LOYOLA COLLEGE (AUTONOMOUS), CHENNAI – 600 034
M.Sc. DEGREE EXAMINATION – STATISTICS
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FIRST SEMESTER – APRIL 2006
ST 1808 – ANALYSIS
Date & Time : 22-04-2006/1.00-4.00 P.M. Dept. No. Max. : 100 Marks
SECTION- A
Answer ALL questions . (10 x 2 = 20 marks)
- Define a discrete metric. Show that it satisfies the properties of a metric.
- If xn → x and xn→ y as n → ∞, show that x =
- Define a norm on a vector space and give an example.
- For all x, y є R(n), show that x . y = is an inner product.
- Check whether or not all the points of any open ball B( a ; r ) are the interior points of B( a ; r ).
- Illustrate that an infinite union of closed sets is not closed.
- If f is continuous, one-to-one and onto function, then show that f -1 in general is not continuous.
- Show that pointwise convergence does not imply uniform convergence of a sequence of functions.
- Let f( x ) = x , 0 ≤ x ≤ 1 . Let D be the partition {0 ,¼ , ½ , ¾ ,1 } of [ 0 , 1 ] . Find the upper sum U( f ; D ) and the lower sum
L( f ; D ) of the function f( x ).
- Let R ( g ; a , b ) be the collection of Riemann – Stieltjes integralble
functions with respect to g on [ a , b ] . If f є R (g ; a , b ),
show that kf є R (g ; a , b ) , where k is any constant.
SECTION – B
Answer any FIVE questions. (5 x 8 = 40 marks)
- In B[ 1 , 2 ], with ρ( f , g ) = sup | f(x) – g(x) | ,
1≤ x ≤ 2
let f n be given by f n(x) = ( 1 + x n ) 1 / n (1≤ x ≤ 2) .
Show that f n → f where f(x) = x (1≤ x ≤ 2).
- In a metric space (X , ρ ), if xn → x and yn→ y as n → ∞,
show that ρ( xn , yn ) → ρ( x , y ) as n → ∞.
- If V is an inner product space, prove that
║ x + y ║2 + ║ x – y ║2 = 2 [║ x ║2 + ║ y ║2 ] for all x , y є V.
- State three equivalent conditions for a point c є X to be a limit point of E С X .
- Show that every convergent sequence in a metric space is a cauchy sequence. Check whether or not the converse is true.
- State and prove Banach’s fixed point principle.
- Prove that a continuous function with compact domain is uniformly continuous.
- State and prove Cauchy’s root test for the absolute convergence or divergence of a series of complex terms.
SECTION – C
Answer any TWO questions. (2 x 20 = 40 marks)
19(a) With respect to the usual metric , prove that joint convergence of a
sequence is equivalent to the marginal convergence of the
components of that sequence. (10)
19(b) State and prove Cauchy – Schwartz inequality regarding inner
product space. (10)
20(a) Let V , W be the normed vector spaces. Let f : V → W be a linear
transformation. Then prove that the following three statements are
equivalent : (16)
- f is continuous on V.
- There exists a point xo in V at which f is continuous.
- ║f(x)║ ∕ ║x║ is bounded for x є V – { ө }.
What do we conclude from the equivalence of statements (i) & (ii)?
20(b) Show that a compact set in a metric space is complete. (4)
21(a) Prove that the number Λ is the upper limit of the sequence
{x n , n ≥ 1 } iff for all є > 0
- x n < Λ + є for all sufficiently large n and
- x n > Λ – є for infinitely many n. (10)
21(b) Let {f n} be a sequence of real functions integrable over the
finite interval [a , b]. If f n→ f uniformly on [a , b],
prove that f is integrable over [a , b]. (10)
22(a) State and prove the Cauchy’s general principle of uniform
convergence of a sequence of real or complex valued functions. (8)
22(b) State and prove a necessary and sufficient condition for a function
f(x) to be Riemann – Stieltjes integrable on [a , b]. (12)
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