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Differential Equations

Multiple Choice Questions

91.

The solution of the differential equation $\frac{d y}{d x} = \sin (x + y) \tan (x + y) - 1$ is

$\csc (x + y) + \tan (x + y) = x + c$
$x + \csc (x + y) = c$
$x + \tan (x + y) = c$
$x + \sec (x + y) = c$

92.

The differential equation of all straight lines touching the circle x² + y² = a² is

${(y - \frac{dy}{dx})}^{2} = a^{2} [1 + {(\frac{dy}{dx})}^{2}]$
${(y - x \frac{dy}{dx})}^{2} = a^{2} [1 + {(\frac{dy}{dx})}^{2}]$
$(y - x \frac{dy}{dx}) = a^{2} [1 + \frac{dy}{dx}]$
$(y - \frac{dy}{dx}) = a^{2} [1 - \frac{dy}{dx}]$

93.

The differential equation $|\frac{dy}{dx}| + |y| + 3 = 0$ admits

infinite number of solutions
no solutions
a unique solution
many solutions

94.

Solution of the differential equation $xdy - ydx - \sqrt{x^{2} + y^{2}} dx = 0$

$y - \sqrt{x^{2} + y^{2}} = {cx}^{2}$
$y + \sqrt{x^{2} + y^{2}} = {cx}^{2}$
$y + \sqrt{x^{2} + y^{2}} = {cy}^{2}$
$x - \sqrt{x^{2} + y^{2}} = {cy}^{2}$

95.

If $xsin (\frac{x}{y}) dy = [ysin (\frac{y}{x}) - x] dx$ and $y (1) = \frac{π}{2}$ , then the value of $\cos (\frac{y}{x})$ is equal to :

x
$\frac{1}{x}$
$\log (x)$
e^x

96.

The differential equation of the system of all circles of radius r in the xy plane is :

${[1 + {(\frac{dy}{dx})}^{3}]}^{2} = r^{2} {(\frac{d^{2} y}{{dx}^{2}})}^{2}$
${[1 + {(\frac{dy}{dx})}^{3}]}^{2} = r^{2} {(\frac{d^{2} y}{{dx}^{2}})}^{3}$
${[1 + {(\frac{dy}{dx})}^{2}]}^{3} = r^{2} {(\frac{d^{2} y}{{dx}^{2}})}^{2}$
${[1 + {(\frac{dy}{dx})}^{2}]}^{3} = r^{2} {(\frac{d^{2} y}{{dx}^{2}})}^{3}$

97.
The general solution of the differential equation
$\frac{d^{2} y}{{dx}^{2}} + 2 \frac{d y}{d x} + y = 2 e^{3 x}$ is given by

$y = (c_{1} + c_{2} x) e^{x} + \frac{e^{3 x}}{8}$

$y = (c_{1} + c_{2} x) e^{- x} + \frac{e^{- 3 x}}{8}$

$y = (c_{1} + c_{2} x) e^{- x} + \frac{e^{3 x}}{8}$

$y = (c_{1} + c_{2} x) e^{x} + \frac{e^{- 3 x}}{8}$

$y = (c_{1} + c_{2} x) e^{- x} + \frac{e^{3 x}}{8}$

The equation can be written as

(D² + 2D + 1)y = 2e^3x, where $\frac{d}{dx} = D$

Here, F(D) = D² + 2D + 1 and Q = 2e^3x

The auxillary equation is

m² + 2m + 1 = 0 $\Rightarrow$ (m + 1)² = 0

$\Rightarrow$ m = - 1, - 1

$∴ The CF = (c_{1} + c_{2} x) e^{- x}$

$and PI = \frac{1}{F (D)} 2 e^{3 x} = 2 . \frac{1}{D^{2} + 2 D + 1} . e^{3 x} = 2 . \frac{e^{3 x}}{9 + 6 + 1} = \frac{e^{3 x}}{8}$

Hence, the complete solution is

y = CF + PI

$\Rightarrow y = (c_{1} + c_{2} x) e^{- x} + \frac{e^{3 x}}{8}$

98.

The solution of the differential ydx + (x - y³)dy = 0 is:

xy = $\frac{1}{3} y^{3} + c$
xy = y⁴ + c
y⁴ = 4xy + c
4y = y³ + c

99.

If the distances covered by a particle in time t is proportional to the cube root of its velocity, then the acceleration is

a constant
$\propto s^{3}$
$\propto \frac{1}{s^{3}}$
$\propto s^{5}$

100.

The solution of the differential equation $\frac{dy}{dx} = \frac{y}{x} + \frac{ϕ (\frac{y}{x})}{ϕ' (\frac{y}{x})}$ is

$xϕ (\frac{y}{x}) = k$
$ϕ (\frac{y}{x}) = kx$
$yϕ (\frac{y}{x}) = k$
$ϕ (\frac{y}{x}) = ky$

Previous Year Papers

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Multiple Choice Questions

97. The general solution of the differential equationd2ydx2 + 2dydx + y = 2e3x is given by y = c1 + c2xex + e3x8 y = c1 + c2xe- x + e- 3x8 y = c1 + c2xe- x + e3x8 y = c1 + c2xex + e- 3x8