MCQ Questions for Class 11 Engineering Maths Introduction To Three Dimensional Geometry Quiz 8

The point equidistant from the point $$O(0, 0, 0), A(a, 0, 0), B(0, b, 0)$$ and $$C(0, 0, c)$$ has the coordinates

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$$(a, b, c)$$
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$$(a/2, b/2, c/2)$$
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$$(a/3, b/3, c/3)$$
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$$(a/4, b/4, c/4)$$

If the distance between a point P and the point (1, 1, 1) on the line $$\frac{{x\, - \,1}}{3}\, = \,\frac{{y - \,1}}{4}\, = \,\frac{{z\, - 1}}{{12}}$$ is 13, then the coordinates of P are

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(3, 4, 12)
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$$\left( {\frac{3}{{13}},\,\frac{4}{{13}},\,\frac{{12}}{{13}}} \right)$$
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(4, 5, 12)
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(40, 53, 157)

$$A$$ point $$C$$ with position vector $$\frac{{3a + 4b - 5c}}{3}$$ (where a,b and c are non co-planar vectors) divides the line joining $$A$$ and $$B$$ in the ratio $$2:1$$. If the position vector of $$A$$ is $$a-2b+3c$$, then the position vector of $$B$$ is

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$$2a+3b-4c$$
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$$2a-3b+4c$$
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$$2a+3b+4c$$
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$$a+3b-4c$$

The xy-plane divides the line joining the points (-1, 3, 4) and (2,-5,6).

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internally in the ratio $$2 : 3$$
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externally in the ratio $$2 : 3$$
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internally in the ratio $$3 : 2$$
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externally in the ratio $$3 : 2$$

If $$a,b$$ and $$c$$ are non coplanar vectors then $$-\bar {a}+4\bar {b}-3\bar {c},3\bar {a}+2\bar {b}-5\bar {c},-3\bar {a}+8\bar {b}-5\bar {c},-3\bar {a}+2\bar {b}+\bar {c}$$ are collinear.

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True
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False

Let $$O$$ be the origin and $$P$$ be the point at a distance $$3$$ units from origin. If d.x.s' of OP are 1, - 2, - 2, then coordinates of P is given by

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$$1, - 2, - 2$$
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$$3, - 6, - 6$$
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$$\dfrac{1}{3}, - \dfrac{2}{3}, - \dfrac{2}{3}$$
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$$\dfrac{1}{9}, - \dfrac{2}{9}, - \dfrac{2}{9}$$

If $$A(2, 2, -3), B(5, 6, 9), C(2, 7, 9)$$ be the vertices of a triangle. The internal bisector of the angle $$A$$ meets $$BC$$ at the point $$D$$, then find the coordinates of $$D$$.

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$$(\dfrac{13}{2},\dfrac{7}{2},9)$$
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$$(\dfrac{7}{2},\dfrac{13}{2},9)$$
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$$(\dfrac{9}{2},\dfrac{7}{2},9)$$
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$$(\dfrac{13}{2},\dfrac{9}{2},9)$$

If the lines $$\frac{x - 0}{1} =\frac{y+1}{2}=\frac{z-1}{-1}$$ and $$\frac{x+1}{k}=\frac{y-3}{-2}=\frac{z-2}{1}$$ are at right angles, then the value of k is

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$$5$$
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$$0$$
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$$3$$
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$$-1$$

The vector $$\vec{AF}$$, is given by?

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$$-\left|\dfrac{\vec{a}}{\vec{c}}\right|\vec{c}$$
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$$\left|\dfrac{\vec{a}}{\vec{c}}\right|\vec{c}$$
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$$\dfrac{2|\vec{a}|}{|\vec{c}|}\vec{c}$$
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$$\dfrac{1}{3}\left|\dfrac{\vec{a}}{\vec{c}}\right|\vec{c}$$

The position vector of the vertices of a triangle $$ABC$$ are $$\hat { i } ,\hat { j } ,\hat { k } $$ then the position vector of its orthocentre is

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$$\hat { i } +\hat { j } +\hat { k } $$
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$$2(\hat { i } +\hat { j } +\hat { k } )$$
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$$\cfrac{1}{3}(\hat { i } +\hat { j } +\hat { k } )$$
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$$\cfrac{1}{\sqrt{3}}(\hat { i } +\hat { j } +\hat { k } )$$

The graph of the equation $$y^{2}+z^{2}=0$$ in three dimensional space is

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x- axis
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y- axis
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z- axis
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yz-plane

The area of triangle whose vertices are $$(1, 2, 3), (2, 5, -1)$$ and $$(-1, 1, 2)$$ is

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$$150\ sq. units$$
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$$145\ sq. units$$
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$$\sqrt {155}/2\ sq. units$$
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$$155/2\ sq. units$$

If the point $$(x, y)$$ is equidistant from the points $$(a + b, b - a)$$ and $$(a - b , a + b)$$, then $$bx = ay$$.

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True
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False

A tangent to the curve $$y = f(x)$$ at $$p(x, y)$$ meets $$x - axis$$ at $$A$$ and $$y-axis$$ at $$B$$. If $$\overline {AP} : \overline {BP} = 1 : 3$$ and $$f(1) = 1$$ then the curve also passes through the point.

