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Vah0GQp8qnQsrnOi | maths | definite-integration | properties-of-definite-integration | If $$y=f(x)$$ makes +$$ve$$ intercept of $$2$$ and $$0$$ unit on $$x$$ and $$y$$ axes and encloses an area of $$3/4$$ square unit with the axes then $$\int\limits_0^2 {xf'\left( x \right)dx} $$ is | [{"identifier": "A", "content": "$$3/2$$ "}, {"identifier": "B", "content": "$$1$$ "}, {"identifier": "C", "content": "$$5/4$$ "}, {"identifier": "D", "content": "$$-3/4$$ "}] | ["D"] | null | We have $$\int\limits_0^2 {f\left( x \right)} dx = {3 \over 4};Now,$$
<br><br>$$\int\limits_0^2 {xf'\left( x \right)} dx$$
<br><br>$$ = x\int\limits_0^2 {f'\left( x \right)dx} - \int\limits_0^2 {f\left( x \right)} dx$$
<br><br>$$ = \left[ {x\,f\left( x \right)} \right]_0^2 - {3 \over 4}$$
<br><br>$$ = 2f\left( 2 \righ... | mcq | aieee-2002 | 5,582 |
tiedgbvfIFzGtJ0O | maths | definite-integration | properties-of-definite-integration | If $$f\left( y \right) = {e^y},$$ $$g\left( y \right) = y;y > 0$$ and
<br/><br>$$F\left( t \right) = \int\limits_0^t {f\left( {t - y} \right)g\left( y \right)dy,} $$ then :</br> | [{"identifier": "A", "content": "$$F\\left( t \\right) = t{e^{ - t}}$$ "}, {"identifier": "B", "content": "$$F\\left( t \\right) = 1t - t{e^{ - 1}}\\left( {1 + t} \\right)$$ "}, {"identifier": "C", "content": "$$F\\left( t \\right) = {e^t} - \\left( {1 + t} \\right)$$ "}, {"identifier": "D", "content": "$$F\\left( t \\... | ["C"] | null | $$F\left( t \right) = \int\limits_0^t {f\left( {t - y} \right)g\left( y \right)} dy$$
<br><br>$$ = \int\limits_0^t {{e^{t - y}}} ydy = {e^t}\int\limits_0^t {{e^{ - y}}} \,ydy$$
<br><br>$$ = {e^t}\left[ { - y{e^{ - y}} - {e^{ - y}}} \right]_0^t$$
<br><br>$$ = - {e^t}\left[ {y{e^{ - y}} + {e^{ - y}}} \right]_0^t$$
<br><... | mcq | aieee-2003 | 5,583 |
5d1PWQJ8XGbfoKZR | maths | definite-integration | properties-of-definite-integration | The value of the integral $$I = \int\limits_0^1 {x{{\left( {1 - x} \right)}^n}dx} $$ is | [{"identifier": "A", "content": "$${1 \\over {n + 1}} + {1 \\over {n + 2}}$$ "}, {"identifier": "B", "content": "$${1 \\over {n + 1}}$$ "}, {"identifier": "C", "content": "$${1 \\over {n + 2}}$$ "}, {"identifier": "D", "content": "$${1 \\over {n + 1}} - {1 \\over {n + 2}}$$"}] | ["D"] | null | $$I = \int\limits_0^1 {x{{\left( {1 - x} \right)}^n}} dx$$
<br><br>$$ = \int\limits_0^1 {\left( {1 - x} \right){{\left( {1 - 1 + x} \right)}^n}dx} $$
<br><br>$$ = \int\limits_0^1 {\left( {1 - x} \right)} {x^n}dx$$
<br><br>$$ = \left[ {{{{x^{n + 1}}} \over {n + 1}} - {{{x^{n + 2}}} \over {n + 2}}} \right]_0^1$$
<br><br... | mcq | aieee-2003 | 5,584 |
CGM65kHJRMbNg3A6 | maths | definite-integration | properties-of-definite-integration | The value of $$I = \int\limits_0^{\pi /2} {{{{{\left( {\sin x + \cos x} \right)}^2}} \over {\sqrt {1 + \sin 2x} }}dx} $$ is | [{"identifier": "A", "content": "$$3$$ "}, {"identifier": "B", "content": "$$1$$"}, {"identifier": "C", "content": "$$2$$"}, {"identifier": "D", "content": "$$0$$"}] | ["C"] | null | $$I = \int\limits_0^{{\pi \over 2}} {{{{{\left( {\sin \,x + \cos x} \right)}^2}} \over {\sqrt {1 + \sin 2x} }}} dx$$
<br><br>We know $$\left[ {{{\left( {\sin x + \cos x} \right)}^2} = 1 + \sin 2x} \right],\,$$ So
<br><br>$$I = \int\limits_0^{{\pi \over 2}} {{{{{\left( {\sin x + \cos x} \right)}^2}} \over {\left( {\si... | mcq | aieee-2004 | 5,587 |
yxxHHZHxwFw8kp9m | maths | definite-integration | properties-of-definite-integration | The value of $$\int\limits_{ - 2}^3 {\left| {1 - {x^2}} \right|dx} $$ is | [{"identifier": "A", "content": "$${1 \\over 3}$$ "}, {"identifier": "B", "content": "$${14 \\over 3}$$"}, {"identifier": "C", "content": "$${7 \\over 3}$$"}, {"identifier": "D", "content": "$${28 \\over 3}$$"}] | ["D"] | null | $$\int\limits_{ - 2}^3 {\left| {1 - {x^2}} \right|} dx = \int\limits_{ - 2}^3 {\left| {{x^2} - 1} \right|} dx$$
<br><br>Now $$\left| {{x^2} - 1} \right| = \left\{ {\matrix{
{{x^2} - 1} & {if} & {x \le - 1} \cr
{1 - {x^2}} & {if} & { - 1 \le x \le 1} \cr
{{x^2} - 1} & {if} & {x \ge ... | mcq | aieee-2004 | 5,588 |
mF2HI0v3oqpZ6K8Y | maths | definite-integration | properties-of-definite-integration | If $$\int\limits_0^\pi {xf\left( {\sin x} \right)dx = A\int\limits_0^{\pi /2} {f\left( {\sin x} \right)dx,} } $$ then $$A$$ is | [{"identifier": "A", "content": "$$2\\pi $$ "}, {"identifier": "B", "content": "$$\\pi $$ "}, {"identifier": "C", "content": "$${\\pi \\over 4}$$ "}, {"identifier": "D", "content": "$$0$$"}] | ["B"] | null | Let $$I = \int\limits_0^\pi {xf\left( {\sin x} \right)} dx$$
<br><br>$$ = \int\limits_0^\pi {\left( {\pi - x} \right)} f\left( {\sin x} \right)dx$$
<br><br>$$\therefore$$ $$2I = \pi \int\limits_2^\pi {f\left( {\sin x} \right)} dx$$
<br><br>$$ = \pi .2\int\limits_0^{{\pi \over 2}} {f\left( {\sin x} \right)} dx$$
<b... | mcq | aieee-2004 | 5,589 |
tPVNHNIpqwfMq5M6 | maths | definite-integration | properties-of-definite-integration | If $$f\left( x \right) = {{{e^x}} \over {1 + {e^x}}},{I_1} = \int\limits_{f\left( { - a} \right)}^{f\left( a \right)} {xg\left\{ {x\left( {1 - x} \right)} \right\}dx} $$
<br/>and $${I_2} = \int\limits_{f\left( { - a} \right)}^{f\left( a \right)} {g\left\{ {x\left( {1 - x} \right)} \right\}dx} ,$$ then the value of $${... | [{"identifier": "A", "content": "$$1$$"}, {"identifier": "B", "content": "$$-3$$ "}, {"identifier": "C", "content": "$$-1$$"}, {"identifier": "D", "content": "$$2$$"}] | ["D"] | null | $$f\left( x \right) = {{{e^x}} \over {1 + {e^x}}}$$
<br><br>$$ \Rightarrow f\left( { - x} \right) = {{{e^{ - x}}} \over {1 + {e^{ - x}}}} = {1 \over {{e^x} + 1}}$$
<br><br>$$\therefore$$ $$f\left( x \right) + f\left( { - x} \right) = 1\forall x$$
<br><br>Now $${I_1} = \int\limits_{f\left( { - a} \right)}^{f\left( a \ri... | mcq | aieee-2004 | 5,590 |
WZH8LobJQ9h9MXPm | maths | definite-integration | properties-of-definite-integration | If $${I_1} = \int\limits_0^1 {{2^{{x^2}}}dx,{I_2} = \int\limits_0^1 {{2^{{x^3}}}dx,\,{I_3} = \int\limits_1^2 {{2^{{x^2}}}dx} } } $$ and $${I_4} = \int\limits_1^2 {{2^{{x^3}}}dx} $$ then | [{"identifier": "A", "content": "$${I_2} > {I_1}$$ "}, {"identifier": "B", "content": "$${I_1} > {I_2}$$"}, {"identifier": "C", "content": "$${I_3} = {I_4}$$"}, {"identifier": "D", "content": "$${I_3} > {I_4}$$"}] | ["B"] | null | $${I_1} = \int\limits_0^1 {{2^{{x^2}}}} dx,\,{I_2} = \int\limits_0^1 {{2^{{x^3}}}} dx,$$
<br><br>$$ = {I_3} = \int\limits_0^1 {{2^{{x^2}}}} dx,\,$$
<br><br>$${I_4} = \int\limits_0^1 {{2^{{x^3}}}} dx\,\,$$
<br><br>$$\forall 0 < x < 1,\,{x^2} > {x^3}$$
<br><br>$$ \Rightarrow \int\limits_0^1 {{2^{{x^2}}}} \,dx &g... | mcq | aieee-2005 | 5,591 |
hYawqjqSy59anVIp | maths | definite-integration | properties-of-definite-integration | The value of integral, $$\int\limits_3^6 {{{\sqrt x } \over {\sqrt {9 - x} + \sqrt x }}} dx $$ is | [{"identifier": "A", "content": "$${1 \\over 2}$$ "}, {"identifier": "B", "content": "$${3 \\over 2}$$"}, {"identifier": "C", "content": "$$2$$"}, {"identifier": "D", "content": "$$1$$"}] | ["B"] | null | $$I = \int\limits_3^6 {{{\sqrt x } \over {\sqrt {9 - x} + \sqrt x }}} dx\,\,\,\,\,\,\,\,\,...\left( 1 \right)$$
<br><br>$$I = \int\limits_3^6 {{{\sqrt {9 - x} } \over {\sqrt {9 - x} + \sqrt x }}} dx\,\,\,\,\,\,\,\,\,...\left( 2 \right)$$
<br><br>$$\left[ \, \right.$$ using $$\int\limits_a^b {f\left( x \right)dx = \in... | mcq | aieee-2005 | 5,593 |
83nydnA4phzxG3p2 | maths | definite-integration | properties-of-definite-integration | $$\int\limits_{ - {{3\pi } \over 2}}^{ - {\pi \over 2}} {\left[ {{{\left( {x + \pi } \right)}^3} + {{\cos }^2}\left( {x + 3\pi } \right)} \right]} dx$$ is equal to | [{"identifier": "A", "content": "$${{{\\pi ^4}} \\over {32}}$$ "}, {"identifier": "B", "content": "$${{{\\pi ^4}} \\over {32}} + {\\pi \\over 2}$$ "}, {"identifier": "C", "content": "$${\\pi \\over 2}$$ "}, {"identifier": "D", "content": "$${\\pi \\over 4} - 1$$ "}] | ["C"] | null | $$I = \int\limits_{ - {{3\pi } \over 2}}^{ - {\pi \over 2}} {\left[ {{{\left( {x + \pi } \right)}^3} + {{\cos }^2}\left( {x + 3\pi } \right)} \right]} \,dx$$
<br><br>Put $$x + \pi = t$$
<br><br>$$I = \int\limits_{ - {\pi \over 2}}^{{\pi \over 2}} {\left( {{t^3} + {{\cos }^2}t} \right)dt} $$
<br><br>$$ = 2\int\limit... | mcq | aieee-2006 | 5,595 |
G92XWMOvhmMdnIWk | maths | definite-integration | properties-of-definite-integration | The solution for $$x$$ of the equation $$\int\limits_{\sqrt 2 }^x {{{dt} \over {t\sqrt {{t^2} - 1} }} = {\pi \over 2}} $$ is | [{"identifier": "A", "content": "$${{\\sqrt 3 } \\over 2}$$ "}, {"identifier": "B", "content": "$$2\\sqrt 2 $$ "}, {"identifier": "C", "content": "$$2$$ "}, {"identifier": "D", "content": "None "}] | ["D"] | null | $$\int_{\sqrt 2 }^x {{{dt} \over {t\sqrt {{t^2} - 1} }}} = {\pi \over 2}$$
<br><br>$$\therefore$$ $$\left[ {{{\sec }^{ - 1}}t} \right]_{\sqrt 2 }^x = {\pi \over 2}$$
<br><br>$$\left[ {} \right.$$ As $$\int {{{dx} \over {x\sqrt {{x^2} - 1} }}} = {\sec ^{ - 1}}x$$ $$\left. {} \right]$$
<br><br>$$ \Rightarrow {\sec ^... | mcq | aieee-2007 | 5,597 |
mzirftcb0gLb9BvX | maths | definite-integration | properties-of-definite-integration | Let $$I = \int\limits_0^1 {{{\sin x} \over {\sqrt x }}dx} $$ and $$J = \int\limits_0^1 {{{\cos x} \over {\sqrt x }}dx} .$$ Then which one of the following is true? | [{"identifier": "A", "content": "$$1 > {2 \\over 3}$$ and $$J > 2$$ "}, {"identifier": "B", "content": "$$1 < {2 \\over 3}$$ and $$J < 2$$ "}, {"identifier": "C", "content": "$$1 < {2 \\over 3}$$ and $$J > 2$$ "}, {"identifier": "D", "content": "$$1 > {2 \\over 3}$$ and $$J < 2$$ "}] | ["B"] | null | We know that $${{\sin x} \over x} < 1,$$ for $$x \in \left( {0,1} \right)$$
<br><br>$$ \Rightarrow {{\sin x} \over {\sqrt x }} < \sqrt x $$ on $$x \in \left( {0,1} \right)$$
<br><br>$$ \Rightarrow \int\limits_0^1 {{{\sin x} \over {\sqrt x }}dx < \int\limits_0^1 {\sqrt x dx} = \left[ {{{2{x^{3/2}}} \over 3}} \... | mcq | aieee-2007 | 5,598 |
