Govt. M M college, Jessore
Dept. of Mathematics
3rd Year Test Examination-2011
Sub-Real Analysis Code-3732
Full Marks-100, Time-4 hours
[All questions are of equal value. Answer any six questions ]
1.(a) State and prove Archimedean property of real numbers.
(b) Prove that between any two distinct real numbers, there is always an irrational numbers and therefore infinitely many irrational numbers .
2.(a) State and prove the Heine Borel Theorem.
(b) Define:- (i) open set. (ii) closed set (iii) limit point of a set . (iv) Prove that a set is closed if and only if its complement is open.
3. (a) Define monotonic sequence. Prove that a monotonic increasing sequence which is bounded above converges to its least upper bound.
(b) State and prove Cauchy’s general Principle of Convergence of a sequence.
4. (a) Define:- (i) Infinite series (ii) alternating series
(iii) convergent series. If a series is convergent, then .
(b) Test the convergence of any two:- (i)
(ii) (iii)
5. (a) State and prove the first mean value Theorem of differential calculus.
(b) Verify Rolle’s theorem to the functions (i) in [1,3]
(ii) in [1,3]
6. (a) Define (i) point wise convergence of sequence (ii) uniform convergence of a sequence
State and prove Weierstrass’s M-test theorem for uniform convergence of series of functions.
(b) Test for uniform convergence, the sequence < > defined by on [0, 1]
7. (a) Prove that if a function f(x) is Continuous on [a, b] then prove that the function attains its supermum and infimum at least once in
[a, b].
(b) State and prove the intermediate value Theorem for Continuous function.
8. (a) Write out necessary and sufficient Condition for the Riemann integrability of a function defined on [a, b] and prove its sufficiency.
(b) If is Riemann integral on [a, b], then prove that
(i) is also Riemann integrable (ii)
9. (a) Define point wise convergence and uniform convergence of sequence of functions.
prove Mn -test for uniform convergence of sequence.
(b) If , where and .
Show that Converges point wise but not uniformly on [0,1].
10. (a) Define:- (i) Euclidean n-space , (ii) Melrice space, Prove that Euclidean n-space is Complete.
(b) Let d: be a function defined by where
show that is metric space for .
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