GATE ECE 2024 | GATE ECE Year Wise Previous Years Questions

GATE ECE 2024

MCQ (More than One Correct Answer)

-1.33

Which of the following statements is/are true for a BJT with respect to its DC current gain $\beta$?

Under high-level injection condition in forward active mode, $\beta$ will decrease with increase in the magnitude of collector current.

Under low-level injection condition in forward active mode, where the current at the emitter-base junction is dominated by recombination-generation process, $\beta$ will decrease with increase in the magnitude of collector current.

$\beta$ will be lower when the BJT is in saturation region compared to when it is in active region.

A higher value of $\beta$ will lead to a lower value of the collector-to-emitter breakdown voltage.

GATE ECE 2024

Numerical

-1.33

An NMOS transistor operating in the linear region has $I_{D}$ of 5 $\mu$A at $V_{DS}$ of 0.1 V. Keeping $V_{GS}$ constant, the $V_{DS}$ is increased to 1.5 V.

Given that $\mu_{n}C_{ox} \frac{W}{L}$ = 50 $\mu$A/$V^2$, the transconductance at the new operating point (in $\mu$A/V, rounded off to two decimal places) is ______.

Your input ____

GATE ECE 2024

MCQ (Single Correct Answer)

-0.33

A digital communication system transmits through a noiseless bandlimited channel $[-W, W]$. The received signal $z(t)$ at the output of the receiving filter is given by $z(t) = \sum\limits_{n} b[n]x(t-nT)$ where $b[n]$ are the symbols and $x(t)$ is the overall system response to a single symbol. The received signal is sampled at $t = mT$. The Fourier transform of $x(t)$ is $X(f)$. The Nyquist condition that $X(f)$ must satisfy for zero intersymbol interference at the receiver is ______.

$$\sum\limits_{m=-\infty}^{\infty} X \left( f + \frac{m}{T}\right) = T$$

$$\sum\limits_{m=-\infty}^{\infty} X \left( f + \frac{m}{T}\right) = \frac{1}{T}$$

$$\sum\limits_{m=-\infty}^{\infty} X (f + mT) = T$$

$$\sum\limits_{m=-\infty}^{\infty} X (f + mT) = \frac{1}{T}$$

GATE ECE 2024

MCQ (Single Correct Answer)

-0.33

A white Gaussian noise $w(t)$ with zero mean and power spectral density $\frac{N_0}{2}$,

when applied to a first-order RC low pass filter produces an output $n(t)$. At a particular time $t = t_k$, the variance of the random variable $n(t_k)$ is ________.

$\frac{N_0}{4RC}$

$\frac{N_0}{2RC}$

$\frac{N_0}{RC}$

$\frac{2N_0}{RC}$

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2024