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Join (topology)

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Geometric join of two line segments. The original spaces are shown in green and blue. The join is a three-dimensional solid, a disphenoid, in gray.

In topology, a field of mathematics, the join of two topological spaces A {\displaystyle A} and B {\displaystyle B} , often denoted by A B {\displaystyle A\ast B} or A B {\displaystyle A\star B} , is a topological space formed by taking the disjoint union of the two spaces, and attaching line segments joining every point in A {\displaystyle A} to every point in B {\displaystyle B} . The join of a space A {\displaystyle A} with itself is denoted by A 2 := A A {\displaystyle A^{\star 2}:=A\star A} . The join is defined in slightly different ways in different contexts

Geometric sets

If A {\displaystyle A} and B {\displaystyle B} are subsets of the Euclidean space R n {\displaystyle \mathbb {R} ^{n}} , then:

A B   :=   { t a + ( 1 t ) b   |   a A , b B , t [ 0 , 1 ] } {\displaystyle A\star B\ :=\ \{t\cdot a+(1-t)\cdot b~|~a\in A,b\in B,t\in \}} ,

that is, the set of all line-segments between a point in A {\displaystyle A} and a point in B {\displaystyle B} .

Some authors restrict the definition to subsets that are joinable: any two different line-segments, connecting a point of A to a point of B, meet in at most a common endpoint (that is, they do not intersect in their interior). Every two subsets can be made "joinable". For example, if A {\displaystyle A} is in R n {\displaystyle \mathbb {R} ^{n}} and B {\displaystyle B} is in R m {\displaystyle \mathbb {R} ^{m}} , then A × { 0 m } × { 0 } {\displaystyle A\times \{0^{m}\}\times \{0\}} and { 0 n } × B × { 1 } {\displaystyle \{0^{n}\}\times B\times \{1\}} are joinable in R n + m + 1 {\displaystyle \mathbb {R} ^{n+m+1}} . The figure above shows an example for m=n=1, where A {\displaystyle A} and B {\displaystyle B} are line-segments.

Examples

  • The join of two simplices is a simplex: the join of an n-dimensional and an m-dimensional simplex is an (m+n+1)-dimensional simplex. Some special cases are:
    • The join of two disjoint points is an interval (m=n=0).
    • The join of a point and an interval is a triangle (m=0, n=1).
    • The join of two line segments is homeomorphic to a solid tetrahedron or disphenoid, illustrated in the figure above right (m=n=1).
    • The join of a point and an (n-1)-dimensional simplex is an n-dimensional simplex.
  • The join of a point and a polygon (or any polytope) is a pyramid, like the join of a point and square is a square pyramid. The join of a point and a cube is a cubic pyramid.
  • The join of a point and a circle is a cone, and the join of a point and a sphere is a hypercone.

Topological spaces

If A {\displaystyle A} and B {\displaystyle B} are any topological spaces, then:

A B   :=   A p 0 ( A × B × [ 0 , 1 ] ) p 1 B , {\displaystyle A\star B\ :=\ A\sqcup _{p_{0}}(A\times B\times )\sqcup _{p_{1}}B,}

where the cylinder A × B × [ 0 , 1 ] {\displaystyle A\times B\times } is attached to the original spaces A {\displaystyle A} and B {\displaystyle B} along the natural projections of the faces of the cylinder:

A × B × { 0 } p 0 A , {\displaystyle {A\times B\times \{0\}}\xrightarrow {p_{0}} A,}
A × B × { 1 } p 1 B . {\displaystyle {A\times B\times \{1\}}\xrightarrow {p_{1}} B.}

Usually it is implicitly assumed that A {\displaystyle A} and B {\displaystyle B} are non-empty, in which case the definition is often phrased a bit differently: instead of attaching the faces of the cylinder A × B × [ 0 , 1 ] {\displaystyle A\times B\times } to the spaces A {\displaystyle A} and B {\displaystyle B} , these faces are simply collapsed in a way suggested by the attachment projections p 1 , p 2 {\displaystyle p_{1},p_{2}} : we form the quotient space

