MCQ Questions for Class 11 Engineering Maths Complex Numbers And Quadratic Equations Quiz 8

The locus of $$z$$ such that $$\left| {\dfrac{{z + i}}{{z - 1}}} \right| = 2$$

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straight line
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circle with radius $$2$$
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circle with radius $$\frac{{2\sqrt 2 }}{3}$$
0%
none of these

$$\left(\dfrac{1 + i}{1 - i}\right)^4 + \left(\dfrac{1 - i}{1 + i}\right)^4 = $$

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$$0$$
0%
$$1$$
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$$2$$
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$$4$$

If $$|z_1+z_2|=|z_1|+|z_2|$$ where $$z_1$$ and $$z_2$$ are different non - zero complex number, then ?

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$$Re\left(\dfrac{z_1}{z_2}\right)=0$$
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$$Im\left(\dfrac{z_1}{z_2}\right)=0$$
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$$z_1+z_2=0$$
0%
None

Explanation

$$let\quad { z }_{ 1 }=a+ib\quad \quad and\quad \quad { z }_{ 2 }=c+id\\ \Rightarrow \quad \left| \quad { z }_{ 1 }+\quad { z }_{ 2 } \right| \quad \quad \quad \quad =\quad \quad \quad \left| \quad { z }_{ 1 } \right| +\left| \quad { z }_{ 2 } \right| \\ \Rightarrow \quad \quad \left| a+ib+c+id \right| \quad =\quad \quad \left| a+ib \right| +\left| c+id \right| \\ \Rightarrow \left| a+c+i\left( b+d \right) \right| \quad \quad \quad =\quad \quad \quad \left| a+ib \right| +\left| c+id \right| \\ \Rightarrow \sqrt { \left( a+c \right) ^{ 2 }+\left( b+d \right) ^{ 2 } } =\quad \quad \sqrt { { a }^{ 2 }+{ b }^{ 2 } } +\sqrt { { c }^{ 2 }+d^{ 2 } } \\ \quad \quad \quad \quad squaring\quad both\quad sides\\ \Rightarrow \left( a+c \right) ^{ 2 }+\left( b+d \right) ^{ 2 }={ a }^{ 2 }+{ b }^{ 2 }+{ c }^{ 2 }+d^{ 2 }+2\sqrt { { a }^{ 2 }+{ b }^{ 2 } } .\sqrt { { c }^{ 2 }+d^{ 2 } } \\ \Rightarrow 2ac+2bd\quad \quad =\quad \quad 2\sqrt { { a }^{ 2 }+{ b }^{ 2 } } .\sqrt { { c }^{ 2 }+d^{ 2 } } \\ \Rightarrow ac+bd\quad \quad =\quad \quad \sqrt { { a }^{ 2 }+{ b }^{ 2 } } .\sqrt { { c }^{ 2 }+d^{ 2 } } \\ \quad \quad \quad again\quad squaring\quad both\quad sides\\ \Rightarrow { \left( ac \right) }^{ 2 }+{ \left( bd \right) }^{ 2 }+2abcd\quad =\quad \left( { a }^{ 2 }+{ b }^{ 2 } \right) \left( { c }^{ 2 }+d^{ 2 } \right) \\ \Rightarrow { \left( ac \right) }^{ 2 }+{ \left( bd \right) }^{ 2 }+2abcd\quad =\quad { \left( ac \right) }^{ 2 }+{ \left( ad \right) }^{ 2 }+{ \left( bc \right) }^{ 2 }+{ \left( bd \right) }^{ 2 }\\ \Rightarrow { \left( ad \right) }^{ 2 }+{ \left( bc \right) }^{ 2 }-2abcd\quad =\quad 0\\ \Rightarrow \left( ad-bc \right) ^{ 2 }\quad \quad \quad \quad \quad \quad \quad \quad \quad =\quad 0\\ \Rightarrow ad-bc\quad \quad \quad \quad \quad \quad \quad \quad \quad \quad \quad =\quad 0\\ \quad \quad \quad \quad \quad \quad \quad \quad \quad \quad \quad \quad ad\quad \quad =\quad \quad \quad bc\quad \quad \quad \quad \longrightarrow \left( 1 \right) \\ Now\quad \quad \dfrac { { z }_{ 1 } }{ { z }_{ 2 } } \quad =\quad \dfrac { a+ib }{ c+id } \\ \quad \quad \quad \quad \quad \quad \quad \quad \quad =\quad \dfrac { \left( a+ib \right) \left( c-id \right) }{ \left( c+id \right) \left( c-id \right) } \\ \quad \quad \quad \quad \quad \quad \quad \quad \quad =\quad \dfrac { ac-iad+ibc-{ i }^{ 2 }bd }{ { c }^{ 2 }+{ d }^{ 2 } } \\ \quad \quad \quad \quad \quad \quad \quad \quad \quad =\quad \dfrac { ac+bd+i\left( bc-ad \right) }{ { c }^{ 2 }+{ d }^{ 2 } } \quad \quad \quad \\ \quad \quad \quad \quad \quad \quad \quad \quad \quad =\quad \dfrac { ac+bd }{ { c }^{ 2 }+{ d }^{ 2 } } \quad +\quad 0\quad \quad \quad using\quad equation\quad \left( 1 \right) \\ Imaginary\quad part\quad is\quad zero\quad as\quad there\quad is\quad only\quad real\quad part\\ \therefore \quad Im\left( \frac { { z }_{ 1 } }{ { z }_{ 2 } } \right) =\quad 0$$

