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			{{Short description\|Integer invariant of certain classes of topological manifolds}}
⚫	In ], ~~the '''signature''' of an oriented~~ ] ~~''M'' is defined when~~ ''M'' ~~has~~ dimension ''d'' ~~]. In that case~~, ~~when ''M'' is ] and ],~~ ] gives rise to a ] ''Q'' on the 'middle' real ]
			In the field of ], the '''signature''' is an integer ] which is defined for an oriented ] ''M'' of dimension ].

			This invariant of a manifold has been studied in detail, starting with ] for 4-manifolds, and ].
	:''H''<sup>2''n''</sup>(''M'',''R''),

			== Definition ==
	where
		⚫	Given a ] and ] manifold ''M'' of dimension 4''k'', the ] gives rise to a ] ''Q'' on the 'middle' real ]

			:<math>H^{2k}(M,\mathbf{R})</math>.
	:''d'' = 4''n''.

	The basic identity for the cup product		The basic identity for the cup product
Line 11:		Line 13:
	:<math>\alpha^p \smile \beta^q = (-1)^{pq}(\beta^q \smile \alpha^p)</math>		:<math>\alpha^p \smile \beta^q = (-1)^{pq}(\beta^q \smile \alpha^p)</math>

	shows that with ''p'' = ''q'' = 2''n'' the product is ]. It takes values in		shows that with ''p'' = ''q'' = 2''k'' the product is ]. It takes values in

			:<math>H^{4k}(M,\mathbf{R})</math>.
	:''H''<sup>4''n''</sup>(''M'',''R'').

	If we assume also that ''M'' is ], ] identifies this with		If we assume also that ''M'' is ], ] identifies this with

			:<math>H^{0}(M,\mathbf{R})</math>
	:''H''<sub>0</sub>(''M'',''R''),

	which ~~is a one-dimensional real vector space and~~ can be identified with ''R''. Therefore cup product, under these hypotheses, does give rise to a ] on ''H''<sup>2''n''</sup>(''M'',''R''); and therefore to a quadratic form ''Q''. More generally, the signature can		which can be identified with <math>\mathbf{R}</math>. Therefore the cup product, under these hypotheses, does give rise to a ] on ''H''<sup>2''k''</sup>(''M'',''R''); and therefore to a quadratic form ''Q''. The form ''Q'' is ] due to Poincaré duality, as it pairs non-degenerately with itself.<ref>{{cite book\|last1=Hatcher\|first1=Allen\|title=Algebraic topology\|date=2003\|publisher=Cambridge Univ. Pr.\|location=Cambridge\|isbn=978-0521795401\|page=250\|edition=Repr.\|url=https://pi.math.cornell.edu/~hatcher/AT/AT.pdf\|accessdate=8 January 2017\|language=en}}</ref> More generally, the signature can be defined in this way for any general compact ] with ''4n''-dimensional Poincaré duality.
	be defined in this way for any general compact ] with ''4n''-dimensional ].

	The '''signature''' of ''M'' is by definition the ] of ''Q''. ~~If ''M''~~ is ~~not connected~~, ~~its~~ ~~signature~~ is ~~defined~~ to be ~~the~~ ~~sum~~ of ~~the signatures of its connected components. If~~ ''M'' has ~~dimension~~ ~~not~~ ~~divisible~~ by 4, ~~its~~ ~~signature~~ is ~~usually~~ ~~defined~~ to be 0. ~~The form~~ ''Q'' is ]. ~~This~~ ~~invariant~~ of a ~~manifold~~ ~~has~~ ~~been~~ ~~studied~~ in ~~detail,~~ ~~starting~~ ~~with~~ ] ~~for 4-manifolds~~.		The '''signature''' <math>\sigma(M)</math> of ''M'' is by definition the ] of ''Q'', that is, <math>\sigma(M) = n_+ - n_-</math> where any diagonal matrix defining ''Q'' has <math>n_+</math> positive entries and <math>n_-</math> negative entries.<ref>{{cite book\|last1=Milnor\|first1=John\|last2=Stasheff\|first2=James\|title=Characteristic classes\|date=1962\|publisher=Annals of Mathematics Studies 246\|page=224\|isbn=978-0691081229\|language=en\|citeseerx=10.1.1.448.869}}</ref> If ''M'' is not connected, its signature is defined to be the sum of the signatures of its connected components.

