GATE EE 2015 Set 2 | Continuous Time Signal Fourier Transform Question 4 | Signals and Systems

GATE EE 2015 Set 2

MCQ (Single Correct Answer)

-0.6

Consider a signal defined by $$$x\left(t\right)=\left\{\begin{array}{l}e^{j10t}\;\;\;for\;\left|t\right|\leq1\\0\;\;\;\;\;\;\;for\;\;\left|t\right|>1\end{array}\right.$$$ Its Fourier Transform is

$$\frac{2\sin\left(\omega-10\right)}{\omega-10}$$

$$2e^{j10}\frac{\sin\left(\omega-10\right)}{\omega-10}$$

$$\frac{2\sin\left(\omega\right)}{\omega-10}$$

$$e^{j10\omega\frac{2\sin\omega}\omega}$$

GATE EE 2014 Set 1

MCQ (Single Correct Answer)

-0.6

Let f(t) be a continuous time signal and let F($$\omega$$) be its Fourier Transform defined by $$F\left(\omega\right)=\int_{-\infty}^\infty f\left(t\right)e^{-j\omega t}dt$$. Define g(t) by $$g\left(t\right)=\int_{-\infty}^\infty F\left(u\right)e^{-jut}du$$. What is the relationship between f(t) and g(t)?

g(t) would always be proportional to f(t)

g(t) would be proportional to f(t) if f(t) is an even function

g(t) would be proportional to f(t) only if f(t) is a sinusoidal function

g(t) would never be proportional to f(t)

GATE EE 2014 Set 3

MCQ (Single Correct Answer)

-0.6

A differentiable non constant even function x(t) has a derivative y(t), and their respective Fourier Transforms are X($$\omega$$) and Y($$\omega$$). Which of the following statements is TRUE?

X($$\omega$$) and Y($$\omega$$) are both real.

X($$\omega$$) is real and Y($$\omega$$) is imaginary.

X($$\omega$$) and Y($$\omega$$) are both imaginary.

X($$\omega$$) is imaginary and Y($$\omega$$) is real.

GATE EE 2014 Set 2

MCQ (Single Correct Answer)

-0.6

A 10 kHz even-symmetric square wave is passed through a bandpass filter with centre frequency at 30 kHz and 3 dB passband of 6 kHz. The filter output is

a highly attenuated square wave at 10 kHz

nearly zero.

a nearly perfect cosine wave at 30 kHz.

a nearly perfect sine wave at 30 kHz.

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GATE EE Subjects

Electric Circuits

Three Phase Circuits Transient Response Graph Theory Two Port Networks Sinusoidal Steady State Analysis Network Elements Network Theorems

Electromagnetic Fields

Time Varying Fields Electrostatics Magnetostatics

Signals and Systems

Linear Time Invariant Systems Continuous and Discrete Time Signals Continuous Time Signal Fourier Transform Continuous Time Periodic Signal Fourier Series Discrete Time Signal Z Transformation Miscellaneous Continuous Time Signal Laplace Transform Sampling Theorem