Modulus of $$\dfrac{\cos \theta - i\sin \theta}{\sin \theta - i \cos \theta}$$ is

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$$0$$
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$$2\theta$$
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$$\pi - 2\theta$$
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None of these

If $$\cfrac{\pi}{3}$$ and $$\cfrac{\pi}{4}$$ are the arguments of $${z}_{1}$$ and $${\overline { z } }_{ 2 }$$, then the value of arg $$({z}_{1}{z}_{2})$$ is

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$$\cfrac{5\pi}{12}$$
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$$\cfrac{\pi}{12}$$
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$$\cfrac{7\pi}{12}$$
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None of these

$$n\in N,\ { \left( \dfrac { 1+i }{ \sqrt { 2 } } \right) }^{ 8n }+{ \left( \dfrac { 1-i }{ \sqrt { 2 } } \right) }^{ 8n }=$$

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$$0$$
0%
$$1$$
0%
$$2$$
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$$-2$$

The roots of the equation $${x}^{\sqrt{x}}={(\sqrt{x})}^{x}$$ are

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$$0$$ and $$1$$
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$$0$$ and $$4$$
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$$1$$ and $$4$$
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$$0,1$$ and $$4$$

$$\left(\dfrac{1+\cos \dfrac{\pi}{8}+i\sin \dfrac{\pi}{8}}{1+\cos \dfrac{\pi}{8}-i\sin \dfrac{\pi}{8}}\right)^{8}=$$ ?

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$$1+i$$
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$$1-i$$
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$$1$$
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$$-1$$

The complex number $$z$$ satisfies $$z+|z|=2+8i$$. The value of $$|z|$$ is

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$$10$$
0%
$$13$$
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$$17$$
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$$23$$

For a complex number $$z$$, the minimum value of $$\left| z \right| + \left| {z - 1} \right|$$ is

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1
0%
2
0%
3
0%
none of these

The value of $$\sum\limits_{n = 1}^{13} {\left( {{i^n} + {i^{n + 1}}} \right)} $$, where $$i = \sqrt { - 1} $$ equals:

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$$i$$
0%
$$i - 1$$
0%
$$ - i$$
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0

The modulus of the complex quantity $$(2-3i)(-1+7i)$$.

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$$5\sqrt{13}$$
0%
$$5\sqrt{26}$$
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$$13\sqrt{5}$$
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$$26\sqrt{5}$$

If A and B be two complex numbers satisfying $$\dfrac{A}{B}+\dfrac{B}{A}=1$$. Then the two points represented by A and B and the origin form the vertices of

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An equilateral triangle
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An isosceles triangle which is not equilateral
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An isosceles triangle which is not right angled
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A right angled triangle

$$3+2\ i\ \sin \theta$$ will be real, if $$\theta=$$

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$$2n \pi $$
0%
$$n \pi +\pi/2$$
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$$n\pi$$
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$$none\ of\ these$$

If $$z_{1},\ z_{2}$$ are two complex numbers such that $$arg\left( { z }_{ 1 }+{ z }_{ 2 } \right) =0$$ and $$Im\left( { z }_{ 1 }{ z }_{ 2 } \right) =0$$, then

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$$z_{1}=-z_{2}$$
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$$z_{1}=z_{2}$$
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$$z_{1}=\bar { { z }_{ 2 } } $$
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$$none\ of\ these$$

The argument of the complex number $$\sin \dfrac {6\pi}{5}+i\left(1+\cos \dfrac {6\pi}{5}\right)$$ is

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$$\dfrac {6\pi}{5}$$
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$$\dfrac {5\pi}{6}$$
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$$\dfrac {9\pi}{10}$$
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$$\dfrac {2\pi}{5}$$

Let $$a, b, c\epsilon R_{0}$$ and $$1$$ be a root of the equation $$ax^{2} + bx + c = 0$$, then the equation $$4ax^{2} + 3bx + 2c = 0$$ has

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Imaginary roots
0%
Real and equal roots
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Real and unequal roots
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Rational roots

If z is a complex number such that $$|z|\ge 2$$, then the minimumm value of $$\left|z+\dfrac{1}{2}\right|$$:

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is equal to $$\dfrac{5}{2}$$
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lies in the interval $$(1,2)$$
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is strictly greater then $$\dfrac{5}{2}$$
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is strictly greater than $$\dfrac{3}{2}$$ but less than $$\dfrac{5}{2}$$

The complex no. $$\dfrac{1+2i}{1-i}$$ lies in which quadrant of the complex plane

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first
0%
second
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third
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fourth

If $$z \neq 0$$, then $$ \overset{100}{\underset{0}{\int}}arg(-|z|)dx =$$

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$$0$$
0%
Not defined
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$$100$$
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$$100\pi$$

If $$z$$ is purely real and $$Re(z)<0$$, then $$arg(x)$$ is

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$$0$$
0%
$${\pi}$$
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$$-{\pi}$$
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$$\dfrac{\pi}{2}$$

If $$Z$$ is a complex number such that $$|z| \ge 2$$,
then the minimum value of $$\left|z + \dfrac{1}{2}\right|$$

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Is equal to $$\dfrac{5}{2}$$
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Lies in the interval $$(1, 2)$$
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Is strictly grater than $$\dfrac{5}{2}$$
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Is strictly greater than $$\dfrac{3}{2}$$ but less than $$\dfrac{5}{2}$$

If $$|z|=1$$ and $$|\omega -1| =1$$ where $$z, \omega \in C$$, then the largest set of values of $$|2z - 1|^2 + | 2\omega -1|^2$$ equals

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$$[1, 9]$$
0%
$$[2, 6]$$
0%
$$[2, 12]$$
0%
$$[2, 18]$$

If for complex number $$z_{1}and z_{2}arg(z_{1})-arg(z_{2})=0then \mid z_{ 1}-z_{2}\mid $$ is equal to:

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$$ \mid z_{1}+z_{2}\mid $$
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$$ \mid z_{1}\mid +\mid z_{2}\mid$$
0%
$$ \parallel z_{1}\mid -\mid z_{2}\parallel$$
0%
0

If $$z_{1}$$ and $$z_{2}$$ are two non zero complex numbers such that $$|z_{1}+z_{2}|=|z_{1}|+|z_{2}|$$ then $$arg\ z_{1} $$-$$arg\ z_{2}$$ is equal to

0%
$$-\pi$$
0%
$$\dfrac {\pi}{2}$$
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$$-\dfrac {\pi}{2}$$
0%
$$0$$

Argument and modules of $$[\dfrac{1+i}{1-i}]^{2\pi i}$$ are respectively.................

