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<p>Let the equation of two diameters of a circle $$x^{2}+y^{2}-2 x+2 f y+1=0$$ be $$2 p x-y=1$$ and $$2 x+p y=4 p$$. Then the slope m $$ \in $$ $$(0, \infty)$$ of the tangent to the hyperbola $$3 x^{2}-y^{2}=3$$ passing through the centre of the circle is equal to _______________.</p> Options: []
2 Explanation: $$ \begin{aligned} &2 p+f-1=0 \quad\dots(1)\\\\ &2-p f-4 p=0 \quad\dots(2)\\\\ &2=p(f+4) \\\\ &p=\frac{2}{f+4} \\\\ &2 p=1-f \\\\ &\frac{4}{f+4}=1-f \\\\ &f^2+3 f=0 \\\\ &f=0 \text { or }-3 \end{aligned} $$<br/><br/> Hyperbola $3 x^2-y^2=3, x^2-\frac{y^2}{3}=1$<br/><br/> $$ \mathrm{y}=\mathrm{mx} \pm \s...
<p>Let $$\mathrm{P}\left(x_{0}, y_{0}\right)$$ be the point on the hyperbola $$3 x^{2}-4 y^{2}=36$$, which is nearest to the line $$3 x+2 y=1$$. Then $$\sqrt{2}\left(y_{0}-x_{0}\right)$$ is equal to :</p> Options: [{"identifier": "A", "content": "3"}, {"identifier": "B", "content": "$$-$$9"}, {"identifier": "C", "cont...
["B"] Explanation: If $\left(x_0, y_0\right)$ is point on hyperbola then tangent at $\left(x_0, y_0\right)$ is parallel to $3 x+2 y=1$ <br/><br/>Equation of tangent $= \frac{x x_0}{12}-\frac{y y_0}{9}=2$ <br/><br/>Slope of tangent $=\frac{-3}{2}$ <br/><br/>Equation of tangent in slope form <br/><br/>$y=\frac{-3}{2} x ...
<p>The foci of a hyperbola are $$( \pm 2,0)$$ and its eccentricity is $$\frac{3}{2}$$. A tangent, perpendicular to the line $$2 x+3 y=6$$, is drawn at a point in the first quadrant on the hyperbola. If the intercepts made by the tangent on the $$\mathrm{x}$$ - and $$\mathrm{y}$$-axes are $$\mathrm{a}$$ and $$\mathrm{b}...
12 Explanation: <p>Given that the foci are at $(\pm 2, 0)$, the distance between the foci is $2ae = 2\times2 = 4$. <br/><br/>So, $a = \frac{4}{3}$. </p> <p>The eccentricity of the hyperbola is given as $\frac{3}{2}$. Thus, $e = \frac{3}{2}$. </p> <p>For a hyperbola, $e^2 = 1 + \frac{b^2}{a^2}$, which gives $b^2 = a^2(...
<p>Let $$m_{1}$$ and $$m_{2}$$ be the slopes of the tangents drawn from the point $$\mathrm{P}(4,1)$$ to the hyperbola $$H: \frac{y^{2}}{25}-\frac{x^{2}}{16}=1$$. If $$\mathrm{Q}$$ is the point from which the tangents drawn to $$\mathrm{H}$$ have slopes $$\left|m_{1}\right|$$ and $$\left|m_{2}\right|$$ and they make po...
8 Explanation: Equation of tangent to the hyperbola $\frac{y^2}{a^2}-\frac{x^2}{b^2}=1$ <br/><br/>$$ y=m x \pm \sqrt{a^2-b^2 m^2} $$ <br/><br/>Given the hyperbola $H: \frac{y^2}{25} - \frac{x^2}{16} = 1$, the equation of the tangent to this hyperbola can be written as : <br/><br/>$$y=mx \pm \sqrt{25 - 16m^2}$$ <br/>...
<p>Consider a hyperbola $$\mathrm{H}$$ having centre at the origin and foci on the $$\mathrm{x}$$-axis. Let $$\mathrm{C}_1$$ be the circle touching the hyperbola $$\mathrm{H}$$ and having the centre at the origin. Let $$\mathrm{C}_2$$ be the circle touching the hyperbola $$\mathrm{H}$$ at its vertex and having the cent...
["A"] Explanation: <p><img src="https://app-content.cdn.examgoal.net/fly/@width/image/1lwhfif9k/1a3e3d85-d2e7-4099-8558-58b863f1c6ee/866ac480-1802-11ef-b156-f754785ad3ce/file-1lwhfif9l.png?format=png" data-orsrc="https://app-content.cdn.examgoal.net/image/1lwhfif9k/1a3e3d85-d2e7-4099-8558-58b863f1c6ee/866ac480-1802-11...
<p>The length of the latus rectum and directrices of hyperbola with eccentricity e are 9 and $$x= \pm \frac{4}{\sqrt{3}}$$, respectively. Let the line $$y-\sqrt{3} x+\sqrt{3}=0$$ touch this hyperbola at $$\left(x_0, y_0\right)$$. If $$\mathrm{m}$$ is the product of the focal distances of the point $$\left(x_0, y_0\righ...
61 Explanation: <p><img src="https://app-content.cdn.examgoal.net/fly/@width/image/1lwaskftu/d526b7cc-575f-4620-8047-7c036e1ade54/189a8020-145c-11ef-a76a-45e5478b32e1/file-1lwaskftv.png?format=png" data-orsrc="https://app-content.cdn.examgoal.net/image/1lwaskftu/d526b7cc-575f-4620-8047-7c036e1ade54/189a8020-145c-11ef-...
If $$\int {{{2{e^x} + 3{e^{ - x}}} \over {4{e^x} + 7{e^{ - x}}}}dx = {1 \over {14}}(ux + v{{\log }_e}(4{e^x} + 7{e^{ - x}})) + C} $$, where C is a constant of integration, then u + v is equal to _____________. Options: []
7 Explanation: $$2{e^x} + 3{e^{ - x}} = A(4{e^x} + 7{e^{ - x}}) + B(4{e^x} - 7{e^{ - x}}) + \lambda $$<br><br>2 = 4A + 4B ; 3 = 7A $$-$$ 7B ; $$\lambda$$ = 0<br><br>$$A + B = {1 \over 2}$$<br><br>$$A - B = {3 \over 7}$$<br><br>$$A = {1 \over 2}\left( {{1 \over 2} + {3 \over 7}} \right) = {{7 + 6} \over {28}} = {{13} \...
If $$\int {{{\sin x} \over {{{\sin }^3}x + {{\cos }^3}x}}dx = } $$ <br/><br/>$$\alpha {\log _e}|1 + \tan x| + \beta {\log _e}|1 - \tan x + {\tan ^2}x| + \gamma {\tan ^{ - 1}}\left( {{{2\tan x - 1} \over {\sqrt 3 }}} \right) + C$$, when C is constant of integration, then the value of $$18(\alpha + \beta + {\gamma ^2}...
3 Explanation: $$ = \int {{{{{\sin x} \over {{{\cos }^3}x}}} \over {1 + {{\tan }^3}x}}dx = \int {{{\tan x.{{\sec }^2}x} \over {(\tan x + 1)(1 + {{\tan }^2}x - \tan x)}}dx} } $$<br><br>Let $$\tan x = t \Rightarrow {\sec ^2}x.\,dx = dt$$<br><br>$$ = \int {{t \over {(t + 1)({t^2} - t + 1)}}dt} $$<br><br>$$ = \int {\left(...
The integral $$\int {\left( {1 + x - {1 \over x}} \right){e^{x + {1 \over x}}}dx} $$ is equal to Options: [{"identifier": "A", "content": "<img class=\"question-image\" src=\"https://res.cloudinary.com/dckxllbjy/image/upload/v1734264772/exam_images/je7jltiyhhqoek98uddy.webp\" loading=\"lazy\" alt=\"JEE Main 2014 (Off...
["D"] Explanation: Let $$I = \int {\left( {1 + x - {1 \over x}} \right)} {e^{x + {\raise0.5ex\hbox{$\scriptstyle 1$} \kern-0.1em/\kern-0.15em \lower0.25ex\hbox{$\scriptstyle x$}}}}dx$$ <br><br>$$ = \int {{e^{x + {\raise0.5ex\hbox{$\scriptstyle 1$} \kern-0.1em/\kern-0.15em \lower0.25ex\hbox{$\scriptstyle x$}}}}} dx + \...
The integral $$\int \, $$cos(log<sub>e</sub> x) dx is equal to : (where C is a constant of integration) Options: [{"identifier": "A", "content": "$${x \\over 2}$$[sin(log<sub>e</sub> x) $$-$$ cos(log<sub>e</sub> x)] + C"}, {"identifier": "B", "content": "x[cos(log<sub>e</sub> x) + sin(log<sub>e</sub> x)] + C"}, {"id...
["C"] Explanation: $${\rm I} = \int {\cos \left( {\ell nx} \right)} dx$$ <br><br>$${\rm I} = \cos (\ln x).x + \int {\sin \left( {\ell nx} \right)dx} $$ <br><br>$${\rm I} = \cos \left( {\ell nx} \right)x + \left[ {\sin \left( {\ell nx} \right).x - \int {\cos \left( {\ell nx} \right)dx} } \right]$$ <br><br>$${\rm I} = {...
<p>For $$I(x)=\int \frac{\sec ^{2} x-2022}{\sin ^{2022} x} d x$$, if $$I\left(\frac{\pi}{4}\right)=2^{1011}$$, then</p> Options: [{"identifier": "A", "content": "$$3^{1010} I\\left(\\frac{\\pi}{3}\\right)-I\\left(\\frac{\\pi}{6}\\right)=0$$"}, {"identifier": "B", "content": "$$3^{1010} I\\left(\\frac{\\pi}{6}\\right)-...
["A"] Explanation: <p>Given,</p> <p>$$I(x) = \int {{{{{\sec }^2}x - 2022} \over {{{\sin }^{2022}}x}}dx} $$</p> <p>$$ = \int {{{{{\sec }^2}x} \over {{{\sin }^{2022}}x}}dx - \int {{{2022} \over {{{\sin }^{2022}}x}}dx} } $$</p> <p>$$ = \int {{1 \over {{{\sin }^{2022}}x}}\,.\,{{\sec }^2}x\,dx - \int {{{2022} \over {{{\sin...
<p>If $$I(x) = \int {{e^{{{\sin }^2}x}}(\cos x\sin 2x - \sin x)dx} $$ and $$I(0) = 1$$, then $$I\left( {{\pi \over 3}} \right)$$ is equal to :</p> Options: [{"identifier": "A", "content": "$$ - {e^{{3 \\over 4}}}$$"}, {"identifier": "B", "content": "$$ - {1 \\over 2}{e^{{3 \\over 4}}}$$"}, {"identifier": "C", "conten...
["D"] Explanation: $$ \begin{aligned} & \text { Given, } I(x)=\int e^{\sin ^2 x}(\cos x \sin 2 x-\sin x) d x \\\\ & =\int e^{\sin ^2 x} \cdot \cos x \cdot \sin 2 x d x-\int \sin x e^{\sin ^2 x} d x \\\\ & =\int \frac{\cos x}{\mathrm{I}} \cdot \frac{e^{\sin ^2 x} \cdot \sin 2 x}{\mathrm{II}} d x-\int \sin x \cdot e^{\s...
<p>Let $$I(x)=\int \frac{x^{2}\left(x \sec ^{2} x+\tan x\right)}{(x \tan x+1)^{2}} d x$$. If $$I(0)=0$$, then $$I\left(\frac{\pi}{4}\right)$$ is equal to :</p> Options: [{"identifier": "A", "content": "$$\\log _{e} \\frac{(\\pi+4)^{2}}{32}-\\frac{\\pi^{2}}{4(\\pi+4)}$$"}, {"identifier": "B", "content": "$$\\log _{e} \...
["A"] Explanation: We have, <br/><br/>$$ \begin{aligned} I(x)= & \int \frac{x^2\left(x \sec ^2 x+\tan x\right)}{(x \tan x+1)^2} d x \\\\ = & x^2 \int \frac{x \sec ^2 x+\tan x}{(x \tan x+1)^2} d x \\\\ & \quad-\int\left\{\frac{d}{d x}\left(x^2\right) \int \frac{x \sec ^2 x+\tan x}{(x \tan x+1)^2} d x\right\} d x \text ...
