Loyola College M.Sc. Mathematics Nov 2006 Topology Question Paper PDF Download

             LOYOLA COLLEGE (AUTONOMOUS), CHENNAI – 600 034  M.Sc. DEGREE EXAMINATION – MATHEMATICS

AA 23

THIRD SEMESTER – NOV 2006

         MT 3803 – TOPOLOGY

(Also equivalent to MT 3800)

 

 

Date & Time : 25-10-2006/9.00-12.00         Dept. No.                                                       Max. : 100 Marks

 

 

            Answer all the questions.

 

01.(a)(i)   Let X be a metric space with metric d.  Show that d1. defined by

d1(x,y) =

is also a metric on X.

(OR)

(ii)   Let X and Y be metric spaces and f be a mapping of X into Y.

Show that f 1(G) is open in X whenever G is open in Y.

 

(b)(i)  Let X be a metric space.  Prove that any arbitrary union of open sets in X is
open and any finite intersection of open sets in X is open.

 

(ii)   Give an example to show that any arbitrary intersection of open sets in X
need not be open.

 

(iii)   In any metric space X, prove that each closed sphere is a closed set.(6+4+5)

(OR)

(iv)  If a convergent sequence in a metric space has infinitely many distinct
points, prove that its limit is a limit point of the set of points of the
sequence.

 

(v)   State and prove Cantor’s Intersection Theorem.

 

(vi)   If {An} is a sequence of nowhere dense sets in a complete metric space X,
show that there exists a point in X which is not in any of the An’s.    (4+6+5)

 

02.(a) (i)    Prove that every separable metric space is second countable.

(OR)

(ii)   Let X be a non–empty set, and let there be give a “closure” operation
which  assigns to each subset A of X a subset   of X in such a manner
that  (1)  = ,  (2)  A Í ,  (3)  , and  (4)   =.

If a “closed” set A is defined to be one for which A = , show that the
class of all complements of such sets is a topology on X whole closure
operation is precisely that initially given.

 

  • (i) Show that any closed subspace of a compact space is compact.

 

(ii)   Give an example to show that a proper subspace of a compact space need
not be closed.

 

(iii)  Prove that any continuous image of a compact space is compact.     (5+4+6)

(OR)

(iv)  Let C(X  đ) be the set of all bounded continuous real functions defined
on a topological space X.  Show that  (1) C (X  đ) is a real Banach space
with respect  to pointwise addition and multiplication and the  norm
defined by  = sup;    (2)  If multiplication is defined pointwise
C(X,  R) is a commutative real algebra with identity in which
£     and   = 1.

 

03.(a) (i)     State and prove Tychonoff’s Theorem.

(OR)

(ii)     Show that a metric space is compact Û it is complete and totally
bounded.

 

(b) (i)    Prove that in a sequentially compact space, every open cover has a
Lesbesgue number.

 

(ii)    Show that every sequentially compact metric space is totally bounded.(9+6)

(OR)

(iii)    State and prove Ascoli’s Theorem.

 

04.(a)(i)     Show that every subspace of Hausdorff is also a Hausdorff.

(OR)

(ii)     Prove that every compact Haurdolff space is normal.

 

(b)(i)     Let X be a T1 – space.

Show that X is a normal Û each neighbourhood of a closed set F contains
the closure of  some neighbourhood of F.

 

(ii)    State and prove Uryjohn’s Lemma.                                                        (6+9)

(OR)

(iii)    If X is a second countable normal space, show that there exists a
homeomorphism  f  of X onto a subspace of R¥.

 

05.(a)(i)     Prove that any continuous image of a connected space is connected.

(OR)

(ii)    Show that the components of a totally disconnected space are its points.

 

(b)(i)    Let X be a topological space and A be a connected subspace of X.  If B is a
subspace of X such that A Í B Í , show that B is connected.

 

(ii)   If X is an arbitrary topological space, then prove the following:

(1)  each point in X is contained in exactly one component of X;

  • each connected subspace of X is contained in a component of X;
  • a connected subspace of X which is both open and closed is a            component of X.                                                                        (6+9)

(OR)

 

(iii)   State and prove the Weierstrass Approximation Theorem.

 

 

Go To Main page

 

Latest Govt Job & Exam Updates:

View Full List ...

© Copyright Entrance India - Engineering and Medical Entrance Exams in India | Website Maintained by Firewall Firm - IT Monteur