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3.2 CONNECTEDNESS IN CLOSURE SPACES.

In this section we introduce and study connectedness.

Definition 3.2.1

(X,c) is said to be disconnected if it can be written as two disjoint nonempty subsets A and B such that cA U cB =X, cA ∩ cB = φ and cA and cB are nonempty. A space which is not disconnected is said to be connected.

Example 3.2.2

X = {a,b,c}

c can be defined on X such that

c {a}={a,b}, c{b}=c{c}=c{b,c}={b,c}, c{a,b}=c{a,c}=cX=X, cφ=φ)

Then c is a closure operation on X.

Here (X,c) is connected because we can not find nonempty subsets A and B such that cA U cB=X and cA ∩ cB=φ.

Definition 3.2.3

(X,c) is said to be feebly disconnected if it can be written as two disjoint nonempty subsets A and B such that A U cB = cA U B=X and cA ∩ B=φ=A ∩ cB.

Note 3.2.4

It is clear that (X,c) is disconnected implies (X,c) is feebly disconnected. The following example shows that the converse is not true

Example 3.2.5

X={a,b,c}

c{a}={a,c},c{b}=c{c}=c{b,c}={b,c},c{a,b}=c{a,c}=cX=X,cφ=φ

c is a closure operation on X.

Here (X,c) is feebly disconnected, but not disconnected.

Result 3.2.6

(x,t) is disconnected ⇒ (X,c) is disconnected.

Proof

(X,t) is disconnected implies that it is the union of two disjoint nonempty subsets A and B such that clA U clB =X, clA ∩ clB=φ and clA, clB are nonempty. clA∩clB=φ)). So cA ∩ cB=φ. That is (X,c) is disconnected.

Note 3.2.7

(X,t) is connected need not imply that (X,c) is connected.

Example

X={a,b,c} . Let c be a closure operation defined on X in such a way that

c {a} = {a},c {b}= {b,c},c {c}= c {a .b} = c {b ,c }= cX = X , cφ=φ)

(X,t)={X,φ,{b,c}}

Here (X,c) is disconnected, but (X,t) is connected.

Remark

Connectedness of a subspace Y of (X,c) can be defined in the same manner.

Note 3.2.8

Let (X ,c) be a closure space and Y be a connected subset of (X ,c). Then cY  need not be connected.

Example 3.2.9

X={a,b,c,d,e}

Let c be defined on X such that

c{a}= {a},c{b}= {a,b,c},c{c}= {b,c},c{d} = {b,c,d },

c{a,b}=c{a,c}=c{b,c}=c{a,b,c}={a,b,c},

c{c,d}={b,c,d}, c{a,d}=c{b,d}=c{a,b,d}=c{a,c,d}=c{b,c,d}=c{a,b,c,d}={a,b,c,d},

c {e}= c {a,e}= c {b,e}= c {c ,e}= c{d,e}= c {a ,b ,e }= c {a ,c ,e }= c {a ,d ,e }= c {b ,c ,e }

= c {c,d ,e} =c{b,d,e}=c{a,b,d,e}=c{a,c,d,e}=c{b,c,d,e}=cX=X,cφ=φ

Here Y={b,c} is connected.

cY={a,b,c}; if c' isthe induced closure operation on cY, then 

c'{a}={a},c'{c}={b,c},c'{b}:=;c'{a,b}=c'{b,c}=c'{a,c}=c'cY=cY. 

cY is disconnected.

Note 3.2.10

If cA and cB form a separation o f X and i f Y is a connected subset o f X, then Y need not be entirely within either cA or cB.

Example 3.2.11

X={a,b,c}

Let c be a closure operation defined on X such that 

c{a}={a},c{b}={b,c} c{c}={a,c},c{a,b}=c{b,c}=cX=X,c{a,c}={a,c}.

Y={a,c} is connected •

Note 3.2.12

The image of a connected space under a c -c' morphism need not be connected. 

Example

Let X={a,b,c,d,e}. A closure operation c is defined on X as in Example 3.2.9

Let Y={a,b,c}

c' be defined on Y such that

c'{a}={a},c'{b}={b,c},c'{c}=c'{a,b}=c'{b,c}=c'{a,c}=c'X=X c'φ =φ

Let f be a map from (X,c) into (Y,c') defined in such a way that f(a)=a, f(b)=c, f(c)-b, 

f(d)=c, f(e)=c.

Here f is a c-c' moiphism. But f(X) is disconnected.

Result 3.2.13 

Suppose c, is a closure operator on Y with degree k and f is a c-c, morphism from (X ,c) to (Y,c1). If c1 k(A) and c1k(B) form a separation of Y, then c (f-1(c1k(A)) and c(f-1(c1k(B)) form a separation on X.