<p>If $$\int \operatorname{cosec}^5 x d x=\alpha \cot x \operatorname{cosec} x\left(\operatorname{cosec}^2 x+\frac{3}{2}\right)+\beta \log _x\left|\tan \frac{x}{2}\right|+\mathrm{C}$$ where $$\alpha, \beta \in \mathbb{R}$$ and $$\mathrm{C}$$ is the constant of integration, then the value of $$8(\alpha+\beta)$$ equals _...
1 Explanation: <p>$$\begin{aligned} & I=\int(\operatorname{cosec} x)^5 d x=\int(\operatorname{cosec} x)^3(\operatorname{cosec} x)^2 d x \\ & =(\operatorname{cosec} x)^3 \int \operatorname{cosec}^2 x d x- \\ & \int\left(\frac{d}{d x}(\operatorname{cosec} x)^3 \int \operatorname{cosec}^2 x d x\right) d x \end{aligned}$$...
$$\int {{{\left\{ {{{\left( {\log x - 1} \right)} \over {1 + {{\left( {\log x} \right)}^2}}}} \right\}}^2}\,\,dx} $$ is equal to Options: [{"identifier": "A", "content": "$${{\\log x} \\over {{{\\left( {\\log x} \\right)}^2} + 1}} + C$$ "}, {"identifier": "B", "content": "$${x \\over {{x^2} + 1}} + C$$ "}, {"identifi...
["D"] Explanation: $$\int {{{{{\left( {\log x - 1} \right)}^2}} \over {{{\left( {1 + {{\left( {\log x} \right)}^2}} \right)}^2}}}} dx$$ <br><br>$$ = \int {{{1 + {{\left( {\log x} \right)}^2} - 2\log x} \over {{{\left[ {1 + {{\left( {\log x} \right)}^2}} \right]}^2}}}} $$ <br><br>$$ = \int {\left[ {{1 \over {\left( {1 ...
The value of $$\sqrt 2 \int {{{\sin xdx} \over {\sin \left( {x - {\pi \over 4}} \right)}}} $$ is Options: [{"identifier": "A", "content": "$$\\,x + \\log \\,\\left| {\\,\\cos \\left( {x - {\\pi \\over 4}} \\right)\\,} \\right| + c$$"}, {"identifier": "B", "content": "$$\\,x - \\log \\,\\left| {\\,\\sin \\left( {x -...
["C"] Explanation: Let $$I = \sqrt 2 \int {{{\sin \,xdx} \over {\sin \left( {x - {\pi \over 4}} \right)}}} $$ <br><br>Put $$x - {\pi \over 4} = t$$ <br><br>$$ \Rightarrow dx = dt$$ <br><br>$$ \Rightarrow I = \sqrt 2 \int {{{\sin \left( {t + {\pi \over 4}} \right)} \over {\sin \,t}}} dt$$ <br><br>$$\,\,\,\,\,\,\,\,\...
If the $$\int {{{5\tan x} \over {\tan x - 2}}dx = x + a\,\ln \,\left| {\sin x - 2\cos x} \right| + k,} $$ then $$a$$ is <br/>equal to : Options: [{"identifier": "A", "content": "$$-1$$ "}, {"identifier": "B", "content": "$$-2$$ "}, {"identifier": "C", "content": "$$1$$ "}, {"identifier": "D", "content": "$$2$$ "}]
["D"] Explanation: $$\int {{{5\tan x} \over {\tan x - 2}}} dx$$ <br><br>$$ = \int {{{5{{\sin x} \over {\cos x}}} \over {{{\sin x} \over {\cos x}} - 2}}} \,dx$$ <br><br>$$ = \int {\left( {{{5\sin x} \over {\cos x}} \times {{\cos x} \over {\sin x - 2\cos x}}} \right)} \,dx$$ <br><br>$$ = \int {{{5\,\sin \,x\,dx} \over {...
If $$\int {f\left( x \right)dx = \psi \left( x \right),} $$ then $$\int {{x^5}f\left( {{x^3}} \right)dx} $$ is equal to Options: [{"identifier": "A", "content": "$${1 \\over 3}\\left[ {{x^3}\\psi \\left( {{x^3}} \\right) - \\int {{x^2}\\psi \\left( {{x^3}} \\right)dx} } \\right] + C$$ "}, {"identifier": "B", "content...
["C"] Explanation: Let $$\int {f\left( x \right)dx = \psi \left( x \right)} $$ <br><br>Let $$I = \int {{x^5}} f\left( {{x^3}} \right)dx$$ <br><br>put $${x^3} = t \Rightarrow 3{x^2}dx = dt$$ <br><br>$$I = {1 \over 3}\int {3.{x^2}} .{x^3}.f\left( {{x^3}} \right).dx$$ <br><br>$$ = {1 \over 3}\int {tf} \left( t \right)dt$...
The integral $$\int {{{dx} \over {{x^2}{{\left( {{x^4} + 1} \right)}^{3/4}}}}} $$ equals : Options: [{"identifier": "A", "content": "$$ - {\\left( {{x^4} + 1} \\right)^{{1 \\over 4}}} + c$$"}, {"identifier": "B", "content": "$$ - {\\left( {{{{x^4} + 1} \\over {{x^4}}}} \\right)^{{1 \\over 4}}} + c$$ "}, {"identifier":...
["B"] Explanation: $$1 = \int {{{dx} \over {{x^2}{{\left( {{x^4} + 1} \right)}^{3/4}}}}} $$ <br><br>$$ = \int {{{dx} \over {{x^3}{{\left( {1 + {x^{ - 4}}} \right)}^{3/4}}}}} $$ <br><br>Let $${x^{ - 4}} = y$$ <br><br>$$ \Rightarrow - 4{x^{ - 3}}\,dx = dy$$ <br><br>$$ \Rightarrow dx = {{ - 1} \over 4}{x^3}dy$$ <br><br...
The integral $$\int {{{2{x^{12}} + 5{x^9}} \over {{{\left( {{x^5} + {x^3} + 1} \right)}^3}}}} dx$$ is equal to : Options: [{"identifier": "A", "content": "$${{{x^5}} \\over {2{{\\left( {{x^5} + {x^3} + 1} \\right)}^2}}} + C$$ "}, {"identifier": "B", "content": "$${{ - {x^{10}}} \\over {2{{\\left( {{x^5} + {x^3} + 1} \...
["D"] Explanation: $$\int {{{2{x^{12}} + 5{x^9}} \over {{{\left( {{x^5} + {x^3} + 1} \right)}^3}}}} dx$$ <br><br>Dividing by $${x^{15}}$$ in numerator and denominator <br><br>$$\int {{{{2 \over {{x^3}}} + {5 \over {{x^6}}}dx} \over {{{\left( {1 + {1 \over {{x^2}}} + {1 \over 5}} \right)}^3}}}} $$ <br><br>Substitute $...
The integral $$\int {{{dx} \over {\left( {1 + \sqrt x } \right)\sqrt {x - {x^2}} }}} $$ is equal to : <br/><br/>(where C is a constant of integration.) Options: [{"identifier": "A", "content": "$$ - 2\\sqrt {{{1 + \\sqrt x } \\over {1 - \\sqrt x }}} + C$$ "}, {"identifier": "B", "content": "$$ - 2\\sqrt {{{1 - \\sq...
["B"] Explanation: I &nbsp;&nbsp;= &nbsp;&nbsp;$$\int {{{dx} \over {\left( {1 + \sqrt x } \right)\sqrt {x - {x^2}} }}} $$ <br><br>=&nbsp;&nbsp;$$\int {{{dx} \over {\left( {1 + \sqrt x } \right)\sqrt x \sqrt {1 - x} }}} $$ <br><br>Let&nbsp;&nbsp;1 + $$\sqrt x $$ = t <br><br>$$ \Rightarrow $$$$\,\,\,$$$${1 \over {2\sqrt...
If   $$\int {{{dx} \over {{{\cos }^3}x\sqrt {2\sin 2x} }}} = {\left( {\tan x} \right)^A} + C{\left( {\tan x} \right)^B} + k,$$ <br/><br/>where k is a constant of integration, then A + B +C equals : Options: [{"identifier": "A", "content": "$${{21} \\over 5}$$ "}, {"identifier": "B", "content": "$${{16} \\over 5}$$"},...
["B"] Explanation: $$\int {{{dx} \over {{{\cos }^3}x\sqrt {2\sin 2x} }}} $$ <br><br>=&nbsp;&nbsp;$$\int {{{dx} \over {{{\cos }^3}x\sqrt {4\sin x\cos x} }}} $$ <br><br>=&nbsp;&nbsp;$$\int {{{dx} \over {2{{\cos }^4}x\sqrt {\tan x} }}} $$ <br><br>Let tan x&nbsp;&nbsp; =&nbsp;&nbsp; t<sup>2</sup> <br><br>$$ \Rightarrow $$...
Let $${I_n} = \int {{{\tan }^n}x\,dx} ,\,\left( {n &gt; 1} \right).$$ <br/><br/>If $${I_4} + {I_6}$$ = $$a{\tan ^5}x + b{x^5} + C$$, where C is a constant of integration, <br/><br/>then the ordered pair $$\left( {a,b} \right)$$ is equal to Options: [{"identifier": "A", "content": "$$\\left( {{1 \\over 5},0} \\right)$$...
["A"] Explanation: Given, <br><br>In = $$\int {{{\tan }^n}x\,dx,\,\,\,n &gt; 1} $$ <br><br>$$\therefore\,\,\,$$ I<sub>4</sub> = $$\int {{{\tan }^4}x\,dx} $$ <br><br>and I<sub>6</sub> = $$\int {{{\tan }^6}} x\,dx$$ <br><br>$$\therefore\,\,\,$$ I = I<sub>4</sub> + I<sub>6</sub> <br><br>= $$\int {\left( {{{\tan }^4}x + ...
If $$\int {{{\tan x} \over {1 + \tan x + {{\tan }^2}x}}dx = x - {K \over {\sqrt A }}{{\tan }^{ - 1}}} $$ $$\left( {{{K\,\tan x + 1} \over {\sqrt A }}} \right) + C,(C\,\,$$ is a constant of integration) then the ordered pair (K, A) is equal to : Options: [{"identifier": "A", "content": "(2, 1)"}, {"identifier": "B", "...
["C"] Explanation: Given, <br><br>$$\int {{{\tan x} \over {1 + \tan x + {{\tan }^2}x}}} \,\,dx$$ <br><br>Let tanx = t <br><br>$$ \Rightarrow $$$$\,\,\,$$ sec<sup>2</sup>x dx = dt <br><br>$$ \Rightarrow $$$$\,\,\,$$ dx = $${{dt} \over {{{\sec }^2}x}}$$ <br><br>$$ \Rightarrow $$$$\,\,\,$$ $$dx = {{dt} \over {1 + {{\tan...
The integral <br/><br/>$$\int {{{{{\sin }^2}x{{\cos }^2}x} \over {{{\left( {{{\sin }^5}x + {{\cos }^3}x{{\sin }^2}x + {{\sin }^3}x{{\cos }^2}x + {{\cos }^5}x} \right)}^2}}}} dx$$ <br/><br/>is equal to Options: [{"identifier": "A", "content": "$${{ - 1} \\over {1 + {{\\cot }^3}x}} + C$$"}, {"identifier": "B", "content"...
["C"] Explanation: Given, <br><br>$$\int {{{{{\sin }^2}x{{\cos }^2}x} \over {{{\left( {{{\sin }^5}x + {{\cos }^3}x{{\sin }^2}x + {{\sin }^3}x{{\cos }^2}x + {{\cos }^5}x} \right)}^2}}}}\,dx $$ <br><br>$$ = \int {{{{{\sin }^2}x\,{{\cos }^2}x} \over {{{\left[ {{{\sin }^3}x\left( {{{\sin }^2}x + {{\cos }^2}x} \right) + ...