T2DpS7dxrPgx0DCQ | maths | definite-integration | properties-of-definite-integration | Let $$F\left( x \right) = f\left( x \right) + f\left( {{1 \over x}} \right),$$ where $$f\left( x \right) = \int\limits_l^x {{{\log t} \over {1 + t}}dt,} $$ Then $$F(e)$$ equals | [{"identifier": "A", "content": "$$1$$"}, {"identifier": "B", "content": "$$2$$"}, {"identifier": "C", "content": "$$1/2$$ "}, {"identifier": "D", "content": "$$0$$"}] | ["C"] | null | Given $$f\left( x \right) = f\left( x \right) + f\left( {{1 \over x}} \right),$$
<br><br>where $$f\left( x \right) = \int_1^x {{{\log \,t} \over {1 + t}}} \,dt$$
<br><br>$$\therefore$$ $$F\left( e \right) = f\left( e \right) + f\left( {{1 \over e}} \right)$$
<br><br>$$ \Rightarrow F\left( e \right)$$
<br><br>$$ = \int... | mcq | aieee-2007 | 5,599 |
qzGZ9MQkHcseTyc4 | maths | definite-integration | properties-of-definite-integration | $$\int\limits_0^\pi {\left[ {\cot x} \right]dx,} $$ where $$\left[ . \right]$$ denotes the greatest integer function, is equal to: | [{"identifier": "A", "content": "$$1$$"}, {"identifier": "B", "content": "$$-1$$ "}, {"identifier": "C", "content": "$$ - {\\pi \\over 2}$$ "}, {"identifier": "D", "content": "$$ {\\pi \\over 2}$$"}] | ["C"] | null | Let $$I = \int_0^\pi {\left[ {\cot x} \right]dx\,\,\,\,\,\,...\left( 1 \right)} $$
<br><br>$$ = \int_0^\pi {\left[ {\cot \left( {\pi - x} \right)} \right]} dx$$
<br><br>$$ = \int_0^\pi {\left[ { - \cot x} \right]dx\,\,\,\,\,\,...\left( 2 \right)} $$
<br><br>Adding two values of $$I$$ in $$e{q^n}s\left( 1 \right)\,\... | mcq | aieee-2009 | 5,600 |
vm6dQ1l0S3JOzXyO | maths | definite-integration | properties-of-definite-integration | Let $$p(x)$$ be a function defined on $$R$$ such that $$p'(x)=p'(1-x),$$ for all $$x \in \left[ {0,1} \right],p\left( 0 \right) = 1$$ and $$p(1)=41.$$ Then $$\int\limits_0^1 {p\left( x \right)dx} $$ equals : | [{"identifier": "A", "content": "$$21$$"}, {"identifier": "B", "content": "$$41$$ "}, {"identifier": "C", "content": "$$42$$ "}, {"identifier": "D", "content": "$$\\sqrt {41} $$ "}] | ["A"] | null | $$p'\left( x \right) = p'\left( {1 - x} \right)$$
<br><br>$$ \Rightarrow p\left( x \right) = - p\left( {1 - x} \right) + c$$
<br><br>at $$x=0$$
<br><br>$$p\left( 0 \right) = - p\left( 1 \right) + c \Rightarrow 42 = c$$
<br><br>Now, $$p\left( x \right) = - p\left( {1 - x} \right) + 42$$
<br><br>$$ \Rightarrow p\lef... | mcq | aieee-2010 | 5,601 |
vJfDoRzgVdTiREgH | maths | definite-integration | properties-of-definite-integration | The value of $$\int\limits_0^1 {{{8\log \left( {1 + x} \right)} \over {1 + {x^2}}}} dx$$ is | [{"identifier": "A", "content": "$${\\pi \\over 8}\\log 2$$ "}, {"identifier": "B", "content": "$${\\pi \\over 2}\\log 2$$"}, {"identifier": "C", "content": "$$\\log 2$$ "}, {"identifier": "D", "content": "$$\\pi \\log 2$$ "}] | ["D"] | null | $$I = \int\limits_0^1 {{{8\log \left( {1 + x} \right)} \over {1 + {x^2}}}} dx$$
<br><br>put $$x = \tan \,\theta ,$$
<br><br>$$\therefore$$ $${{dx} \over {d\theta }} = {\sec ^2}\theta \Rightarrow dx = {\sec ^2}\theta d\theta $$
<br><br>$$\therefore$$ $$I = 8\int\limits_0^{\pi /4} {{{\log \left( {1 + \tan \theta } \rig... | mcq | aieee-2011 | 5,602 |
zUWPh9e7UZjwhvpd | maths | definite-integration | properties-of-definite-integration | If $$g\left( x \right) = \int\limits_0^x {\cos 4t\,dt,} $$ then $$g\left( {x + \pi } \right)$$ equals | [{"identifier": "A", "content": "$${{g\\left( x \\right)} \\over {8\\left( \\pi \\right)}}$$ "}, {"identifier": "B", "content": "$$g\\left( x \\right) + g\\left( \\pi \\right)$$ "}, {"identifier": "C", "content": "$$g\\left( x \\right) - g\\left( \\pi \\right)$$"}, {"identifier": "D", "content": "$$g\\left( x \\righ... | null | null | $$\left( {b,c} \right)g\left( {x + \pi } \right) = \int\limits_0^{x + \pi } {\cos \,4t\,dt} $$
<br><br>$$ = \int\limits_0^\pi {\cos 4tdt + \int\limits_\pi ^{\pi + x} {\cos 4t\,dt} } $$
<br><br>$$ = g\left( \pi \right) + \int\limits_0^x {\cos \,4t\,dt} $$
<br><br>Putting $$t = \pi + y$$ in second integral, we get ... | mcqm | aieee-2012 | 5,603 |
ntDZ2U0Brhjp26Vh | maths | definite-integration | properties-of-definite-integration | <b>Statement-1 :</b> The value of the integral
<br/>$$\int\limits_{\pi /6}^{\pi /3} {{{dx} \over {1 + \sqrt {\tan \,x} }}} $$ is equal to $$\pi /6$$
<p><b>Statement-2 :</b> $$\int\limits_a^b {f\left( x \right)} dx = \int\limits_a^b {f\left( {a + b - x} \right)} dx.$$</p> | [{"identifier": "A", "content": "Statement-1 is true, Statement-2 is true; Statement-2 is a correct explanation for Statement-1."}, {"identifier": "B", "content": "Statement-1 is true, Statement-2 is true; Statement-2 is not a correct explanation for Statement-1."}, {"identifier": "C", "content": "Statement- 1 is true;... | ["D"] | null | Let $$I = \int\limits_{\pi /6}^{\pi /3} {{{dx} \over {1 + \sqrt {\tan \,x} }}} $$
<br><br>$$ = \int\limits_{\pi /6}^{\pi /3} {{{dx} \over {\sqrt {\tan \left( {{\pi \over 2} - x} \right)} }}} $$
<br><br>$$ = \int\limits_{\pi /6}^{\pi /3} {{{\sqrt {\tan \,x} \,dx} \over {1 + \sqrt {\tan \,x} }}} \,\,\,\,\,\,\,\,\,\,\,\,... | mcq | jee-main-2013-offline | 5,604 |
4BKFMfmAUvUVke3R | maths | definite-integration | properties-of-definite-integration | The integral $$\int\limits_0^\pi {\sqrt {1 + 4{{\sin }^2}{x \over 2} - 4\sin {x \over 2}{\mkern 1mu} } } dx$$ equals: | [{"identifier": "A", "content": "$$4\\sqrt 3 - 4$$ "}, {"identifier": "B", "content": "$$4\\sqrt 3 - 4 - {\\pi \\over 3}$$ "}, {"identifier": "C", "content": "$$\\pi - 4$$ "}, {"identifier": "D", "content": "$${{2\\pi } \\over 3} - 4 - 4\\sqrt 3 $$ "}] | ["B"] | null | Let $$I = \int\limits_0^\pi {\sqrt {1 + 4{{\sin }^2}{x \over 2} - 4\sin {x \over 2}} } dx$$
<br><br>$$ = \int\limits_0^\pi {\left| {2\sin {x \over 2} - 1} \right|} dx$$
<br><br>$$ = \int\limits_0^{\pi /3} {\left( {1 - 2\sin {x \over 2}} \right)} dx + \int\limits_{\pi /3}^\pi {\left( {2\sin {x \over 2} - 1} \right)} ... | mcq | jee-main-2014-offline | 5,605 |
t8g0J8Q5j5Uqh3wN | maths | definite-integration | properties-of-definite-integration | The integral
<br/>$$\int\limits_2^4 {{{\log \,{x^2}} \over {\log {x^2} + \log \left( {36 - 12x + {x^2}} \right)}}dx} $$ is equal to : | [{"identifier": "A", "content": "$$1$$"}, {"identifier": "B", "content": "$$6$$"}, {"identifier": "C", "content": "$$2$$"}, {"identifier": "D", "content": "$$4$$"}] | ["A"] | null | $$I = \int\limits_2^4 {{{\log {x^2}} \over {\log {x^2} + \log \left( {36 - 12x + {x^2}} \right)}}} $$
<br><br>$$I = \int\limits_2^4 {{{\log {x^2}} \over {\log {x^2} + \log {{\left( {6 - x} \right)}^2}}}} \,\,\,\,\,\,\,\,\,\,...\left( i \right)$$
<br><br>$$I = \int\limits_2^4 {{{\log {{\left( {6 - x} \right)}^2}} \over ... | mcq | jee-main-2015-offline | 5,606 |
m9JhdOqShTaju1uZ4jGNd | maths | definite-integration | properties-of-definite-integration | The value of the integral
<br/><br/>$$\int\limits_4^{10} {{{\left[ {{x^2}} \right]dx} \over {\left[ {{x^2} - 28x + 196} \right] + \left[ {{x^2}} \right]}}} ,$$
<br/><br/>where [x] denotes the greatest integer less than or
equal to x, is : | [{"identifier": "A", "content": "6"}, {"identifier": "B", "content": "3"}, {"identifier": "C", "content": "7"}, {"identifier": "D", "content": "$${1 \\over 3}$$ "}] | ["B"] | null | Let I = $$\int\limits_4^{10} {{{\left[ {{x^2}} \right]\,dx} \over {\left[ {{x^2} - 28x + 196} \right] + \left[ {{x^2}} \right]}}} $$
<br><br> = $$\int\limits_4^{10} {{{\left[ {{x^2}} \right]dx} \over {\left[ {{{\left( {x - 14} \right)}^2}} \right] + \left[ {{x... | mcq | jee-main-2016-online-10th-april-morning-slot | 5,607 |
5PeyGagsIrrEEA35wifL0 | maths | definite-integration | properties-of-definite-integration | If $$2\int\limits_0^1 {{{\tan }^{ - 1}}xdx = \int\limits_0^1 {{{\cot }^{ - 1}}} } \left( {1 - x + {x^2}} \right)dx,$$
<br/><br/>then $$\int\limits_0^1 {{{\tan }^{ - 1}}} \left( {1 - x + {x^2}} \right)dx$$ is equalto : | [{"identifier": "A", "content": "log4"}, {"identifier": "B", "content": "$${\\pi \\over 2}$$ + log2"}, {"identifier": "C", "content": "log2"}, {"identifier": "D", "content": "$${\\pi \\over 2}$$ $$-$$ log4"}] | ["C"] | null | Given,
<br><br>$$2\int\limits_0^1 {{{\tan }^{ - {1_x}\,{d_x}}}} = \int\limits_0^1 {{{\cot }^{ - 1}}} \left( {1 - x + {x^2}} \right)dx$$
<br><br>= $$\int\limits_0^1 {\left( {{\pi \over 2} - {{\tan }^{ - 1}}\left( {1 - x + {x^2}} \right)} \right)} dx$$
<br><br>$$ \Rightarrow $$$$\,\,\,$$$$2\int\limits_0^1 {{... | mcq | jee-main-2016-online-9th-april-morning-slot | 5,608 |
HG6YBLywBgnrD491MxStk | maths | definite-integration | properties-of-definite-integration | The integral $$\int_{{\pi \over {12}}}^{{\pi \over 4}} {\,\,{{8\cos 2x} \over {{{\left( {\tan x + \cot x} \right)}^3}}}} \,dx$$ equals : | [{"identifier": "A", "content": "$${{15} \\over {128}}$$"}, {"identifier": "B", "content": "$${{15} \\over {64}}$$"}, {"identifier": "C", "content": "$${{13} \\over {32}}$$"}, {"identifier": "D", "content": "$${{13} \\over {256}}$$"}] | ["A"] | null | tan x + cot x
<br><br>= $${{\sin x} \over {\cos x}}$$ + $${{\cos x} \over {\sin x}}$$
<br><br>= $${{{{\sin }^2}x + {{\cos }^2}x} \over {\sin x\,\,\cos x}}$$
<br><br>= $${1 \over {\sin x\,\,\cos x}}$$
<br><br>= $${2 \over {\sin 2x}}$$
<br><br>$$\therefore\,\,\,$$ $$\int\limits_{{\pi \over {12}}}^{{\pi \ove... | mcq | jee-main-2017-online-8th-april-morning-slot | 5,609 |
43iXG9zjRuTrzgRtZqrQT | maths | definite-integration | properties-of-definite-integration | If $$\int\limits_1^2 {{{dx} \over {{{\left( {{x^2} - 2x + 4} \right)}^{{3 \over 2}}}}}} = {k \over {k + 5}},$$ then k is equal to : | [{"identifier": "A", "content": "1"}, {"identifier": "B", "content": "2"}, {"identifier": "C", "content": "3"}, {"identifier": "D", "content": "4"}] | ["A"] | null | Given, I = $$\int\limits_1^2 {{{dx} \over {{{\left( {{x^2} - 2x + 4} \right)}^{{3 \over 2}}}}}} $$
<br><br>= $$\int\limits_1^2 {{{dx} \over {{{\left[ {{{\left( {x - 1} \right)}^2} + 3} \right]}^{{3 \over 2}}}}}} $$
<br><br>Let x $$-$$ 1 = $$\sqrt 3 $$ tan$$\theta $$