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$$\dfrac{-\pi}{2}$$ and $$1$$
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$$\dfrac{\pi}{2}$$ and $$\sqrt{2}$$
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$$0$$ and $$\sqrt{2}$$
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$$\dfrac{\pi}{2}$$ and $$1$$

In Argand diagram, O, P, Q represents the origin, $$z$$ and $$z+iz$$
respectively. then $$\angle OPQ = $$

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$$\dfrac{\pi }{4}$$
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$$\dfrac{\pi }{6}$$
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$$\dfrac{\pi }{2}$$
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$$\dfrac{\pi }{3}$$

What is the modulus of following complex number:$$-2+2\sqrt { 3i } $$

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4
0%
5
0%
2
0%
3

If $$\theta$$ and $$\phi$$ are the roots of the equation $$8x^{2}+22x+5=0$$, then

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both $$\sin^{-1}{\theta}$$ and $$\sin^{-1}{\phi}$$ are real
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both $$\sec^{-1}{\theta}$$ and $$\sec^{-1}{\phi}$$ are real
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both $$\tan^{-1}{\theta}$$ and $$\tan^{-1}{\phi}$$ are real
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None of these

If root of the equation $${ \left( q-r \right) x }^{ 2 }+\left( r-p \right) x+\left( p-q \right) =0$$ are equal, then $$p,q,r$$ are in

0%
$$AP$$
0%
$$GP$$
0%
$$HP$$
0%
$$None\ of\ these$$

The integral values of $$'a'$$ for which the equation $$\cos ^{2}x-(a^{2}+a+5)|\cos x|+(a^{3}+3a^{2}+2a+6)=0$$ has real solution(s)

0%
$$-3$$
0%
$$-2$$
0%
$$-1$$
0%
$$0$$

If $$x_{r}=\cos(\dfrac{\pi}{3^{r}})+i\sin(\dfrac{\pi}{3^{r}})$$, then $$x_{1}x_{2}x_{3}$$.... upto $$infinity=i$$.

0%
True
0%
False

If $$z=(3+7i)(p+iq)$$ where $$p,q\in I-\left\{ 0 \right\} $$, is purely imaginary then minimum value of $${ \left| z \right| }^{ 2 }$$ is

0%
$$0$$
0%
$$58$$
0%
$$\dfrac{3364}{3}$$
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$$3364$$

The figure formed by four points $$1+0i;-1+0i,3+4i$$ and $$\cfrac{25}{-3-4i}$$ on the argand plane is

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parallelogram but not a rectangle
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a trapesium which is not equilateral
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cyclic quadrilateral
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none of these

The amplitude of $$\cfrac { 1+\sqrt { 3i } }{ \sqrt { 3 } +1 } $$ is

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$$\cfrac { \pi }{ 3 } $$
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$$-\cfrac { \pi }{ 3 } $$
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$$\cfrac { \pi }{ 6 } $$
0%
$$-\cfrac { \pi }{ 6 } $$

If $$Z = \frac{{1 - \sqrt 3 i}}{{1 + \sqrt 3 i}}$$ then find $$arg(z).$$

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$$- \dfrac{2\pi }{3} $$
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$$ \dfrac{2\pi }{5} $$
0%
$$ \dfrac{\pi }{3} $$
0%
$$ \dfrac{2\pi }{3} $$

If $$\left| {z + 2 - i} \right| = 5$$ then the maximum value of $$\left| {3z + 9 - 7i} \right|$$ is

0%
18
0%
19
0%
20
0%
8

The set of the possible values of $$a$$ for which the expression $$x^{2}-ax+1-2a^{2}$$ is always positive is $$(\alpha, \beta)$$, then

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$$\alpha-2\beta=2$$
0%
$$\alpha+2\beta=2$$
0%
$$\beta+2\alpha=2$$
0%
$$\beta-2\alpha=2$$