Let n $$ \ge $$ 2 be a natural number and $$0 &lt; \theta &lt; {\pi \over 2}.$$ Then $$\int {{{{{\left( {{{\sin }^n}\theta - \sin \theta } \right)}^{1/n}}\cos \theta } \over {{{\sin }^{n + 1}}\theta }}} \,d\theta $$ is equal to - (where C is a constant of integration) Options: [{"identifier": "A", "content": "$${n ...
["C"] Explanation: $$\int {{{{{\left( {{{\sin }^n}\theta - \sin \theta } \right)}^{1/n}}\cos \theta } \over {{{\sin }^{n + 1}}\theta }}} \,d\theta $$ <br><br>$$ = \int {{{\sin \theta {{\left( {1 - {1 \over {{{\sin }^{n - 1}}\theta }}} \right)}^{1/n}}} \over {{{\sin }^{n + 1}}\theta }}} \,d\theta $$ <br><br>Put $$1 - ...
Let $$a \in \left( {0,{\pi \over 2}} \right)$$ be fixed. If the integral <br/><br>$$\int {{{\tan x + \tan \alpha } \over {\tan x - \tan \alpha }}} dx$$ = A(x) cos 2$$\alpha $$ + B(x) sin 2$$\alpha $$ + C, where C is a <br/><br/>constant of integration, then the functions A(x) and B(x) are respectively : </br> Option...
["D"] Explanation: <p>To solve the given integral, first we simplify the expression in the integral as follows :</p> <p>$$\int {{{\tan x + \tan \alpha } \over {\tan x - \tan \alpha }}} dx = \int {{{\sin x \over \cos x} + {\sin \alpha \over \cos \alpha }} \over {{\sin x \over \cos x} - {\sin \alpha \over \cos \alpha }}...
If $$\int {{x^5}} {e^{ - {x^2}}}dx = g\left( x \right){e^{ - {x^2}}} + c$$, where c is a constant of integration, then $$g$$(–1) is equal to : Options: [{"identifier": "A", "content": "1"}, {"identifier": "B", "content": "- 1"}, {"identifier": "C", "content": "$$ - {5 \\over 2}$$"}, {"identifier": "D", "content": "$$...
["C"] Explanation: Let x<sup>2</sup> = t<br><br> $$ \Rightarrow {1 \over 2}\int {{t^2}{e^{ - t}}dt} $$<br><br> $$ \Rightarrow {1 \over 2}\left[ { - {t^2}{e^{ - t}} + \int {2t{e^{ - t}}dt} } \right]$$<br><br> $$ \Rightarrow {{ - {t^2}{e^{ - t}}} \over 2} - t{e^{ - t}} - {e^{ - t}}$$<br><br> $$ \Rightarrow \left( { - {{...
If $$\int {{{dx} \over {{{\left( {{x^2} - 2x + 10} \right)}^2}}}} = A\left( {{{\tan }^{ - 1}}\left( {{{x - 1} \over 3}} \right) + {{f\left( x \right)} \over {{x^2} - 2x + 10}}} \right) + C$$ <br/><br/> where C is a constant of integration then : Options: [{"identifier": "A", "content": "A =$${1 \\over {54}}$$ and f(x...
["B"] Explanation: $$\int {{{dx} \over {{{({x^2} - 2x + 10)}^2}}} = \int {{{dx} \over {{{({{(x - 1)}^2} + 9)}^2}}}} } $$<br><br> $$Let{\rm{ }}{\left( {x{\rm{ }}-{\rm{ }}1} \right)^2}{\rm{ }} = {\rm{ }}9ta{n^2}\theta \,\,\,\,...\left( i \right)$$<br><br> $$ \Rightarrow \tan \theta = {{x - 1} \over 3}$$<br><br> On Diff...
The integral $$\int {{\rm{se}}{{\rm{c}}^{{\rm{2/ 3}}}}\,{\rm{x }}\,{\rm{cose}}{{\rm{c}}^{{\rm{4 / 3}}}}{\rm{x \,dx}}} $$ is equal to (Hence C is a constant of integration) Options: [{"identifier": "A", "content": "-3/4 tan <sup>- 4 / 3</sup> x + C"}, {"identifier": "B", "content": "3tan<sup>\u20131/3</sup>x + C"}, {"i...
["D"] Explanation: $$\int {{{\sec }^{{2 \over 3}}}} x\cos e{c^{{4 \over 3}}}xdx$$ <br><br>= $$\int {{{{{\sec }^{{2 \over 3}}}x} \over {\cos e{c^{{2 \over 3}}}x}}\cos e{c^2}xdx} $$ <br><br>= $$\int {{1 \over {{{\cot }^{{2 \over 3}}}x}}\cos e{c^2}xdx} $$ <br><br>Let cot x = t<sup>3</sup> <br><br>$$ \Rightarrow $$ - cose...
If $$\int {{{dx} \over {{x^3}{{(1 + {x^6})}^{2/3}}}} = xf(x){{(1 + {x^6})}^{{1 \over 3}}} + C} $$ <br/> where C is a constant of integration, then the function ƒ(x) is equal to Options: [{"identifier": "A", "content": "$${3 \\over {{x^2}}}$$"}, {"identifier": "B", "content": "$$ - {1 \\over {6{x^3}}}$$"}, {"identifier...
["C"] Explanation: I = $$\int {{{dx} \over {{x^3}{{\left( {1 + {x^6}} \right)}^{{2 \over 3}}}}}} $$ <br><br>= $$\int {{{dx} \over {{x^7}{{\left( {{1 \over {{x^6}}} + 1} \right)}^{{2 \over 3}}}}}} $$ <br><br>Let $${{1 \over {{x^6}}} + 1}$$ = t <br><br>$$ \Rightarrow $$ $${{ - 6} \over {{x^7}}}dx = dt$$ <br><br>$$ \Righ...
The integral $$\int {{{3{x^{13}} + 2{x^{11}}} \over {{{\left( {2{x^4} + 3{x^2} + 1} \right)}^4}}}} \,dx$$ is equal to : (where C is a constant of integration) Options: [{"identifier": "A", "content": "$${{{x^{12}}} \\over {6{{\\left( {2{x^4} + 3{x^2} + 1} \\right)}^3}}}$$ + $$C$$"}, {"identifier": "B", "content": "$$...
["A"] Explanation: $$\int {{{3{x^{13}} + 2{x^{11}}} \over {{{\left( {2{x^4} + 3{x^2} + 1} \right)}^4}}}} dx$$ <br><br>$$\int {{{\left( {{3 \over {{x^3}}} + {2 \over {{x^5}}}} \right)dx} \over {{{\left( {2 + {3 \over {{x^2}}} + {1 \over {{x^4}}}} \right)}^4}}}} $$ <br><br>Let&nbsp;&nbsp;$$\left( {2 + {3 \over {{x^2}}} ...
If   $$\int {{{x + 1} \over {\sqrt {2x - 1} }}} \,dx$$ = f(x) $$\sqrt {2x - 1} $$ + C, where C is a constant of integration, then f(x) is equal to : Options: [{"identifier": "A", "content": "$${2 \\over 3}$$ (x $$-$$ 4)"}, {"identifier": "B", "content": "$${1 \\over 3}$$ (x + 4)"}, {"identifier": "C", "content": "$${...
["B"] Explanation: $$\sqrt {2x - 1} = t \Rightarrow 2x - 1 = {t^2} \Rightarrow 2dx = 2t.dt$$ <br><br>$$\int {{{x + 1} \over {\sqrt {2x - 1} }}dx = \int {{{{{{t^2} + 1} \over 2} + 1} \over t}tdt = \int {{{{t^2} + 3} \over 2}dt} } } $$ <br><br>$$ = {1 \over 2}\left( {{{{t^3}} \over 3} + 3t} \right) = {t \over 6}\left( ...
If  $$\int {{{\sqrt {1 - {x^2}} } \over {{x^4}}}} $$ dx = A(x)$${\left( {\sqrt {1 - {x^2}} } \right)^m}$$ + C, for a suitable chosen integer m and a function A(x), where C is a constant of integration, then (A(x))<sup>m</sup> equals : Options: [{"identifier": "A", "content": "$${1 \\over {27{x^6}}}$$"}, {"identifier":...
["B"] Explanation: $$\int {{{\sqrt {1 - {x^2}} } \over {{x^4}}}} $$ dx = A(x)$${\left( {\sqrt {1 - {x^2}} } \right)^m}$$ + C <br><br>$$\int {{{\left| x \right|\sqrt {{1 \over {{x^2}}} - 1} } \over {{x^4}}}} \,dx,$$ <br><br>Put&nbsp;&nbsp;$${1 \over {{x^2}}} - 1 = t \Rightarrow {{dt} \over {dx}} = {{ - 2} \over {{x^3}}...
If  $$\int \, $$x<sup>5</sup>.e<sup>$$-$$4x<sup>3</sup></sup> dx = $${1 \over {48}}$$e<sup>$$-$$4x<sup>3</sup></sup> f(x) + C, where C is a constant of inegration, then f(x) is equal to - Options: [{"identifier": "A", "content": "$$-$$2x<sup>3</sup> $$-$$ 1"}, {"identifier": "B", "content": "$$-$$ 2x<sup>3</sup> + 1 ...
["D"] Explanation: $$\int {{x^5}} .{e^{ - 4{x^3}}}\,dx = {1 \over {48}}{e^{ - 4{x^3}}}f\left( x \right) + c$$ <br><br>Put&nbsp;&nbsp;$${x^3} = t$$ <br><br>$$3{x^2}\,dx = dt$$ <br><br>$$\int {{x^3}.{e^{ - 4{x^3}}}.\,{x^2}} dx$$ <br><br>$${1 \over 3}\int {t.{e^{ - 4t}}dt} $$ <br><br>$${1 \over 3}\left[ {t.{{{e^{ - 4t}}}...
If   $$f\left( x \right) = \int {{{5{x^8} + 7{x^6}} \over {{{\left( {{x^2} + 1 + 2{x^7}} \right)}^2}}}} \,dx,\,\left( {x \ge 0} \right),$$ <br/><br/>$$f\left( 0 \right) = 0,$$    then the value of $$f(1)$$ is : Options: [{"identifier": "A", "content": "$$ - $$ $${1 \\over 2}$$"}, {"identifier": "B", "content": "$$ - ...
["D"] Explanation: $$f\left( x \right) = \int {{{5{x^8} + 7{x^6}} \over {{{\left( {{x^2} + 1 + 2{x^7}} \right)}^2}}}} \,dx$$ <br><br>$$f\left( x \right) = \int {{{5{x^8} + 7{x^6}} \over {{x^{14}}{{\left( {{x^{ - 5}} + {x^{ - 7}} + 2} \right)}^2}}}} \,dx$$ <br><br>$$f\left( x \right) = \int {{{5{x^{ - 6}} + 7{x^{ - 8}}...
For x<sup>2</sup> $$ \ne $$ n$$\pi $$ + 1, n $$ \in $$ N (the set of natural numbers), the integral <br/><br/>$$\int {x\sqrt {{{2\sin ({x^2} - 1) - \sin 2({x^2} - 1)} \over {2\sin ({x^2} - 1) + \sin 2({x^2} - 1)}}} dx} $$ is equal to : <br/><br/>(where c is a constant of integration) Options: [{"identifier": "A", "co...
["D"] Explanation: $$\int {x\sqrt {{{2\sin \left( {{x^2} - } \right) - \sin 2\left( {{x^2} - 1} \right)} \over {2\sin \left( {{x^2} - 1} \right) + \sin 2\left( {{x^2} - 1} \right)}}} } \,\,dx$$ <br><br>$$ = \int {x\sqrt {{{2\sin \left( {{x^2} - 1} \right) - 2sin\left( {{x^2} - 1} \right)\cos \left( {{x^2} - 1} \right)...
If $$\int {{{d\theta } \over {{{\cos }^2}\theta \left( {\tan 2\theta + \sec 2\theta } \right)}}} = \lambda \tan \theta + 2{\log _e}\left| {f\left( \theta \right)} \right| + C$$<br/><br/> where C is a constant of integration, then the ordered pair ($$\lambda $$, ƒ($$\theta $$)) is equal to : Options: [{"identifier"...