<br><br>$$ \Rightarrow $$$$\,\,\,$$ dx = $$\sqrt 3 $$... | mcq | jee-main-2017-online-9th-april-morning-slot | 5,610 |
q5elwpzUgF4Mve5d | maths | definite-integration | properties-of-definite-integration | The integral $$\int\limits_{{\pi \over 4}}^{{{3\pi } \over 4}} {{{dx} \over {1 + \cos x}}} $$ is equal to | [{"identifier": "A", "content": "2"}, {"identifier": "B", "content": "4"}, {"identifier": "C", "content": "$$-$$ 1"}, {"identifier": "D", "content": "$$-$$ 2"}] | ["A"] | null | $$\int\limits_{{\pi \over 4}}^{{{3\pi } \over 4}} {{{dx} \over {1 + \cos x}}} $$
<br><br>= $$\int\limits_{{\pi \over 4}}^{{{3\pi } \over 4}} {{{dx} \over {2{{\cos }^2}{x \over 2}}}} $$
<br><br>= $${1 \over 2}\int\limits_{{\pi \over 4}}^{{{3\pi } \over 4}} {{{\sec }^2}} {x \over 2}\,dx$$
<br><br>$${1 \over 2}\left[ ... | mcq | jee-main-2017-offline | 5,611 |
lmtomciSwqh47mDgXTMln | maths | definite-integration | properties-of-definite-integration | If $$f(x) = \int\limits_0^x {t\left( {\sin x - \sin t} \right)dt\,\,\,} $$ then : | [{"identifier": "A", "content": "f'''(x) + f''(x) = sinx"}, {"identifier": "B", "content": "f'''(x) + f''(x) $$-$$ f'(x) = cosx"}, {"identifier": "C", "content": "f'''(x) + f'(x) = cosx $$-$$ 2x sinx"}, {"identifier": "D", "content": "f'''(x) $$-$$ f''(x) = cosx $$-$$ 2x sinx"}] | ["D"] | null | f(x) = $$\int_0^x {t(\sin x - \sin t).dt} $$
<br><br>= sin x$$\int_0^x {t.dt - \int_0^x {t\sin t.dt} } $$
<br><br>= $${{{x^2}} \over 2}$$ sin x +$$\left[ {t\cos t} \right]_0^x$$ + sin x
<br><br>$$ \Rightarrow $$f(x) = $${{{x^2}} \over 2}$$ sinx + xcosx + sinx
<br><br>f'(x) = $${{{x^2}} \over 2}$$ cosx + 2cos x
<br><br>... | mcq | jee-main-2018-online-16th-april-morning-slot | 5,612 |
18LtmLb3I2TL8sFD | maths | definite-integration | properties-of-definite-integration | The value of $$\int\limits_{ - \pi /2}^{\pi /2} {{{{{\sin }^2}x} \over {1 + {2^x}}}} dx$$ is | [{"identifier": "A", "content": "$${\\pi \\over 4}$$"}, {"identifier": "B", "content": "$${\\pi \\over 8}$$"}, {"identifier": "C", "content": "$${\\pi \\over 2}$$"}, {"identifier": "D", "content": "$${4\\pi }$$"}] | ["A"] | null | As we know,
<br><br>$$\int\limits_a^b { + \left( x \right)dx} = \int\limits_a^b {f\left( {a + b - x} \right)} dx$$
<br><br>Let $$I = \int\limits_{ - {\pi \over 2}}^{{\pi \over 2}} {\,\,{{{{\sin }^2}x} \over {1 + {2^x}}}} \,dx$$
<br><br>$$ \Rightarrow \,\,\,\,I = \int\limits_{ - {\pi \over 2}}^{{\pi \over 2}} {\,\... | mcq | jee-main-2018-offline | 5,613 |
sDlJBQ4AqBdys5neBbBT4 | maths | definite-integration | properties-of-definite-integration | The value of integral $$\int_{{\pi \over 4}}^{{{3\pi } \over 4}} {{x \over {1 + \sin x}}dx} $$ is : | [{"identifier": "A", "content": "$$\\pi \\sqrt 2 $$ "}, {"identifier": "B", "content": "$$\\pi \\left( {\\sqrt 2 - 1} \\right)$$"}, {"identifier": "C", "content": "$${\\pi \\over 2}\\left( {\\sqrt 2 + 1} \\right)$$"}, {"identifier": "D", "content": "$$2\\pi \\left( {\\sqrt 2 - 1} \\right)$$"}] | ["B"] | null | Let $$I = \int_{{\pi \over 4}}^{{{3\pi } \over 4}} {{x \over {1 + \sin x}}dx} $$
<br><br>also let K = $${x \over {1 + \sin x}}$$
<br><br>Multiplying numerator and denominator by
<br>(1 $$-$$ sin x) we get;
<br><br>$$K = {{x\left( {1 - \sin x} \right)} \over {1 - {{\left( {\sin x} \right)}^2}}} = {{x(1 - \sin x)... | mcq | jee-main-2018-online-15th-april-evening-slot | 5,614 |
bzr1Kmi7SeJ5VlDhpuDlx | maths | definite-integration | properties-of-definite-integration | If $${I_1} = \int_0^1 {{e^{ - x}}} {\cos ^2}x{\mkern 1mu} dx;$$
<br/><br/> $${I_2} = \int_0^1 {{e^{ - {x^2}}}} {\cos ^2}x{\mkern 1mu} dx$$ and
<br/><br/>$${I_3} = \int_0^1 {{e^{ - {x^3}}}} dx;$$ then | [{"identifier": "A", "content": "I<sub>2</sub> > I<sub>3</sub> > I<sub>1</sub>"}, {"identifier": "B", "content": "I<sub>2</sub> > I<sub>1</sub> > I<sub>3</sub>"}, {"identifier": "C", "content": "I<sub>3</sub> > I<sub>2</sub> > I<s... | ["C"] | null | Given,
<br><br>$${I_1} = \int_0^1 {{e^{ - x}}} {\cos ^2}x{\mkern 1mu} dx;$$
<br><br>$${I_2} = \int_0^1 {{e^{ - {x^2}}}} {\cos ^2}x{\mkern 1mu} dx$$ and
<br><br>$${I_3} = \int_0^1 {{e^{ - {x^3}}}} dx$$
<br><br>For x $$ \in $$ (0, 1)
<br><br>$$ \Rightarrow $$ x > x<sup>2</sup> or $$-$$ x < $$-$$ x<sup>2... | mcq | jee-main-2018-online-15th-april-evening-slot | 5,616 |
maAWrFq0m2nmYcAJtZ3rsa0w2w9jx5cfz6r | maths | definite-integration | properties-of-definite-integration | If $$\int\limits_0^{{\pi \over 2}} {{{\cot x} \over {\cot x + \cos ecx}}} dx$$ = m($$\pi $$ + n), then m.n is equal to | [{"identifier": "A", "content": "- 1"}, {"identifier": "B", "content": "1"}, {"identifier": "C", "content": "$$ - {1 \\over 2}$$"}, {"identifier": "D", "content": "$${1 \\over 2}$$"}] | ["A"] | null | $$\int\limits_0^{\pi /2} {{{\cot x} \over {\cot x + {\mathop{\rm cosec}\nolimits} \,x}}dx = } \int\limits_0^{\pi /2} {{{\cos x} \over {\cos x + 1}}dx} $$<br><br>
$$ \Rightarrow \int\limits_0^{\pi /2} {{{2{{\cos }^2}{x \over 2} - 1} \over {2{{\cos }^2}{x \over 2}}}dx = } \int\limits_0^{\pi /2} {\left( {1 - {1 \over 2}{{... | mcq | jee-main-2019-online-12th-april-morning-slot | 5,619 |
Ve0Btsv6GeVJ9Ug36y3rsa0w2w9jx25p121 | maths | definite-integration | properties-of-definite-integration | The integral $$\int\limits_{\pi /6}^{\pi /3} {{{\sec }^{2/3}}} x\cos e{c^{4/3}}xdx$$ is equal to : | [{"identifier": "A", "content": "$${3^{{5 \\over 3}}} - {3^{{1 \\over 3}}}$$"}, {"identifier": "B", "content": "$${3^{{5 \\over 6}}} - {3^{{2 \\over 3}}}$$"}, {"identifier": "C", "content": "$${3^{{4 \\over 3}}} - {3^{{1 \\over 3}}}$$"}, {"identifier": "D", "content": "$${3^{{7 \\over 6}}} - {3^{{5 \\over 6}}}$$"}] | ["D"] | null | $$\int\limits_{\pi /6}^{\pi /3} {{{\sec }^{2/3}}x\,{{{\mathop{\rm cosec}\nolimits} }^{4/3}}x\,dx} $$<br><br>
$$ = \int {{{{{\sec }^2}x} \over {{{\tan }^{4/3}}x}}dx} $$<br><br>
Let tan x = t, sec<sup>2</sup> x dx = dt<br><br>
$$ = \int {{{dt} \over {{t^{4/3}}}}} $$<br><br>
$$I = - 3\left( {{t^{ - 1/3}}} \right)$$<br><b... | mcq | jee-main-2019-online-10th-april-evening-slot | 5,620 |
g1HvVGGm3HmxOOwDTB3rsa0w2w9jwxzkfe2 | maths | definite-integration | properties-of-definite-integration | The value of $$\int\limits_0^{2\pi } {\left[ {\sin 2x\left( {1 + \cos 3x} \right)} \right]} dx$$,
<br/>where [t] denotes the greatest integer function is : | [{"identifier": "A", "content": "2$$\\pi $$"}, {"identifier": "B", "content": "$$\\pi $$"}, {"identifier": "C", "content": "-2$$\\pi $$"}, {"identifier": "D", "content": "-$$\\pi $$"}] | ["D"] | null | $$I = \int\limits_0^{2\pi } {\left[ {\sin 2x(1 + \cos 3x)} \right]} dx$$ .... (i)<br><br>
$$ \therefore\int\limits_0^a {f(x)} = \int\limits_0^a {f(a - x)} dx$$<br><br>
$$ \because I = \int\limits_0^{2\pi } {\left[ { - \sin 2x(1 + \cos 3x)} \right]} dx$$<br><br>
By (i) + (ii)<br><br>
$$ \Rightarrow 2I = \int\limits_0^{... | mcq | jee-main-2019-online-10th-april-morning-slot | 5,621 |
AZI26JLdbb4NGYwieCd4T | maths | definite-integration | properties-of-definite-integration | The value of $$\int\limits_0^{\pi /2} {{{{{\sin }^3}x} \over {\sin x + \cos x}}dx} $$ is | [{"identifier": "A", "content": "$${{\\pi - 2} \\over 8}$$"}, {"identifier": "B", "content": "$${{\\pi - 2} \\over 4}$$"}, {"identifier": "C", "content": "$${{\\pi - 1} \\over 2}$$"}, {"identifier": "D", "content": "$${{\\pi - 1} \\over 4}$$"}] | ["D"] | null | I = $$\int\limits_0^{\pi /2} {{{{{\sin }^3}x} \over {\sin x + \cos x}}dx} $$ .....(1)
<br><br>$$ \Rightarrow $$ I = $$\int\limits_0^{{\pi \over 2}} {{{{{\cos }^3}x} \over {\sin x + \cos x}}} dx$$ ......(2)
<br><br>Adding those two
<br><br>2I = $$\int\limits_0^{{\pi \over 2}} {{{si{n^3}x + {{\cos }^3}x} \over {\sin x ... | mcq | jee-main-2019-online-9th-april-morning-slot | 5,623 |
6w5HWVsQQcJWqT6LDMHjl | maths | definite-integration | properties-of-definite-integration | If $$f(x) = {{2 - x\cos x} \over {2 + x\cos x}}$$ and g(x) = log<sub>e</sub>x, (x > 0) then
the value of integral<br/><br/> $$\int\limits_{ - {\pi \over 4}}^{{\pi \over 4}} {g\left( {f\left( x \right)} \right)dx{\rm{ }}} $$ is | [{"identifier": "A", "content": "log<sub>e</sub>3"}, {"identifier": "B", "content": "log<sub>e</sub>2"}, {"identifier": "C", "content": "log<sub>e</sub>1"}, {"identifier": "D", "content": "log<sub>e</sub>e"}] | ["C"] | null | $$g\left( {f\left( x \right)} \right)$$ = $$\ln \left( {f\left( x \right)} \right)$$ = $$\ln \left( {{{2 - x\cos x} \over {2 + x\cos x}}} \right)$$
<br><br>$$ \therefore $$ I = $$\int\limits_{ - {\pi \over 4}}^{{\pi \over 4}} {\ln \left( {{{2 - x\cos x} \over {2 + x\cos x}}} \right)dx} $$
<br><br>( Using property $$\... | mcq | jee-main-2019-online-8th-april-morning-slot | 5,624 |
WJSwZSmnDltFY0gKeEQW0 | maths | definite-integration | properties-of-definite-integration | Let f and g be continuous functions on [0, a] such that f(x) = f(a – x) and g(x) + g(a – x) = 4, then $$\int\limits_0^a \, $$f(x) g(x) dx is equal to : | [{"identifier": "A", "content": "4$$\\int\\limits_0^a \\, $$f(x)dx"}, {"identifier": "B", "content": "$$-$$ 3$$\\int\\limits_0^a \\, $$f(x)dx"}, {"identifier": "C", "content": "$$\\int\\limits_0^a \\, $$f(x)dx"}, {"identifier": "D", "content": "2$$\\int\\limits_0^a \\, $$f(x)dx"}] | ["D"] | null | $${\rm I} = \int_0^a {f\left( x \right)g\left( x \right)dx} $$
<br><br>$${\rm I} = \int_0^a {f\left( {a - x} \right)g\left( {a - x} \right)dx} $$
<br><br>$${\rm I} = \int_0^a {f\left( x \right)\left( {4 - g\left( x \right.} \right)dx} $$
<br><br>$${\rm I} = 4\int_0^a {f\left( x \right)dx - {\rm I}} $$
<br><br>$$ \Right... | mcq | jee-main-2019-online-12th-january-morning-slot | 5,625 |
vnub8GmPI1I4MyT3bDdFj | maths | definite-integration | properties-of-definite-integration | The integral $$\int\limits_{\pi /6}^{\pi /4} {{{dx} \over {\sin 2x\left( {{{\tan }^5}x + {{\cot }^5}x} \right)}}} $$ equals : | [{"identifier": "A", "content": "$${\\pi \\over {40}}$$"}, {"identifier": "B", "content": "$${1 \\over {20}}{\\tan ^{ - 1}}\\left( {{1 \\over {9\\sqrt 3 }}} \\right)$$"}, {"identifier": "C", "content": "$${1 \\over {10}}\\left( {{\\pi \\over 4} - {{\\tan }^{ - 1}}\\left( {{1 \\over {9\\sqrt 3 }}} \\right)} \\right)$$... | ["C"] | null | I $$=$$ $$\int\limits_{\pi /6}^{\pi /4} {{{dx} \over {\sin 2x\left( {{{\tan }^5}x + {{\cot }^5}x} \right)}}} $$
