GATE ECE 2013 | Transmission of Signal Through Continuous Time LTI Systems Question 9 | Signals and Systems

Let g(t) = $${e^{ - \pi {t^2}}}$$, and h(t) is a filter matched to g(t). If g(t) is applied as input to h(t), then the Fourier transform of the output is

$${e^{ - \pi {f^2}}}\,$$

$${e^{ - \pi {f^2}/2}}\,$$

$${e^{ - \pi \left| f \right|}}$$

$${e^{ - 2\pi {f^2}}}$$

GATE ECE 2013

MCQ (Single Correct Answer)

-0.3

Assuming zero initial condition, the response y (t) of the system given below to a unit step input u(t) is GATE ECE 2013 Signals and Systems - Transmission of Signal Through Continuous Time LTI Systems Question 29 English

GATE ECE 2013 Signals and Systems - Transmission of Signal Through Continuous Time LTI Systems Question 29 English

u (t)

tu (t)

$${{{t^2}} \over 2}(t)$$

$${e^{ - t}}u(t)$$

GATE ECE 2010

MCQ (Single Correct Answer)

-0.3

A system with the transfer function $${{Y(s)} \over {X(s)}} = {s \over {s + p}}\,\,$$ has an output
$$y(t) = \cos \left( {2t - {\pi \over 3}} \right)\,$$ for the input signal
$$x(t) = p\cos \left( {2t - {\pi \over 2}} \right)$$. Then, the system parameter 'p' is

$$\sqrt 3 $$

$$\,{2 \over {\sqrt 3 \,}}$$

$${{\sqrt 3 \,} \over 2}$$

GATE ECE 2010

MCQ (Single Correct Answer)

-0.3

Consider the pulse shape s(t) as shown. The impulse response h(t) of the filter matched to this pulse is GATE ECE 2010 Signals and Systems - Transmission of Signal Through Continuous Time LTI Systems Question 30 English