A B   :=   ( A × B × [ 0 , 1 ] ) / , {\displaystyle A\star B\ :=\ (A\times B\times )/\sim ,}

where the equivalence relation {\displaystyle \sim } is generated by

( a , b 1 , 0 ) ( a , b 2 , 0 ) for all  a A  and  b 1 , b 2 B , {\displaystyle (a,b_{1},0)\sim (a,b_{2},0)\quad {\mbox{for all }}a\in A{\mbox{ and }}b_{1},b_{2}\in B,}
( a 1 , b , 1 ) ( a 2 , b , 1 ) for all  a 1 , a 2 A  and  b B . {\displaystyle (a_{1},b,1)\sim (a_{2},b,1)\quad {\mbox{for all }}a_{1},a_{2}\in A{\mbox{ and }}b\in B.}

At the endpoints, this collapses A × B × { 0 } {\displaystyle A\times B\times \{0\}} to A {\displaystyle A} and A × B × { 1 } {\displaystyle A\times B\times \{1\}} to B {\displaystyle B} .

If A {\displaystyle A} and B {\displaystyle B} are bounded subsets of the Euclidean space R n {\displaystyle \mathbb {R} ^{n}} , and A U {\displaystyle A\subseteq U} and B V {\displaystyle B\subseteq V} , where U , V {\displaystyle U,V} are disjoint subspaces of R n {\displaystyle \mathbb {R} ^{n}} such that the dimension of their affine hull is d i m U + d i m V + 1 {\displaystyle dimU+dimV+1} (e.g. two non-intersecting non-parallel lines in R 3 {\displaystyle \mathbb {R} ^{3}} ), then the topological definition reduces to the geometric definition, that is, the "geometric join" is homeomorphic to the "topological join":

( ( A × B × [ 0 , 1 ] ) / ) { t a + ( 1 t ) b   |   a A , b B , t [ 0 , 1 ] } {\displaystyle {\big (}(A\times B\times )/\sim {\big )}\simeq \{t\cdot a+(1-t)\cdot b~|~a\in A,b\in B,t\in \}}

Abstract simplicial complexes

If A {\displaystyle A} and B {\displaystyle B} are any abstract simplicial complexes, then their join is an abstract simplicial complex defined as follows:

  • The vertex set V ( A B ) {\displaystyle V(A\star B)} is a disjoint union of V ( A ) {\displaystyle V(A)} and V ( B ) {\displaystyle V(B)} .
  • The simplices of A B {\displaystyle A\star B} are all disjoint unions of a simplex of A {\displaystyle A} with a simplex of B {\displaystyle B} : A B := { a b : a A , b B } {\displaystyle A\star B:=\{a\sqcup b:a\in A,b\in B\}} (in the special case in which V ( A ) {\displaystyle V(A)} and V ( B ) {\displaystyle V(B)} are disjoint, the join is simply { a b : a A , b B } {\displaystyle \{a\cup b:a\in A,b\in B\}} ).

Examples

  • Suppose A = { , { a } } {\displaystyle A=\{\emptyset ,\{a\}\}} and B = { , { b } } {\displaystyle B=\{\emptyset ,\{b\}\}} , that is, two sets with a single point. Then A B = { , { a } , { b } , { a , b } } {\displaystyle A\star B=\{\emptyset ,\{a\},\{b\},\{a,b\}\}} , which represents a line-segment. Note that the vertex sets of A and B are disjoint; otherwise, we should have made them disjoint. For example, A 2 = A A = { , { a 1 } , { a 2 } , { a 1 , a 2 } } {\displaystyle A^{\star 2}=A\star A=\{\emptyset ,\{a_{1}\},\{a_{2}\},\{a_{1},a_{2}\}\}} where a1 and a2 are two copies of the single element in V(A). Topologically, the result is the same as A B {\displaystyle A\star B} - a line-segment.
  • Suppose A = { , { a } } {\displaystyle A=\{\emptyset ,\{a\}\}} and B = { , { b } , { c } , { b , c } } {\displaystyle B=\{\emptyset ,\{b\},\{c\},\{b,c\}\}} . Then A B = P ( { a , b , c } ) {\displaystyle A\star B=P(\{a,b,c\})} , which represents a triangle.
  • Suppose A = { , { a } , { b } } {\displaystyle A=\{\emptyset ,\{a\},\{b\}\}} and B = { , { c } , { d } } {\displaystyle B=\{\emptyset ,\{c\},\{d\}\}} , that is, two sets with two discrete points. then A B {\displaystyle A\star B} is a complex with facets { a , c } , { b , c } , { a , d } , { b , d } {\displaystyle \{a,c\},\{b,c\},\{a,d\},\{b,d\}} , which represents a "square".