["C"] Explanation: I = $$\int {{{d\theta } \over {{{\cos }^2}\theta \left( {\tan 2\theta + \sec 2\theta } \right)}}}$$ <br><br>= $$\int {{{{{\sec }^2}\theta d\theta } \over {{{2\tan \theta } \over {1 - {{\tan }^2}\theta }} + {{1 + {{\tan }^2}\theta } \over {1 - {{\tan }^2}\theta }}}}} $$ <br><br>= $$\int {{{\left( {1...
If <br/>$$\int {{{\cos \theta } \over {5 + 7\sin \theta - 2{{\cos }^2}\theta }}} d\theta $$ = A$${\log _e}\left| {B\left( \theta \right)} \right| + C$$, <br/><br/>where C is a constant of integration, then $${{{B\left( \theta \right)} \over A}}$$ <br/>can be : Options: [{"identifier": "A", "content": "$${{2\\sin \\...
["C"] Explanation: $$\int {{{\cos \theta } \over {5 + 7\sin \theta - 2{{\cos }^2}\theta }}} d\theta $$ <br><br>= $$\int {{{\cos \theta d\theta } \over {5 + 7\sin \theta - 2\left( {1 - {{\sin }^2}\theta } \right)}}} $$ <br><br>= $$\int {{{\cos \theta d\theta } \over {3 + 7\sin \theta + 2{{\sin }^2}\theta }}} $$ <br>...
If <br/>$$\int {\left( {{e^{2x}} + 2{e^x} - {e^{ - x}} - 1} \right){e^{\left( {{e^x} + {e^{ - x}}} \right)}}dx} $$ = $$g\left( x \right){e^{\left( {{e^x} + {e^{ - x}}} \right)}} + c$$<br/><br/> where c is a constant of integration, then g(0) is equal to : Options: [{"identifier": "A", "content": "1"}, {"identifier": "...
["B"] Explanation: I = $$\int {\left( {{e^{2x}} + 2{e^x} - {e^{ - x}} - 1} \right){e^{\left( {{e^x} + {e^{ - x}}} \right)}}dx} $$ <br><br>= $$\int {\left( {\left( {{e^{2x}} + {e^x} - 1} \right) + \left( {{e^x} - {e^{ - x}}} \right)} \right)} {e^{\left( {{e^x} + {e^{ - x}}} \right)}}dx$$ <br><br>= $$\int {\left( {{e^{2...
Let $$f\left( x \right) = \int {{{\sqrt x } \over {{{\left( {1 + x} \right)}^2}}}dx\left( {x \ge 0} \right)} $$. Then f(3) – f(1) is eqaul to : Options: [{"identifier": "A", "content": "$$ - {\\pi \\over {12}} + {1 \\over 2} + {{\\sqrt 3 } \\over 4}$$"}, {"identifier": "B", "content": "$$ {\\pi \\over {12}} + {1 \\...
["B"] Explanation: $$\int {{{\sqrt x } \over {{{(1 + x)}^2}}}} dx(x &gt; 0)$$<br><br>Put x = tan<sup>2</sup>$$\theta $$ $$ \Rightarrow $$ 2xdx = 2tan$$\theta $$sec<sup>2</sup>$$\theta $$d$$\theta $$<br><br>$$I = \int {{{2{{\tan }^2}\theta .{{\sec }^2}\theta } \over 2}} d\theta = \int {2{{\sin }^2}\theta d\theta = \i...
The integral $$\int {{{dx} \over {{{(x + 4)}^{{8 \over 7}}}{{(x - 3)}^{{6 \over 7}}}}}} $$ is equal to :<br/> (where C is a constant of integration) Options: [{"identifier": "A", "content": "$${1 \\over 2}{\\left( {{{x - 3} \\over {x + 4}}} \\right)^{{3 \\over 7}}} + C$$"}, {"identifier": "B", "content": "$${\\left( {...
["B"] Explanation: $$\int {{{dx} \over {{{(x + 4)}^{{8 \over 7}}}{{(x - 3)}^{{6 \over 7}}}}}} $$ <br><br>= $$\int {{{dx} \over {{{\left( {x + 4} \right)}^2}{{\left( {{{x - 3} \over {x + 4}}} \right)}^{{6 \over 7}}}}}} $$ <br><br>Put $${{{x - 3} \over {x + 4}}}$$ = t <br><br>$$ \Rightarrow $$ $$\left\{ {{{\left( {x + 4...
If $$\int {{{\cos xdx} \over {{{\sin }^3}x{{\left( {1 + {{\sin }^6}x} \right)}^{2/3}}}}} = f\left( x \right){\left( {1 + {{\sin }^6}x} \right)^{1/\lambda }} + c$$ <br/><br/>where c is a constant of integration, then $$\lambda f\left( {{\pi \over 3}} \right)$$ is equal to Options: [{"identifier": "A", "content": "$${...
["C"] Explanation: Given I = $$\int {{{\cos xdx} \over {{{\sin }^3}x{{\left( {1 + {{\sin }^6}x} \right)}^{2/3}}}}}$$ <br><br>Let sin x = t <br><br>$$ \Rightarrow $$ cos xdx = dt <br><br>$$ \therefore $$ I = $$\int {{{dt} \over {{t^3}{{\left( {1 + {t^6}} \right)}^{2/3}}}}} $$ <br><br>I = $$\int {{{dt} \over {{t^7}{{\l...
If $$\int {{{\sin }^{ - 1}}\left( {\sqrt {{x \over {1 + x}}} } \right)} dx$$ = A(x)$${\tan ^{ - 1}}\left( {\sqrt x } \right)$$ + B(x) + C, <br/>where C is a constant of integration, then the ordered pair (A(x), B(x)) can be : Options: [{"identifier": "A", "content": "(x + 1, -$${\\sqrt x }$$)"}, {"identifier": "B", "c...
["A"] Explanation: Given, I = $$\int {{{\sin }^{ - 1}}\left( {\sqrt {{x \over {1 + x}}} } \right)} dx$$ <br><br>Let $${\sin ^{ - 1}}\left( {{{\sqrt x } \over {\sqrt {1 + x} }}} \right)$$ = $$\theta $$ <br><br>$$ \Rightarrow $$ $${{{\sqrt x } \over {\sqrt {1 + x} }} = \sin \theta }$$ <br><br>$$ \Rightarrow $$ tan $$\th...
If $$\int {{{\cos x - \sin x} \over {\sqrt {8 - \sin 2x} }}} dx = a{\sin ^{ - 1}}\left( {{{\sin x + \cos x} \over b}} \right) + c$$, where c is a constant of integration, then the ordered pair (a, b) is equal to : Options: [{"identifier": "A", "content": "(-1, 3)"}, {"identifier": "B", "content": "(1, 3)"}, {"identifi...
["B"] Explanation: Given $$\int {{{\cos x - \sin x} \over {\sqrt {8 - \sin 2x} }}} dx$$ <br><br>Write sin2x = 1 + sin2x - 1 <br><br>= $$\int {{{\cos x - \sin x} \over {\sqrt {8 - \left[ {1 + \sin 2x - 1} \right]} }}} dx$$ <br><br>= $$\int {{{\cos x - \sin x} \over {\sqrt {8 - \left[ {{{\sin }^2}x + {{\cos }^2}x + 2\si...
The value of the integral <br/>$$\int {{{\sin \theta .\sin 2\theta ({{\sin }^6}\theta + {{\sin }^4}\theta + {{\sin }^2}\theta )\sqrt {2{{\sin }^4}\theta + 3{{\sin }^2}\theta + 6} } \over {1 - \cos 2\theta }}} \,d\theta $$ is : Options: [{"identifier": "A", "content": "$${1 \\over {18}}{\\left[ {9 - 2{{\\cos }^6}\\...
["C"] Explanation: $$\int {{{2{{\sin }^2}\theta \cos \theta ({{\sin }^6}\theta + {{\sin }^4}\theta + {{\sin }^2}\theta )\sqrt {2{{\sin }^4}\theta + 3{{\sin }^2}\theta + 6} } \over {2{{\sin }^2}\theta }}d\theta } $$<br><br>Let sin$$\theta$$ = t, cos$$\theta$$ d$$\theta$$ = dt<br><br>$$ = \int {({t^6} + {t^4} + {t^2...
The integral $$\int {{{{e^{3{{\log }_e}2x}} + 5{e^{2{{\log }_e}2x}}} \over {{e^{4{{\log }_e}x}} + 5{e^{3{{\log }_e}x}} - 7{e^{2{{\log }_e}x}}}}} dx$$, x &gt; 0, is equal to : (where c is a constant of integration) Options: [{"identifier": "A", "content": "$${\\log _e}\\sqrt {{x^2} + 5x - 7} + c$$"}, {"identifier": "B...
["B"] Explanation: $$\int {{{{e^{3{{\log }_e}2x}} + 5{e^{2{{\log }_e}2x}}} \over {{e^{4{{\log }_e}x}} + 5{e^{3{{\log }_e}x}} - 7{e^{2{{\log }_e}x}}}}dx} $$<br><br>$$ = \int {{{8{x^3} + 5(4{x^2})} \over {{x^4} + 5{x^3} - 7{x^2}}}} $$<br><br>$$ = \int {{{8{x^3} + 20{x^2}} \over {{x^4} + 5{x^3} - 7{x^2}}}} $$<br><br>$$ =...
For real numbers $$\alpha$$, $$\beta$$, $$\gamma$$ and $$\delta $$, if <br/>$$\int {{{({x^2} - 1) + {{\tan }^{ - 1}}\left( {{{{x^2} + 1} \over x}} \right)} \over {({x^4} + 3{x^2} + 1){{\tan }^{ - 1}}\left( {{{{x^2} + 1} \over x}} \right)}}dx} $$<br/><br/> $$ = \alpha {\log _e}\left( {{{\tan }^{ - 1}}\left( {{{{x^2} + 1...
6 Explanation: $$\int {{{({x^2} - 1) + {{\tan }^{ - 1}}\left( {{{{x^2} + 1} \over x}} \right)} \over {({x^4} + 3{x^2} + 1){{\tan }^{ - 1}}\left( {{{{x^2} + 1} \over x}} \right)}}dx} $$ <br><br>= $$\int {{{{x^2} - 1} \over {({x^4} + 3{x^2} + 1){{\tan }^{ - 1}}\left( {{{{x^2} + 1} \over x}} \right)}}dx + \int {{1 \over ...
The integral $$\int {{{(2x - 1)\cos \sqrt {{{(2x - 1)}^2} + 5} } \over {\sqrt {4{x^2} - 4x + 6} }}} dx$$ is equal to (where c is a constant of integration) Options: [{"identifier": "A", "content": "$${1 \\over 2}\\sin \\sqrt {{{(2x - 1)}^2} + 5} + c$$"}, {"identifier": "B", "content": "$${1 \\over 2}\\cos \\sqrt {{{(...
["A"] Explanation: $$\int {{{(2x - 1)\cos \sqrt {{{(2x - 1)}^2} + 5} } \over {\sqrt {{{(2x - 1)}^2} + 5} }}} dx$$<br><br>$${(2x - 1)^2} + 5 = {t^2}$$<br><br>$$2(2x - 1)2dx = 2t\,dt$$<br><br>$$2\sqrt {{t^2} - 5} dx = t\,dt$$<br><br>So, $$\int {{{\sqrt {{t^2} - 5} \cos t} \over {2\sqrt {{t^2} - 5} }}dt = {1 \over 2}\sin...
If $$f(x) = \int {{{5{x^8} + 7{x^6}} \over {{{({x^2} + 1 + 2{x^7})}^2}}}dx,(x \ge 0),f(0) = 0} $$ and $$f(1) = {1 \over K}$$, then the value of K is Options: []
4 Explanation: $$\int {{{5{x^8} + 7{x^6}} \over {{{(2{x^7} + {x^2} + 1)}^2}}}dx = \int {{{5{x^8} + 7{x^6}} \over {{x^{14}}{{\left( {2 + {1 \over {{x^5}}} + {1 \over {{x^7}}}} \right)}^2}}}dx} } $$<br><br>$$\int {{{{5 \over {{x^6}}} + {7 \over {{x^8}}}} \over {{{\left( {2 + {1 \over {{x^5}}} + {1 \over {{x^7}}}} \right...
