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In [[differential topology]], a branch of [[mathematics]], the '''Whitney conditions''' are conditions on a pair of [[submanifold]]s of a [[manifold]] introduced by [[Hassler Whitney]] in 1965. A finite [[filtration (mathematics)|filtration]] by closed subsets ''F''<sub>i</sub> of a smooth manifold such that the difference between successive members ''F''<sub>i</sub>'' and ''F''<sub>(i-1)</sub>'' of the filtration is either empty or a smooth submanifold of dimension ''i'', is called a '''stratification'''. The connected components of the difference ''F''<sub>i</sub> - ''F''<sub>(i-1)</sub> are the '''strata''' of dimension ''i''. A stratification is called a '''Whitney stratification''' if all pairs of strata satisfy the Whitney conditions A and B, as defined below.
In [[differential topology]], a branch of [[mathematics]], the '''Whitney conditions''' are conditions on a pair of [[submanifold]]s of a [[manifold]] introduced by [[Hassler Whitney]] in 1965.


A '''stratification''' of a [[topological space]] is a finite [[filtration (mathematics)|filtration]] by closed subsets ''F''<sub>''i''</sub> , such that the difference between successive members ''F''<sub>''i''</sub> and ''F''<sub>(''i'' &minus; 1)</sub> of the filtration is either empty or a smooth submanifold of dimension ''i''. The connected components of the difference ''F''<sub>''i''</sub> &minus; ''F''<sub>(''i'' &minus; 1)</sub> are the '''strata''' of dimension ''i''. A stratification is called a '''Whitney stratification''' if all pairs of strata satisfy the Whitney conditions A and B, as defined below.
==The Whitney conditions in R<sup>n </sup> ==


==The Whitney conditions in '''R'''<sup>''n''</sup> ==
Let ''X'' and ''Y'' be two disjoint locally closed submanifolds of '''R'''<sup> n </sup>, of dimensions ''i'' and ''j''.


Let ''X'' and ''Y'' be two disjoint ([[locally closed]]) submanifolds of '''R'''<sup>''n''</sup>, of dimensions ''i'' and ''j''.
* ''X'' and ''Y'' satisfy '''Whitney's condition A''' if whenever a sequence of points ''x''<sub>1</sub>, ''x''<sub>2</sub>, ... in ''X'' converges to a point ''y'' in ''Y'', and the sequence of tangent ''i''-planes ''T''<sub>m</sub>, to ''X'' at the points ''x<sub>m</sub>'' converges to an ''i''-plane ''T'' as ''m'' tends to infinity, then ''T'' contains the tangent ''j''-plane to ''Y'' at ''y''.


* ''X'' and ''Y'' satisfy '''Whitney's condition B''' if for each sequence ''x''<sub>1</sub>, ''x''<sub>2</sub>, ... of points in ''X'' and each sequence ''y''<sub>1</sub>, ''y''<sub>2</sub>, ... of points in ''Y'', both converging to the same point ''y'' in ''Y'', such that the sequence of secant lines ''L<sub>m</sub>'' between ''x<sub>m</sub>'' and ''y<sub>m</sub>'' converges to a line ''L'' as ''m'' tends to infinity, and the sequence of tangent ''i''-planes ''T''<sub>m</sub>, to ''X'' at the points ''x<sub>m</sub>'' converges to an ''i''-plane ''T'' as ''m'' tends to infinity, then ''L'' is contained in ''T''.
* ''X'' and ''Y'' satisfy '''Whitney's condition A''' if whenever a sequence of points ''x''<sub>1</sub>, ''x''<sub>2</sub>, in ''X'' converges to a point ''y'' in ''Y'', and the sequence of tangent ''i''-planes ''T''<sub>''m''</sub> to ''X'' at the points ''x<sub>m</sub>'' converges to an ''i''-plane ''T'' as ''m'' tends to infinity, then ''T'' contains the tangent ''j''-plane to ''Y'' at ''y''.
* ''X'' and ''Y'' satisfy '''Whitney's condition B''' if for each sequence ''x''<sub>1</sub>, ''x''<sub>2</sub>, … of points in ''X'' and each sequence ''y''<sub>1</sub>, ''y''<sub>2</sub>, … of points in ''Y'', both converging to the same point ''y'' in ''Y'', such that the sequence of secant lines ''L<sub>m</sub>'' between ''x<sub>m</sub>'' and ''y<sub>m</sub>'' converges to a line ''L'' as ''m'' tends to infinity, and the sequence of tangent ''i''-planes ''T''<sub>''m''</sub> to ''X'' at the points ''x<sub>m</sub>'' converges to an ''i''-plane ''T'' as ''m'' tends to infinity, then ''L'' is contained in ''T''.