			== Other dimensions ==
	When ''d'' is ], the same construction gives rise to an ]. Such forms do not have a signature invariant; if they are non-degenerate, any two such forms are equivalent.
			{{details\|L-theory}}
			If ''M'' has dimension not divisible by 4, its signature is usually defined to be 0. There are alternative generalization in ]: the signature can be interpreted as the 4''k''-dimensional (simply connected) symmetric L-group <math>L^{4k},</math> or as the 4''k''-dimensional quadratic L-group <math>L_{4k},</math> and these invariants do not always vanish for other dimensions. The ] is a mod 2 (i.e., an element of <math>\mathbf{Z}/2</math>) for framed manifolds of dimension 4''k''+2 (the quadratic L-group <math>L_{4k+2}</math>), while the ] is a mod 2 invariant of manifolds of dimension 4''k''+1 (the symmetric L-group <math>L^{4k+1}</math>); the other dimensional L-groups vanish.

			=== Kervaire invariant ===
⚫	] (1954) showed that the signature of a manifold is a cobordism invariant, and in particular is given by some linear combination of its ] numbers. ] (1954) found an explicit expression for this linear combination as the ] of the manifold. ] (1962) proved that a simply-connected compact ] with ''4n''-dimensional ] is homotopy equivalent to a manifold if and only if its signature satisfies the expression of the ]
			{{main\|Kervaire invariant}}
			When <math>d=4k+2=2(2k+1)</math> is twice an odd integer (]), the same construction gives rise to an ]. Such forms do not have a signature invariant; if they are non-degenerate, any two such forms are equivalent. However, if one takes a ] of the form, which occurs if one has a ], then the resulting ]s need not be equivalent, being distinguished by the ]. The resulting invariant of a manifold is called the ].

	==~~See~~ ~~also~~==		== Properties ==

			*Compact oriented manifolds ''M'' and ''N'' satisfy <math>\sigma(M \sqcup N) = \sigma(M) + \sigma(N)</math> by definition, and satisfy <math>\sigma(M\times N) = \sigma(M)\sigma(N)</math> by a ].

			*If ''M'' is an oriented boundary, then <math>\sigma(M)=0</math>.

			*] (1954) showed that the signature of a manifold is a cobordism invariant, and in particular is given by some linear combination of its ] ].<ref>{{cite news\|last1=Thom\|first1=René\|title=Quelques proprietes globales des varietes differentiables\|publisher=Comm. Math. Helvetici 28 (1954), S. 17–86\|url=https://www.maths.ed.ac.uk/~v1ranick/papers/thomcob.pdf\|accessdate=26 October 2019\|language=fr}}</ref> For example, in four dimensions, it is given by <math>\frac{p_1}{3}</math>. ] (1954) found an explicit expression for this linear combination as the ] of the manifold.

		⚫	*] (1962) proved that a simply connected compact ] with 4''n''-dimensional ] is homotopy equivalent to a manifold if and only if its signature satisfies the expression of the ].

			*] says that the signature of a 4-dimensional simply connected manifold with a ] is divisible by 16.

			==See also==
	*]		*]
	*]		*]
			*]

			==References==
			{{Reflist}}

			{{DEFAULTSORT:Signature (Topology)}}
	]		]
	]
	]		]

Latest revision as of 15:02, 6 January 2025

Integer invariant of certain classes of topological manifolds

In the field of topology, the signature is an integer invariant which is defined for an oriented manifold M of dimension divisible by four.

This invariant of a manifold has been studied in detail, starting with Rokhlin's theorem for 4-manifolds, and Hirzebruch signature theorem.