The combinatorial definition is equivalent to the topological definition in the following sense: for every two abstract simplicial complexes A {\displaystyle A} and B {\displaystyle B} , | | A B | | {\displaystyle ||A\star B||} is homeomorphic to | | A | | | | B | | {\displaystyle ||A||\star ||B||} , where | | X | | {\displaystyle ||X||} denotes any geometric realization of the complex X {\displaystyle X} .

Maps

Given two maps f : A 1 A 2 {\displaystyle f:A_{1}\to A_{2}} and g : B 1 B 2 {\displaystyle g:B_{1}\to B_{2}} , their join f g : A 1 B 1 A 2 B 2 {\displaystyle f\star g:A_{1}\star B_{1}\to A_{2}\star B_{2}} is defined based on the representation of each point in the join A 1 B 1 {\displaystyle A_{1}\star B_{1}} as t a + ( 1 t ) b {\displaystyle t\cdot a+(1-t)\cdot b} , for some a A 1 , b B 1 {\displaystyle a\in A_{1},b\in B_{1}} :

f g   ( t a + ( 1 t ) b )     =     t f ( a ) + ( 1 t ) g ( b ) {\displaystyle f\star g~(t\cdot a+(1-t)\cdot b)~~=~~t\cdot f(a)+(1-t)\cdot g(b)}

Special cases

The cone of a topological space X {\displaystyle X} , denoted C X {\displaystyle CX} , is a join of X {\displaystyle X} with a single point.

The suspension of a topological space X {\displaystyle X} , denoted S X {\displaystyle SX} , is a join of X {\displaystyle X} with S 0 {\displaystyle S^{0}} (the 0-dimensional sphere, or, the discrete space with two points).

Properties

Commutativity

The join of two spaces is commutative up to homeomorphism, i.e. A B B A {\displaystyle A\star B\cong B\star A} .

Associativity

It is not true that the join operation defined above is associative up to homeomorphism for arbitrary topological spaces. However, for locally compact Hausdorff spaces A , B , C {\displaystyle A,B,C} we have ( A B ) C A ( B C ) . {\displaystyle (A\star B)\star C\cong A\star (B\star C).} Therefore, one can define the k-times join of a space with itself, A k := A A {\displaystyle A^{*k}:=A*\cdots *A} (k times).

It is possible to define a different join operation A ^ B {\displaystyle A\;{\hat {\star }}\;B} which uses the same underlying set as A B {\displaystyle A\star B} but a different topology, and this operation is associative for all topological spaces. For locally compact Hausdorff spaces A {\displaystyle A} and B {\displaystyle B} , the joins A B {\displaystyle A\star B} and A ^ B {\displaystyle A\;{\hat {\star }}\;B} coincide.

Homotopy equivalence

If A {\displaystyle A} and A {\displaystyle A'} are homotopy equivalent, then A B {\displaystyle A\star B} and A B {\displaystyle A'\star B} are homotopy equivalent too.

Reduced join

Given basepointed CW complexes ( A , a 0 ) {\displaystyle (A,a_{0})} and ( B , b 0 ) {\displaystyle (B,b_{0})} , the "reduced join"

A B A { b 0 } { a 0 } B {\displaystyle {\frac {A\star B}{A\star \{b_{0}\}\cup \{a_{0}\}\star B}}}

is homeomorphic to the reduced suspension

Σ ( A B ) {\displaystyle \Sigma (A\wedge B)}

of the smash product. Consequently, since A { b 0 } { a 0 } B {\displaystyle {A\star \{b_{0}\}\cup \{a_{0}\}\star B}} is contractible, there is a homotopy equivalence

A B Σ ( A B ) . {\displaystyle A\star B\simeq \Sigma (A\wedge B).}

This equivalence establishes the isomorphism H ~ n ( A B ) H n 1 ( A B )   ( = H n 1 ( A × B / A B ) ) {\displaystyle {\widetilde {H}}_{n}(A\star B)\cong H_{n-1}(A\wedge B)\ {\bigl (}=H_{n-1}(A\times B/A\vee B){\bigr )}} .