[[John Mather]] first pointed out that ''Whitney's condition B'' implies ''Whitney's condition A'' in the notes of his lectures at Harvard in 1970, which have been widely distributed. He also defined the notion of Thom-Mather stratified space, and proved that every Whitney stratification is a Thom-Mather stratified space and hence is a [[topologically stratified space]]. Another approach to this fundamental result was given earlier by [[René Thom]] in 1969.
[[John Mather (mathematician)|John Mather]] first pointed out that ''Whitney's condition B'' implies ''Whitney's condition A'' in the notes of his lectures at Harvard in 1970, which have been widely distributed. He also defined the notion of Thom–Mather stratified space, and proved that every Whitney stratification is a Thom–Mather stratified space and hence is a [[topologically stratified space]]. Another approach to this fundamental result was given earlier by [[René Thom]] in 1969.


[[David Trotman]] showed in his 1978 Warwick thesis that a stratification of a closed subset in a smooth manifold ''M'' satifies ''Whitney's condition A'' if and only if the subspace of the space of smooth mappings from a smooth manifold ''N'' into ''M'' consisting of all those maps which are transverse to all of the strata of the stratification, is open (using the Whitney, or strong, topology). The subspace of mappings transversal to any countable family of submanifolds of ''M'' is always dense by Thom's transversality theorem. The density of the set of transversal mappings is interpreted by saying that transversality is a 'generic' property for smooth mappings, while the openness is interpreted by saying that the property is 'stable'.
[[David Trotman]] showed in his 1977 Warwick thesis that a stratification of a closed subset in a smooth manifold ''M'' satisfies ''Whitney's condition A'' if and only if the subspace of the space of smooth mappings from a smooth manifold ''N'' into ''M'' consisting of all those maps which are transverse to all of the strata of the stratification, is open (using the Whitney, or strong, topology). The subspace of mappings transverse to any countable family of submanifolds of ''M'' is always dense by Thom's [[transversality theorem]]. The density of the set of transverse mappings is often interpreted by saying that transversality is a [[generic property|'generic' property]] for smooth mappings, while the openness is often interpreted by saying that the property is 'stable'.


The reason that Whitney conditions have become so widely used is because of Whitney's 1965 theorem that every algebraic variety, or indeed analytic variety, admits a Whitney stratification,i.e. a partition into smooth submanifolds satisfying the Whitney conditions. More general singular spaces can be given Whitney stratifications, such as semialgebraic sets (due to [[Rene Thom]]) and subanalytic sets (due to [[Heisuke Hironaka]]). This has led to their use in engineering, control theory and robotics. In his thesis under the direction of Wieslaw Pawlucki at the [[Jagellonian University]] in Krakow, Poland, the Vietnamese mathematician Ta Lê Loi proved further that every definable set in an [[o-minimal structure]] can be given a Whitney stratification.
The reason that Whitney conditions have become so widely used is because of Whitney's 1965 theorem that every algebraic variety, or indeed analytic variety, admits a Whitney stratification, i.e. admits a partition into smooth submanifolds satisfying the Whitney conditions. More general singular spaces can be given Whitney stratifications, such as [[semialgebraic set]]s (due to [[René Thom]]) and [[subanalytic set]]s (due to [[Heisuke Hironaka]]). This has led to their use in engineering, control theory and robotics. In a thesis under the direction of Wieslaw Pawlucki at the [[Jagellonian University]] in Kraków, Poland, the Vietnamese mathematician Ta Lê Loi proved further that every definable set in an [[o-minimal structure]] can be given a Whitney stratification.{{citation needed|date=June 2021}}