If $$\int {{{dx} \over {{{({x^2} + x + 1)}^2}}} = a{{\tan }^{ - 1}}\left( {{{2x + 1} \over {\sqrt 3 }}} \right) + b\left( {{{2x + 1} \over {{x^2} + x + 1}}} \right) + C} $$, x &gt; 0 where C is the constant of integration, then the value of $$9\left( {\sqrt 3 a + b} \right)$$ is equal to _____________. Options: []
15 Explanation: $\int \frac{d x}{\left(x^2+x+1\right)^2}$ <br/><br/>$=\int \frac{d x}{\left[\left(x+\frac{1}{2}\right)^2+\left(\frac{\sqrt{3}}{2}\right)^2\right]^2}$ <br/><br/>Let $x+\frac{1}{2}=\frac{\sqrt{3}}{2} \tan \theta$ <br/><br/>$$ \Rightarrow d x=\frac{\sqrt{3}}{2} \sec ^2 \theta d \theta $$ <br/><br/>$\there...
The integral $$\int {{1 \over {\root 4 \of {{{(x - 1)}^3}{{(x + 2)}^5}} }}} \,dx$$ is equal to : (where C is a constant of integration) Options: [{"identifier": "A", "content": "$${3 \\over 4}{\\left( {{{x + 2} \\over {x - 1}}} \\right)^{{1 \\over 4}}} + C$$"}, {"identifier": "B", "content": "$${3 \\over 4}{\\left( {{...
["C"] Explanation: $$\int {{{dx} \over {{{(x - 1)}^{3/4}}{{(x + 2)}^{5/4}}}}} $$<br><br>$$ = \int {{{dx} \over {{{\left( {{{x + 2} \over {x - 1}}} \right)}^{5/4}}.\,{{(x - 1)}^2}}}} $$<br><br>put $${{x + 2} \over {x - 1}} = t$$<br><br>$$ = - {1 \over 3}\int {{{dt} \over {{t^{5/4}}}}} $$<br><br>$$ = {4 \over 3}.{1 \ov...
<p>If $$\int {{1 \over x}\sqrt {{{1 - x} \over {1 + x}}} dx = g(x) + c} $$, $$g(1) = 0$$, then $$g\left( {{1 \over 2}} \right)$$ is equal to :</p> Options: [{"identifier": "A", "content": "$${\\log _e}\\left( {{{\\sqrt 3 - 1} \\over {\\sqrt 3 + 1}}} \\right) + {\\pi \\over 3}$$"}, {"identifier": "B", "content": "$$...
["A"] Explanation: Given, $$\int {{1 \over x}\sqrt {{{1 - x} \over {1 + x}}} dx = g(x) + c} $$, $$g(1) = 0$$ <br/><br/>Let I = $\int {{1 \over x}\sqrt {{{1 - x} \over {1 + x}}} dx}$ <br/><br/>= $\int {{1 \over x}\sqrt {{{\left( {1 - x} \right)\left( {1 + x} \right)} \over {\left( {1 + x} \right)\left( {1 + x} \right)...
If $\int \sqrt{\sec 2 x-1} d x=\alpha \log _e\left|\cos 2 x+\beta+\sqrt{\cos 2 x\left(1+\cos \frac{1}{\beta} x\right)}\right|+$ constant, then $\beta-\alpha$ is equal to ____________. Options: []
1 Explanation: <p>$$I = \int {\sqrt {\sec 2x - 1} dx=\int {\sqrt {{{1 - \cos 2x} \over {\cos 2x}}} dx} } $$</p> <p>$$ = \int {\sqrt {{{2{{\sin }^2}x} \over {2{{\cos }^2}x - 1}}} dx} $$</p> <p>Let $$\sqrt {2\cos } x = t - \sqrt 2 \sin xdx = dt$$</p> <p>$$I = \int { - {{dt} \over {\sqrt {{t^2} - 1} }} = - \ln \left| {t...
<p>Let $$f(x) = \int {{{2x} \over {({x^2} + 1)({x^2} + 3)}}dx} $$. If $$f(3) = {1 \over 2}({\log _e}5 - {\log _e}6)$$, then $$f(4)$$ is equal to</p> Options: [{"identifier": "A", "content": "$${\\log _e}19 - {\\log _e}20$$"}, {"identifier": "B", "content": "$${\\log _e}17 - {\\log _e}18$$"}, {"identifier": "C", "conte...
["D"] Explanation: $f(x)=\int \frac{2 x}{\left(x^{2}+1\right)\left(x^{2}+3\right)} d x$ <br/><br/> $$ \begin{aligned} & \text { Put } x^{2}=t \Rightarrow 2 x d x=d t \\\\ & f(x)=\int \frac{d t}{(t+1)(t+3)}=\int \frac{d t}{(t+2)^{2}-1} \\\\ & =\frac{1}{2} \log _{e}\left|\frac{t+1}{t+3}\right|+C \\\\ & f(x)=\frac{1}{2} ...
Let $f(x)=\int \frac{d x}{\left(3+4 x^{2}\right) \sqrt{4-3 x^{2}}},|x|&lt;\frac{2}{\sqrt{3}}$. If $f(0)=0$<br/><br/> and $f(1)=\frac{1}{\alpha \beta} \tan ^{-1}\left(\frac{\alpha}{\beta}\right)$, $\alpha, \beta&gt;0$, then $\alpha^{2}+\beta^{2}$ is equal to ____________. Options: []
28 Explanation: $$ \begin{aligned} & f(x)=\int \frac{d x}{\left(3+4 x^2\right) \sqrt{4-3 x^2}} \\\\ & x=\frac{1}{t} \\\\ & =\int \frac{\frac{-1}{t^2} d t}{\frac{\left(3 t^2+4\right)}{t^2} \frac{\sqrt{4 t^2-3}}{t}} \\\\ & =\int \frac{-d t \cdot t}{\left(3 t^2+4\right) \sqrt{4 t^2-3}}: \text { Put } 4 t^2-3=z^2 \\\\ & =...
<p>Let $$I(x)=\int \sqrt{\frac{x+7}{x}} \mathrm{~d} x$$ and $$I(9)=12+7 \log _{e} 7$$. If $$I(1)=\alpha+7 \log _{e}(1+2 \sqrt{2})$$, then $$\alpha^{4}$$ is equal to _________.</p> Options: []
64 Explanation: Given integral: $$\int \sqrt{\frac{x+7}{x}} \, dx$$ <br/><br/>Let's make the substitution $$x = t^2$$. Then, $$dx = 2t \, dt$$. <br/><br/>Substituting these values, the integral becomes : <br/><br/>$$\int 2 \sqrt{t^2 + 7} \, dt$$ <br/><br/>Now, let's evaluate this integral : <br/><br/>$$I(t) = 2\l...
<p>Let $$I(x)=\int \frac{(x+1)}{x\left(1+x e^{x}\right)^{2}} d x, x &gt; 0$$. If $$\lim_\limits{x \rightarrow \infty} I(x)=0$$, then $$I(1)$$ is equal to :</p> Options: [{"identifier": "A", "content": "$$\\frac{e+1}{e+2}-\\log _{e}(e+1)$$"}, {"identifier": "B", "content": "$$\\frac{e+1}{e+2}+\\log _{e}(e+1)$$"}, {"ide...
["C"] Explanation: $$ \begin{aligned} & \mathrm{I}=\int \frac{x+1}{x\left(1+x e^x\right)^2} d x \\\\ & \text { Put } 1+x e^x=t \Rightarrow x e^x=t-1 \\\\ & \Rightarrow\left(x e^x+e^x\right) d x=d t \\\\ & \Rightarrow e^x(x+1) d x=d t \end{aligned} $$ <br/><br/>$$ \therefore I=\int \frac{d t}{e^x \cdot x t^2}=\int \fra...
<p>$$\text { The integral } \int \frac{\left(x^8-x^2\right) \mathrm{d} x}{\left(x^{12}+3 x^6+1\right) \tan ^{-1}\left(x^3+\frac{1}{x^3}\right)} \text { is equal to : }$$</p> Options: [{"identifier": "A", "content": "$$\\log _{\\mathrm{e}}\\left(\\left|\\tan ^{-1}\\left(x^3+\\frac{1}{x^3}\\right)\\right|\\right)^{1 / 3...
["A"] Explanation: <p>$$I=\int \frac{x^8-x^2}{\left(x^{12}+3 x^6+1\right) \tan ^{-1}\left(x^3+\frac{1}{x^3}\right)} d x$$</p> <p>$$\begin{aligned} & \text { Let } \tan ^{-1}\left(x^3+\frac{1}{x^3}\right)=t \\ & \Rightarrow \frac{1}{1+\left(x^3+\frac{1}{x^3}\right)^2} \cdot\left(3 x^2-\frac{3}{x^4}\right) d x=d t \\ & ...
<p>For $$x \in\left(-\frac{\pi}{2}, \frac{\pi}{2}\right)$$, if $$y(x)=\int \frac{\operatorname{cosec} x+\sin x}{\operatorname{cosec} x \sec x+\tan x \sin ^2 x} d x$$, and $$\lim _\limits{x \rightarrow\left(\frac{\pi}{2}\right)^{-}} y(x)=0$$ then $$y\left(\frac{\pi}{4}\right)$$ is equal to</p> Options: [{"identifier": ...
["D"] Explanation: <p>$$\begin{aligned} & y(x)=\int \frac{\left(1+\sin ^2 x\right) \cos x}{1+\sin ^4 x} d x \\ & \text { Put } \sin x=t \\ & =\int \frac{1+t^2}{t^4+1} d t=\frac{1}{\sqrt{2}} \tan ^{-1} \frac{\left(t-\frac{1}{t}\right)}{\sqrt{2}}+C \\ & x=\frac{\pi}{2}, t=1 \quad \therefore C=0 \\ & y\left(\frac{\pi}{4}...
<p>If $$\int \frac{\sin ^{\frac{3}{2}} x+\cos ^{\frac{3}{2}} x}{\sqrt{\sin ^3 x \cos ^3 x \sin (x-\theta)}} d x=A \sqrt{\cos \theta \tan x-\sin \theta}+B \sqrt{\cos \theta-\sin \theta \cot x}+C$$, where $$C$$ is the integration constant, then $$A B$$ is equal to</p> Options: [{"identifier": "A", "content": "$$2 \\sec ...
["B"] Explanation: <p>$$\begin{aligned} & \text {} \int \frac{\sin ^{\frac{3}{2}} x+\cos ^{\frac{3}{2}} x}{\sqrt{\sin ^3 x \cos ^3 x \sin (x-\theta)}} d x \\ & I=\int \frac{\sin ^{\frac{3}{2}} x+\cos ^{\frac{3}{2}} x}{\sqrt{\sin ^3 x \cos ^3 x(\sin x \cos \theta-\cos x \sin \theta)}} d x \\ & =\int \frac{\sin ^{\frac{...
<p>Let $$\int \frac{2-\tan x}{3+\tan x} \mathrm{~d} x=\frac{1}{2}\left(\alpha x+\log _e|\beta \sin x+\gamma \cos x|\right)+C$$, where $$C$$ is the constant of integration. Then $$\alpha+\frac{\gamma}{\beta}$$ is equal to :</p> Options: [{"identifier": "A", "content": "3"}, {"identifier": "B", "content": "7"}, {"identi...
["D"] Explanation: <p>$$I=\int \frac{2-\tan x}{3+\tan x} d x=\int \frac{2 \cos x-\sin x}{3 \cos x+\sin x} d x$$</p> <p>Put, $$2 \cos x-\sin x=a(-3 \sin x+\cos x)+ b(3 \cos x+\sin x)$$</p> <p>$$\begin{aligned} & a+3 b=2 \quad \text{.... (i)}\\ & -3 a+b=-1 \quad \text{.... (ii)} \end{aligned}$$</p> <p>From equation (i) ...