<br><br>$${\rm I} = {1 \over 2}\int\limits_{\pi /6}^{\pi /4} {{{{{\tan }^4}x{{\sec }^2}xdx} \over {\left( {1 + {{\tan }^{10}}x} \right)}}} $$ Put tan<sup>5</sup>x $$=$$ t
<br><br>$${\rm I} = ... | mcq | jee-main-2019-online-11th-january-evening-slot | 5,626 |
cSvyruRIVbuUj4gZhH0nC | maths | definite-integration | properties-of-definite-integration | The value of the integral $$\int\limits_{ - 2}^2 {{{{{\sin }^2}x} \over { \left[ {{x \over \pi }} \right] + {1 \over 2}}}} \,dx$$ (where [x] denotes the greatest integer less than or equal to x) is | [{"identifier": "A", "content": "0"}, {"identifier": "B", "content": "4"}, {"identifier": "C", "content": "4$$-$$ sin 4"}, {"identifier": "D", "content": "sin 4"}] | ["A"] | null | I $$=$$ $$\int\limits_{ - 2}^2 {{{{{\sin }^2}x} \over { \left[ {{x \over \pi }} \right] + {1 \over 2}}}} \,dx$$
<br><br>$${\rm I} = \int\limits_0^2 {\left( {{{{{\sin }^2}x} \over {\left[ {{x \over \pi }} \right] + {1 \over 2}}} + {{{{\sin }^2}\left( { - x} \right)} \over {\left[ { - {x \over \pi }} \right] + {1 \over 2... | mcq | jee-main-2019-online-11th-january-morning-slot | 5,627 |
ZtWfcgjHBtokIgHrSu7d4 | maths | definite-integration | properties-of-definite-integration | The value of $$\int\limits_{ - \pi /2}^{\pi /2} {{{dx} \over {\left[ x \right] + \left[ {\sin x} \right] + 4}}} ,$$ where [t] denotes the greatest integer less than or equal to t, is | [{"identifier": "A", "content": "$${1 \\over {12}}\\left( {7\\pi - 5} \\right)$$"}, {"identifier": "B", "content": "$${1 \\over {12}}\\left( {7\\pi + 5} \\right)$$"}, {"identifier": "C", "content": "$${3 \\over {10}}\\left( {4\\pi - 3} \\right)$$"}, {"identifier": "D", "content": "$${3 \\over {20}}\\left( {4\\pi - ... | ["D"] | null | $${\rm I} = \int\limits_{{{ - \pi } \over 2}}^{{\pi \over 2}} {{{dx} \over {\left[ x \right] + \left[ {\sin x} \right] + 4}}} $$
<br><br>$$ = \int\limits_{{{ - \pi } \over 2}}^{ - 1} {{{dx} \over { - 2 - 1 + 4}}} + \int\limits_{ - 1}^0 {{{dx} \over { - 1 - 1 + 4}}} $$
<br><br>$$\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\, + \i... | mcq | jee-main-2019-online-10th-january-evening-slot | 5,628 |
ZEOwvZM6M2qrjJ73t9XSz | maths | definite-integration | properties-of-definite-integration | Let $${\rm I} = \int\limits_a^b {\left( {{x^4} - 2{x^2}} \right)} dx.$$ If I is minimum then the ordered pair (a, b) is - | [{"identifier": "A", "content": "$$\\left( {\\sqrt 2 , - \\sqrt 2 } \\right)$$"}, {"identifier": "B", "content": "$$\\left( {0,\\sqrt 2 } \\right)$$"}, {"identifier": "C", "content": "$$\\left( { - \\sqrt 2 ,\\sqrt 2 } \\right)$$"}, {"identifier": "D", "content": "$$\\left( { - \\sqrt 2 ,0} \\right)$$"}] | ["C"] | null | Let f(x) = x<sup>2</sup><sup></sup>(x<sup>2</sup><sup></sup> $$-$$ 2)
<br><br><img src="https://res.cloudinary.com/dckxllbjy/image/upload/v1734266617/exam_images/eleslqkk6r7otnrfth9a.webp" style="max-width: 100%; height: auto;display: block;margin: 0 auto;" loading="lazy" alt="JEE Main 2019 (Online) 10th January Morni... | mcq | jee-main-2019-online-10th-january-morning-slot | 5,629 |
vbOxkVhe5Ag4Et5ukbMbS | maths | definite-integration | properties-of-definite-integration | If $$\int\limits_0^{{\pi \over 3}} {{{\tan \theta } \over {\sqrt {2k\,\sec \theta } }}} \,d\theta = 1 - {1 \over {\sqrt 2 }},\left( {k > 0} \right),$$ then value of k is : | [{"identifier": "A", "content": "4"}, {"identifier": "B", "content": "$${1 \\over 2}$$"}, {"identifier": "C", "content": "1"}, {"identifier": "D", "content": "2"}] | ["D"] | null | $$\int\limits_0^{{\pi \over 3}} {{{\tan \theta } \over {\sqrt {2k\,\sec \theta } }}} \,d\theta = 1 - {1 \over {\sqrt 2 }},\left( {k > 0} \right),$$
<br><br>$$ \Rightarrow \,\,\int\limits_0^{\pi /3} {{{\tan \theta } \over {\sqrt {2k\sec \theta } }}} \,d\theta = 1 - {1 \over {\sqrt 2 }}\left( {k > 0} \right)$$
... | mcq | jee-main-2019-online-9th-january-evening-slot | 5,630 |
S2eHDIbrxUdmooH9dWT9i | maths | definite-integration | properties-of-definite-integration | The value of $$\int\limits_0^\pi {{{\left| {\cos x} \right|}^3}} \,dx$$ is : | [{"identifier": "A", "content": "$$4 \\over 3$$"}, {"identifier": "B", "content": "$$-$$ $$4 \\over 3$$"}, {"identifier": "C", "content": "0"}, {"identifier": "D", "content": "$$2 \\over 3$$"}] | ["A"] | null | $$\int\limits_0^\pi {{{\left| {\cos x} \right|}^3}} \,dx$$
<br><br>The period of $$\left| {\cos x} \right|$$ = $${\pi \over 2}$$
<br><br>$$ \therefore $$ I = 2 $$\int\limits_0^{{\pi \over 2}} {{{\left| {\cos x} \right|}^3}} \,dx$$
<br><br>as in the range 0 to $${\pi \over 2}$$ $$\left| {\cos x} \right|... | mcq | jee-main-2019-online-9th-january-morning-slot | 5,631 |
Bi9Bsa02Lq6vcZ6XI5adz | maths | definite-integration | properties-of-definite-integration | The integral $$\int\limits_1^e {\left\{ {{{\left( {{x \over e}} \right)}^{2x}} - {{\left( {{e \over x}} \right)}^x}} \right\}} \,$$ log<sub>e</sub> x dx is equal to : | [{"identifier": "A", "content": "$$ - {1 \\over 2} + {1 \\over e} - {1 \\over {2{e^2}}}$$"}, {"identifier": "B", "content": "$${3 \\over 2} - e - {1 \\over {2{e^2}}}$$"}, {"identifier": "C", "content": "$${1 \\over 2} - e - {1 \\over {{e^2}}}$$"}, {"identifier": "D", "content": "$${3 \\over 2} - {1 \\over e} - {1 \\ove... | ["B"] | null | $$\int\limits_1^e {\left\{ {{{\left( {{x \over e}} \right)}^{2x}} - {{\left( {{e \over x}} \right)}^x}} \right\}} \,$$
<br><br>Let $${\left( {{x \over e}} \right)^{2x}} = t,{\left( {{e \over x}} \right)^x} = v$$
<br><br>$$ = {1 \over 2}\int\limits_{{{\left( {{1 \over e}} \right)}^2}}^1 {dt + \int\limits_e^1 ... | mcq | jee-main-2019-online-12th-january-evening-slot | 5,632 |
U4z6G7UL3Nk0YHsoqLjgy2xukf40epci | maths | definite-integration | properties-of-definite-integration | Suppose f(x) is a polynomial of degree four,
having critical points at –1, 0, 1. If
<br/>T = {x $$ \in $$ R |
f(x) = f(0)}, then the sum of squares of all the
elements of T is : | [{"identifier": "A", "content": "6"}, {"identifier": "B", "content": "2"}, {"identifier": "C", "content": "8"}, {"identifier": "D", "content": "4"}] | ["D"] | null | Critical points = $$ - $$1, 0, 1.<br><br>$$ \therefore $$ f'(x) = a(x $$ - $$ 1)(x + 1)x<br><br>$$ \therefore $$ f(x) = a$$\left( {{{{x^4}} \over 4} - {{{x^2}} \over 2}} \right) + C$$<br><br>$$ \because $$ f(x) = f(0)<br><br>$$ - a\left( {{{{x^4}} \over 4} - {{{x^2}} \over 2}} \right) + C = C$$<br><br>$$a{{{x^2}} \over... | mcq | jee-main-2020-online-3rd-september-evening-slot | 5,634 |
nbq0G4yuH6pBXiIQ7yjgy2xukf7gl39c | maths | definite-integration | properties-of-definite-integration | Let $$f(x) = \left| {x - 2} \right|$$ and g(x) = f(f(x)), $$x \in \left[ {0,4} \right]$$. Then <br/>$$\int\limits_0^3 {\left( {g(x) - f(x)} \right)} dx$$ is equal to: | [{"identifier": "A", "content": "1"}, {"identifier": "B", "content": "0"}, {"identifier": "C", "content": "$${1 \\over 2}$$"}, {"identifier": "D", "content": "$${3 \\over 2}$$"}] | ["A"] | null | $$f(x) = |x - 2|$$<br><br>$$ \therefore $$ $$f(f(x)) = \left| {|x - 2| - 2} \right| = g(x)$$<br><br>$$ \Rightarrow g(x) = \left| {|x - 2| - 2} \right| = \left\{ {\matrix{
{|x - 4|} & {if\,x \ge 2} \cr
{| - x|} & {if\,x < 2} \cr
} } \right.$$<br><br>$$ \therefore $$ $$\int\limits_0^3 {(g(x) - f(x)... | mcq | jee-main-2020-online-4th-september-morning-slot | 5,635 |
fCbDUKnetkr7Rql8k5jgy2xukfajri80 | maths | definite-integration | properties-of-definite-integration | The integral <br/>$$\int\limits_{{\pi \over 6}}^{{\pi \over 3}} {{{\tan }^3}x.{{\sin }^2}3x\left( {2{{\sec }^2}x.{{\sin }^2}3x + 3\tan x.\sin 6x} \right)dx} $$
<br/>is equal to: | [{"identifier": "A", "content": "$$ - {1 \\over {9}}$$"}, {"identifier": "B", "content": "$$ - {1 \\over {18}}$$"}, {"identifier": "C", "content": "$$ {7 \\over {18}}$$"}, {"identifier": "D", "content": "$${9 \\over 2}$$"}] | ["B"] | null | Given,
<br><br>I = $$\int\limits_{{\pi \over 6}}^{{\pi \over 3}} {{{\tan }^3}x.{{\sin }^2}3x\left( {2{{\sec }^2}x.{{\sin }^2}3x + 3\tan x.\sin 6x} \right)dx} $$
<br><br>$$I = \int\limits_{\pi /6}^{\pi /3} ({2.{{\tan }^3}} x{\sec ^2}x{\sin ^4}3x + 3{\tan ^4}x{\sin ^2}3x.\,2\sin 3xcos\,3x\,)dx$$<br><br>$$ = {1 \over 2}... | mcq | jee-main-2020-online-4th-september-evening-slot | 5,636 |
P3rIEyoJ27C0Cw6PThjgy2xukfaktyu2 | maths | definite-integration | properties-of-definite-integration | Let {x} and [x] denote the fractional part of x and <br/>the greatest integer $$ \le $$ x respectively of a real<br/> number x. If $$\int_0^n {\left\{ x \right\}dx} ,\int_0^n {\left[ x \right]dx} $$ and 10(n<sup>2</sup> – n), <br/>$$\left( {n \in N,n > 1} \right)$$ are three consecutive terms of a G.P., then n is e... | [] | null | 21 | $$\int\limits_0^n {\left\{ x \right\}} dx = n\int\limits_0^1 x dx = n\left( {{{{x^2}} \over 2}} \right)_0^1 = {n \over 2}$$
<br><br>[As period of {x} = 1]
<br><br>$$\int\limits_0^n {\left[ x \right]} dx = \int\limits_0^1 0 dx + \int\limits_1^2 1 dx + ... + \int\limits_{n - 1}^n {\left( {n - 1} \right)} dx$$
<br><br>= 1... | integer | jee-main-2020-online-4th-september-evening-slot | 5,637 |
QwXQqjMdV5LMiJiAdJ7k9k2k5hikkq5 | maths | definite-integration | properties-of-definite-integration | If $$I = \int\limits_1^2 {{{dx} \over {\sqrt {2{x^3} - 9{x^2} + 12x + 4} }}} $$, then : | [{"identifier": "A", "content": "$${1 \\over 16} < {I^2} < {1 \\over 9}$$"}, {"identifier": "B", "content": "$${1 \\over 8} < {I^2} < {1 \\over 4}$$"}, {"identifier": "C", "content": "$${1 \\over 9} < {I^2} < {1 \\over 8}$$"}, {"identifier": "D", "content": "$${1 \\over 6} < {I^2} < {1 \\over 2}... | ["C"] | null | Let f(x) = $${1 \over {\sqrt {2{x^3} - 9{x^2} + 12x + 4} }}$$
<br><br>f'(x) = $$ - {1 \over 2}{{ - 6{x^2} - 18x + 12} \over {2{{\left( {2{x^3} - 9{x^2} + 12x + 4} \right)}^{3/2}}}}$$
<br><br>= $${{ - 6\left( {x - 1} \right)\left( {x - 2} \right)} \over {2{{\left( {2{x^3} - 9{x^2} + 12x + 4} \right)}^{3/2}}}}$$
<br><br>... | mcq | jee-main-2020-online-8th-january-evening-slot | 5,638 |
ojZlauFkWetuotMrqmjgy2xukfg7467a | maths | definite-integration | properties-of-definite-integration | The value of $$\int\limits_{{{ - \pi } \over 2}}^{{\pi \over 2}} {{1 \over {1 + {e^{\sin x}}}}dx} $$ is: | [{"identifier": "A", "content": "$$\\pi $$"}, {"identifier": "B", "content": "$${{3\\pi \\over 2}}$$"}, {"identifier": "C", "content": "$${{\\pi \\over 2}}$$"}, {"identifier": "D", "content": "$${{\\pi \\over 4}}$$"}] | ["C"] | null | I = $$\int\limits_{{{ - \pi } \over 2}}^{{\pi \over 2}} {{1 \over {1 + {e^{\sin x}}}}dx} $$ ....(1)
<br><br>Replacing x with $$\left( {{\pi \over 2} - {\pi \over 2} + x} \right)$$, we get
<br><br>I = $$\int\limits_{ - {\pi \over 2}}^{{\pi \over 2}} {{{dx} \over {1 + {e^{ - \sin x}}}}} $$
<br><br>= $$\int\limits_{ ... | mcq | jee-main-2020-online-5th-september-morning-slot | 5,639 |
r9KdaZAY4B8jIk7oltjgy2xukezfrqar | maths | definite-integration | properties-of-definite-integration | Let [t] denote the greatest integer less than or
equal to t. <br/>Then the value of $$\int\limits_1^2 {\left| {2x - \left[ {3x} \right]} \right|dx} $$ is ______. | [] | null | 1 | $$\int\limits_1^2 {\left| {2x - \left[ {3x} \right]} \right|dx} $$ <br><br>
$$ = \int\limits_1^2 {\left| {2x - \left( {3x - \left\{ {3x} \right\}} \right)} \right|dx} $$<br><br>
$$ = \int\limits_1^2 {\left| {\left\{ {3x} \right\} - x} \right|dx} $$<br><br>
We know, 0 $$ \le $$ $$\left\{ {3x} \right\} < 1$$ and x >... | integer | jee-main-2020-online-2nd-september-evening-slot | 5,642 |
9sxJlaYOooElkHjpOCjgy2xukf0q9pa8 | maths | definite-integration | properties-of-definite-integration | $$\int\limits_{ - \pi }^\pi {\left| {\pi - \left| x \right|} \right|dx} $$ is equal to :
| [{"identifier": "A", "content": "$${\\pi ^2}$$"}, {"identifier": "B", "content": "2$${\\pi ^2}$$"}, {"identifier": "C", "content": "$$\\sqrt 2 {\\pi ^2}$$"}, {"identifier": "D", "content": "$${{{\\pi ^2}} \\over 2}$$"}] | ["A"] | null | $$\int\limits_{ - \pi }^\pi {\left| {\pi - \left| x \right|} \right|dx} $$
<br><br>= $$2\int\limits_0^\pi {\left| {\pi - \left| x \right|} \right|} dx$$ [As it is even function]
<br><br>= $$2\int\limits_0^\pi {\left( {\pi - x} \right)} dx$$
<br><br>= $$2\left[ {\pi x - {{{x^2}} \over 2}} \right]_0^\pi $$
<br><br>... | mcq | jee-main-2020-online-3rd-september-morning-slot | 5,643 |
KYxZdnmXcvF8YGpLge7k9k2k5fia9dd | maths | definite-integration | properties-of-definite-integration | The value of $$\alpha $$ for which
<br/>$$4\alpha \int\limits_{ - 1}^2 {{e^{ - \alpha \left| x \right|}}dx} = 5$$, is: | [{"identifier": "A", "content": "$${\\log _e}2$$"}, {"identifier": "B", "content": "$${\\log _e}\\sqrt 2 $$"}, {"identifier": "C", "content": "$${\\log _e}\\left( {{4 \\over 3}} \\right)$$"}, {"identifier": "D", "content": "$${\\log _e}\\left( {{3 \\over 2}} \\right)$$"}] | ["A"] | null | $$4\alpha \int\limits_{ - 1}^2 {{e^{ - \alpha \left| x \right|}}dx} = 5$$
<br><br>$$ \Rightarrow $$ $$4\alpha \int\limits_{ - 1}^0 {{e^{\alpha x}}dx} + 4\alpha \int\limits_0^2 {{e^{ - \alpha x}}dx} $$ = 5
<br><br>$$ \Rightarrow $$ $$4\alpha \left[ {{{{e^{\alpha x}}} \over \alpha }} \right]_{ - 1}^0 + 4\alpha \left[ {... | mcq | jee-main-2020-online-7th-january-evening-slot | 5,645 |
jCA7Iy7zecSUIYnIOg7k9k2k5fnvr31 | maths | definite-integration | properties-of-definite-integration | If $$\theta $$<sub>1</sub>
and $$\theta $$<sub>2</sub>
be respectively the smallest and the largest values of $$\theta $$ in (0, 2$$\pi $$) - {$$\pi $$} which satisfy
the equation,
<br/>2cot<sup>2</sup>$$\theta $$ - $${5 \over {\sin \theta }}$$ + 4 = 0, then
<br/>$$\int\limits_{{\theta _1}}^{{\theta _2}} {{{\cos }^2}... | [{"identifier": "A", "content": "$${\\pi \\over 9}$$"}, {"identifier": "B", "content": "$${{2\\pi } \\over 3}$$"}, {"identifier": "C", "content": "$${{\\pi } \\over 3}$$"}, {"identifier": "D", "content": "$${\\pi \\over 3} + {1 \\over 6}$$"}] | ["C"] | null | 2cot<sup>2</sup>$$\theta $$ - $${5 \over {\sin \theta }}$$ + 4 = 0
<br><br>$$ \Rightarrow $$ $$2{{{{\cos }^2}\theta } \over {{{\sin }^2}\theta }} - {5 \over {\sin \theta }} + 4$$ = 0
<br><br>$$ \Rightarrow $$ 2sin<sup>2</sup>
$$\theta $$ – 5sin$$\theta $$ + 2 = 0
<br><br>$$ \Rightarrow $$ (2sin$$\theta $$ – 1)(sin$$\t... | mcq | jee-main-2020-online-7th-january-evening-slot | 5,646 |
xOohIAUZiGPdaMQWK1jgy2xukewsvkoq | maths | definite-integration | properties-of-definite-integration | The integral $$\int\limits_0^2 {\left| {\left| {x - 1} \right| - x} \right|dx} $$<br/> is equal to______. | [] | null | 1.50 | $$\int\limits_0^2 {\left| {\left| {x - 1} \right| - x} \right|dx} $$
<br><br>= $$\int\limits_0^1 {\left| { - \left( {x - 1} \right) - x} \right|} dx$$ + $$ + \int\limits_1^2 {\left| {\left( {x - 1} \right) - x} \right|} dx$$
<br><br>= $$\int\limits_0^1 {\left| {1 - x - x} \right|} dx + \int\limits_1^2 {dx} $$
<br><br>=... | integer | jee-main-2020-online-2nd-september-morning-slot | 5,648 |
RKAHShP0JRx0cMT8Pe7k9k2k5ipaxrd | maths | definite-integration | properties-of-definite-integration | The value of
<br/>$$\int\limits_0^{2\pi } {{{x{{\sin }^8}x} \over {{{\sin }^8}x + {{\cos }^8}x}}} dx$$ is equal to : | [{"identifier": "A", "content": "4$$\\pi $$"}, {"identifier": "B", "content": "2$$\\pi $$"}, {"identifier": "C", "content": "$$\\pi $$<sup>2</sup>"}, {"identifier": "D", "content": "2$$\\pi $$<sup>2</sup>"}] | ["C"] | null | I = $$\int\limits_0^{2\pi } {{{x{{\sin }^8}x} \over {{{\sin }^8}x + {{\cos }^8}x}}} dx$$ .....(1)
<br><br>I = $$\int\limits_0^{2\pi } {{{\left( {2\pi - x} \right){{\sin }^8}x} \over {{{\sin }^8}x + {{\cos }^8}x}}} dx$$ ......(2)
<br><br>Adding (1) and (2)
<br><br>2I = $$\int\limits_0^{2\pi } {{{2\pi {{\sin }^8}x} \ove... | mcq | jee-main-2020-online-9th-january-morning-slot | 5,649 |
IfPvLnsNDscWEEcX6S1klrjrrft | maths | definite-integration | properties-of-definite-integration | If $$\int\limits_{ - a}^a {\left( {\left| x \right| + \left| {x - 2} \right|} \right)} dx = 22$$, (a > 2) and [x] denotes the greatest integer $$ \le $$ x, then$$\int\limits_{ - a}^a {\left( {x + \left[ x \right]} \right)} dx$$ is equal to _________. | [] | null | 3 | $$\int\limits_{ - a}^a {\left( {\left| x \right| + \left| {x - 2} \right|} \right)} dx = 22$$
<br><br>$$ \Rightarrow $$ $$\int\limits_{ - a}^0 {( - 2x + 2)dx} + \int\limits_0^2 {(x + 2 - x)dx} + \int\limits_2^a {(2x - 2)dx} = 22$$<br><br>$$ \Rightarrow $$ $${x^2} - 2x|_0^{ - a} + 2x|_0^2 + {x^2} - 2x|_2^a = 22$$<br>... | integer | jee-main-2021-online-24th-february-morning-slot | 5,650 |
fLZLj1ECpiOuil3cac1klrkgs1n | maths | definite-integration | properties-of-definite-integration | The value of the integral, $$\int\limits_1^3 {[{x^2} - 2x - 2]dx} $$, where [x] denotes the greatest integer less than or equal to x, is : | [{"identifier": "A", "content": "$$-$$ 5"}, {"identifier": "B", "content": "$$ - \\sqrt 2 - \\sqrt 3 + 1$$"}, {"identifier": "C", "content": "$$-$$ 4"}, {"identifier": "D", "content": "$$ - \\sqrt 2 - \\sqrt 3 - 1$$"}] | ["D"] | null | $$I = \int\limits_1^3 { - 3dx + \int\limits_1^3 {\left[ {{{(x - 1)}^2}} \right]dx} } $$<br><br>Put x $$-$$ 1 = t ; dx = dt<br><br>$$I = ( - 6) + \int\limits_0^2 {\left[ {{t^2}} \right]} dt$$<br><br>$$I = - 6 + \int\limits_0^1 {0dt} + \int\limits_1^{\sqrt 2 } {1dt} + \int\limits_{\sqrt 2 }^{\sqrt 3 } {2dt} + \int\li... | mcq | jee-main-2021-online-24th-february-evening-slot | 5,651 |
oryA5enuTQBkUls5XD1klrkw9n0 | maths | definite-integration | properties-of-definite-integration | Let f(x) be a differentiable function defined on [0, 2] such that f'(x) = f'(2 $$-$$ x) for all x$$ \in $$ (0, 2), f(0) = 1 and f(2) = e<sup>2</sup>. Then the value of $$\int\limits_0^2 {f(x)} dx$$ is : | [{"identifier": "A", "content": "1 + e<sup>2</sup>"}, {"identifier": "B", "content": "2(1 + e<sup>2</sup>)"}, {"identifier": "C", "content": "1 $$-$$ e<sup>2</sup>"}, {"identifier": "D", "content": "2(1 $$-$$ e<sup>2</sup>)"}] | ["A"] | null | f'(x) = f'(2 $$-$$ x)<br><br>On integrating both side f(x) = $$-$$f(2 $$-$$ x) + c<br><br>put x = 0<br><br>f(0) + f(2) = c $$ \Rightarrow $$ c = 1 + e<sup>2</sup><br><br>$$ \Rightarrow $$ f(x) + f(2 $$-$$ x) = 1 + e<sup>2</sup> ..... (i)<br><br>$$I = \int\limits_0^2 {f(x)dx} = \int\limits_0^1 {\{ f(x) + f(2 - x)\} dx ... | mcq | jee-main-2021-online-24th-february-evening-slot | 5,652 |
sP3TYDhkd2SEqbv1Om1klrli04i | maths | definite-integration | properties-of-definite-integration | Let f be a twice differentiable function defined on R such that f(0) = 1, f'(0) = 2 and f'(x) $$ \ne $$ 0 for all x $$ \in $$ R. If $$\left| {\matrix{
{f(x)} & {f'(x)} \cr
{f'(x)} & {f''(x)} \cr
} } \right|$$ = 0, for all x$$ \in $$R, then the value of f(1) lies in the interval : | [{"identifier": "A", "content": "(0, 3)"}, {"identifier": "B", "content": "(9, 12)"}, {"identifier": "C", "content": "(3, 6)"}, {"identifier": "D", "content": "(6, 9)"}] | ["D"] | null | $$\left| {\matrix{
{f(x)} & {f'(x)} \cr
{f'(x)} & {f''(x)} \cr
} } \right| = 0$$<br><br>$$ \Rightarrow f(x).f''(x) - {\left( {f'(x)} \right)^2} = 0$$<br><br>Dividing by $${\left( {f(x)} \right)^2}$$, we get<br><br>$$ \Rightarrow {{f(x).f''(x) - {{\left( {f'(x)} \right)}^2}} \over {{{\left( {f(x)} \r... | mcq | jee-main-2021-online-24th-february-evening-slot | 5,653 |
6mNbfsr4rNmQELaPU61kls409xr | maths | definite-integration | properties-of-definite-integration | The value of $$\int\limits_{ - 1}^1 {{x^2}{e^{[{x^3}]}}} dx$$, where [ t ] denotes the greatest integer $$ \le $$ t, is : | [{"identifier": "A", "content": "$${{e + 1} \\over 3}$$"}, {"identifier": "B", "content": "$${{e - 1} \\over {3e}}$$"}, {"identifier": "C", "content": "$${1 \\over {3e}}$$"}, {"identifier": "D", "content": "$${{e + 1} \\over {3e}}$$"}] | ["D"] | null | $$I = \int\limits_{ - 1}^1 {{x^2}{e^{[{x^3}]}}dx} $$
<br><br>Here -1 $$ \le $$ x $$ \le $$ 1 then -1 $$ \le $$ x<sup>3</sup> $$ \le $$ 1
<br><br>Integer between -1 and 1 is 0. So integration will be divided into two parts, -1 to 0 and 0 to 1.