==See also==
==See also==

*[[Whitney stratified space]]
*[[Thom-Mather stratified space]]
*[[Thom–Mather stratified space]]
*[[Topologically stratified space]]
*[[Topologically stratified space]]
*[[Thom's first isotopy lemma]]
*[[Stratified space]]


==References==
==References==

* [[John Mather|Mather, John]] ''Notes on topological stability'', Harvard, 1970 ([http://www.math.princeton.edu/facultypapers/mather/notes_on_topological_stability.pdf available on his webpage at Princeton University]).
{{Reflist}}
* [[René Thom|Thom, René]] ''[http://www.ams.org/bull/1969-75-02/S0002-9904-1969-12138-5/ Ensembles et morphismes stratifiés]'', Bulletin of the American Mathematical Society Vol. 75, pp. 240-284), 1969.
* [[John Mather (mathematician)|Mather, John]] ''Notes on topological stability'', Harvard, 1970 ([http://www.math.princeton.edu/facultypapers/mather/notes_on_topological_stability.pdf available on his webpage at Princeton University]).
* [[David Trotman|Trotman, David]] ''Stability of transversality to a stratification implies Whitney (a)-regularity,'' Inventiones Mathematicae 50(3), pp. 273--277, 1979.
* [[René Thom|Thom, René]] ''[http://www.ams.org/bull/1969-75-02/S0002-9904-1969-12138-5/ Ensembles et morphismes stratifiés]'', Bulletin of the American Mathematical Society Vol. 75, pp.&nbsp;240–284), 1969.
* [[David Trotman|Trotman, David]] ''Comparing regularity conditions on stratifications,'' Singularities, Part 2 (Arcata, Calif., 1981), volume 40 of Proc. Sympos. Pure Math., pp. 575--586. American Mathematical Society, Providence, R.I., 1983.
* [[David Trotman|Trotman, David]] ''Stability of transversality to a stratification implies Whitney (a)-regularity,'' Inventiones Mathematicae 50(3), pp.&nbsp;273–277, 1979.
* [[Hassler Whitney|Whitney, Hassler]] ''Local properties of analytic varieties.'' Differential and Combinatorial Topology (A Symposium in Honor of [[Marston Morse]]) pp. 205--244 Princeton Univ. Press, Princeton, N. J., 1965.
* [[David Trotman|Trotman, David]] ''Comparing regularity conditions on stratifications,'' Singularities, Part 2 (Arcata, Calif., 1981), volume 40 of Proc. Sympos. Pure Math., pp.&nbsp;575–586. American Mathematical Society, Providence, R.I., 1983.
* [[Hassler Whitney|Whitney, Hassler]], ''Tangents to an analytic variety,'' Annals of Mathematics 81, no. 3 (1965), pp. 496--549.
* [[Hassler Whitney|Whitney, Hassler]] ''Local properties of analytic varieties.'' Differential and Combinatorial Topology (A Symposium in Honor of [[Marston Morse]]) pp.&nbsp;205–244 Princeton Univ. Press, Princeton, N. J., 1965.
* [[Hassler Whitney|Whitney, Hassler]], ''Tangents to an analytic variety,'' Annals of Mathematics 81, no. 3 (1965), pp.&nbsp;496–549.


[[Category:Differential topology]]
[[Category:Differential topology]]
[[Category:Singularity theory]]
[[Category:Singularity theory]]
[[Category:Stratifications]]

{{topology-stub}}

Latest revision as of 23:03, 1 November 2022

In differential topology, a branch of mathematics, the Whitney conditions are conditions on a pair of submanifolds of a manifold introduced by Hassler Whitney in 1965.