<p>If $$\int \frac{1}{\sqrt[5]{(x-1)^4(x+3)^6}} \mathrm{~d} x=\mathrm{A}\left(\frac{\alpha x-1}{\beta x+3}\right)^B+\mathrm{C}$$, where $$\mathrm{C}$$ is the constant of integration, then the value of $$\alpha+\beta+20 \mathrm{AB}$$ is _________.</p> Options: []
7 Explanation: <p>$$\begin{aligned} & I=\int \frac{1}{\sqrt[5]{(x-1)^4(x+3)^6}} d x \\ & \frac{x+3}{x-1}=t \Rightarrow d x=\frac{-4}{(t-1)^2} d t \Rightarrow x=\left(\frac{3+t}{t-1}\right) \\ & \Rightarrow(x-1)^4(x+3)^6=(x-1)^5(x+3)^5\left(\frac{x+3}{x-1}\right) \\ & I=\int \frac{\frac{-4}{(t-1)^2} d t}{t^{1 / 5}\left...
<p>Let $$I(x)=\int \frac{6}{\sin ^2 x(1-\cot x)^2} d x$$. If $$I(0)=3$$, then $$I\left(\frac{\pi}{12}\right)$$ is equal to</p> Options: [{"identifier": "A", "content": "$$\\sqrt3$$"}, {"identifier": "B", "content": "$$2\\sqrt3$$"}, {"identifier": "C", "content": "$$6\\sqrt3$$"}, {"identifier": "D", "content": "$$3\\sq...
["D"] Explanation: <p>$$\begin{aligned} & I(x)=\int \frac{6}{\sin ^2 x(1-\cot x)^2} d x \\ & I(x)=\int \frac{6}{(\sin x-\cos x)^2} d x \\ & =\int \frac{6 \sec ^2 x}{(\tan x-1)^2} d x \end{aligned}$$</p> <p>$$\begin{aligned} & \text { Let } \tan x=t \Rightarrow \sec ^2 x d x=d t \\ & =\int \frac{6 d t}{(t-1)^2} \\ & =-...
$$\int {{{dx} \over {\cos x - \sin x}}} $$ is equal to Options: [{"identifier": "A", "content": "$${1 \\over {\\sqrt 2 }}\\log \\left| {\\tan \\left( {{x \\over 2} + {{3\\pi } \\over 8}} \\right)} \\right| + C$$ "}, {"identifier": "B", "content": "$${1 \\over {\\sqrt 2 }}\\log \\left| {\\cot \\left( {{x \\over 2}} \\...
["A"] Explanation: $$\int {{{dx} \over {\cos x - \sin x}}} $$ <br><br>$$ = \int {{{dx} \over {\sqrt 2 \cos \left( {x + {\pi \over 4}} \right)}}} $$ <br><br>$$ = {1 \over {\sqrt 2 }}\int {\sec \left( {x + {\pi \over 4}} \right)dx} $$ <br><br>$$ = {1 \over {\sqrt 2 }}\log \left| {\tan \left( {{\pi \over 4} + {x \over...
If $$\int {{{\sin x} \over {\sin \left( {x - \alpha } \right)}}dx = Ax + B\log \sin \left( {x - \alpha } \right), + C,} $$ then value of <br/>$$(A, B)$$ is Options: [{"identifier": "A", "content": "$$\\left( { - \\cos \\alpha ,\\sin \\alpha } \\right)$$ "}, {"identifier": "B", "content": "$$\\left( { \\cos \\alpha ...
["B"] Explanation: $$\int {{{\sin x} \over {\sin \left( {x - \alpha } \right)}}} dx$$ <br><br>$$ = \int {{{\sin \left( {x - \alpha + \alpha } \right)} \over {\sin \left( {x - \alpha } \right)}}} dx$$ <br><br>$$ = \int {{{\sin \left( {x - \alpha } \right)\cos \alpha + \cos \left( {x - \alpha } \right)\sin \alpha } \o...
$$\int {{{dx} \over {\cos x + \sqrt 3 \sin x}}} $$ equals Options: [{"identifier": "A", "content": "$$\\log \\,\\tan \\,\\left( {{x \\over 2} + {\\pi \\over {12}}} \\right) + C$$ "}, {"identifier": "B", "content": "$$\\log \\,\\tan \\,\\left( {{x \\over 2} - {\\pi \\over {12}}} \\right) + C$$"}, {"identifier": "C", ...
["C"] Explanation: $$I = \int {{{dx} \over {\cos x + \sqrt 3 \sin x}}} $$ <br><br>$$ \Rightarrow I = \int {{{dx} \over {2\left[ {{1 \over 2}\cos x + {{\sqrt 3 } \over 2}\sin x} \right]}}} $$ <br><br>$$ = {1 \over 2}\int {{{dx} \over {\left[ {\sin {\pi \over 6}\cos x + \cos {\pi \over 6}\sin x} \right]}}} $$ <br><br>...
The integral <br/><br/>$$\int {\sqrt {1 + 2\cot x(\cos ecx + \cot x)\,} \,\,dx} $$ <br/><br/>$$\left( {0 &lt; x &lt; {\pi \over 2}} \right)$$ is equal to : <br/><br/>(where C is a constant of integration) Options: [{"identifier": "A", "content": "4 log(sin $${x \\over 2}$$ ) + C"}, {"identifier": "B", "content": "2...
["B"] Explanation: Let, I = $$\int {\sqrt {1 + 2\cot x\cos ec + 2{{\cot }^2}x} .dx} $$<br><br> $$ \Rightarrow $$ I = $$\int {\sqrt {{{{{\sin }^2}x + 2\cos x + 2{{\cos }^2}x} \over {{{\sin }^2}x}}} .dx} $$<br><br> $$ \Rightarrow $$ I = $$\int {\sqrt {{{1 + 2\cos x + {{\cos }^2}x} \over {\sin x}}} .dx} $$<br><br> $$ \R...
If $$\,\,\,$$ f$$\left( {{{3x - 4} \over {3x + 4}}} \right)$$ = x + 2, x $$ \ne $$ $$-$$ $${4 \over 3}$$, and <br/><br/>$$\int {} $$f(x) dx = A log$$\left| {} \right.$$1 $$-$$ x $$\left| {} \right.$$ + Bx + C, <br/><br/>then the ordered pair (A, B) is equal to : <br/><br/>(where C is a constant of integration) O...
["B"] Explanation: Given, <br><br>f$$\left( {{{3x - 4} \over {3x + 4}}} \right)$$ = x + 2, &nbsp;&nbsp;&nbsp;x &nbsp;$$ \ne $$&nbsp;$$-$$ $${4 \over 3}$$ <br><br>Let, $${{3x - 4} \over {3x + 4}}$$ = t <br><br>$$ \Rightarrow $$$$\,\,\,$$ 3x $$-$$ 4 = 3tx + 4t <br><br>$$ \Rightarrow $$$$\,\,\,$$ 3x $$-$$ 3tx = 4t + 4 ...
If $$f\left( {{{x - 4} \over {x + 2}}} \right) = 2x + 1,$$ (x $$ \in $$ <b>R</b> $$-$${1, $$-$$ 2}), then $$\int f \left( x \right)dx$$ is equal to : <br/>(where C is a constant of integration) Options: [{"identifier": "A", "content": "12 log<sub>e</sub> | 1 $$-$$ x | + 3x + C"}, {"identifier": "B", "content": "$$-$$ ...
["B"] Explanation: Let, $${{{x - 4} \over {x + 2}}}$$ = t<br><br> $$ \Rightarrow $$ x - 4 = t(x+2)<br><br> $$ \Rightarrow $$ x (1 -t) = 2(t+2)<br><br> $$ \Rightarrow $$ x = $${{2(t + 2)} \over {1 - t}}$$<br><br> $$ \therefore $$ f(t) = 2($${{2(t + 2)} \over {1 - t}}$$) + 1<br><br> = $${{4t + 8} \over {1 - t}} + 1$$<br...
If    $$\int {{{2x + 5} \over {\sqrt {7 - 6x - {x^2}} }}} \,\,dx = A\sqrt {7 - 6x - {x^2}} + B{\sin ^{ - 1}}\left( {{{x + 3} \over 4}} \right) + C$$ <br/>(where C is a constant of integration), then the ordered pair (A, B) is equal to : Options: [{"identifier": "A", "content": "(2, &nbsp;1)"}, {"identifier": "B", ...
["B"] Explanation: We can write, <br><br>7 - 6x - x<sup>2</sup> = 16 - (x + 3)<sup>2</sup> <br><br>and $${d \over {dx}}\left( {7 - 6x - {x^2}} \right) = - (2x + 6)$$ <br><br>So, $$\int {{{2x + 5} \over {\sqrt {7 - 6x - {x^2}} }}} dx$$ <br><br>= $$\int {{{2x + 6 - 1} \over {\sqrt {7 - 6x - {x^2}} }}} dx$$ <br><br>= $$...
$$\int {{e^{\sec x}}}$$ $$(\sec x\tan xf(x) + \sec x\tan x + se{x^2}x)dx$$<br/> = e<sup>secx</sup>f(x) + C then a possible choice of f(x) is :- Options: [{"identifier": "A", "content": "x sec x + tan x + 1/2"}, {"identifier": "B", "content": "sec x + xtan x - 1/2"}, {"identifier": "C", "content": "sec x - tan x - 1/2...
["D"] Explanation: Given <br><br>$$\int {{e^{\sec x}}\left( {\sec x\tan x\,f(x) + (sec\,x\,tan\,x\, + se{c^2}x)} \right)} $$<br><br> $$ = {e^{\sec x}}f(x) + C$$ <br><br>Differentiating both sides with respect to x, <br><br>$${e^{\sec x}}.\sec x\tan x\,f\left( x \right)$$ + $${e^{\sec x}}\left( {\sec x\tan x + {{\sec }...
The integral $$\int {{{2{x^3} - 1} \over {{x^4} + x}}} dx$$ is equal to : <br/>(Here C is a constant of integration) Options: [{"identifier": "A", "content": "$${\\log _e}{{\\left| {{x^3} + 1} \\right|} \\over {{x^2}}} + C$$"}, {"identifier": "B", "content": "$${1 \\over 2}{\\log _e}{{\\left| {{x^3} + 1} \\right|} \\...
["C"] Explanation: $$\int {{{2{x^3} - 1} \over {{x^4} + x}}dx = \int {{{2x - {x^{ - 2}}} \over {{x^2} + {x^{ - 1}}}}dx = \ln ({x^2} + {x^{ - 1}}} } ) + c$$<br><br> $$ \Rightarrow \ln ({x^3} + 1) - \ln x + c$$
$$\int {{{\sin {{5x} \over 2}} \over {\sin {x \over 2}}}dx} $$ is equal to<br/> (where c is a constant of integration) Options: [{"identifier": "A", "content": "2x + sinx + 2sin2x + c"}, {"identifier": "B", "content": "x + 2sinx + sin2x + c"}, {"identifier": "C", "content": "x + 2sinx + 2sin2x + c"}, {"identifier": "D...
["B"] Explanation: $$\int {{{\sin {{5x} \over 2}} \over {\sin {x \over 2}}}dx} $$ <br><br>= $$\int {{{2\cos {x \over 2}.\sin {{5x} \over 2}} \over {2\cos {x \over 2}.\sin {x \over 2}}}} dx $$ <br><br>= $$\int {{{\sin \left( {{{5x} \over 2} + {x \over 2}} \right) + \sin \left( {{{5x} \over 2} - {x \over 2}} \right)} \o...
If ƒ'(x) = tan<sup>–1</sup>(secx + tanx), $$ - {\pi \over 2} &lt; x &lt; {\pi \over 2}$$, <br/>and ƒ(0) = 0, then ƒ(1) is equal to : Options: [{"identifier": "A", "content": "$${1 \\over 4}$$"}, {"identifier": "B", "content": "$${{\\pi - 1} \\over 4}$$"}, {"identifier": "C", "content": "$${{\\pi + 1} \\over 4}$$"}...
["C"] Explanation: ƒ'(x) = tan<sup>–1</sup>(secx + tanx) <br><br>$$ \Rightarrow $$ ƒ'(x) = $${\tan ^{ - 1}}\left( {{{1 + \sin x} \over {\cos x}}} \right)$$ = $${\tan ^{ - 1}}\left( {{{1 + \tan {x \over 2}} \over {1 - \tan {x \over 2}}}} \right)$$ <br><br>= $${\tan ^{ - 1}}\left( {\tan \left( {{\pi \over 4} + {x \over...