Homotopical connectivity

Given two triangulable spaces A , B {\displaystyle A,B} , the homotopical connectivity ( η π {\displaystyle \eta _{\pi }} ) of their join is at least the sum of connectivities of its parts:

  • η π ( A B ) η π ( A ) + η π ( B ) {\displaystyle \eta _{\pi }(A*B)\geq \eta _{\pi }(A)+\eta _{\pi }(B)} .

As an example, let A = B = S 0 {\displaystyle A=B=S^{0}} be a set of two disconnected points. There is a 1-dimensional hole between the points, so η π ( A ) = η π ( B ) = 1 {\displaystyle \eta _{\pi }(A)=\eta _{\pi }(B)=1} . The join A B {\displaystyle A*B} is a square, which is homeomorphic to a circle that has a 2-dimensional hole, so η π ( A B ) = 2 {\displaystyle \eta _{\pi }(A*B)=2} . The join of this square with a third copy of S 0 {\displaystyle S^{0}} is a octahedron, which is homeomorphic to S 2 {\displaystyle S^{2}} , whose hole is 3-dimensional. In general, the join of n copies of S 0 {\displaystyle S^{0}} is homeomorphic to S n 1 {\displaystyle S^{n-1}} and η π ( S n 1 ) = n {\displaystyle \eta _{\pi }(S^{n-1})=n} .

Deleted join

The deleted join of an abstract complex A is an abstract complex containing all disjoint unions of disjoint faces of A:

A Δ 2 := { a 1 a 2 : a 1 , a 2 A , a 1 a 2 = } {\displaystyle A_{\Delta }^{*2}:=\{a_{1}\sqcup a_{2}:a_{1},a_{2}\in A,a_{1}\cap a_{2}=\emptyset \}}

Examples

  • Suppose A = { , { a } } {\displaystyle A=\{\emptyset ,\{a\}\}} (a single point). Then A Δ 2 := { , { a 1 } , { a 2 } } {\displaystyle A_{\Delta }^{*2}:=\{\emptyset ,\{a_{1}\},\{a_{2}\}\}} , that is, a discrete space with two disjoint points (recall that A 2 = { , { a 1 } , { a 2 } , { a 1 , a 2 } } {\displaystyle A^{\star 2}=\{\emptyset ,\{a_{1}\},\{a_{2}\},\{a_{1},a_{2}\}\}} = an interval).
  • Suppose A = { , { a } , { b } } {\displaystyle A=\{\emptyset ,\{a\},\{b\}\}} (two points). Then A Δ 2 {\displaystyle A_{\Delta }^{*2}} is a complex with facets { a 1 , b 2 } , { a 2 , b 1 } {\displaystyle \{a_{1},b_{2}\},\{a_{2},b_{1}\}} (two disjoint edges).
  • Suppose A = { , { a } , { b } , { a , b } } {\displaystyle A=\{\emptyset ,\{a\},\{b\},\{a,b\}\}} (an edge). Then A Δ 2 {\displaystyle A_{\Delta }^{*2}} is a complex with facets { a 1 , b 1 } , { a 1 , b 2 } , { a 2 , b 1 } , { a 2 , b 2 } {\displaystyle \{a_{1},b_{1}\},\{a_{1},b_{2}\},\{a_{2},b_{1}\},\{a_{2},b_{2}\}} (a square). Recall that A 2 {\displaystyle A^{\star 2}} represents a solid tetrahedron.
  • Suppose A represents an (n-1)-dimensional simplex (with n vertices). Then the join A 2 {\displaystyle A^{\star 2}} is a (2n-1)-dimensional simplex (with 2n vertices): it is the set of all points (x1,...,x2n) with non-negative coordinates such that x1+...+x2n=1. The deleted join A Δ 2 {\displaystyle A_{\Delta }^{*2}} can be regarded as a subset of this simplex: it is the set of all points (x1,...,x2n) in that simplex, such that the only nonzero coordinates are some k coordinates in x1,..,xn, and the complementary n-k coordinates in xn+1,...,x2n.