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$$\left (\dfrac {1}{2}, 4\right )$$
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$$\left (\dfrac {1}{3}, 24\right )$$
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$$\left (2, \dfrac {1}{8}\right )$$
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$$\left (3, \dfrac {1}{28}\right )$$

If the distance between a point $$P$$ and the point $$(1, 1, 1)$$ on the line $$\dfrac {x - 1}{3} = \dfrac {y - 1}{4} = \dfrac {z - 1}{12}$$ is $$13$$, then the coordinates of $$P$$ are

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$$(3, 4, 12)$$
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$$\left (\dfrac {3}{13}, \dfrac {4}{13}, \dfrac {12}{13}\right )$$
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$$(4, 5, 13)$$
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$$(40, 53, 157)$$

The points $$(10,7,0)$$, $$(6,6-1)$$ and $$(6,9,-4)$$ form a

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Right -angled triangle
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Isosceles triangle
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Both $$(1)$$ & $$(2)$$
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Equilateral triangle

The ratio in which the line joining $$(3,4,-7)$$ and $$(4,2,1)$$ is dividing the xy-plane

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$$3:4$$
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$$2:1$$
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$$7:1$$
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$$4:3$$

The ratio in which the line joining points $$(2,4,5)$$ and $$(3,5,-4)$$ divide YZ -plane is

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$$-2:3$$
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$$2:3$$
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$$-3:2$$
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$$3:2$$

The vertices of a triangle are $$)2, 3, 5), (-1, 3, 2), (3, 5, -2)$$, then the angles are

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$$30^o, 30^o, 30^o$$
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$$\cos^{-1}\left(\dfrac{1}{\sqrt{5}}\right), 90^o, \cos^{-1} \left(\dfrac{\sqrt{5}}{\sqrt{3}}\right)$$
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$$30^o, 60^o, 90^o$$
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$$\cos^{-1}\left(\dfrac{1}{\sqrt{3}}\right), 90^o, \cos^{-1} \left(\dfrac{\sqrt{2}}{\sqrt{3}}\right)$$

The values of a for which $$(8, -7, a), (5, 2, 4)$$ and $$(6, -1, 2)$$ are collinear, is given by?

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$$2$$
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$$-2$$
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$$-1$$
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$$1$$

The shortest distance of the point $$(1,2,3)$$ from $${x}^{2}+{y}^{2}=0$$ is

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$$5$$
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$$\sqrt{5}$$
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$$2$$
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$$\sqrt{14}$$

A triangle $$ABC$$ is placed so that the mid-points of the sides are on the $$x,y,z$$ axes. Lengths of the intercepts made by the plane containing the triangle on these axes are respectively $$\alpha, \beta, \gamma$$. Coordinates of the centroid of the triangle $$ABC$$ are

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$$(-\alpha/ 3, \beta/ 3,\gamma/3)$$
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$$(\alpha/3,-\beta/3,\gamma/3)$$
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$$(\alpha/ 3, \beta/3, -\gamma/ 3)$$
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$$(\alpha/3, \beta/ 3, \gamma/ 3)$$

The triangle with vertices $$A (1, 0, 1), B (2, - 1, 4) \ and \ C (3, - 4, - 1),$$ is right-angled.

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True
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False

The distance between two points $$(1,1)$$ and $$\left( {\dfrac{{2{t^2}}}{{1 + {t^2}}},\dfrac{{{{\left( {1 - t} \right)}^2}}}{{1 + {t^2}}}} \right)$$ is

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4t
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3t
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1
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none of these

The plane $$x = 0$$ divides the joinning of $$( - 2, 3, 4)$$ and $$(1, - 2, 3)$$ in the ratio :

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$$2 : 1$$
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$$1 : 2$$
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$$3 : 2$$
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$$ - 4 : 3$$

The points (-5,12), (-2,-3),(9,-10),(6,5) taken in order, form

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Parallelogram
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rectangle
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rhombus
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square

The vertices of a triangle are $$(2, 3, 5), (-1, 3, 2), (3, 5, -2)$$, then the angles are

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$$30^{\circ}, 30^{\circ}, 120^{\circ}$$
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$$\cos^{-1} \left (\dfrac {1}{\sqrt {5}}\right ), 90^{\circ}, \cos^{-1} \left (\dfrac {\sqrt {5}}{\sqrt {3}}\right )$$
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$$30^{\circ}, 60^{\circ}, 90^{\circ}$$
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$$\cos^{-1} \left (\dfrac {1}{\sqrt {3}}\right ), 90^{\circ}, \cos^{-1} \left (\sqrt{\dfrac { {2}}{ {3}}}\right )$$

The plane passing through the point $$\left(-2,-2,2\right)$$ and containing the line joining the points $$\left(1,1,1\right)$$ and $$\left(1,-1,2\right)$$ makes intercepts on the coordinates axes, the sum whose lengths is ?

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$$3$$
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$$4$$
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$$6$$
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$$12$$

The nearest point from the origin is

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$$(2,3,-1)$$
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$$(-3,2,1)$$
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$$(2,2,2)$$
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$$(1,2,-1)$$

The points $$(3,\ 2,\ 0),\ (5,\ 3,\ 2)$$ and $$(-9,\ 6,\ -3)$$, are the vertices of a triangle $$ABC.AD$$ is the internal bisector of $$\angle\ BAC$$ which meets $$BC$$ at $$D$$. Then the co-ordinates of $$D$$, are

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$$\left[ {\dfrac{{17}}{{16}},\ \dfrac{{57}}{{16}},\ \dfrac{{19}}{8}} \right]$$
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$$\left[ {\dfrac{{19}}{{8}},\ \dfrac{{57}}{{16}},\ \dfrac{{17}}{16}} \right]$$
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$$\left[0,\ 0,\ {\dfrac{{17}}{{16}}}\right]$$
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$$\left[{\dfrac{{17}}{{16}}},\ 0,\ 0\right]$$

CBSE Questions for Class 11 Engineering Maths Introduction To Three Dimensional Geometry Quiz 8 - MCQExams.com

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Practice Class 11 Engineering Maths Quiz Questions and Answers

CBSE Questions for Class 11 Engineering Maths Introduction To Three Dimensional Geometry Quiz 8 - MCQExams.com

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Practice Class 11 Engineering Maths Quiz Questions and Answers

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