which can be realized via this Morin surface.

Stephen Smale classified the regular homotopy classes of a k-sphere immersed in R n {\displaystyle \mathbb {R} ^{n}} – they are classified by homotopy groups of Stiefel manifolds, which is a generalization of the Gauss map, with here k partial derivatives not vanishing. More precisely, the set I ( n , k ) {\displaystyle I(n,k)} of regular homotopy classes of embeddings of sphere S k {\displaystyle S^{k}} in R n {\displaystyle \mathbb {R} ^{n}} is in one-to-one correspondence with elements of group π k ( V k ( R n ) ) {\displaystyle \pi _{k}\left(V_{k}\left(\mathbb {R} ^{n}\right)\right)} . In case k = n 1 {\displaystyle k=n-1} we have V n 1 ( R n ) S O ( n ) {\displaystyle V_{n-1}\left(\mathbb {R} ^{n}\right)\cong SO(n)} . Since S O ( 1 ) {\displaystyle SO(1)} is path connected, π 2 ( S O ( 3 ) ) π 2 ( R P 3 ) π 2 ( S 3 ) 0 {\displaystyle \pi _{2}(SO(3))\cong \pi _{2}\left(\mathbb {R} P^{3}\right)\cong \pi _{2}\left(S^{3}\right)\cong 0} and π 6 ( S O ( 6 ) ) π 6 ( S O ( 7 ) ) π 6 ( S 6 ) π 5 ( S O ( 6 ) ) π 5 ( S O ( 7 ) ) {\displaystyle \pi _{6}(SO(6))\to \pi _{6}(SO(7))\to \pi _{6}\left(S^{6}\right)\to \pi _{5}(SO(6))\to \pi _{5}(SO(7))} and due to Bott periodicity theorem we have π 6 ( S O ( 6 ) ) π 6 ( Spin ( 6 ) ) π 6 ( S U ( 4 ) ) π 6 ( U ( 4 ) ) 0 {\displaystyle \pi _{6}(SO(6))\cong \pi _{6}(\operatorname {Spin} (6))\cong \pi _{6}(SU(4))\cong \pi _{6}(U(4))\cong 0} and since π 5 ( S O ( 6 ) ) Z ,   π 5 ( S O ( 7 ) ) 0 {\displaystyle \pi _{5}(SO(6))\cong \mathbb {Z} ,\ \pi _{5}(SO(7))\cong 0} then we have π 6 ( S O ( 7 ) ) 0 {\displaystyle \pi _{6}(SO(7))\cong 0} . Therefore all immersions of spheres S 0 ,   S 2 {\displaystyle S^{0},\ S^{2}} and S 6 {\displaystyle S^{6}} in euclidean spaces of one more dimension are regular homotopic. In particular, spheres S n {\displaystyle S^{n}} embedded in R n + 1 {\displaystyle \mathbb {R} ^{n+1}} admit eversion if n = 0 , 2 , 6 {\displaystyle n=0,2,6} . A corollary of his work is that there is only one regular homotopy class of a 2-sphere immersed in R 3 {\displaystyle \mathbb {R} ^{3}} . In particular, this means that sphere eversions exist, i.e. one can turn the 2-sphere "inside-out".

Both of these examples consist of reducing regular homotopy to homotopy; this has subsequently been substantially generalized in the homotopy principle (or h-principle) approach.

Non-degenerate homotopy

For locally convex, closed space curves, one can also define non-degenerate homotopy. Here, the 1-parameter family of immersions must be non-degenerate (i.e. the curvature may never vanish). There are 2 distinct non-degenerate homotopy classes. Further restrictions of non-vanishing torsion lead to 4 distinct equivalence classes.

References

  1. Feldman, E. A. (1968). "Deformations of closed space curves". Journal of Differential Geometry. 2 (1): 67–75. doi:10.4310/jdg/1214501138.
  2. Little, John A. (1971). "Third order nondegenerate homotopies of space curves". Journal of Differential Geometry. 5 (3): 503–515. doi:10.4310/jdg/1214430012.
Categories: