MCQ 11 Mark
The equation of the plane parallel to the lines $x - 1 = 2y - 5 = 2z$ and $3x = 4y - 11 = 3z -4$ and passing through the point $(2, 3, 3)$ is:
- ✓
$x - 4y + 2z + 4 = 0$
- B
$x + 4y + 2z + 4 = 0$
- C
$x - 4y + 2z - 4 = 0$
- D
AnswerCorrect option: A. $x - 4y + 2z + 4 = 0$
Let $a, b, c$ be the dirction ratios of the required plane.
The given line equation can be rewritten as
$\frac{\text{x}-1}{1}=\frac{\text{y}-\frac{5}{2}}{\frac{1}{2}}=\frac{\text{z}-0}{\frac{1}{2}}\ .....(1)$
$\frac{\text{x}-0}{\frac{1}{3}}=\frac{\text{y}-\frac{11}{4}}{\frac{1}{4}}=\frac{\text{z}-\frac{4}{3}}{\frac{1}{3}}\ .....(2)$
Since the required plane is parallel to the lines $(1)$ and $(2),$
$\text{a}+\frac{\text{b}}{2}+\frac{\text{c}}{2}=0$
$\Rightarrow2\text{a}+\text{b}+\text{c}=0....(3)$
$\frac{\text{a}}{1}=\frac{\text{b}}{-4}=\frac{\text{c}}{2}=0$
$\Rightarrow4\text{a}+3\text{b}+4\text{c}=0....(4)$
Solving $(3)$ and $(4)$ using cross$-$multiplication method, we get
$\frac{\text{a}}{1}=\frac{\text{b}}{-4}=\frac{\text{c}}{2}=\lambda\text{(say)}$
$\Rightarrow\text{a}=\lambda,\text{b}=-4\lambda,\text{c}=2\lambda$
Now, the eqution of the plane whose direction ratios are $\lambda,-4\lambda,2\lambda$ and passing through the point.
$\lambda(\text{x}-2)+(-4\lambda)(\text{y}-3)+2\lambda(\text{z}-3)=0$
$\Rightarrow\text{x}-4\text{y}+2\text{z}+4=0$
View full question & answer→MCQ 21 Mark
The distance between the point $(3, 4, 5)$ and the point where the line $\frac{\text{x}-3}{\text{1}}=\frac{\text{y}-4}{\text{2}}=\frac{\text{z}-5}{\text{2}}$ meets the plane $x + y + z = 17$ is:
AnswerThe coordinates of any point on the given line are of the from
$\frac{\text{x}-3}{\text{1}}=\frac{\text{y}-4}{\text{2}}=\frac{\text{z}-5}{\text{2}}=\lambda$
$\Rightarrow \text{x}=\lambda+3;\text{y}=2\lambda+4;\text{z}=2\lambda+5$
So, the coordinates of the point on the given line are $(\lambda+3,2\lambda+4,2\lambda+5)$
This point lies on the plane
$x + y + z = 17$
$\Rightarrow\lambda+3,2\lambda+4+2\lambda+5=17$
$\Rightarrow5\lambda=5$
$\Rightarrow\lambda=1$
So, the coordinates of the point are
$(\lambda+3,2\lambda+4,2\lambda+5)$
$=(1+3,2(1))+4,2(1)+5)$
$=(4,6,7)$
Now, the distance between the points $(4, 6, 7)$ and $(3, 4, 5)$ is
$\sqrt{(3+4)^2+(4-6)^2+(5-7)^2}$
$\sqrt{1+4+4}$
$=3\text{ units}$
View full question & answer→MCQ 31 Mark
The distance of the line $\vec{\text{r}}=2\hat{\text{i}}-2\hat{\text{j}}+3\hat{\text{k}}+\lambda(\hat{\text{i}}-\hat{\text{j}}+4\hat{\text{k}})$ from the plane $\vec{\text{r}}.(\hat{\text{i}}+5\hat{\text{j}}+\hat{\text{k}})=5$ is:
- A
$\frac{5}{3\sqrt{3}}$
- ✓
$\frac{10}{3\sqrt{3}}$
- C
$\frac{25}{3\sqrt{3}}$
- D
$\text{None of these}$
AnswerCorrect option: B. $\frac{10}{3\sqrt{3}}$
The given line passes through the point whose position vector is $\vec{\text{a}}=2\hat{\text{i}}-2\hat{\text{j}}+3\hat{\text{k}}$
We know that the perpendicular distance of a point $P$ of position vector $\vec{\text{a}}$ from the plane $\vec{\text{r}}.\vec{\text{n}}=\text{d}$ is given by
$\text{P}=\frac{\big|\vec{\text{a}}.\vec{\text{n}}-\text{d}\big|}{|\vec{\text{n}}|}$
Here, $\vec{\text{a}}=2\hat{\text{i}}-2\hat{\text{j}}+3\hat{\text{k}},\vec{\text{n}}=\hat{\text{i}}+5\hat{\text{j}}+\hat{\text{k}},\text{d}=5$
So, the required distance $P$ is given by
$\text{P}=\frac{\Big|\big(2\hat{\text{i}}-2\hat{\text{j}}+3\hat{\text{k}}\big),\big(\hat{\text{i}}+5\hat{\text{j}}+\hat{\text{k}}\big)-5\Big|}{\Big|\hat{\text{i}}+5\hat{\text{j}}+\hat{\text{k}}\Big|}$
$=\frac{|2-10+3-5|}{\sqrt{1+25+1}}$
$=\frac{|-10|}{\sqrt{27}}$
$=\frac{10}{3\sqrt{3}}\text{units}$
View full question & answer→MCQ 41 Mark
The image of the point $(1, 3, 4)$ in the plane $2x - y + z + 3 = 0$ is:
- A
$(3, 5, 2)$
- ✓
$(-3, 5, 2)$
- C
$(3, 5, -2)$
- D
$(3, -5, 2)$
AnswerCorrect option: B. $(-3, 5, 2)$
Let $Q$ be the image of the point $P(1, 3, 4)$ in the plane $2x - y +z + 3 = 0$
Then $PQ$ is normal to the plane.
So, the direction ratios of $PQ$ are proportional to $2, -1, 1$ equation of $PQ$ is
Let the coordinates of $Q$ be $(2r + 1, -r + 3, r + 4)$
Let $R$ be the mid point of $PQ.$
Then,
$\text{R}=\Big(\frac{2\text{r}+1+1}{2},\frac{-\text{r}+3+3}{2},\frac{\text{r}+4+4}{2}\Big)$
$=\Big(\text{r}+1,\frac{-\text{r}+6}{2},\frac{\text{r}+8}{2}\Big)$
Since $R$ lies in the plane $2x - y + z + 3 = 0$,
$2(\text{r}+1)-\Big(\frac{-\text{r}+6}{2}\Big)+\frac{\text{r}+8}{2}+3=0$
$\Rightarrow 4r + 4 + r - 6 + r + 8 + 6 = 0$
$\Rightarrow 6r + 12 = 0$
$\Rightarrow r = -2$
Substituting this in the coordinates of $Q$, we get
$Q = (2r + 1, -r + 3, r + 4)$
$=(2 (-2) + 1, 2 + 3, -2 + 4)$
$=(-3, 5, 2).$
View full question & answer→MCQ 51 Mark
The eqution of the plane $\vec{\text{r}}=\hat{\text{i}}-\hat{\text{j}}+\lambda(\hat{\text{i}}+\hat{\text{j}}+\hat{\text{k}})+\mu(\hat{\text{i}}-2\hat{\text{j}}+3\hat{\text{k}})$ in scalar product from is:
- ✓
$\vec{\text{r}}.(5\hat{\text{i}}-2\hat{\text{j}}-3\hat{\text{k}})=7$
- B
$\vec{\text{r}}.(5\hat{\text{i}}+2\hat{\text{j}}-3\hat{\text{k}})=7$
- C
$\vec{\text{r}}.(5\hat{\text{i}}-2\hat{\text{j}}+3\hat{\text{k}})=7$
- D
$\text{None of these}$
AnswerCorrect option: A. $\vec{\text{r}}.(5\hat{\text{i}}-2\hat{\text{j}}-3\hat{\text{k}})=7$
We know that the equation $\vec{\text{r}}=\vec{\text{a}}+\lambda\vec{\text{b}}+\mu\vec{\text{c}}$ represents a plane passing through a point whose position vectors is $\vec{\text{a}}$ and parrallel to the vectors $\vec{\text{b}}$ and $\vec{\text{c}}$.
Here, $\vec{\text{a}}=\hat{\text{i}}-\hat{\text{j}}+0\hat{\text{k}};\ \vec{\text{b}}=\hat{\text{i}}+\hat{\text{j}}+\hat{\text{k}};\ \vec{\text{c}}=\hat{\text{i}}-2\hat{\text{j}}+3\hat{\text{k}}$
Normal vector, $\vec{\text{n}}=\vec{\text{b}}\times\vec{\text{c}}$
$=\begin{vmatrix}\hat{\text{i}}&\hat{\text{j}}&\hat{\text{k}}\\1&1&1\\1&-2&3\end{vmatrix}$
$=5\hat{\text{i}}-2\hat{\text{j}}-3\hat{\text{k}}$
The vector equation of the plane in scalar product from is
$\vec{\text{r}}.\vec{\text{n}}=\vec{\text{a}}.\vec{\text{n}}$
$\Rightarrow\vec{\text{r}}.\big(5\hat{\text{i}}-2\hat{\text{j}}-3\hat{\text{k}}\big)=\big(\hat{\text{i}}-\hat{\text{j}}-0\hat{\text{k}}\big).\big(5\hat{\text{i}}-2\hat{\text{j}}-3\hat{\text{k}}\big)$
$\Rightarrow\vec{\text{r}}.\big(5\hat{\text{i}}-2\hat{\text{j}}-3\hat{\text{k}}\big)=5+2+0$
$\Rightarrow\vec{\text{r}}.\big(5\hat{\text{i}}-2\hat{\text{j}}-3\hat{\text{k}}\big)=7$
$\Rightarrow\vec{\text{r}}.\big(5\hat{\text{i}}-2\hat{\text{j}}-3\hat{\text{k}}\big)=7$
View full question & answer→MCQ 61 Mark
The plane $2\text{x}-(1-\lambda)\text{y}+3\lambda\text{z}=0$ passes through the intersection of the planes:
- ✓
$2x - y = 0$ and $y- 3z = 0$
- B
$2x + 3z = 0$ and $y = 0$
- C
$2x - y + 3z = 0$ and $y - 3z = 0$
- D
AnswerCorrect option: A. $2x - y = 0$ and $y- 3z = 0$
The given plane is
$2\text{x}-(1-\lambda)\text{y}+3\lambda\text{z}=0$
$\Rightarrow(2\text{x}-\text{y})+\lambda(-\text{y}+3\text{z})=0$
So, this plane passes through the intersection of the planes
$2x - y = 0$ and $-y + 3z = 0$
$\Rightarrow 2x - y = 0$ and $y - 3z = 0.$
View full question & answer→MCQ 71 Mark
A plane meets the coordinate axes at $A, B,$ and $C$ such that the centroid of $\triangle{\text{ABC}}$ is the point $(a, b, c)$ if
the eqution of the plane is $\frac{\text{x}}{\text{a}}+\frac{\text{y}}{\text{b}}+\frac{\text{z}}{\text{c}}=\text{k}$,then $k =$
AnswerLet and be the interceots of the given plane on the coordinate axes.
Then, the plane meets the coordinate axes at
$\text{A}(\alpha,0,0),\text{B}(0,\beta,0)$ and $\text{C}=(0,0,\gamma)$
Given that the centroid of the triangle $= (a, b, c)$
$\Rightarrow\Big(\frac{\alpha+0+0}{3},\frac{0+\beta+0}{3},\frac{0+0+\gamma}{3}\Big)=(\text{a}+\text{b}+\text{c})$
$\Rightarrow\Big(\frac{\alpha}{3},\frac{\beta}{3},\frac{\gamma}{3}\Big)=(\text{a},\text{b},\text{c})$
$\Rightarrow\frac{\alpha}{3}=\text{a},\frac{\beta}{3}=\text{b},\frac{\gamma}{3}=\text{c}$
$\Rightarrow\alpha=3\text{a},\beta=3\text{b},\gamma=3\text{c}\ .....(1)$
Equation of the plane whose intercepts on the coordinate axes are $\alpha,\beta$ and $\gamma$ is
$\frac{\text{x}}{\alpha}+\frac{\text{y}}{\beta}+\frac{\text{z}}{\gamma}=1$
$\Rightarrow\frac{\text{x}}{3\alpha}+\frac{\text{y}}{3\beta}+\frac{\text{z}}{3\gamma}=1\ [\text{From (1)}]$
$\frac{\text{x}}{\text{a}}+\frac{\text{y}}{\text{b}}+\frac{\text{z}}{\text{c}}=3$
View full question & answer→MCQ 81 Mark
The distance between the planes $2x + 2y - z +2 = 0$ and $4x + 4y - 2z + 5 = 0$ is:
- A
$\frac{1}{2}$
- B
$\frac{1}{4}$
- ✓
$\frac{1}{6}$
- D
$\text{None of these}$
AnswerCorrect option: C. $\frac{1}{6}$
Multiplying the first equation of the plane by
$4x + 4y - 2z + 4 = 0$
$4x + 4y - 2z = -4 .....(1)$
The second eqution of the plane is
$4x + 4y - 2z + 5 = 0$
$4x + 4y - 2z = -5 .....(2)$
We know that the distance between two planes $ax + by + cz = d_1$ and $ax + by + cz = d_2$ is,
$=\frac{|\text{d}_2-\text{d}_1|}{\sqrt{\text{a}^2+\text{b}^2+\text{c}^2}}$
So, the required distance
$=\frac{|-5+4|}{\sqrt{4^2+4^2+(-2)^2}}$
$=\frac{|-1|}{\sqrt{16+16+4}}$
$=\frac{1}{\sqrt{36}}$
$=\frac{1}{6}\text{units}$
View full question & answer→MCQ 91 Mark
The vector equation of the plane containing the line $\vec{\text{r}}=(-2\hat{\text{i}}-3\hat{\text{j}}+\hat{\text{k}})+\lambda(3\hat{\text{i}}-2\hat{\text{j}}-\hat{\text{k}})$ and the point $\hat{\text{i}}+2\hat{\text{j}}+3\hat{\text{k}}$ is:
- ✓
$\vec{\text{r}}.(\hat{\text{i}}+3\hat{\text{k}})=10$
- B
$\vec{\text{r}}.(\hat{\text{i}}-3\hat{\text{k}})=10$
- C
$\vec{\text{r}}.(3\hat{\text{i}}+\hat{\text{k}})=10$
- D
$\text{None of these}$
AnswerCorrect option: A. $\vec{\text{r}}.(\hat{\text{i}}+3\hat{\text{k}})=10$
Let the direction ratio of the required plane be proportinal to $a, b, c.$
Scince the required plane contains the line $\vec{\text{r}}=(-2\hat{\text{i}}-3\hat{\text{j}}+\hat{\text{k}})+\lambda(3\hat{\text{i}}-2\hat{\text{j}}-\hat{\text{k}})$
It must pass through the point $(-2, -3, 4)$ and it should be parallel to the line.
So, the equation of the plane is
$a(x + 2) + b(y + 3) + c(z - 4) = 0 ....(1)$ and
$3a - 2b - c = 0 ....(2)$
It is given that plane $(1)$ passes through the point $\hat{\text{i}}+2\hat{\text{j}}+3\hat{\text{k}}$ or $(1, 2, 3).$
$a(1 + 2) + b(2 + 3) + c(3 - 4) = 0$
$3a + 5b - c = 0 .......(3)$
So,
Solving $(1) (2)$ and $(3),$ we get
$\begin{vmatrix}\text{x}+2&\text{y}+3&\text{z}-4\\3&-2&-1\\3&5&-1\end{vmatrix}=0$
$\Rightarrow7(\text{x}+2)+0(\text{y}+3)+21(\text{y}-4)=0$
$\Rightarrow\text{x}+2+3\text{z}-12=0$
$\Rightarrow\text{x}+3\text{z}=10$ or $\vec{\text{r}}.\big(\hat{\text{i}}+3\hat{\text{k}}\big)=10$
View full question & answer→MCQ 101 Mark
The acute angle between the planes $2x - y + z = 0$ and $x + y + 2z = 3$ is:
- A
$45^\circ$
- ✓
$60^\circ$
- C
$30^\circ$
- D
$75^\circ$
AnswerCorrect option: B. $60^\circ$
We know that the angle between the planes $a_1x + b_1y + c_1z + d_1 = 0$ and $a_2x + b_2y + c_2z + d_2 = 0$ is given by
$\cos\theta=\frac{\text{a}_1\text{a}_2+\text{b}_1\text{b}_2+\text{c}_1\text{c}_2}{\sqrt{\text{a}^2_1+\text{b}^2_1+\text{c}^2_1}\sqrt{\text{a}^2_2+\text{b}^2_2+\text{c}^2_2}}$
So, the angle between $2x - y + z = 0$ and $x + y + 2x = 3$ is given by
So, $\cos\theta=\frac{(2)(1)+(-1)(1)+(1)(2)}{\sqrt{2^2+(-1)^2+1^2}\sqrt{1^2+1^2+2^2}}$
$=\frac{2-1+2}{\sqrt{4+1+1}\sqrt{1+1+4}}$
$=\frac{3}{\sqrt{6}\sqrt{6}}=\frac{3}{6}=\frac{1}{2}$
$\Rightarrow\theta\cos^{-1}\Big(\frac{1}{2}\Big)=60^\circ$
View full question & answer→MCQ 111 Mark
The eqution of the plane through the line $x + y + 3 = 0 = 2x - y + 3z + 1$ and parallel to the line $\frac{\text{x}}{1}=\frac{\text{y}}{2}=\frac{\text{z}}{3}$ is:
- ✓
$x - 5y + 3z = 7$
- B
$x - 5y + 3z = -7$
- C
$x + 5y + 3z = 7$
- D
$x + 5y + 3z = -7$
AnswerCorrect option: A. $x - 5y + 3z = 7$
The equation of the plane passing though the line of intersection of the given planes is
$\text{x}+\text{y}+\text{z}+3+\lambda(2\text{x}-\text{y}+3\text{z}+1)=0$
$(1+2\lambda)\text{x}+(1-\lambda)\text{y}+(1+3\lambda)\text{z}+3+\lambda=0\ ....(1)$
This plane is parallel to the line $\frac{\text{x}}{1}=\frac{\text{y}}{2}=\frac{\text{z}}{3}.$
It means that this line is perpendicular to the normal of the plane $(1).$
$\Rightarrow1(1+2\lambda)\text{x}+2(1-\lambda)+3(1+3\lambda)=0($Because $a_1a_2 + b_1b_2 + c_1c_2 = 0)$
$\Rightarrow1+2\lambda+2-2\lambda+3+9\lambda=0$
$\Rightarrow9\lambda+6=0$
$\Rightarrow\lambda=\frac{-2}{3}$
Substituting this in $(1)$, we get
$\Big(1+2\Big(\frac{-2}{3}\Big)\Big)\text{x}+\Big(1-\Big(\frac{-2}{3}\Big)\Big)\text{y}+\Big(1+3\Big(\frac{-2}{3}\Big)\Big)\text{z}+3+\Big(\frac{-2}{3}\Big)=0$
$\Rightarrow -x + 5y - 3z + 7 = 0$
$\Rightarrow x - 5y + 3z = 7$
View full question & answer→MCQ 121 Mark
The equation of the plane through the intersection of the planes $x + 2y + 3z = 4$ and $2x + y - z = -5$ and perpendicular to the plane $5x + 3y + 6z + 8 = 0$ is:
AnswerCorrect option: C. $51x - 15y - 50z + 173 = 0$
The eqution of the plane passing through the line of intersection of the given planes is
$\text{x}+2\text{y}+3\text{z}-4+\lambda(2\text{x}+\text{y}-\text{z}+5)=0$
$(1+2\lambda)\text{x}+(2+\lambda)\text{y}+6(3-\lambda)\text{z}-4+5\lambda=0\ ....(1)$
This plane is perpendicular to $5x + 3y + 6z + 8 = 0.$ So,
$5(1+2\lambda)+3(2+\lambda)+6(3-\lambda)=0 ($Because $a_1a_2 + b_1b_2 + c_1c_2 = 0)$
$\Rightarrow5+10\lambda+6+3\lambda+18-6\lambda=0$
$\Rightarrow7\lambda+29=0$
$\Rightarrow\lambda=\frac{-29}{7}$
Substituting this in (1), we get
$\Big(1+2\Big(\frac{-29}{7}\Big)\Big)\text{x}+\Big(2+\Big(\frac{-29}{7}\Big)\Big)\text{y}+\Big(3+\frac{29}{7}\Big)\text{z}-4+5\Big(\frac{-29}{7}\Big)=0$
$\Rightarrow 51x + 15y - 50z + 173 = 0.$
View full question & answer→MCQ 131 Mark
A vector parallel to the line of intersection of the plance $\vec{\text{r}}.(3\hat{\text{i}}-\hat{\text{j}}+\hat{\text{k}})=1$ and $\vec{\text{r}}.(\hat{\text{i}}-4\hat{\text{j}}+2\hat{\text{k}})=2$ is:
- ✓
$-2\hat{\text{i}}+7\hat{\text{j}}+13\hat{\text{k}}$
- B
$2\hat{\text{i}}+7\hat{\text{j}}-13\hat{\text{k}}$
- C
$-2\hat{\text{i}}-7\hat{\text{j}}+13\hat{\text{k}}$
- D
$2\hat{\text{i}}+7\hat{\text{j}}+13\hat{\text{k}}$
AnswerCorrect option: A. $-2\hat{\text{i}}+7\hat{\text{j}}+13\hat{\text{k}}$
Let the required vector be a $\text{a}\hat{\text{i}}+\text{b}\hat{\text{j}}+\text{c}\hat{\text{k}}\ ....(1)$
Since the vector is parallel to the line of intersection of the given planes,
$3a - b + c = 0 .....(2)$
$a + 4b - 2c = 0 ....(3)$
Solving $(2)$ and $(3),$ we get
$\frac{\text{a}}{-2}=\frac{\text{b}}{7}=\frac{\text{c}}{13}$
Substituting these values in $(1)$, we get
$-2\hat{\text{i}}+7\hat{\text{j}}+13\hat{\text{k}}$ which is the required vector.
View full question & answer→MCQ 141 Mark
The distance of the point $(-1, -5, -10)$ from the point of intersection of the line $\vec{\text{r}}.=2\hat{\text{i}}-\hat{\text{j}}+2\hat{\text{k}}+\lambda(3\hat{\text{i}}+4\hat{\text{j}}+12\hat{\text{k}})$ and the plane $\vec{\text{r}}.=(\hat{\text{i}}-\hat{\text{j}}+\hat{\text{k}})=5$ is:
AnswerGiven equation of line is
$\vec{\text{r}}.=(2\hat{\text{i}}-\hat{\text{j}}+2\hat{\text{k}})+\lambda(3\hat{\text{i}}+4\hat{\text{j}}+12\hat{\text{k}})$
$\vec{\text{r}}.=(2+3\lambda)\hat{\text{i}}+(-1+4\lambda)\hat{\text{j}}+(2+12\lambda)\hat{\text{k}}$
The coordinates of any point on this line are of the from
$(2+3\lambda)\hat{\text{i}}+(-1+4\lambda)\hat{\text{j}}+(2+12\lambda)\hat{\text{k}}$ or $(2+3\lambda,-1+4\lambda,2+12\lambda)$
Scince this point lies on the plane $\vec{\text{r}}.(\hat{\text{i}}-\hat{\text{j}}+\hat{\text{k}})=5,$
$\Big[(2+3\lambda)\hat{\text{i}}+(-1+4\lambda)\hat{\text{j}}+(2+12\lambda)\hat{\text{k}}\Big].(\hat{\text{i}}-\hat{\text{j}}+\hat{\text{k}})=5,$
$\Rightarrow2+3\lambda+1-4\lambda+2+12\lambda-5=0$
$\Rightarrow\lambda=0$
So, the coordinates of the point are
$(2+3\lambda,-1+4\lambda,2+2\lambda)$
$=(2+0,-1+0,2+0)$
$=(2, -1,2)$
Distance between $(2, -1, 2)$ and $(-1, -5, -10)$
$=\sqrt{(1-2)^2+(-5+1)^2+(-10-2)^2}$
$=\sqrt{9+16+144}$
$=13 \text{ units}$
View full question & answer→MCQ 151 Mark
The eqution of the plane which cute equal intercepts of unit length on the coordinate axes is:
- ✓
$x + y + z = 1$
- B
$x + y + z = 0$
- C
$x + y - z = 1$
- D
$x + y + z = 2$
AnswerCorrect option: A. $x + y + z = 1$
We know that the equation of aplane whose intercepts are $a, b, c$ is,
$\frac{\text{x}}{\text{a}}+\frac{\text{y}}{\text{b}}+\frac{\text{z}}{\text{c}}=1\ ....(1)$
It is given that $a = b = c$
So, from $(1),$
$\frac{\text{x}}{\text{a}}+\frac{\text{y}}{\text{b}}+\frac{\text{z}}{\text{c}}=1$
$\Rightarrow\text{x}+\text{y}+\text{z}=\text{a}\ ....(2)$
Since it is given that the intercepts of the required plane are of unit length,
$a = b = c = 1$
Substituting $a = 1$ in $(2),$ we get
$x + y + z = 1$
View full question & answer→MCQ 161 Mark
If a plane passes through the point $(1, 1, 1)$ and is perpendicular to the line $\frac{\text{x}-1}{3}=\frac{\text{y}-1}{0}=\frac{\text{z}-1}{4}$ then its perpendicular distance from the origin is:
- A
$\frac{3}{4}$
- B
$\frac{4}{3}$
- ✓
$\frac{7}{5}$
- D
$1$
AnswerCorrect option: C. $\frac{7}{5}$
Since the plane is perpendicular to the given line, its direction ratios are proportinal to $3, 0, 4.$
So the required equation of the plane is of the form
$3x + 0y + 4z + d = 0 .....(1),$
where $d$ is a constant.
