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Differential Equations

Multiple Choice Questions

201.

The degree and order of the differential equation ${[1 + {(\frac{dy}{dx})}^{3}]}^{\frac{7}{3}} = 7 (\frac{d^{2} y}{{dx}^{2}})$ respectively are

3 and 7
3 and 2
7 and 3
2 and 3

202.

The particular solution of the differential equation

$y (1 + \log (x)) \frac{d x}{d y} - xlog (x) = 0$ , when, x = e, y = e² is

y = exlog(x)
ey = xlog(x)
xy = elog(x)
ylog(x) = ex

203.

If $\sin (x)$ is the integrating factor (IF) of the linear differential equation $\frac{dy}{dx} + Py = Q$ , then P is

$\log (\sin (x))$
$\cos (x)$
$\tan (x)$
$\cot (x)$

204.

The solution of the differential equation

$\frac{dy}{dx} = \tan (\frac{y}{x}) + \frac{y}{x}$ is

$\cos (\frac{y}{x}) = cx$
$\sin (\frac{y}{x}) = cx$
$\cos (\frac{y}{x}) = cy$
$\sin (\frac{y}{x}) = cy$

205.

The differential equation of all parabolas whose axis is Y-axis, is

$x \frac{d^{2} y}{{dx}^{2}} - \frac{dy}{dx} = 0$
$x \frac{d^{2} y}{{dx}^{2}} + \frac{dy}{dx} = 0$
$\frac{d^{2} y}{{dx}^{2}} - y = 0$
$\frac{d^{2} y}{{dx}^{2}} - \frac{dy}{dx} = 0$

206.
The particular solution of the differential equation xdy + 2ydx = 0, when x = 2, y = 1 is

xy = 4

x²y = 4

xy² = 4

x²y² = 4

x²y = 4

$We have, xdy + 2 ydx = 0 \Rightarrow \frac{dy}{dx} + \frac{2 dx}{x} = 0 [dividing both sides by xy] On Integrating both sides, we get \int \frac{1}{y} dy + 2 \int \frac{1}{x} dx = \log (C) \Rightarrow \log (y) + 2 \log (x) = \log (C) [∵ nlog (m) = \log (m^{n})] ∴ \log ({yx}^{2}) = \log (C) \Rightarrow {yx}^{2} = C When x = 2 and y = 1, then C = 1 \times 2^{2} = 4 ∴ Particular solution is x^{2} y = 4 .$

207.

The general solution of the equation $\frac{dy}{dx} = \frac{y^{2} - x}{2 y (x + 1)}$ is

y² = (1 + x)log(1 + x) - c
$y^{2} = (1 + x) \log (\frac{c}{(1 - x)}) - 1$
$y^{2} = (1 - x) \log (\frac{c}{(1 - x)}) - 1$
$y^{2} = (1 + x) \log (\frac{c}{(1 + x)}) - 1$

208.

The general solution of the differential equation $\frac{dy}{dx} + \sin (\frac{x + y}{2}) = \sin (\frac{x - y}{2})$ is

$\log_{e} |\tan (\frac{y}{2})| = - 2 \sin (\frac{x}{2}) + C$
$\log_{e} |\tan (\frac{y}{4})| = 2 \sin (\frac{x}{2}) + C$
$\log_{e} (\tan (\frac{y}{2})) = - 2 \sin (\frac{x}{2}) + C$
$\log_{e} (\tan (\frac{y}{4})) = - 2 \sin (\frac{x}{2}) + C$

209.

The function y specified implicitly by the relation $\int_{0}^{y} e^{t} dt + \int_{0}^{x} \cos (t) dt$ = 0 satisfies the differential equation

$e^{2 y} (\frac{d^{2} y}{{dx}^{2}} + {(\frac{dy}{dx})}^{2}) = \sin (x)$
$e^{y} (\frac{d^{2} y}{{dx}^{2}} + {(\frac{dy}{dx})}^{2}) = \sin (2 x)$
$e^{y} (2 \frac{d^{2} y}{{dx}^{2}} + {(\frac{dy}{dx})}^{2}) = \sin (x)$
$e^{y} (\frac{d^{2} y}{{dx}^{2}} + {(\frac{dy}{dx})}^{2}) = \sin (x)$

210.

The solution of the differential equation $\frac{dy}{dx} = 2 e^{x - y} + x^{2} e^{- y}$ is

$e^{y} = 2 e^{x} + \frac{x^{3}}{3} + C$
$e^{- y} = 2 e^{x} + \frac{x^{- 3}}{3} + C$
$e^{- y} = 2 e^{x} + \frac{x^{3}}{3} + C$
$e^{y} = 2 e^{- x} + \frac{x^{3}}{3} + C$

Previous Year Papers

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Multiple Choice Questions

206. The particular solution of the differential equation xdy + 2ydx = 0, when x = 2, y = 1 is xy = 4 x2y = 4 xy2 = 4 x2y2 = 4

206.
The particular solution of the differential equation xdy + 2ydx = 0, when x = 2, y = 1 is

xy = 4

x²y = 4

xy² = 4

x²y² = 4