<br><br>$$ = \int\limits_{ - 1}^0 {{x^2}{e^{[{x^3}]}}dx} + \int\limits_0^1 {... | mcq | jee-main-2021-online-25th-february-morning-slot | 5,654 |
cIyKJCgctnZpVSvWHD1klt84ywd | maths | definite-integration | properties-of-definite-integration | If $${I_n} = \int\limits_{{\pi \over 4}}^{{\pi \over 2}} {{{\cot }^n}x\,dx} $$, then : | [{"identifier": "A", "content": "$${1 \\over {{I_2} + {I_4}}},{1 \\over {{I_3} + {I_5}}},{1 \\over {{I_4} + {I_6}}}$$ are in A.P."}, {"identifier": "B", "content": "I<sub>2</sub> + I<sub>4</sub>, I<sub>3</sub> + I<sub>5</sub>, I<sub>4</sub> + I<sub>6</sub> are in A.P."}, {"identifier": "C", "content": "$${1 \\over {{I_... | ["A"] | null | $${I_n} = \int\limits_{\pi /4}^{\pi /2} {{{\cot }^n}xdx} = \int\limits_{\pi /4}^{\pi /2} {{{\cot }^{n - 2}}x(\cos e{c^2}x - 1)dx} $$
<br><br>= $$\int\limits_{{\pi \over 4}}^{{\pi \over 2}} {{{\cot }^{n - 2}}x.co{{\sec }^2}} xdx - \int\limits_{{\pi \over 4}}^{{\pi \over 2}} {{{\cot }^{n - 2}}x} dx$$
<br><br>$$ = \l... | mcq | jee-main-2021-online-25th-february-evening-slot | 5,655 |
F2KjHonbVsNXO5wm871klt9qgz7 | maths | definite-integration | properties-of-definite-integration | The value of $$\int\limits_{ - 2}^2 {|3{x^2} - 3x - 6|dx} $$ is ___________. | [] | null | 19 | x<sup>2</sup> – x – 2 = (x - 2)(x + 1)
<br><br><img src="https://res.cloudinary.com/dckxllbjy/image/upload/v1734263548/exam_images/bgqekrzfra42hxdnfxsj.webp" style="max-width: 100%;height: auto;display: block;margin: 0 auto;" loading="lazy" alt="JEE Main 2021 (Online) 25th February Evening Shift Mathematics - Definite ... | integer | jee-main-2021-online-25th-february-evening-slot | 5,656 |
NNxLSevDSb1pc2kNN81klugd103 | maths | definite-integration | properties-of-definite-integration | The value of $$\int\limits_{ - \pi /2}^{\pi /2} {{{{{\cos }^2}x} \over {1 + {3^x}}}} dx$$ is : | [{"identifier": "A", "content": "$$2\\pi $$"}, {"identifier": "B", "content": "$${\\pi \\over 2}$$"}, {"identifier": "C", "content": "$$4\\pi $$"}, {"identifier": "D", "content": "$${\\pi \\over 4}$$"}] | ["D"] | null | Let $$I = \int\limits_{ - {\pi \over 2}}^{{\pi \over 2}} {{{{{\cos }^2}x} \over {1 + {3^x}}}} dx$$ .... (1)<br><br>Replace x with $$-$$x,<br><br>$$ \therefore $$ $$I = \int\limits_{ - {\pi \over 2}}^{{\pi \over 2}} {{{{{\cos }^2}x} \over {1 + {1 \over {{3^x}}}}}} $$ .... (2)<br><br>Adding (1) and (2), we get,<br><b... | mcq | jee-main-2021-online-26th-february-morning-slot | 5,657 |
xeclbysY3loXLaNaYZ1klugk4ig | maths | definite-integration | properties-of-definite-integration | The value of $$\sum\limits_{n = 1}^{100} {\int\limits_{n - 1}^n {{e^{x - [x]}}dx} } $$, where [ x ] is the greatest integer $$ \le $$ x, is : | [{"identifier": "A", "content": "100e"}, {"identifier": "B", "content": "100(e $$-$$ 1)"}, {"identifier": "C", "content": "100(1 + e)"}, {"identifier": "D", "content": "100(1 $$-$$ e)"}] | ["B"] | null | $$\sum\limits_{n = 1}^{100} {\int\limits_{n - 1}^n {{e^{x - [x]}}} dx} $$<br><br>Here, $$n - 1 \le x < n$$<br><br>$$ \therefore $$ $$[x] = n - 1$$<br><br>$$ \therefore $$ $$\int\limits_{n - 1}^n {{e^{x - (n - 1)}}} dx$$<br><br>$$ = \left[ {{e^{x - (n - 1)}}} \right]_{n - 1}^n$$<br><br>$$ = {e^1} - {e^0}$$<br><br>$$ ... | mcq | jee-main-2021-online-26th-february-morning-slot | 5,658 |
1gtnINHDALrDtWp8iv1kluhl7sf | maths | definite-integration | properties-of-definite-integration | The value of the integral $$\int\limits_0^\pi {|{{\sin }\,}2x|dx} $$ is ___________. | [] | null | 2 | $\begin{aligned} & \text { Let } I=\int_0^\pi|\sin 2 x| d x
\\\\ & =2 \int_0^{\pi / 2}|\sin 2 x| d x \quad[\because \sin 2 x \text { is periodic function }]
\\\\ & =2 \int_0^{\pi / 2} \sin 2 x \,d x[\sin 2 x \text { is positive in range }(0, \pi / 2)]
\\\\ & =2\left[\frac{-\cos 2 x}{2}\right]_0^{\pi / 2} \\\\ & =-[\... | integer | jee-main-2021-online-26th-february-morning-slot | 5,659 |
VUYHG22OPDyh47l3sQ1kluwtm7l | maths | definite-integration | properties-of-definite-integration | For x > 0, if $$f(x) = \int\limits_1^x {{{{{\log }_e}t} \over {(1 + t)}}dt} $$, then $$f(e) + f\left( {{1 \over e}} \right)$$ is equal to : | [{"identifier": "A", "content": "$${1 \\over 2}$$"}, {"identifier": "B", "content": "$$-$$1"}, {"identifier": "C", "content": "0"}, {"identifier": "D", "content": "1"}] | ["A"] | null | $$f(x) = \int_1^x {{{\ln t} \over {1 + t}}dt} $$<br><br>then $$f\left( {{1 \over x}} \right) = \int_1^{1/x} {{{\ln t} \over {1 + t}}dt} $$<br><br>Let $$t = {1 \over u} \Rightarrow dt = - {1 \over {{u^2}}}du$$<br><br>$$ \Rightarrow f\left( {{1 \over x}} \right) = \int_1^x {{{\ln {1 \over u}} \over {1 + {1 \over u}}}\le... | mcq | jee-main-2021-online-26th-february-evening-slot | 5,660 |
r6ZrOjQx5gyiQshwUA1kluywnv0 | maths | definite-integration | properties-of-definite-integration | If $${I_{m,n}} = \int\limits_0^1 {{x^{m - 1}}{{(1 - x)}^{n - 1}}dx} $$, for m, $$n \ge 1$$, and <br/>$$\int\limits_0^1 {{{{x^{m - 1}} + {x^{n - 1}}} \over {{{(1 + x)}^{m + 1}}}}} dx = \alpha {I_{m,n}}\alpha \in R$$, then $$\alpha$$ equals ___________. | [] | null | 1 | $${I_{m,n}} = \int\limits_0^1 {{x^{m - 1}}} .{(1 - x)^{n - 1}}dx$$<br><br>Put $$x = {1 \over {y + 1}} \Rightarrow dx = {{ - 1} \over {{{(y + 1)}^2}}}dy$$<br><br>$$1 - x = {y \over {y + 1}}$$<br><br>$$ \therefore $$ $${I_{m,n}} = \int\limits_\infty ^0 {{{{y^{n - 1}}} \over {{{(y + 1)}^{m + n}}}}( - 1)dy = } \int\limits_... | integer | jee-main-2021-online-26th-february-evening-slot | 5,661 |
ZJfj298ec1lDoMQg4x1kmhzfc4e | maths | definite-integration | properties-of-definite-integration | Let f : R $$ \to $$ R be a continuous function such that f(x) + f(x + 1) = 2, for all x$$\in$$R. <br/><br/>If $${I_1} = \int\limits_0^8 {f(x)dx} $$ and $${I_2} = \int\limits_{ - 1}^3 {f(x)dx} $$, then the value of I<sub>1</sub> + 2I<sub>2</sub> is equal to ____________. | [] | null | 16 | $$f(x) + f(x + 1) = 2$$ .... (i)<br><br>$$x \to (x + 1)$$<br><br>$$f(x + 1) + f(x + 2) = 2$$ .... (ii)<br><br>by (i) & (ii)<br><br>$$f(x) - f(x + 2) = 0$$<br><br>$$f(x + 2) = f(x)$$<br><br>$$ \therefore $$ f(x) is periodic with T = 2<br><br>$${I_1} = \int_0^{2 \times 4} {f(x)dx} = 4\int_0^2 {f(x)dx} $$<br><br>$${I... | integer | jee-main-2021-online-16th-march-morning-shift | 5,662 |
r5s4VH5sw0Fo8RRTCT1kmiwph7t | maths | definite-integration | properties-of-definite-integration | Let P(x) = x<sup>2</sup> + bx + c be a quadratic polynomial with real coefficients such that $$\int_0^1 {P(x)dx} $$ = 1 and P(x) leaves remainder 5 when it is divided by (x $$-$$ 2). Then the value of 9(b + c) is equal to : | [{"identifier": "A", "content": "9"}, {"identifier": "B", "content": "11"}, {"identifier": "C", "content": "7"}, {"identifier": "D", "content": "15"}] | ["C"] | null | $$(x - 2)Q(x) + 5 = {x^2} + bx + c$$<br><br>Put x = 2<br><br>5 = 2b + c + 4 .... (1)<br><br>$$\int_0^1 {({x^2} + bx + c)dx} = 1$$<br><br>$$ \Rightarrow {1 \over 3} + {b \over 2} + c = 1$$<br><br>$${b \over 2} + c = {2 \over 3}$$ .... (2)<br><br>Solve (1) & (2)<br><br>$$b = {2 \over 9}$$<br><br>$$c = {5 \over 9}$$<... | mcq | jee-main-2021-online-16th-march-evening-shift | 5,664 |
o4pjeaV1pkGvUJWd111kmjab62m | maths | definite-integration | properties-of-definite-integration | Which of the following statements is correct for the function g($$\alpha$$) for $$\alpha$$ $$\in$$ R such that <br/><br/>$$g(\alpha ) = \int\limits_{{\pi \over 6}}^{{\pi \over 3}} {{{{{\sin }^\alpha }x} \over {{{\cos }^\alpha }x + {{\sin }^\alpha }x}}dx} $$ | [{"identifier": "A", "content": "$$g(\\alpha )$$ is a strictly increasing function"}, {"identifier": "B", "content": "$$g(\\alpha )$$ is an even function"}, {"identifier": "C", "content": "$$g(\\alpha )$$ has an inflection point at $$\\alpha$$ = $$-$$$${1 \\over 2}$$"}, {"identifier": "D", "content": "$$g(\\alpha )$$ i... | ["B"] | null | $$g(\alpha ) = \int\limits_{\pi /6}^{\pi /3} {{{{{\sin }^\alpha }\left( {{\pi \over 2} - x} \right)} \over {{{\cos }^\alpha }\left( {{\pi \over 2} - x} \right)x + {{\sin }^\alpha }\left( {{\pi \over 2} - x} \right)}}dx} $$<br><br>$$ = \int\limits_{\pi /6}^{\pi /3} {{{{{\cos }^\alpha }x} \over {{{\sin }^\alpha }x + {... | mcq | jee-main-2021-online-17th-march-morning-shift | 5,665 |
AZS5ox5Pdy8Y10mvNF1kmjccvuv | maths | definite-integration | properties-of-definite-integration | If [ . ] represents the greatest integer function, then the value of <br/><br/><br/>$$\left| {\int\limits_0^{\sqrt {{\pi \over 2}} } {\left[ {[{x^2}] - \cos x} \right]dx} } \right|$$ is ____________. | [] | null | 1 | $$\int\limits_0^{\sqrt {{\pi \over 2}} } {\left[ {[{x^2}] - \cos x} \right]} dx$$<br><br>$$ = \int\limits_0^1 {[ - \cos x]dx} + \int\limits_1^{\sqrt {{\pi \over 2}} } {[1 - \cos x]dx} $$
<br><br>= $$\int\limits_0^1 {\left[ { - \cos x} \right]} dx + \int\limits_1^{\sqrt {{\pi \over 2}} } {1dx} + \int\limits_1^{\sqr... | integer | jee-main-2021-online-17th-march-morning-shift | 5,666 |
tBRlCNOOh5nOH5YgEh1kmkn1xxj | maths | definite-integration | properties-of-definite-integration | If the integral
<br/><br/>$$\int_0^{10} {{{[\sin 2\pi x]} \over {{e^{x - [x]}}}}} dx = \alpha {e^{ - 1}} + \beta {e^{ - {1 \over 2}}} + \gamma $$, where $$\alpha$$, $$\beta$$, $$\gamma$$ are integers and [x] denotes the greatest integer less than or equal to x, then the value of $$\alpha$$ + $$\beta$$ + $$\gamma$$ is ... | [{"identifier": "A", "content": "0"}, {"identifier": "B", "content": "10"}, {"identifier": "C", "content": "20"}, {"identifier": "D", "content": "25"}] | ["A"] | null | Given integral<br><br>$$\int\limits_0^{10} {{{[\sin 2\pi x]} \over {{e^{x - [x]}}}}dx = 10\int\limits_0^1 {{{[\sin 2\pi x]} \over {{e^{\{ x\} }}}}dx} } $$ (using property of definite in.)<br><br>$$ = 10\left[ {\int\limits_0^{1/2} {0.dx} + \int\limits_{1/2}^1 {{{ - 1} \over {{e^x}}}dx} } \right]$$<br><br>= $$ - 10\left... | mcq | jee-main-2021-online-17th-march-evening-shift | 5,667 |
qAj5oXiZQmjkLusOyY1kmknyiwo | maths | definite-integration | properties-of-definite-integration | Let $${I_n} = \int_1^e {{x^{19}}{{(\log |x|)}^n}} dx$$, where n$$\in$$N. If (20)I<sub>10</sub> = $$\alpha$$I<sub>9</sub> + $$\beta$$I<sub>8</sub>, for natural numbers $$\alpha$$ and $$\beta$$, then $$\alpha$$ $$-$$ $$\beta$$ equals to ___________. | [] | null | 1 | $${I_n} = 2\int\limits_1^e {{x^{19}}{{(\ln x)}^n}\,.\,dx} $$<br><br>$$ = {(\ln x)^n}\,.\,\left. {{{{x^{20}}} \over {20}}} \right|_1^e -\int\limits_1^e {n{{{{(\ln x)}^{n - 1}}} \over x}{{{x^{20}}} \over {20}}dx} $$<br><br>$${I_n} = {{{e^{20}}} \over {20}} - {n \over {20}}({I_{n - 1}})$$<br><br>$$20{I_n} = {e^{20}} - n\,... | integer | jee-main-2021-online-17th-march-evening-shift | 5,668 |
LAeG6W8QyF222p0jls1kmm38pjl | maths | definite-integration | properties-of-definite-integration | Let g(x) = $$\int_0^x {f(t)dt} $$, where f is continuous function in [ 0, 3 ] such that $${1 \over 3}$$ $$ \le $$ f(t) $$ \le $$ 1 for all t$$\in$$ [0, 1] and 0 $$ \le $$ f(t) $$ \le $$ $${1 \over 2}$$ for all t$$\in$$ (1, 3]. The largest possible interval in which g(3) lies is : | [{"identifier": "A", "content": "$$\\left[ { - 1, - {1 \\over 2}} \\right]$$"}, {"identifier": "B", "content": "$$\\left[ { - {3 \\over 2}, - 1} \\right]$$"}, {"identifier": "C", "content": "[1, 3]"}, {"identifier": "D", "content": "$$\\left[ {{1 \\over 3},2} \\right]$$"}] | ["D"] | null | Given, $g(x)=\int_0^x f(t) d t$<br/><br/>
$\therefore g(3)=\int_0^3 f(t) d t=\int_0^1 f(t) d t+\int_1^3 f(t) d t$<br/><br/>
$\Rightarrow \int_0^1 \frac{1}{3} d t+\int_1^3 0 \cdot d t \leq g(3) \leq \int_0^1 1 d t+\int_1^3 \frac{1}{2} d t$<br/><br/>
$\Rightarrow \frac{1}{3} \leq g(3) \leq 1+1$<br/><br/>