Since this plane passes through $(1, 1, 1),$
$3 + 0 + 4 + d = 0$
$d = -7$
Substituting this in $(1)$, we get
$3x + 0y + 4z -7 = 0 ......(2)$
perpendicular distance of $(2)$ from the origin
$=\frac{|3(0)+0+4(0)-7|}{\sqrt{3^2+0^2+4^2}}$
$=\frac{|0+0-7|}{\sqrt{25}}$
$=\frac{7}{5}\text{ units}$
View full question & answer→MCQ 171 Mark
The distance of the plane through the intersection of the planes $ax + by + cz +d = 0$ and $lx + my + nz + P = 0$ and parallel to the line $y = 0, z = 0$
- ✓
$(bl - am)y + (cl - an)z + dl - ap = 0$
- B
$(am - bl)x + (mc - bn)z + md - bp = 0$
- C
$(na - cl)x + (bn - cm)y + nd - cp = 0$
- D
AnswerCorrect option: A. $(bl - am)y + (cl - an)z + dl - ap = 0$
The equation of the plane passing through the intersection of the planes
$ax + by + cz + d = 0$
and $lx + my + nz + p =0$
Will be $(\text{ax} + \text{by} +\text{cz} +\text{d})+\lambda(\text{lm}+\text{my}+\text{nz}+\text{p})=0$
$\text{x}(\text{a}+\lambda1)+\text{y}(\text{b}+\lambda\text{m})+\text{z}(\text{c}+\lambda\text{n})+(\text{d}+\lambda\text{p})=0\ (1)$
Since the plane is parallel to the line $y = 0$ and $z = 0$
$\text{a}+\lambda1=0$
$\lambda=\frac{-\text{a}}{\text{l}}$
Putting the value of $A$ in eqution $(1),$ we get
$\text{x}\Big(\text{a}+\Big(\frac{\text{-a}}{\text{l}}\Big)\text{l}\Big)+\text{y}\Big(\text{b}+\Big(\frac{-\text{a}}{\text{l}}\Big)\text{m}+\text{y}\Big(\text{c}+\Big(\frac{-\text{a}}{\text{l}}\Big)\text{n}+\text{d}+\Big(\frac{-\text{a}}{\text{l}}\Big)\text{p}=0$
$\text{y}(\text{bl}-\text{am})+\text{z}(\text{cl}-\text{an})+\text{dl}-\text{ap}=0$
Heance, option $(a)$
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The eqution of the plane contaning the two lines $\frac{\text{x}-1}{2}=\frac{\text{y}+1}{-1}=\frac{\text{z}-0}{3}$ and $\frac{\text{x}}{-2}=\frac{\text{y}-2}{-3}=\frac{\text{z}+1}{-1}$ is:
- A
$8x + y - 5z - 7 = 0$
- B
$8x + y + 5z - 7 = 0$
- C
$8x - y - 5z - 7 = 0$
- ✓
Answer$\frac{\text{x}-1}{2}=\frac{\text{y}+1}{-1}=\frac{\text{z}-0}{3}$ and $\frac{\text{x}}{-2}=\frac{\text{y}-2}{-3}=\frac{\text{z}+1}{-1}$
Now, if these two lines lie on a plane,
so the direction ratio of lines will be perpendicular to the plane's normal vector.
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