Proof

Compactness and connectedness: Linear Functional Analysis - 2 | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

Compactness and connectedness: Linear Functional Analysis - 2 | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

Compactness and connectedness: Linear Functional Analysis - 2 | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

Compactness and connectedness: Linear Functional Analysis - 2 | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

Compactness and connectedness: Linear Functional Analysis - 2 | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

In similar manner

Compactness and connectedness: Linear Functional Analysis - 2 | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

Compactness and connectedness: Linear Functional Analysis - 2 | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET form a separation on X •

Result 3.2.14

Let (X,c) be connected and f is a c-c1 morphism from (X,c) on to (Y, c1). Then(Y,t1) is connected.

Proof

Compactness and connectedness: Linear Functional Analysis - 2 | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET morphism and we get f is c - cl1 morphism. Suppose cl1 A and cl1 B form a separation on Y. Then  Compactness and connectedness: Linear Functional Analysis - 2 | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET and  Compactness and connectedness: Linear Functional Analysis - 2 | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET By th e above  result  Compactness and connectedness: Linear Functional Analysis - 2 | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET form a separation on X. This is a contradiction . Hence (Y,t) is connected.

3.3 PATHWISE AND LOCAL CONNECTEDNESS

In this section we define and study pathwise connectedness and local connnectedness.

Definition 3.3.1

A space (X,c) is pathwise connected if and only if for any two points x and y in X, there is a cl1 -cmorphism f : I → X such that f(o) = x and f (l) = y where cl1 is th e usual closure on I, f is called a path from x to y.

Result 3.3.2

(X,c) is pathwise connected implies (X,t) is pathwise connected.

Proof

If (X,c) is pathwise connected, then for any two points x and y in X there is a cl1 - cmorphism f : I → X such th a t f(0)=x and f(l) = y. If f is cl1-cmorphism ,then f is cl1-cl morphism. Therefore (X,t) is pathwise connected.

Note 3.3.3

The converse of the above result is not true.

Note 3.3.4

Pathwise connected space need not be a connected space.

Definition 3.3.5

A space X is said to be locally connected at x if for every neighbourhood U of x, there is a connected neighbourhood V of x contained in U. If X is locally connected at each of its points, then X is said to be locally connected.

Definintion 3.3.6

A space X is said to be locally path connected at x if for every neighbourhood U of x, there is a path connected neighbourhood V of x contained in U. If X is locally path connected at each of its points, then it is said to be locally path connected.

Note 3.3.7

A space (X,c) is locally connected need not imply that (X,t) is locally connected and vice-versa.

A parallel study of the above concepts in the set up of closure spaces is interesting; however we are not attempting it in this thesis.

3.4. COMPACTNESS AND CONNECTEDNESS IN MONOTONE SPACES

Definition 3.4.1

Let (X,c*) be a monotone space. F be a proper filter on X and x be an element of X. We shall say that x is a cluster point of F in (X,c*) if x belongs to ∩{c*F : F∈F}. That is each neighbourhood of x intersects each F ∈ F.

Definition 3.4.2

A monotone space (X,c*) is said to be compact, if every proper filter of sets on X has a cluster point in X.

Remark 3.4.3

It is clear that if (X,c*) is compact, then (X,c) is compact but the converse is not true.

Result 3.4.4

Any image under a c-c* morphism of a compact monotone space (X,c*) onto a monotone space (Y,c*) is compact.

The proof is similar to the Proof of 41 A - 15 in [CE2] .

Result 3.4.5

Every closed subspace of a compact monotone space is compact.

The proof is similar to the Proof of 41 A - 10 in [CE2] .

Result 3.4.6

If (Y , c') is a compact subspace of a Hausdorff monotone space (X ,c*),then Y is closed in X.

The proof is similar to the Proof of 41 A-11 in [CE2] .

Definition 3.4.7

A monotone space (X,c*) is said to be discomiected if it can be written as two disjoint nonempty subsets A and B such that c*A U c*B = X, c*A ∩ c*B=φ). A space which is not disconnected is said to be connected.

Remark 3.4.8

(X,c) is disconnected implies (X,c*) is disconnected,and the converse is not true. 

Example 3.4. 9

X={a,b,c}

c* be defined on X such that

c*{a}={a},c*{b}={b,c}, c*{c}={b,c}, c*{a,b}=c*{b,c}=c{a,c}=c*X=X,c*φ=φ

c* is a monotone operator.

(X,c*) is disconnected. But (X,c) is connected.

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