For an integer \( n \), let \( f_n(x) = xe^{-nx }\), where \( x \in [0, 1] \). Let \( S := \{f_n : n \geq 1\} \). Consider the metric space \( (C([0, 1]), d) \), where \[ d(f, g) = \sup_{x \in [0, 1]} |f(x) - g(x)|, \quad f, g \in C([0, 1]). \] Which of the following statement(s) is/are true?}
For an integer \( n \), let \( f_n(x) = xe^{-nx }\), where \( x \in [0, 1] \). Let \( S := \{f_n : n \geq 1\} \). Consider the metric space \( (C([0, 1]), d) \), where \[ d(f, g) = \sup_{x \in [0, 1]} |f(x) - g(x)|, \quad f, g \in C([0, 1]). \] Which of the following statement(s) is/are true?}
Show Hint
- \( S \) is an equi-continuous family of continuous functions
(2) (3) (4)\( S \) is closed in \( (C([0, 1]), d) \)
\( S \) is bounded in \( (C([0, 1]), d) \)
\( S \) is compact in \( (C([0, 1]), d) \)Show Solution
Verified By CollegeduniaThe Correct Option is A
Solution and Explanation
Step 1: Checking equi-continuity of \( S \). The functions \( f_n(x) = xe^{-nx} \) are continuous for all \( n \geq 1 \), and for each \( \epsilon>0 \), the variation in \( f_n(x) \) can be made arbitrarily small by choosing \( x \) close enough to a fixed point. Hence, \( S \) is equi-continuous.
Step 2: Checking whether \( S \) is closed. The limit of a sequence of functions in \( S \) need not belong to \( S \) (e.g., \( f_n \to 0 \) pointwise as \( n \to \infty \), but \( 0 \notin S \)). Thus, \( S \) is not closed.
Step 3: Checking boundedness of \( S \). For any \( f_n(x) \in S \), we have \[ |f_n(x)| = |xe^{-nx}| \leq \max_{x \in [0, 1]} |xe^{-nx}| \leq \frac{1}{e}. \] Thus, \( S \) is bounded in \( (C([0, 1]), d) \).
Step 4: Checking compactness of \( S \). The family \( S \) is not compact because it is not closed (as shown above), violating a necessary condition for compactness in a metric space.
Step 5: Conclusion. The correct answers are \( {(1), (3)} \).Was this answer helpful?00
Top GATE MA Mathematics Questions
- Consider the following condition on a function \( f : {C} \to {C} \): \[ |f(z)| = 1 \quad {for all } z \in {C} { such that } \operatorname{Im}(z) = 0. \] Which one of the following is correct?
- Let \( C \) be the ellipse \( \{ z \in \mathbb{C} : |z - 2| + |z + 2| = 8 \} \) traversed counter-clockwise. The value of the contour integral \[ \int_C \frac{z^2 \, dz}{z^2 - 2z + 2} \] is equal to:
- Let \( X \) be a topological space and \( A \subseteq X \). Given a subset \( S \) of \( X \), let \( {int}(S), \partial S, \) and \( \overline{S} \) denote the interior, boundary, and closure, respectively, of the set \( S \). Which one of the following is NOT necessarily true?
Consider the following limit: $ \lim_{\epsilon \to 0} \frac{1}{\epsilon} \int_{0}^{\infty} e^{-x / \epsilon} \left( \cos(3x) + x^2 + \sqrt{x + 4} \right) dx. $
Which one of the following is correct?- Let \( {R}[X^2, X^3] \) be the subring of \( {R}[X] \) generated by \( X^2 \) and \( X^3 \). Consider the following statements: 1. The ring \( {R}[X^2, X^3] \) is a unique factorization domain.
2. The ring \( {R}[X^2, X^3] \) is a principal ideal domain.
Which one of the following is correct?
Top GATE MA Product of Matrices Questions
- Consider the following condition on a function \( f : {C} \to {C} \): \[ |f(z)| = 1 \quad {for all } z \in {C} { such that } \operatorname{Im}(z) = 0. \] Which one of the following is correct?
- Let \( {R}[X^2, X^3] \) be the subring of \( {R}[X] \) generated by \( X^2 \) and \( X^3 \). Consider the following statements: 1. The ring \( {R}[X^2, X^3] \) is a unique factorization domain.
2. The ring \( {R}[X^2, X^3] \) is a principal ideal domain.
Which one of the following is correct? - Given a prime number \( p \), let \( n_p(G) \) denote the number of \( p \)-Sylow subgroups of a finite group \( G \). Which one of the following is TRUE for every group \( G \) of order \( 2024 \)?
- Let \( A \in M_2({C}) \) be given by \[ A = \begin{bmatrix} 0 & 2
2 & 0 \end{bmatrix}. \] Let \( T: M_2({C}) \to M_2({C}) \) be the linear transformation given by \( T(B) = AB \). The characteristic polynomial of \( T \) is: - For the initial value problem \[ \frac{dy}{dx} = f(x, y), \quad y(x_0) = y_0, \] generate approximations \( y_n \) to \( y(x_n) \) using the recursion formula \[ y_n = y_{n-1} + a k_1 + b k_2, \] where \[ k_1 = h f(x_{n-1}, y_{n-1}), \quad k_2 = h f(x_{n-1} + \beta h, y_{n-1} + \beta k_1). \] Which one of the following choices of \( a, b, \alpha, \beta \) gives the Runge-Kutta method of order 2?
Top GATE MA Questions
- No. of group homomorphism from Z4 to S4
- Number of finite non-isomorphic groups with exactly 3 conjugacy classes_____.
- f(x,y)=\(\left\{\begin{matrix} 1-cos(\frac{x^2}{y^2}) \\ \sqrt{x^2+y^2} \end{matrix}\right.\) ;if y≠0 & n∈R, then
- If ‘=’ denotes increasing order of intensity, then the meaning of the words [drizzle — rain — downpour] is analogous to [ — quarrel — feud]. Which one of the given options is appropriate to fill the blank?
- Statements: 1. All heroes are winners.
2. All winners are lucky people. Inferences: I. All lucky people are heroes.
II. Some lucky people are heroes.
III. Some winners are heroes. Which of the above inferences can be logically deduced from statements 1 and 2?