If $$\left|z\right|=1$$ and $$\varpi=\dfrac{z-1}{z+1}$$, where $$z\neq-1$$, then $$Re\left(\varpi\right)$$ is

0%
$$0$$
0%
$$-\dfrac{1}{|z+1|^{2}}$$
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$$\dfrac{1}{\sqrt{2}}{\left|z+1\right|^{2}}$$
0%
$$\dfrac{\sqrt{2}}{|z+1|^{2}}$$

If $$a,b,c$$ are distinct, positive in $$H.P$$, then quadratic equation $${ ax }^{ 2 }+2bx+c=0$$ has

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Two non-real roots such that their sum is real
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Two distinct real roots
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Two non real conjugate roots
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Two equal real roots

The root of the equation $${\left| x \right|^2} + \left| x \right| - 6 = 0$$ are -

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only one real number
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real and sum =$$1 \, or \, -1$$
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real and sum =$$0$$
0%
real and product =$$0$$

If $$z=(3+7i)(p+iq)$$, where $$p,q\in I-\left\{ 0 \right\} $$, is a purely imaginary, then minimum value of $${ \left| z \right| }^{ 2 }$$ is

0%
$$0$$
0%
$$58$$
0%
$$\cfrac{3364}{3}$$
0%
$$3364$$

If $$z=\dfrac{\sqrt{3}}{2}+\dfrac{1}{2}i$$ then $$z\bar{z}$$ is

0%
$$-1$$
0%
$$0$$
0%
$$1$$
0%
$$2$$

Solve $$i^{57}+\dfrac{1}{i^{125}}$$

0%
$$0$$
0%
$$2i$$
0%
$$-2i$$
0%
$$2$$

$$(y^{2}+1)^{2}-y^{2}=0$$ has .

0%
No real roots
0%
One real root
0%
Two real roots
0%
Three real roots
0%
None of these

If $$z_{1} and z_{2} are on straight line$$ $$\left| \frac { 1 } { 2 } \left( z _ { 1 } + z _ { 2 } \right) + \sqrt { z _ { 1 } z _ { 2 } } \right| + \left| \frac { 1 } { 2 } \left( z _ { 1 } + z _ { 2 } \right) - \sqrt { z _ { 1 } z _ { 2 } } \right| =$$

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$$\left| z _ { 1 } + z _ { 2 } \right|$$
0%
$$\left| z _ { 1 } - z _ { 2 } \right|$$
0%
$$\left| z _ { 1 } \right| + \left| z _ { 2 } \right|$$
0%
$$\left| z _ { 1 } \right| - \left| z _ { 2 } \right|$$

The value of $$2x^{4}+5x^{3}+7x^{2}-x+41$$, when $$x=-2-\sqrt{3i}$$ is:

0%
-4
0%
4
0%
-6
0%
6

The argument of the complex number $$\sin \dfrac{{6\pi }}{5} + i\left( {1 + \cos \dfrac{{6\pi }}{5}} \right)$$ is

0%
$$\dfrac{{6\pi }}{5}$$
0%
$$\dfrac{{5\pi }}{5}$$
0%
$$\dfrac{{9\pi }}{10}$$
0%
$$\dfrac{{7\pi }}{10}$$

If $$Re(\dfrac{z+2i}{z+4})=0$$ then z lies on a circle with center:

0%
(-2,-1)
0%
(-2,1)
0%
(2,-1)
0%
(2,1)

If the six solutions of $$x^6 = -64$$ are written in the form $$a + bi$$, where $$a$$ and $$b$$ are real, then the product those solution with $$a < 0$$, is

0%
$$4$$
0%
$$8$$
0%
$$16$$
0%
$$64$$

CBSE Questions for Class 11 Engineering Maths Complex Numbers And Quadratic Equations Quiz 8 - MCQExams.com

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Practice Class 11 Engineering Maths Quiz Questions and Answers

CBSE Questions for Class 11 Engineering Maths Complex Numbers And Quadratic Equations Quiz 8 - MCQExams.com

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Practice Class 11 Engineering Maths Quiz Questions and Answers

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