The integral $$\int {{{\left( {{x \over {x\sin x + \cos x}}} \right)}^2}dx} $$ is equal to <br/> (where C is a constant of integration): Options: [{"identifier": "A", "content": "$$\\sec x - {{x\\tan x} \\over {x\\sin x + \\cos x}} + C$$"}, {"identifier": "B", "content": "$$\\sec x + {{x\\tan x} \\over {x\\sin x + \\c...
["C"] Explanation: $${\int {\left( {{x \over {x\sin x + \cos x}}} \right)} ^2}dx $$ <br><br>$$= \int {\left( {{x \over {\cos x}}} \right).{{x\cos x\,dx} \over {{{(x\sin x + \cos x)}^2}}}} $$<br><br>= $${x \over {\cos x}}\left( { - {1 \over {x\sin x + \cos x}}} \right) + \int {\left( {{{\cos x + x\sin x} \over {{{\cos ...
If $$\int {{{({x^2} + 1){e^x}} \over {{{(x + 1)}^2}}}dx = f(x){e^x} + C} $$, where C is a constant, then $${{{d^3}f} \over {d{x^3}}}$$ at x = 1 is equal to : Options: [{"identifier": "A", "content": "$$ - {3 \\over 4}$$"}, {"identifier": "B", "content": "$${3 \\over 4}$$"}, {"identifier": "C", "content": "$$ - {3 \\ov...
["B"] Explanation: <p>$$I = \int {{{{e^x}({x^2} + 1)} \over {{{(x + 1)}^2}}}dx = f(x){e^x} + c} $$</p> <p>$$ = \int {{{{e^x}({x^2} - 1 + 1 + 1)} \over {{{(x + 1)}^2}}}dx} $$</p> <p>$$ = \int {{e^x}\left[ {{{x - 1} \over {x + 1}} + {2 \over {{{(x + 1)}^2}}}} \right]dx} $$</p> <p>$$ = {e^x}\left( {{{x - 1} \over {x + 1}...
<p>$$ \text { The integral } \int \frac{\left(1-\frac{1}{\sqrt{3}}\right)(\cos x-\sin x)}{\left(1+\frac{2}{\sqrt{3}} \sin 2 x\right)} d x \text { is equal to } $$</p> Options: [{"identifier": "A", "content": "$$\\frac{1}{2} \\log _{e}\\left|\\frac{\\tan \\left(\\frac{x}{2}+\\frac{\\pi}{12}\\right)}{\\tan \\left(\\frac...
["A"] Explanation: <p>$$ = \int {{{\left( {1 - {1 \over {\sqrt 3 }}} \right)(\cos x - \sin x)} \over {\left( {1 + {2 \over {\sqrt 3 }}\sin 2x} \right)}}dx} $$</p> <p>$$ = \int {{{\left( {{{\sqrt 3 - 1} \over {\sqrt 3 }}} \right)\sqrt 2 \sin \left( {{\pi \over 4} - x} \right)} \over {\left( {{2 \over {\sqrt 3 }}} \ri...
<p>For $$\alpha, \beta, \gamma, \delta \in \mathbb{N}$$, if $$\int\left(\left(\frac{x}{e}\right)^{2 x}+\left(\frac{e}{x}\right)^{2 x}\right) \log _{e} x d x=\frac{1}{\alpha}\left(\frac{x}{e}\right)^{\beta x}-\frac{1}{\gamma}\left(\frac{e}{x}\right)^{\delta x}+C$$ , where $$e=\sum_\limits{n=0}^{\infty} \frac{1}{n !}$$ ...
["D"] Explanation: We have, <br/><br/>$$\int\left(\left(\frac{x}{e}\right)^{2 x}+\left(\frac{e}{x}\right)^{2 x}\right) \log _{e} x d x=\frac{1}{\alpha}\left(\frac{x}{e}\right)^{\beta x}-\frac{1}{\gamma}\left(\frac{e}{x}\right)^{\delta x}+C$$ <br/><br/>$$ \begin{aligned} \left(\frac{x}{e}\right)^{2 x} & =\left(\frac{e...
<p>The integral $$ \int\left[\left(\frac{x}{2}\right)^x+\left(\frac{2}{x}\right)^x\right] \ln \left(\frac{e x}{2}\right) d x $$ is equal to :</p> Options: [{"identifier": "A", "content": "$$\\left(\\frac{x}{2}\\right)^{x}+\\left(\\frac{2}{x}\\right)^{x}+C$$"}, {"identifier": "B", "content": "$$\\left(\\frac{x}{2}\\rig...
["B"] Explanation: <p>To solve the integral:</p> <p>$ I = \int\left[\left(\frac{x}{2}\right)^x+\left(\frac{2}{x}\right)^x\right] \ln \left(\frac{e x}{2}\right) \, dx $</p> <p>we start by simplifying the logarithmic term:</p> <p>$ \ln\left(\frac{e x}{2}\right) = \ln(e) + \ln\left(\frac{x}{2}\right) = 1 + \ln\left(\frac...
<p>If $$\int \frac{1}{\mathrm{a}^2 \sin ^2 x+\mathrm{b}^2 \cos ^2 x} \mathrm{~d} x=\frac{1}{12} \tan ^{-1}(3 \tan x)+$$ constant, then the maximum value of $$\mathrm{a} \sin x+\mathrm{b} \cos x$$, is :</p> Options: [{"identifier": "A", "content": "$$\\sqrt{41}$$\n"}, {"identifier": "B", "content": "$$\\sqrt{39}$$\n"},...
["C"] Explanation: <p>$$\begin{aligned} & \int \frac{1}{a^2 \sin ^2 x+b^2 \cos ^2 x} d x=\frac{1}{12} \tan ^{-1}(3 \tan x)+c \\ & I=\int \frac{\sec ^2 x}{b^2+a^2 \tan ^2 x} d x \\ & \tan x=t \\ & \Rightarrow \sec ^2 x d x=d t \\ & I=\int \frac{d t}{b^2+a^2 t^2} \\ & =\frac{1}{b a} \tan ^{-1}\left(\frac{a t}{b}\right)+...
The trigonometric equation $${\sin ^{ - 1}}x = 2{\sin ^{ - 1}}a$$ has a solution for : Options: [{"identifier": "A", "content": "$$\\left| a \\right| \\ge {1 \\over {\\sqrt 2 }}$$ "}, {"identifier": "B", "content": "$${1 \\over 2} &lt; \\left| a \\right| &lt; {1 \\over {\\sqrt 2 }}$$ "}, {"identifier": "C", "content":...
["D"] Explanation: Given that, <br><br>$${\sin ^{ - 1}}x = 2{\sin ^{ - 1}}a$$ <br><br>We know, <br><br>$$ - {\pi \over 2} \le {\sin ^{ - 1}}x \le {\pi \over 2}$$ <br><br>$$\therefore$$ $$\,\,\,$$ $$ - {\pi \over 2} \le 2{\sin ^{ - 1}}a \le {\pi \over 2}$$ <br><br>$$ \Rightarrow - {\pi \over 4} \le {\sin ^{ - ...
The domain of the function <br/>f(x) = $${\sin ^{ - 1}}\left( {{{\left| x \right| + 5} \over {{x^2} + 1}}} \right)$$ is (– $$\infty $$, -a]$$ \cup $$[a, $$\infty $$). Then a is equal to : Options: [{"identifier": "A", "content": "$${{\\sqrt {17} - 1} \\over 2}$$"}, {"identifier": "B", "content": "$${{1 + \\sqrt {17}...
["B"] Explanation: f(x) = $${\sin ^{ - 1}}\left( {{{\left| x \right| + 5} \over {{x^2} + 1}}} \right)$$ <br><br>$$ \therefore $$ $$ - 1 \le {{\left| x \right| + 5} \over {{x^2} + 1}} \le 1$$ <br><br>Since |x| + 5 &amp; x<sup>2</sup> + 1 is always positive <br><br>So $${{\left| x \right| + 5} \over {{x^2} + 1}} \ge 0$...
The number of solutions of the equation <br/><br/>$${\sin ^{ - 1}}\left[ {{x^2} + {1 \over 3}} \right] + {\cos ^{ - 1}}\left[ {{x^2} - {2 \over 3}} \right] = {x^2}$$, for x$$\in$$[$$-$$1, 1], and [x] denotes the greatest integer less than or equal to x, is : Options: [{"identifier": "A", "content": "0"}, {"identifier"...
["A"] Explanation: There are three cases possible for $$x \in [ - 1,1]$$<br><br>Case I : $$x \in \left[ { - 1, - \sqrt {{2 \over 3}} } \right)$$<br><br>$$ \therefore $$ $${\sin ^{ - 1}}(1) + {\cos ^{ - 1}}(0) = {x^2}$$<br><br>$$ \Rightarrow {x^2} = {\pi \over 2} + {\pi \over 2} = \pi $$<br><br>$$ \Rightarrow x = \p...
The number of real roots of the equation $${\tan ^{ - 1}}\sqrt {x(x + 1)} + {\sin ^{ - 1}}\sqrt {{x^2} + x + 1} = {\pi \over 4}$$ is : Options: [{"identifier": "A", "content": "1"}, {"identifier": "B", "content": "2"}, {"identifier": "C", "content": "4"}, {"identifier": "D", "content": "0"}]
["D"] Explanation: $${\tan ^{ - 1}}\sqrt {x(x + 1)} + {\sin ^{ - 1}}\sqrt {{x^2} + x + 1} = {\pi \over 4}$$<br><br>For equation to be defined,<br><br>x<sup>2</sup> + x $$\ge$$ 0<br><br>$$\Rightarrow$$ x<sup>2</sup> + x + 1 $$\ge$$ 1<br><br>$$\therefore$$ Only possibility that the equation is defined <br><br>x<sup>2...
If the domain of the function $$f(x) = {{{{\cos }^{ - 1}}\sqrt {{x^2} - x + 1} } \over {\sqrt {{{\sin }^{ - 1}}\left( {{{2x - 1} \over 2}} \right)} }}$$ is the interval ($$\alpha$$, $$\beta$$], then $$\alpha$$ + $$\beta$$ is equal to : Options: [{"identifier": "A", "content": "$${3 \\over 2}$$"}, {"identifier": "B", "...
["A"] Explanation: $$O \le {x^2} - x + 1 \le 1$$<br><br>$$ \Rightarrow {x^2} - x \le 0$$<br><br>$$ \Rightarrow x \in [0,1]$$<br><br>Also, $$0 &lt; {\sin ^{ - 1}}\left( {{{2x - 1} \over 2}} \right) \le {\pi \over 2}$$<br><br>$$ \Rightarrow 0 &lt; {{2x - 1} \over 2} \le 1$$<br><br>$$ \Rightarrow 0 &lt; 2x - 1 \le 2$$<b...
The domain of the function $${{\mathop{\rm cosec}\nolimits} ^{ - 1}}\left( {{{1 + x} \over x}} \right)$$ is : Options: [{"identifier": "A", "content": "$$\\left( { - 1, - {1 \\over 2}} \\right] \\cup (0,\\infty )$$"}, {"identifier": "B", "content": "$$\\left[ { - {1 \\over 2},0} \\right) \\cup [1,\\infty )$$"}, {"iden...
["D"] Explanation: $${{1 + x} \over x} \in ( - \infty , - 1] \cup [1,\infty )$$<br><br>$${1 \over x} \in ( - \infty , - 2] \cup [0,\infty )$$<br><br>$$x \in \left[ { - {1 \over 2},0} \right) \cup (0,\infty )$$<br><br>$$x \in \left[ { - {1 \over 2},0} \right) \cup \{ 0\} $$
The domain of the function<br/><br/>$$f(x) = {\sin ^{ - 1}}\left( {{{3{x^2} + x - 1} \over {{{(x - 1)}^2}}}} \right) + {\cos ^{ - 1}}\left( {{{x - 1} \over {x + 1}}} \right)$$ is : Options: [{"identifier": "A", "content": "$$\\left[ {0,{1 \\over 4}} \\right]$$"}, {"identifier": "B", "content": "$$[ - 2,0] \\cup \\left...