Properties

The deleted join operation commutes with the join. That is, for every two abstract complexes A and B:

( A B ) Δ 2 = ( A Δ 2 ) ( B Δ 2 ) {\displaystyle (A*B)_{\Delta }^{*2}=(A_{\Delta }^{*2})*(B_{\Delta }^{*2})}

Proof. Each simplex in the left-hand-side complex is of the form ( a 1 b 1 ) ( a 2 b 2 ) {\displaystyle (a_{1}\sqcup b_{1})\sqcup (a_{2}\sqcup b_{2})} , where a 1 , a 2 A , b 1 , b 2 B {\displaystyle a_{1},a_{2}\in A,b_{1},b_{2}\in B} , and ( a 1 b 1 ) , ( a 2 b 2 ) {\displaystyle (a_{1}\sqcup b_{1}),(a_{2}\sqcup b_{2})} are disjoint. Due to the properties of a disjoint union, the latter condition is equivalent to: a 1 , a 2 {\displaystyle a_{1},a_{2}} are disjoint and b 1 , b 2 {\displaystyle b_{1},b_{2}} are disjoint.

Each simplex in the right-hand-side complex is of the form ( a 1 a 2 ) ( b 1 b 2 ) {\displaystyle (a_{1}\sqcup a_{2})\sqcup (b_{1}\sqcup b_{2})} , where a 1 , a 2 A , b 1 , b 2 B {\displaystyle a_{1},a_{2}\in A,b_{1},b_{2}\in B} , and a 1 , a 2 {\displaystyle a_{1},a_{2}} are disjoint and b 1 , b 2 {\displaystyle b_{1},b_{2}} are disjoint. So the sets of simplices on both sides are exactly the same. □

In particular, the deleted join of the n-dimensional simplex Δ n {\displaystyle \Delta ^{n}} with itself is the n-dimensional crosspolytope, which is homeomorphic to the n-dimensional sphere S n {\displaystyle S^{n}} .

Generalization

The n-fold k-wise deleted join of a simplicial complex A is defined as:

A Δ ( k ) n := { a 1 a 2 a n : a 1 , , a n  are k-wise disjoint faces of  A } {\displaystyle A_{\Delta (k)}^{*n}:=\{a_{1}\sqcup a_{2}\sqcup \cdots \sqcup a_{n}:a_{1},\cdots ,a_{n}{\text{ are k-wise disjoint faces of }}A\}} , where "k-wise disjoint" means that every subset of k have an empty intersection.

In particular, the n-fold n-wise deleted join contains all disjoint unions of n faces whose intersection is empty, and the n-fold 2-wise deleted join is smaller: it contains only the disjoint unions of n faces that are pairwise-disjoint. The 2-fold 2-wise deleted join is just the simple deleted join defined above.

The n-fold 2-wise deleted join of a discrete space with m points is called the (m,n)-chessboard complex.

See also

References

  1. Colin P. Rourke and Brian J. Sanderson (1982). Introduction to Piecewise-Linear Topology. New York: Springer-Verlag. doi:10.1007/978-3-642-81735-9. ISBN 978-3-540-11102-3.
  2. Bryant, John L. (2001-01-01), Daverman, R. J.; Sher, R. B. (eds.), "Chapter 5 - Piecewise Linear Topology", Handbook of Geometric Topology, Amsterdam: North-Holland, pp. 219–259, ISBN 978-0-444-82432-5, retrieved 2022-11-15
  3. ^ Matoušek, Jiří (2007). Using the Borsuk-Ulam Theorem: Lectures on Topological Methods in Combinatorics and Geometry (2nd ed.). Berlin-Heidelberg: Springer-Verlag. ISBN 978-3-540-00362-5. Written in cooperation with Anders Björner and Günter M. Ziegler , Section 4.3
  4. Fomenko, Anatoly; Fuchs, Dmitry (2016). Homotopical Topology (2nd ed.). Springer. p. 20.
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