A stratification of a topological space is a finite filtration by closed subsets Fi , such that the difference between successive members Fi and F(i − 1) of the filtration is either empty or a smooth submanifold of dimension i. The connected components of the difference FiF(i − 1) are the strata of dimension i. A stratification is called a Whitney stratification if all pairs of strata satisfy the Whitney conditions A and B, as defined below.

The Whitney conditions in Rn

[edit]

Let X and Y be two disjoint (locally closed) submanifolds of Rn, of dimensions i and j.

  • X and Y satisfy Whitney's condition A if whenever a sequence of points x1, x2, … in X converges to a point y in Y, and the sequence of tangent i-planes Tm to X at the points xm converges to an i-plane T as m tends to infinity, then T contains the tangent j-plane to Y at y.
  • X and Y satisfy Whitney's condition B if for each sequence x1, x2, … of points in X and each sequence y1, y2, … of points in Y, both converging to the same point y in Y, such that the sequence of secant lines Lm between xm and ym converges to a line L as m tends to infinity, and the sequence of tangent i-planes Tm to X at the points xm converges to an i-plane T as m tends to infinity, then L is contained in T.

John Mather first pointed out that Whitney's condition B implies Whitney's condition A in the notes of his lectures at Harvard in 1970, which have been widely distributed. He also defined the notion of Thom–Mather stratified space, and proved that every Whitney stratification is a Thom–Mather stratified space and hence is a topologically stratified space. Another approach to this fundamental result was given earlier by René Thom in 1969.

David Trotman showed in his 1977 Warwick thesis that a stratification of a closed subset in a smooth manifold M satisfies Whitney's condition A if and only if the subspace of the space of smooth mappings from a smooth manifold N into M consisting of all those maps which are transverse to all of the strata of the stratification, is open (using the Whitney, or strong, topology). The subspace of mappings transverse to any countable family of submanifolds of M is always dense by Thom's transversality theorem. The density of the set of transverse mappings is often interpreted by saying that transversality is a 'generic' property for smooth mappings, while the openness is often interpreted by saying that the property is 'stable'.

The reason that Whitney conditions have become so widely used is because of Whitney's 1965 theorem that every algebraic variety, or indeed analytic variety, admits a Whitney stratification, i.e. admits a partition into smooth submanifolds satisfying the Whitney conditions. More general singular spaces can be given Whitney stratifications, such as semialgebraic sets (due to René Thom) and subanalytic sets (due to Heisuke Hironaka). This has led to their use in engineering, control theory and robotics. In a thesis under the direction of Wieslaw Pawlucki at the Jagellonian University in Kraków, Poland, the Vietnamese mathematician Ta Lê Loi proved further that every definable set in an o-minimal structure can be given a Whitney stratification.[citation needed]

See also

[edit]

References

[edit]
  • Mather, John Notes on topological stability, Harvard, 1970 (available on his webpage at Princeton University).
  • Thom, René Ensembles et morphismes stratifiés, Bulletin of the American Mathematical Society Vol. 75, pp. 240–284), 1969.
  • Trotman, David Stability of transversality to a stratification implies Whitney (a)-regularity, Inventiones Mathematicae 50(3), pp. 273–277, 1979.
  • Trotman, David Comparing regularity conditions on stratifications, Singularities, Part 2 (Arcata, Calif., 1981), volume 40 of Proc. Sympos. Pure Math., pp. 575–586. American Mathematical Society, Providence, R.I., 1983.
  • Whitney, Hassler Local properties of analytic varieties. Differential and Combinatorial Topology (A Symposium in Honor of Marston Morse) pp. 205–244 Princeton Univ. Press, Princeton, N. J., 1965.
  • Whitney, Hassler, Tangents to an analytic variety, Annals of Mathematics 81, no. 3 (1965), pp. 496–549.