While solving an Ordinary Differential Equation using the unilateral Laplace Transform, it is possible to solve if there is no function in the right hand side of the equation in standard form and if the initial conditions are zero.

Laplace transform of the function f(t) is given by $${\text{F}}\left( {\text{s}} \right) = {\text{L}}\left\{ {{\text{f}}\left( {\text{t}} \right)} \right\} = \int_0^\infty {{\text{f}}\left( {\text{t}} \right){{\text{e}}^{ - {\text{st}}}}{\text{dt}}{\text{.}}} $$ Laplace transform of the function shown below is given by
Transform Theory mcq question image

A

$$\frac{{1 - {{\text{e}}^{ - 2{\text{s}}}}}}{{\text{s}}}$$

B

$$\frac{{1 - {{\text{e}}^{ - {\text{s}}}}}}{{2{\text{s}}}}$$

C

$$\frac{{2 - 2{{\text{e}}^{ - {\text{s}}}}}}{{\text{s}}}$$

D

$$\frac{{1 - 2{{\text{e}}^{ - {\text{s}}}}}}{{\text{s}}}$$

While solving the ordinary differential equation using unilateral laplace transform, we consider the initial conditions of the system.

A

True

B

False

The unilateral Laplace transform of f(t) is $${1 \over {{s^2} + s + 1}}.$$ Which one of the following is the unilateral Laplace transform of g(t) = t.f(t)?

A

$${{ - s} \over {{{\left( {{s^2} + s + 1} \right)}^2}}}$$

B

$${{ - \left( {2s + 1} \right)} \over {{{\left( {{s^2} + s + 1} \right)}^2}}}$$

C

$${s \over {{{\left( {{s^2} + s + 1} \right)}^2}}}$$

D

$${{2s + 1} \over {{{\left( {{s^2} + s + 1} \right)}^2}}}$$

The figure shows the plot of y as a function of x
Differential Equations mcq question image

The function shown is the solution of the differential equation (assuming all initial conditions to be zero) is

A

$$\frac{{{{\text{d}}^2}{\text{y}}}}{{{\text{d}}{{\text{x}}^2}}} = 1$$

B

$$\frac{{{\text{dy}}}}{{{\text{dx}}}} = {\text{x}}$$

C

$$\frac{{{\text{dy}}}}{{{\text{dx}}}} = - {\text{x}}$$

D

$$\frac{{{\text{dy}}}}{{{\text{dx}}}} = \left| {\text{x}} \right|$$

In which of the following useful signals, is the bilateral Laplace Transform different from the unilateral Laplace Transform?

A

d(t)

B

s(t)

C

u(t)

D

all of the mentioned

Given that $$F\left( s \right)$$ is the one-side Laplace transform of $$f\left( t \right),$$ the Laplace transform of $$\int_0^t {f\left( \tau \right)d\tau } $$ is

A

$$sF\left( s \right) - f\left( 0 \right)$$

B

$$\frac{1}{s}F\left( s \right)$$

C

$$\int_0^5 {F\left( \tau \right)d\tau } $$

D

$$\frac{1}{s}\left$$

Which of the following statement/s is/are correct? (A) In the Tamil region right-hand and left hand groups were known as idangai and valangai respectively (B) Both the right hand and left-hand groups included non-peasant castes such as those of artisans as well as higher ranking castes (C) Both the right-hand and left-hand groups usually excluded the outcastes, notably the Paraiyas Choose the correct answer from the options given below:

A

(A) only

B

(A) and (B) only

C

(A) and (C) only

D

(B) and (C) only

Laplace transform function f (t) is F(S), then how will you represent Laplace transform for differential of f (t)?

A

S⁄F(S)

B

F(S)

C

S.F(S)

D

F’(S)

A company recruits candidates satisfying the following criteria - 1. Candidates who secured at least 85% in standard 10th or equivalent. 2. Candidates who secured at least 65% in standard 12th or equivalent. 3. Candidates who are not from commerce background. Who among the following candidates will the company definitely select? A. Jitesh is a science student having scored 70% in standard 12th and 80% in 10th with an excellent sports background. B. Jignesh scored 80% in standard 12th, 90% in standard 10th and secured 2nd place in his college among all commerce students. C. Jayesh scored 75% in standard 10th, 75% in standard 12th and is an arts student. D. Jinesh secured 80% in standard 12th, 88% in standard 10th and is a science student with great acting skills

A

B

D

C

D

A

If F(s) is the Laplace transform of function f(t), then Laplace transform of $$\int\limits_0^{\text{t}} {{\text{f}}\left( \tau \right){\text{d}}\tau } $$ is

A

$$\frac{1}{{\text{s}}}{\text{F}}\left( {\text{s}} \right)$$

B

$$\frac{1}{{\text{s}}}{\text{F}}\left( {\text{s}} \right) - {\text{f}}\left( 0 \right)$$

C

$${\text{sF}}\left( {\text{s}} \right) - {\text{f}}\left( 0 \right)$$

D

$$\int {{\text{F}}\left( {\text{s}} \right){\text{ds}}} $$

While solving an Ordinary Differential Equation using the unilateral Laplace Transform, it is possible to solve if there is no function in the right hand side of the equation in standard form and if the initial conditions are zero.

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