Definition

Given a connected and oriented manifold M of dimension 4k, the cup product gives rise to a quadratic form Q on the 'middle' real cohomology group

H^{2k}(M,\mathbf {R} )

The basic identity for the cup product

\alpha ^{p}\smile \beta ^{q}=(-1)^{pq}(\beta ^{q}\smile \alpha ^{p})

shows that with p = q = 2k the product is symmetric. It takes values in

H^{4k}(M,\mathbf {R} )

If we assume also that M is compact, Poincaré duality identifies this with

H^{0}(M,\mathbf {R} )

which can be identified with $\mathbf {R}$ . Therefore the cup product, under these hypotheses, does give rise to a symmetric bilinear form on H(M,R); and therefore to a quadratic form Q. The form Q is non-degenerate due to Poincaré duality, as it pairs non-degenerately with itself. More generally, the signature can be defined in this way for any general compact polyhedron with 4n-dimensional Poincaré duality.

The signature $\sigma (M)$ of M is by definition the signature of Q, that is, $\sigma (M)=n_{+}-n_{-}$ where any diagonal matrix defining Q has $n_{+}$ positive entries and $n_{-}$ negative entries. If M is not connected, its signature is defined to be the sum of the signatures of its connected components.

Other dimensions

Further information: L-theory

If M has dimension not divisible by 4, its signature is usually defined to be 0. There are alternative generalization in L-theory: the signature can be interpreted as the 4k-dimensional (simply connected) symmetric L-group $L^{4k},$ or as the 4k-dimensional quadratic L-group $L_{4k},$ and these invariants do not always vanish for other dimensions. The Kervaire invariant is a mod 2 (i.e., an element of $\mathbf {Z} /2$ ) for framed manifolds of dimension 4k+2 (the quadratic L-group $L_{4k+2}$ ), while the de Rham invariant is a mod 2 invariant of manifolds of dimension 4k+1 (the symmetric L-group $L^{4k+1}$ ); the other dimensional L-groups vanish.

Kervaire invariant

Main article: Kervaire invariant

When $d=4k+2=2(2k+1)$ is twice an odd integer (singly even), the same construction gives rise to an antisymmetric bilinear form. Such forms do not have a signature invariant; if they are non-degenerate, any two such forms are equivalent. However, if one takes a quadratic refinement of the form, which occurs if one has a framed manifold, then the resulting ε-quadratic forms need not be equivalent, being distinguished by the Arf invariant. The resulting invariant of a manifold is called the Kervaire invariant.

Properties

Compact oriented manifolds M and N satisfy $\sigma (M\sqcup N)=\sigma (M)+\sigma (N)$ by definition, and satisfy $\sigma (M\times N)=\sigma (M)\sigma (N)$ by a Künneth formula.

If M is an oriented boundary, then $\sigma (M)=0$ .

René Thom (1954) showed that the signature of a manifold is a cobordism invariant, and in particular is given by some linear combination of its Pontryagin numbers. For example, in four dimensions, it is given by ${\frac {p_{1}}{3}}$ . Friedrich Hirzebruch (1954) found an explicit expression for this linear combination as the L genus of the manifold.

William Browder (1962) proved that a simply connected compact polyhedron with 4n-dimensional Poincaré duality is homotopy equivalent to a manifold if and only if its signature satisfies the expression of the Hirzebruch signature theorem.

Rokhlin's theorem says that the signature of a 4-dimensional simply connected manifold with a spin structure is divisible by 16.

References

Hatcher, Allen (2003). Algebraic topology (PDF) (Repr. ed.). Cambridge: Cambridge Univ. Pr. p. 250. ISBN 978-0521795401. Retrieved 8 January 2017.
Milnor, John; Stasheff, James (1962). Characteristic classes. Annals of Mathematics Studies 246. p. 224. CiteSeerX 10.1.1.448.869. ISBN 978-0691081229.
Thom, René. "Quelques proprietes globales des varietes differentiables" (PDF) (in French). Comm. Math. Helvetici 28 (1954), S. 17–86. Retrieved 26 October 2019.

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