$\Rightarrow \fr... | mcq | jee-main-2021-online-18th-march-evening-shift | 5,670 |
1krpt3zg2 | maths | definite-integration | properties-of-definite-integration | The value of the integral $$\int\limits_{ - 1}^1 {{{\log }_e}(\sqrt {1 - x} + \sqrt {1 + x} )dx} $$ is equal to: | [{"identifier": "A", "content": "$${1 \\over 2}{\\log _e}2 + {\\pi \\over 4} - {3 \\over 2}$$"}, {"identifier": "B", "content": "$$2{\\log _e}2 + {\\pi \\over 4} - 1$$"}, {"identifier": "C", "content": "$${\\log _e}2 + {\\pi \\over 2} - 1$$"}, {"identifier": "D", "content": "$$2{\\log _e}2 + {\\pi \\over 2} - {1 \\... | ["C"] | null | $$\int\limits_{ - 1}^1 {{{\log }_e}(\sqrt 1 - x + \sqrt {1 + x} )dx} $$<br/><br/>We know, $$\int\limits_{ - a}^a {f(x)dx = 2\int\limits_0^a {f(x)dx} } $$<br/><br/>So, $$2\int\limits_0^1 {{{\log }_e}(\sqrt 1 - x + \sqrt {1 + x} )dx} $$<br/><br/>$$l = 2\int\limits_0^1 {{{\log }_e}(\sqrt 1 - x + \sqrt {1 + x} ).1dx} $$... | mcq | jee-main-2021-online-20th-july-morning-shift | 5,673 |
1krrqb9z4 | maths | definite-integration | properties-of-definite-integration | If [x] denotes the greatest integer less than or equal to x, then the value of the integral $$\int_{ - \pi /2}^{\pi /2} {[[x] - \sin x]dx} $$ is equal to : | [{"identifier": "A", "content": "$$-$$ $$\\pi$$"}, {"identifier": "B", "content": "$$\\pi$$"}, {"identifier": "C", "content": "0"}, {"identifier": "D", "content": "1"}] | ["A"] | null | $$I = \int_{ - \pi /2}^{\pi /2} {[[x] - \sin x]dx} $$<br><br>$$ = \int_{ - \pi /2}^{\pi /2} {\left( {[x] + [ - \sin x]} \right)dx} $$<br><br>$$ = \int_0^{\pi /2} {\left( {[x] + [ - \sin x] + [ - x] + [\sin x]} \right)} dx$$<br><br>$$ = \int_0^{\pi /2} {( - 2)dx} $$<br><br>$$ = - \pi $$ | mcq | jee-main-2021-online-20th-july-evening-shift | 5,674 |
1krrqkq1g | maths | definite-integration | properties-of-definite-integration | If the real part of the complex number $${(1 - \cos \theta + 2i\sin \theta )^{ - 1}}$$ is $${1 \over 5}$$ for $$\theta \in (0,\pi )$$, then the value of the integral $$\int_0^\theta {\sin x} dx$$ is equal to: | [{"identifier": "A", "content": "1"}, {"identifier": "B", "content": "2"}, {"identifier": "C", "content": "$$-$$1"}, {"identifier": "D", "content": "0"}] | ["A"] | null | $$z = {1 \over {1 - \cos \theta + 2i\sin \theta }}$$<br><br>$$ = {{2{{\sin }^2}{\theta \over 2} - 2i\sin \theta } \over {{{(1 - \cos \theta )}^2} + 4{{\sin }^2}\theta }}$$<br><br>$$ = {{\sin {\theta \over 2} - 2i\cos {\theta \over 2}} \over {2\sin {\theta \over 2}\left( {{{\sin }^2}{\theta \over 2} + 4{{\cos }^2}... | mcq | jee-main-2021-online-20th-july-evening-shift | 5,675 |
1krru916m | maths | definite-integration | properties-of-definite-integration | Let $$g(t) = \int_{ - \pi /2}^{\pi /2} {\cos \left( {{\pi \over 4}t + f(x)} \right)} dx$$, where $$f(x) = {\log _e}\left( {x + \sqrt {{x^2} + 1} } \right),x \in R$$. Then which one of the following is correct? | [{"identifier": "A", "content": "g(1) = g(0)"}, {"identifier": "B", "content": "$$\\sqrt 2 g(1) = g(0)$$"}, {"identifier": "C", "content": "$$g(1) = \\sqrt 2 g(0)$$"}, {"identifier": "D", "content": "g(1) + g(0) = 0"}] | ["B"] | null | $$\because$$ $$f(x) = \ln \left( {x + \sqrt {{x^2} + 1} } \right)$$<br><br>$$\therefore$$ $$f(x) + f( - x) = \ln \left( {\sqrt {{x^2} + 1} + x} \right) + \ln \left( {\sqrt {{x^2} + 1} - x} \right)$$<br><br>$$\therefore$$ $$f(x) + f( - x) = 0$$ .... (i)<br><br>$$\because$$ $$g(t) = \int_{ - \pi /2}^{\pi /2} {\cos \lef... | mcq | jee-main-2021-online-20th-july-evening-shift | 5,676 |
1krtdtbei | maths | definite-integration | properties-of-definite-integration | If $$\int\limits_0^{100\pi } {{{{{\sin }^2}x} \over {{e^{\left( {{x \over \pi } - \left[ {{x \over \pi }} \right]} \right)}}}}dx = {{\alpha {\pi ^3}} \over {1 + 4{\pi ^2}}},\alpha \in R} $$ where [x] is the greatest integer less than or equal to x, then the value of $$\alpha$$ is : | [{"identifier": "A", "content": "200 (1 $$-$$ e<sup>$$-$$1</sup>)"}, {"identifier": "B", "content": "100 (1 $$-$$ e)"}, {"identifier": "C", "content": "50 (e $$-$$ 1)"}, {"identifier": "D", "content": "150 (e<sup>$$-$$1</sup> $$-$$ 1)"}] | ["A"] | null | $$I = \int_0^{100\pi } {{{{{\sin }^2}x} \over {{e^{\left( {{x \over \pi } - \left[ {{x \over \pi }} \right]} \right)}}}}dx} $$<br><br>$$\because$$ Integrand is periodic with period 1<br><br>$$\therefore$$ $$I = 100\int_0^\pi {{{{{\sin }^2}x} \over {{e^{\left\{ {{x \over \pi }} \right\}}}}}} dx$$<br><br>Let $${x \over ... | mcq | jee-main-2021-online-22th-july-evening-shift | 5,677 |
1krvy4naz | maths | definite-integration | properties-of-definite-integration | The value of the definite integral $$\int\limits_{\pi /24}^{5\pi /24} {{{dx} \over {1 + \root 3 \of {\tan 2x} }}} $$ is : | [{"identifier": "A", "content": "$${\\pi \\over 3}$$"}, {"identifier": "B", "content": "$${\\pi \\over 6}$$"}, {"identifier": "C", "content": "$${\\pi \\over {12}}$$"}, {"identifier": "D", "content": "$${\\pi \\over {18}}$$"}] | ["C"] | null | Let $$I = \int\limits_{\pi /24}^{5\pi /24} {{{{{(\cos 2x)}^{1/3}}} \over {{{(\cos 2x)}^{1/3}} + {{(\sin 2x)}^{1/3}}}}dx} $$ ...... (i)<br><br>$$ \Rightarrow I = \int\limits_{\pi /2}^{5\pi /24} {{{{{\left( {\cos \left\{ {2\left( {{\pi \over 4} - x} \right)} \right\}} \right)}^{{1 \over 3}}}} \over {{{\left( {\cos \left... | mcq | jee-main-2021-online-25th-july-morning-shift | 5,678 |
1krw019ap | maths | definite-integration | properties-of-definite-integration | Let $$f:[0,\infty ) \to [0,\infty )$$ be defined as $$f(x) = \int_0^x {[y]dy} $$<br/><br/>where [x] is the greatest integer less than or equal to x. Which of the following is true? | [{"identifier": "A", "content": "f is continuous at every point in $$[0,\\infty )$$ and differentiable except at the integer points."}, {"identifier": "B", "content": "f is both continuous and differentiable except at the integer points in $$[0,\\infty )$$."}, {"identifier": "C", "content": "f is continuous everywhere ... | ["A"] | null | $$f:[0,\infty ) \to [0,\infty ),f(x) = \int_0^x {[y]dy} $$<br><br>Let $$x = n + f,f \in (0,1)$$<br><br>So, $$f(x) = 0 + 1 + 2 + ... + (n - 1) + \int\limits_n^{n + f} {n\,dy} $$<br><br>$$f(x) = {{n(n - 1)} \over 2} + nf$$<br><br>$$ = {{[x]([x] - 1)} \over 2} + [x]\{ x\} $$<br><br>Note $$\mathop {\lim }\limits_{x \to {n^... | mcq | jee-main-2021-online-25th-july-morning-shift | 5,679 |
1kryg955g | maths | definite-integration | properties-of-definite-integration | If $$\int_0^\pi {({{\sin }^3}x){e^{ - {{\sin }^2}x}}dx = \alpha - {\beta \over e}\int_0^1 {\sqrt t {e^t}dt} } $$, then $$\alpha$$ + $$\beta$$ is equal to ____________. | [] | null | 5 | $$I = 2\int_0^{\pi /2} {{{\sin }^3}x{e^{ - {{\sin }^2}x}}dx} $$<br><br>$$ = 2\int_0^{\pi /2} {\sin x{e^{ - {{\sin }^2}x}}dx} + \int\limits_0^{\pi /2} {\mathop {\cos x}\limits_I \,\underbrace {{e^{ - {{\sin }^2}x}}( - \sin 2x)}_{II}dx} $$$$ = 2\int\limits_0^{\pi /2} {\sin x{e^{ - {{\sin }^2}x}}dx} + \left[ {\cos x{e^{... | integer | jee-main-2021-online-27th-july-evening-shift | 5,680 |
1krzlm5le | maths | definite-integration | properties-of-definite-integration | If $$f(x) = \left\{ {\matrix{
{\int\limits_0^x {\left( {5 + \left| {1 - t} \right|} \right)dt,} } & {x > 2} \cr
{5x + 1,} & {x \le 2} \cr
} } \right.$$, then | [{"identifier": "A", "content": "f(x) is not continuous at x = 2"}, {"identifier": "B", "content": "f(x) is everywhere differentiable "}, {"identifier": "C", "content": "f(x) is continuous but not differentiable at x = 2"}, {"identifier": "D", "content": "f(x) is not differentiable at x = 1"}] | ["C"] | null | $$f(x) = \int\limits_0^1 {(5 + (1 - t))dt + \int\limits_1^x {(5 + (t - 1))dt} } $$<br><br>$$ = \left. {6 - {1 \over 2} + \left( {4t + {{{t^2}} \over 2}} \right)} \right|_1^x$$<br><br>$$ = {{11} \over 2} + 4x + {{{x^2}} \over 2} - 4 - {1 \over 2}$$<br><br>$$ = {{{x^2}} \over 2} + 4x - 1$$<br><br>$$f({2^ + }) = 2 + 8 + 1... | mcq | jee-main-2021-online-25th-july-evening-shift | 5,681 |
1krzmibsx | maths | definite-integration | properties-of-definite-integration | The value of the <br/><br/>integral $$\int\limits_{ - 1}^1 {\log \left( {x + \sqrt {{x^2} + 1} } \right)dx} $$ is : | [{"identifier": "A", "content": "2"}, {"identifier": "B", "content": "0"}, {"identifier": "C", "content": "$$-$$1"}, {"identifier": "D", "content": "1"}] | ["B"] | null | Let $$I = \int\limits_{ - 1}^1 {\log \left( {x + \sqrt {{x^2} + 1} } \right)dx} $$<br><br>$$\because$$ $$\log \left( {x + \sqrt {{x^2} + 1} } \right)$$ is an odd function<br><br>$$\therefore$$ I = 0 | mcq | jee-main-2021-online-25th-july-evening-shift | 5,682 |
1ks05rb02 | maths | definite-integration | properties-of-definite-integration | The value of the definite integral<br/><br/>$$\int\limits_{ - {\pi \over 4}}^{{\pi \over 4}} {{{dx} \over {(1 + {e^{x\cos x}})({{\sin }^4}x + {{\cos }^4}x)}}} $$ is equal to : | [{"identifier": "A", "content": "$$ - {\\pi \\over 2}$$"}, {"identifier": "B", "content": "$${\\pi \\over {2\\sqrt 2 }}$$"}, {"identifier": "C", "content": "$$ - {\\pi \\over 4}$$"}, {"identifier": "D", "content": "$${\\pi \\over {\\sqrt 2 }}$$"}] | ["B"] | null | $$I = \int\limits_{ - {\pi \over 4}}^{{\pi \over 4}} {{{dx} \over {(1 + {e^{x\cos x}})({{\sin }^4}x + {{\cos }^4}x)}}} $$ .... (1)<br><br>Using $$\int\limits_a^b {f(x)dx = \int\limits_a^b {f(a + b - x)dx} } $$<br><br>$$I = \int\limits_{ - {\pi \over 4}}^{{\pi \over 4}} {{{dx} \over {(1 + {e^{ - x\cos x}})({{\sin }^... | mcq | jee-main-2021-online-27th-july-morning-shift | 5,683 |
1ks0ccco5 | maths | definite-integration | properties-of-definite-integration | Let the domain of the function<br/><br/>$$f(x) = {\log _4}\left( {{{\log }_5}\left( {{{\log }_3}(18x - {x^2} - 77)} \right)} \right)$$ be (a, b). Then the value of the integral $$\int\limits_a^b {{{{{\sin }^3}x} \over {({{\sin }^3}x + {{\sin }^3}(a + b - x)}}} dx$$ is equal to _____________. | [] | null | 1 | For domain<br><br>$${\log _5}\left( {{{\log }_3}(18x - {x^2} - 77)} \right) > 0$$<br><br>$${\log _3}(18x - {x^2} - 77) > 1$$<br><br>$$18x - {x^2} - 77 > 3$$<br><br>$${x^2} - 18x + 80 < 0$$<br><br>$$x \in (8,10)$$<br><br>$$\Rightarrow$$ a = 8 and b = 10<br><br>$$I = \int\limits_a^b {{{{{\sin }^3}x} \over {{{... | integer | jee-main-2021-online-27th-july-morning-shift | 5,684 |
1ktcym1ca | maths | definite-integration | properties-of-definite-integration | If the value of the integral <br/>$$\int\limits_0^5 {{{x + [x]} \over {{e^{x - [x]}}}}dx = \alpha {e^{ - 1}} + \beta } $$, where $$\alpha$$, $$\beta$$ $$\in$$ R, 5$$\alpha$$ + 6$$\beta$$ = 0, and [x] denotes the greatest integer less than or equal to x; then the value of ($$\alpha$$ + $$\beta$$)<sup>2</sup> is equal to... | [{"identifier": "A", "content": "100"}, {"identifier": "B", "content": "25"}, {"identifier": "C", "content": "16"}, {"identifier": "D", "content": "36"}] | ["B"] | null | <p>$$I = \int\limits_0^5 {{{x + [x]} \over {{e^{x - [x]}}}}dx = \alpha {e^{ - 1}} + \beta } $$</p>
<p>$$I = \int\limits_0^1 {{x \over {{e^x}}}dx + \int\limits_1^2 {{{x + 1} \over {{e^{x - 1}}}}dx + \int\limits_2^3 {{{x + 2} \over {{e^{x - 2}}}}dx + \int\limits_3^4 {{{x + 3} \over {{e^{x - 3}}}}dx + \int\limits_4^5 {{{x... | mcq | jee-main-2021-online-26th-august-evening-shift | 5,686 |
1kteo6fze | maths | definite-integration | properties-of-definite-integration | $$\int\limits_6^{16} {{{{{\log }_e}{x^2}} \over {{{\log }_e}{x^2} + {{\log }_e}({x^2} - 44x + 484)}}dx} $$ is equal to : | [{"identifier": "A", "content": "6"}, {"identifier": "B", "content": "8"}, {"identifier": "C", "content": "5"}, {"identifier": "D", "content": "10"}] | ["C"] | null | Let $$I = \int\limits_6^{16} {{{{{\log }_e}{x^2}} \over {{{\log }_e}{x^2} + {{\log }_e}({x^2} - 44x + 484)}}dx} $$<br><br>$$I = \int\limits_6^{16} {{{{{\log }_e}{x^2}} \over {{{\log }_e}{x^2} + {{\log }_e}({x^2} - 22)}}dx} $$ .... (1)<br><br>We know,<br><br>$$\int\limits_a^b {f(x)dx} = \int\limits_a^b {f(a + b - x)} \... | mcq | jee-main-2021-online-27th-august-morning-shift | 5,688 |