["C"] Explanation: $$f(x) = {\sin ^{ - 1}}\left( {{{3{x^2} + x - 1} \over {{{(x - 1)}^2}}}} \right) + {\cos ^{ - 1}}\left( {{{x - 1} \over {x + 1}}} \right)$$<br><br>$$ - 1 \le {{x - 1} \over {x + 1}} \le 1 \Rightarrow 0 \le x &lt; \infty $$ .... (1)<br><br>$$ - 1 \le {{3{x^2} + x - 1} \over {{{(x - 1)}^2}}} \le 1 \Ri...
<p>The domain of the function $${\cos ^{ - 1}}\left( {{{2{{\sin }^{ - 1}}\left( {{1 \over {4{x^2} - 1}}} \right)} \over \pi }} \right)$$ is :</p> Options: [{"identifier": "A", "content": "$$R - \\left\\{ { - {1 \\over 2},{1 \\over 2}} \\right\\}$$"}, {"identifier": "B", "content": "$$( - \\infty , - 1] \\cup [1,\\inft...
["D"] Explanation: <p>$$ - 1 \le {{2{{\sin }^{ - 1}}\left( {{1 \over {4{x^2} - 1}}} \right)} \over \pi } \le 1$$</p> <p>$$ \Rightarrow - {\pi \over 2} \le {\sin ^{ - 1}}\left( {{1 \over {4{x^2} - 1}}} \right) \le {\pi \over 2}$$</p> <p>$$ \Rightarrow - 1 \le {1 \over {4{x^2} - 1}} \le 1$$</p> <p>$$\therefore$$ $${...
<p>The domain of the function <br/><br/>$$f(x) = {{{{\cos }^{ - 1}}\left( {{{{x^2} - 5x + 6} \over {{x^2} - 9}}} \right)} \over {{{\log }_e}({x^2} - 3x + 2)}}$$ is :</p> Options: [{"identifier": "A", "content": "$$( - \\infty ,1) \\cup (2,\\infty )$$"}, {"identifier": "B", "content": "$$(2,\\infty )$$"}, {"identifier"...
["D"] Explanation: $-1 \leq \frac{x^{2}-5 x+6}{x^{2}-9} \leq 1$ and $x^{2}-3 x+2>0, \neq 1$ <br/><br/> $$ \frac{(x-3)(2 x+1)}{x^{2}-9} \geq 0 \mid \frac{5(x-3)}{x^{2}-9} \geq 0 $$ <br/><br/> The solution to this inequality is <br/><br/> $x \in\left[\frac{-1}{2}, \infty\right)-\{3\}$ <br/><br/> for $x^{2}-3 x+2>0$ and ...
<p>The domain of the function $$f(x)=\sin ^{-1}\left[2 x^{2}-3\right]+\log _{2}\left(\log _{\frac{1}{2}}\left(x^{2}-5 x+5\right)\right)$$, where [t] is the greatest integer function, is :</p> Options: [{"identifier": "A", "content": "$$\n\\left(-\\sqrt{\\frac{5}{2}}, \\frac{5-\\sqrt{5}}{2}\\right)\n$$"}, {"identifier"...
["C"] Explanation: <p>$$ - 1 \le 2{x^2} - 3 < 2$$</p> <p>or $$2 \le 2{x^2} < 5$$</p> <p>or $$1 \le {x^2} < {5 \over 2}$$</p> <p>$$x \in \left( { - \sqrt {{5 \over 2}} , - 1} \right] \cup \left[ {1,\sqrt {{5 \over 2}} } \right)$$</p> <p>$${\log _{{1 \over 2}}}({x^2} - 5x + 5) > 0$$</p> <p>$$0 < {x^2} - 5x + 5 < 1$$</p>...
<p>The domain of the function $$f(x)=\sin ^{-1}\left(\frac{x^{2}-3 x+2}{x^{2}+2 x+7}\right)$$ is :</p> Options: [{"identifier": "A", "content": "$$[1, \\infty)$$"}, {"identifier": "B", "content": "$$[-1,2]$$"}, {"identifier": "C", "content": "$$[-1, \\infty)$$"}, {"identifier": "D", "content": "$$(-\\infty, 2]$$"}]
["C"] Explanation: $f(x)=\sin ^{-1}\left(\frac{x^{2}-3 x+2}{x^{2}+2 x+7}\right)$ <br/><br/>$$ -1 \leq \frac{x^{2}-3 x+2}{x^{2}+2 x+7} \leq 1 $$ <br/><br/>$$ \begin{aligned} & \frac{x^{2}-3 x+2}{x^{2}+2 x+7} \leq 1 \\\\ & x^{2}-3 x+2 \leq x^{2}+2 x+7 \\\\ & 5 x \geq-5 \\\\ & x \geq-1 \end{aligned} $$ <br/><br/>And $...
If the domain of the function <br/><br/>$f(x)=\log _{e}\left(4 x^{2}+11 x+6\right)+\sin ^{-1}(4 x+3)+\cos ^{-1}\left(\frac{10 x+6}{3}\right)$ is $(\alpha, \beta]$, then <br/><br/>$36|\alpha+\beta|$ is equal to : Options: [{"identifier": "A", "content": "72"}, {"identifier": "B", "content": "54"}, {"identifier": "C",...
["C"] Explanation: <p>To find the domain of the function, we need to consider the individual functions and their respective domains. We have:</p> <p><ol> <li>$f_1(x) = \ln(4x^2 + 11x + 6)$</li> <li>$f_2(x) = \sin^{-1}(4x + 3)$</li> <li>$f_3(x) = \cos^{-1}\left(\frac{10x + 6}{3}\right)$</li> </ol></p> <p><ol> <li>For $...
<p>If the domain of the function $$f(x)=\sec ^{-1}\left(\frac{2 x}{5 x+3}\right)$$ is $$[\alpha, \beta) \mathrm{U}(\gamma, \delta]$$, then $$|3 \alpha+10(\beta+\gamma)+21 \delta|$$ is equal to _________.</p> Options: []
24 Explanation: Given that $f(x)=\sec ^{-1}\left(\frac{2 x}{5 x+3}\right)$ <br/><br/>Since, the domain for $\sec ^{-1} x$ is $|x| \geq 1$ <br/><br/>Therefore $\left|\frac{2 x}{5 x+3}\right| \geq 1$ <br/><br/>$$ \begin{aligned} & \frac{2 x}{5 x+3} \leq-1 \text { or } \frac{2 x}{5 x+3} \geq 1 \\\\ & \frac{2 x+5 x+3}{5...
<p>If the domain of the function $$\sin ^{-1}\left(\frac{3 x-22}{2 x-19}\right)+\log _{\mathrm{e}}\left(\frac{3 x^2-8 x+5}{x^2-3 x-10}\right)$$ is $$(\alpha, \beta]$$, then $$3 \alpha+10 \beta$$ is equal to:</p> Options: [{"identifier": "A", "content": "95"}, {"identifier": "B", "content": "100"}, {"identifier": "C", ...
["C"] Explanation: <p>$$\begin{aligned} & \sin ^{-1}\left(\frac{3 x-22}{2 x-19}\right)+\log _e\left(\frac{3 x^2-8 x+5}{x^2-3 x-10}\right) \\ & -1 \leq \frac{3 x-22}{2 x-19} \leq 1 \\ & \frac{3 x-22}{2 x-19}+1 \geq 0 \text { and } \frac{3 x-22}{2 x-19}-1 \leq 0 \\ & \frac{3 x-22+2 x-19}{2 x-19} \geq 0 \text { and } \fr...
Considering only the principal values of inverse functions, the set <br/>A = { x $$ \ge $$ 0: tan<sup>$$-$$1</sup>(2x) + tan<sup>$$-$$1</sup>(3x) = $${\pi \over 4}$$} Options: [{"identifier": "A", "content": "contains two elements "}, {"identifier": "B", "content": "contains more than two elements "}, {"identifier": ...
["D"] Explanation: tan<sup>$$-$$1</sup>(2x) + tan<sup>$$-$$1</sup>(3x) = $$\pi $$/4 <br><br>$$ \Rightarrow \,\,{{5x} \over {1 - 6{x^2}}}$$ = 1 <br><br>$$ \Rightarrow $$&nbsp;&nbsp;6x<sup>2</sup> + 5x $$-$$ 1 = 0 <br><br>x = $$-$$1 or x = $${1 \over 6}$$ <br><br>x = $${1 \over 6}$$ <br><br>$$ \because $$&nbsp;&nbsp;x...
Given that the inverse trigonometric functions take principal values only. Then, the number of real values of x which satisfy <br/><br/>$${\sin ^{ - 1}}\left( {{{3x} \over 5}} \right) + {\sin ^{ - 1}}\left( {{{4x} \over 5}} \right) = {\sin ^{ - 1}}x$$ is equal to : Options: [{"identifier": "A", "content": "2"}, {"iden...
["C"] Explanation: $${\sin ^{ - 1}}{{3x} \over 5} + {\sin ^{ - 1}}{{4x} \over 5} = {\sin ^{ - 1}}x$$<br><br>$${\sin ^{ - 1}}\left( {{{3x} \over 5}\sqrt {1 - {{16{x^2}} \over {25}}} + {{4x} \over 5}\sqrt {1 - {{9{x^2}} \over {25}}} } \right) = {\sin ^{ - 1}}x$$<br><br>$${{3x} \over 5}\sqrt {1 - {{16{x^2}} \over {25}}}...
$${\cos ^{ - 1}}(\cos ( - 5)) + {\sin ^{ - 1}}(\sin (6)) - {\tan ^{ - 1}}(\tan (12))$$ is equal to :<br/><br/>(The inverse trigonometric functions take the principal values) Options: [{"identifier": "A", "content": "3$$\\pi$$ $$-$$ 11"}, {"identifier": "B", "content": "4$$\\pi$$ $$-$$ 9"}, {"identifier": "C", "content...
["C"] Explanation: $${\cos ^{ - 1}}(\cos ( - 5)) + {\sin ^{ - 1}}(\sin (6)) - {\tan ^{ - 1}}(\tan (12))$$<br><br>$$ = (2\pi - 5) + (6 - 2\pi ) - (12 - 4\pi )$$<br><br>$$ = 4\pi - 11$$.
<p>$${\sin ^1}\left( {\sin {{2\pi } \over 3}} \right) + {\cos ^{ - 1}}\left( {\cos {{7\pi } \over 6}} \right) + {\tan ^{ - 1}}\left( {\tan {{3\pi } \over 4}} \right)$$ is equal to :</p> Options: [{"identifier": "A", "content": "$${{11\\pi } \\over {12}}$$"}, {"identifier": "B", "content": "$${{17\\pi } \\over {12}}$$"...
["A"] Explanation: <p>$${\sin ^{ - 1}}\left( {{{\sqrt 3 } \over 2}} \right) + {\cos ^{ - 1}}\left( {{{ - \sqrt 3 } \over 2}} \right) + {\tan ^{ - 1}}\left( { - 1} \right)$$</p> <p>$$ = {\pi \over 3} + {{5\pi } \over 6} - {\pi \over 4}$$</p> <p>$$ = {{4\pi + 10\pi - 3\pi } \over {12}} = {{11\pi } \over {12}}$$</p>
<p>If the inverse trigonometric functions take principal values then <br/><br/>$${\cos ^{ - 1}}\left( {{3 \over {10}}\cos \left( {{{\tan }^{ - 1}}\left( {{4 \over 3}} \right)} \right) + {2 \over 5}\sin \left( {{{\tan }^{ - 1}}\left( {{4 \over 3}} \right)} \right)} \right)$$ is equal to :</p> Options: [{"identifier": "...
["C"] Explanation: <p>$${\cos ^{ - 1}}\left( {{3 \over {10}}\cos \left( {{{\tan }^{ - 1}}\left( {{4 \over 3}} \right)} \right) + {2 \over 5}\sin \left( {{{\tan }^{ - 1}}\left( {{4 \over 3}} \right)} \right)} \right)$$</p> <p>$$ = {\cos ^{ - 1}}\left( {{3 \over {10}}\,.\,{3 \over 5} + {2 \over 5}\,.\,{4 \over 5}} \righ...