1ktirsgas | maths | definite-integration | properties-of-definite-integration | Let [t] denote the greatest integer $$\le$$ t. Then the value of <br/><br/>$$8.\int\limits_{ - {1 \over 2}}^1 {([2x] + |x|)dx} $$ is ___________. | [] | null | 5 | $$I = \,\int\limits_{ - {1 \over 2}}^1 {([2x] + |x|)dx} $$<br><br>$$ = \int\limits_{ - 1/2}^1 {[2x]\,dx + \int\limits_{ - 1/2}^1 {|x|\,} dx} $$<br><br>$$ = 0 + \int\limits_{ - 1/2}^0 {( - x)\,} dx + \int\limits_0^1 {x\,} dx$$<br><br>$$ = \left( { - {{{x^2}} \over 2}} \right)_{ - 1/2}^0 + \left( {{{{x^2}} \over 2}} \rig... | integer | jee-main-2021-online-31st-august-morning-shift | 5,690 |
1ktisti2k | maths | definite-integration | properties-of-definite-integration | If $$x\phi (x) = \int\limits_5^x {(3{t^2} - 2\phi '(t))dt} $$, x > $$-$$2, and $$\phi$$(0) = 4, then $$\phi$$(2) is __________. | [] | null | 4 | $$x\phi (x) = \int\limits_5^x {3{t^2} - 2\phi '(t)dt} $$<br><br>$$x\phi (x) = {x^3} - 125 - 2[\phi (x) - \phi (5)]$$<br><br>$$x\phi (x) = {x^3} - 125 - 2\phi (x) - 2\phi (5)$$<br><br>$$\phi (0) = 4 \Rightarrow \phi (5) = {{133} \over 2}$$<br><br>$$\phi (x) = {{{x^3} + 8} \over {x + 2}}$$<br><br>$$\phi (2) = 4$$ | integer | jee-main-2021-online-31st-august-morning-shift | 5,691 |
1ktka5vae | maths | definite-integration | properties-of-definite-integration | If [x] is the greatest integer $$\le$$ x, then <br/><br/>$${\pi ^2}\int\limits_0^2 {\left( {\sin {{\pi x} \over 2}} \right)(x - [x]} {)^{[x]}}dx$$ is equal to : | [{"identifier": "A", "content": "2($$\\pi$$ $$-$$ 1)"}, {"identifier": "B", "content": "4($$\\pi$$ $$-$$ 1)"}, {"identifier": "C", "content": "4($$\\pi$$ + 1)"}, {"identifier": "D", "content": "2($$\\pi$$ + 1)"}] | ["B"] | null | <p>$$I = {\pi ^2}\int_0^2 {\sin \left( {{{\pi x} \over 2}} \right){{(x - [x])}^{[x]}}dx} $$</p>
<p>$$ = {\pi ^2}\int_0^1 {\sin \left( {{{\pi x} \over 2}} \right){x^0}dx + {\pi ^2}\int_1^2 {\sin \left( {{{\pi x} \over 2}} \right)(x - 1)dx} } $$</p>
<p>$$ = {\pi ^2}\left[ {{{ - 2} \over \pi }\cos {{\pi x} \over 2}} \righ... | mcq | jee-main-2021-online-31st-august-evening-shift | 5,692 |
1kto5yxz5 | maths | definite-integration | properties-of-definite-integration | Let $${J_{n,m}} = \int\limits_0^{{1 \over 2}} {{{{x^n}} \over {{x^m} - 1}}dx} $$, $$\forall$$ n > m and n, m $$\in$$ N. Consider a matrix $$A = {[{a_{ij}}]_{3 \times 3}}$$ where $${a_{ij}} = \left\{ {\matrix{
{{j_{6 + i,3}} - {j_{i + 3,3}},} & {i \le j} \cr
{0,} & {i > j} \cr
} } \right.$$. Th... | [{"identifier": "A", "content": "(15)<sup>2</sup> $$\\times$$ 2<sup>42</sup>"}, {"identifier": "B", "content": "(15)<sup>2</sup> $$\\times$$ 2<sup>34</sup>"}, {"identifier": "C", "content": "(105)<sup>2</sup> $$\\times$$ 2<sup>38</sup>"}, {"identifier": "D", "content": "(105)<sup>2</sup> $$\\times$$ 2<sup>36</sup>"}] | ["C"] | null | A = $$\left[ {\matrix{
{a_{11}} & {a_{12}} & {a_{13}} \cr
{{a_{21}}} & {{a_{22}}} & {{a_{23}}} \cr
{{a_{31}}} & {{a_{32}}} & {{a_{33}}} \cr
} } \right]$$<br><br>$${J_{6 + i,3}} - {J_{i + 3,3}}; i \le j$$<br><br>$$ = \int_0^{{1 \over 2}} {{{{x^{6 + i}}} \over {{x^3} - 1}} - \int_... | mcq | jee-main-2021-online-1st-september-evening-shift | 5,693 |
1kto9vgym | maths | definite-integration | properties-of-definite-integration | The function f(x), that satisfies the condition<br/> $$f(x) = x + \int\limits_0^{\pi /2} {\sin x.\cos y\,f(y)\,dy} $$, is : | [{"identifier": "A", "content": "$$x + {2 \\over 3}(\\pi - 2)\\sin x$$"}, {"identifier": "B", "content": "$$x + (\\pi + 2)\\sin x$$"}, {"identifier": "C", "content": "$$x + {\\pi \\over 2}\\sin x$$"}, {"identifier": "D", "content": "$$x + (\\pi - 2)\\sin x$$"}] | ["D"] | null | $$f(x) = x + \int\limits_0^{\pi /2} {\sin x\cos y\,f(y)\,dy} $$<br><br>$$f(x) = x + sinx\underbrace {\int_0^{\pi /2} {\cos y\,f(y)\,dy} }_K$$<br><br>$$ \Rightarrow f(x) = x + K\sin x$$<br><br>$$ \Rightarrow f(y) = y + K\sin y$$<br><br>Now, $$K = \int_0^{\pi /2} {\mathop {y\cos y\,dy}\limits_{Apply\,IBP} } + K\int_0^{\... | mcq | jee-main-2021-online-1st-september-evening-shift | 5,694 |
1l545kvee | maths | definite-integration | properties-of-definite-integration | <p>$$\int_0^5 {\cos \left( {\pi \left( {x - \left[ {{x \over 2}} \right]} \right)} \right)dx} $$,</p>
<p>where [t] denotes greatest integer less than or equal to t, is equal to:</p> | [{"identifier": "A", "content": "$$-$$3"}, {"identifier": "B", "content": "$$-$$2"}, {"identifier": "C", "content": "2"}, {"identifier": "D", "content": "0"}] | ["D"] | null | <p>We know,</p>
<p>$$\left[ {{x \over 2}} \right]$$ is discontinuous at 1, 2, 3, 4 ........</p>
<p>$$\therefore$$ [ x ] is discontinuous at 2, 4, 6, 8 .....</p>
<p>In between 0 to 5 it is discontinuous at 2 and 4.</p>
<p>Break the integration into 3 parts</p>
<p>(1) 0 to 2</p>
<p>(2) 2 to 4</p>
<p>(3) 4 to 5</p>
<p>$$\... | mcq | jee-main-2022-online-29th-june-morning-shift | 5,696 |
1l54b0obe | maths | definite-integration | properties-of-definite-integration | <p>Let f be a real valued continuous function on [0, 1] and $$f(x) = x + \int\limits_0^1 {(x - t)f(t)dt} $$.</p>
<p>Then, which of the following points (x, y) lies on the curve y = f(x) ?</p> | [{"identifier": "A", "content": "(2, 4)"}, {"identifier": "B", "content": "(1, 2)"}, {"identifier": "C", "content": "(4, 17)"}, {"identifier": "D", "content": "(6, 8)"}] | ["D"] | null | <p>Given,</p>
<p>$$f(x) = x + \int_0^1 {(x - t)f(t)dt} $$</p>
<p>$$ = x + x\int_0^1 {f(t)dt - \int_0^1 {tf(t)dt} } $$</p>
<p>$$ = x\left( {1 + \int_0^1 {f(t)dt} } \right) - \int_0^1 {tf(t)dt} $$</p>
<p>Now,</p>
<p>let $$A = 1 + \int_0^1 {f(t)dt} $$</p>
<p>and $$B = \int_0^1 {tf(t)dt} $$</p>
<p>$$\therefore$$ $$f(x) = A... | mcq | jee-main-2022-online-29th-june-evening-shift | 5,697 |
1l54b41yo | maths | definite-integration | properties-of-definite-integration | <p>If $$\int\limits_0^2 {\left( {\sqrt {2x} - \sqrt {2x - {x^2}} } \right)dx = \int\limits_0^1 {\left( {1 - \sqrt {1 - {y^2}} - {{{y^2}} \over 2}} \right)dy + \int\limits_1^2 {\left( {2 - {{{y^2}} \over 2}} \right)dy + I} } } $$, then I equals</p> | [{"identifier": "A", "content": "$$\\int\\limits_0^1 {\\left( {1 + \\sqrt {1 - {y^2}} } \\right)dy} $$"}, {"identifier": "B", "content": "$$\\int\\limits_0^1 {\\left( {{{{y^2}} \\over 2} - \\sqrt {1 - {y^2}} + 1} \\right)dy} $$"}, {"identifier": "C", "content": "$$\\int\\limits_0^1 {\\left( {1 - \\sqrt {1 - {y^2}} } \... | ["C"] | null | <p>Given,</p>
<p>$$\int_0^2 {\left( {\sqrt {2x} - \sqrt {2x - {x^2}} } \right)dx = \int_0^1 {\left( {1 - \sqrt {1 - {y^2}} - {{{y^2}} \over 2}} \right)dy + \int_1^2 {\left( {2 - {{{y^2}} \over 2}} \right)dy + I} } } $$</p>
<p>Now,</p>
<p>$$L.H.S. = \int_0^2 {\left( {\sqrt {2x} - \sqrt {2x - {x^2}} } \right)dx} $$</p... | mcq | jee-main-2022-online-29th-june-evening-shift | 5,698 |
1l55hdycb | maths | definite-integration | properties-of-definite-integration | <p>Let f : R $$\to$$ R be a differentiable function such that $$f\left( {{\pi \over 4}} \right) = \sqrt 2 ,\,f\left( {{\pi \over 2}} \right) = 0$$ and $$f'\left( {{\pi \over 2}} \right) = 1$$ and <br/><br/>let $$g(x) = \int_x^{\pi /4} {(f'(t)\sec t + \tan t\sec t\,f(t))\,dt} $$ for $$x \in \left[ {{\pi \over 4},{\p... | [{"identifier": "A", "content": "2"}, {"identifier": "B", "content": "3"}, {"identifier": "C", "content": "4"}, {"identifier": "D", "content": "$$-$$3"}] | ["B"] | null | Given : $f\left(\frac{\pi}{4}\right)=\sqrt{2}, f\left(\frac{\pi}{2}\right)=0$ and $f^{\prime}\left(\frac{\pi}{2}\right)=1$
<br/><br/>
$$
\begin{aligned}
&g(x)=\int_{x}^{\frac{\pi}{4}}\left(f^{\prime}(t) \sec t+\tan t \sec t f(t)\right) d t \\\\
&=[\sec t+f(t)]_{x}^{\frac{\pi}{4}}=2-\sec x f(x)
\end{aligned}
$$
<br/><br... | mcq | jee-main-2022-online-28th-june-evening-shift | 5,699 |
1l55hht4t | maths | definite-integration | properties-of-definite-integration | <p>Let f : R $$\to$$ R be a continuous function satisfying f(x) + f(x + k) = n, for all x $$\in$$ R where k > 0 and n is a positive integer. If $${I_1} = \int\limits_0^{4nk} {f(x)dx} $$ and $${I_2} = \int\limits_{ - k}^{3k} {f(x)dx} $$, then :</p> | [{"identifier": "A", "content": "$${I_1} + 2{I_2} = 4nk$$"}, {"identifier": "B", "content": "$${I_1} + 2{I_2} = 2nk$$"}, {"identifier": "C", "content": "$${I_1} + n{I_2} = 4{n^2}k$$"}, {"identifier": "D", "content": "$${I_1} + n{I_2} = 6{n^2}k$$"}] | ["C"] | null | $f: R \rightarrow R$ and $f(x)+f(x+k)=n \quad \forall x \in R$
<br/><br/>
$$
\begin{aligned}
&x \rightarrow x+k \\\\
&f(x+k)+f(x+2 k)=n \\\\
&\therefore \quad f(x+2 k)=f(x)
\end{aligned}
$$
<br/><br/>
So, period of $f(x)$ is $2 k$
<br/><br/>
$$
\begin{aligned}
&\text { Now, } I_{1}=\int_{0}^{4 n k} f(x) d x = 2 n \int_... | mcq | jee-main-2022-online-28th-june-evening-shift | 5,700 |
1l566dpzj | maths | definite-integration | properties-of-definite-integration | <p>Let [t] denote the greatest integer less than or equal to t. Then, the value of the integral $$\int\limits_0^1 {[ - 8{x^2} + 6x - 1]dx} $$ is equal to :</p> | [{"identifier": "A", "content": "$$-$$1"}, {"identifier": "B", "content": "$${{ - 5} \\over 4}$$"}, {"identifier": "C", "content": "$${{\\sqrt {17} - 13} \\over 8}$$"}, {"identifier": "D", "content": "$${{\\sqrt {17} - 16} \\over 8}$$"}] | ["C"] | null | $\int_{0}^{1}\left[-8 x^{2}+6 x-1\right] d x$<br><br>
<img src="https://app-content.cdn.examgoal.net/fly/@width/image/1lc8eip72/1a7f4845-0be6-46f8-ac5d-62ddcb930a44/438942e0-8717-11ed-b3ec-0bde88094e1e/file-1lc8eip73.png?format=png" data-orsrc="https://app-content.cdn.examgoal.net/image/1lc8eip72/1a7f4845-0be6-46f8-ac5... | mcq | jee-main-2022-online-28th-june-morning-shift | 5,701 |
1l56r4q3p | maths | definite-integration | properties-of-definite-integration | <p>The integral $$\int\limits_0^1 {{1 \over {{7^{\left[ {{1 \over x}} \right]}}}}dx} $$, where [ . ] denotes the greatest integer function, is equal to</p> | [{"identifier": "A", "content": "$$1 + 6{\\log _e}\\left( {{6 \\over 7}} \\right)$$"}, {"identifier": "B", "content": "$$1 - 6{\\log _e}\\left( {{6 \\over 7}} \\right)$$"}, {"identifier": "C", "content": "$${\\log _e}\\left( {{7 \\over 6}} \\right)$$"}, {"identifier": "D", "content": "$$1 - 7{\\log _e}\\left( {{6 \\ove... | ["A"] | null | <p>$$\int_0^1 {{1 \over {{7^{\left[ {{1 \over x}} \right]}}}}dx} $$, let $${1 \over x} = t$$</p>
<p>$${{ - 1} \over {{x^2}}}dx = dt$$</p>
<p>$$ = \int_\infty ^1 {{1 \over { - {t^2}{7^{[t]}}}}dt = \int_1^\infty {{1 \over {{t^2}{7^{[t]}}}}dt} } $$</p>
<p>$$ = \int_1^2 {{1 \over {7{t^2}}}dt + \int_2^3 {{1 \over {{7^2}{t^... | mcq | jee-main-2022-online-27th-june-evening-shift | 5,702 |
1l58aq8wy | maths | definite-integration | properties-of-definite-integration | <p>The value of the integral <br/><br/>$${{48} \over {{\pi ^4}}}\int\limits_0^\pi {\left( {{{3\pi {x^2}} \over 2} - {x^3}} \right){{\sin x} \over {1 + {{\cos }^2}x}}dx} $$ is equal to __________.</p> | [] | null | 6 | <p>$$I = {{48} \over {{\pi ^4}}}\int_0^\pi {\left[ {{{\left( {{\pi \over 2} - x} \right)}^3} - {{3{\pi ^2}} \over 4}\left( {{\pi \over 2} - x} \right) + {{{\pi ^3}} \over 4}} \right]{{\sin xdx} \over {1 + {{\cos }^2}x}}} $$</p>
<p>Using $$\int_a^b {f(x)dx = \int_a^b {f(a + b - x)dx} } $$</p>
<p>$$I = {{48} \over {{\... | integer | jee-main-2022-online-26th-june-morning-shift | 5,705 |
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