Let the circle $x^2 + y^2 = 4$ intersect x-axis at the points A$(a, 0)$, $a > 0$ and B$(b, 0)$. Let $P(2 \cos \alpha, 2 \sin \alpha)$, $0 < \alpha < \frac{\pi}{2}$ and $Q(2 \cos \beta, 2 \sin \beta)$ be two points such that $(\alpha - \beta) = \frac{\pi}{2}$. Then the point of intersection of AQ and BP lies on :
$x^2 + y^2 - 4x - 4 = 0$
$x^2 + y^2 - 4x - 4y = 0$
$x^2 + y^2 - 4x - 4y - 4 = 0$
$x^2 + y^2 - 4y - 4 = 0$
Let $y=x$ be the equation of a chord of the circle $\mathrm{C}_1$ (in the closed half-plane $x \geq 0$ ) of diameter 10 passing through the origin. Let $\mathrm{C}_2$ be another circle described on the given chord as its diameter. If the equation of the chord of the circle $\mathrm{C}_2$, which passes through the point $(2,3)$ and is farthest from the center of $\mathrm{C}_2$, is $x+a y+b=0$, then $a-b$ is equal to
-6
10
6
-2
Let a circle of radius 4 pass through the origin O , the points $\mathrm{A}(-\sqrt{3} a, 0)$ and $\mathrm{B}(0,-\sqrt{2} b)$, where $a$ and $b$ are real parameters and $a b \neq 0$. Then the locus of the centroid of $\triangle \mathrm{OAB}$ is a circle of radius
$\frac{7}{3}$
$\frac{11}{3}$
$\frac{5}{3}$
$\frac{8}{3}$
Let the set of all values of $r$, for which the circles $(x+1)^2+(y+4)^2=r^2$ and $x^2+y^2-4 x-2 y-4=0$ intersect at two distinct points be the interval $(\alpha, \beta)$. Then $\alpha \beta$ is equal to
21
24
20
25
Let PQ and MN be two straight lines touching the circle $x^2+y^2-4 x-6 y-3=0$ at the points $A$ and $B$ respectively. Let $O$ be the centre of the circle and $\angle A O B=\pi / 3$. Then the locus of the point of intersection of the lines PQ and MN is :
$x^2+y^2-18 x-12 y-25=0$
$x^2+y^2-12 x-18 y-25=0$
$3\left(x^2+y^2\right)-12 x-18 y-25=0$
$3\left(x^2+y^2\right)-18 x-12 y+25=0$
Explanation:
$P\left(x_1 y_1\right)$ and point $Q\left(x_2, y_2\right)$
Mid point of $\mathrm{PQ} M=\left(\frac{x_1+x_2}{2}, \frac{y_1+y_2}{2}\right)$
Substitute M into $x-y+1=0$
$ x_1+x_2-y_1-y_2+2=0 . .(i) $
Slope of PQ is Perpendicular to slope of bisector line So, slope of $P Q=-1$
$ y_2=x_1-x_2+y_1 \ldots . .(i i) $
$Q\left(x_2, y_2\right)$ lie on $5 x+y+2=0$
So, $5 x_2+y_2+2=0 \ldots \ldots$. (iii)
Substitute (iii) in (i)
$ x_2=\frac{-x_1-y_1-2}{4} \ldots .(i v) $
Substitute (iii) in (ii)
$ x_2=y_1-1 \ldots . .(v) $
From (iv) and (v)
$ x_1=2-5 y $
$\left(x_1, y_1\right)$ lie on circle
$ x_1^2+y_1^2=4 $
Pt $x_1=2-5 y_1$
$ y_1=0,-\frac{10}{13} $
So, $x_1=2, \frac{-24}{13}$
So, $2+\left(-\frac{24}{13}\right)=\frac{2}{13}$
So, $13 \times \frac{2}{13}=2$
Let $C_1$ be the circle in the third quadrant of radius 3 , that touches both coordinate axes. Let $C_2$ be the circle with centre $(1,3)$ that touches $\mathrm{C}_1$ externally at the point $(\alpha, \beta)$. If $(\beta-\alpha)^2=\frac{m}{n}$ , $\operatorname{gcd}(m, n)=1$, then $m+n$ is equal to
Let a circle C pass through the points (4, 2) and (0, 2), and its centre lie on 3x + 2y + 2 = 0. Then the length of the chord, of the circle C, whose mid-point is (1, 2), is:
4$\sqrt{2}$
2$\sqrt{2}$
2$\sqrt{3}$
$\sqrt{3}$
Let the line x+y=1 meet the circle $x^2+y^2=4$ at the points A and B. If the line perpendicular to AB and passing through the mid-point of the chord AB intersects the circle at C and D, then the area of the quadrilateral ABCD is equal to :
$ \sqrt{14} $
$ 3\sqrt{7} $
$ 2\sqrt{14} $
$ 5\sqrt{7} $
Let the equation of the circle, which touches $x$-axis at the point $(a, 0), a>0$ and cuts off an intercept of length $b$ on $y-a x i s$ be $x^2+y^2-\alpha x+\beta y+\gamma=0$. If the circle lies below $x-a x i s$, then the ordered pair $\left(2 a, b^2\right)$ is equal to
Let circle $C$ be the image of $x^2+y^2-2 x+4 y-4=0$ in the line $2 x-3 y+5=0$ and $A$ be the point on $C$ such that $O A$ is parallel to $x$-axis and $A$ lies on the right hand side of the centre $O$ of $C$. If $B(\alpha, \beta)$, with $\beta<4$, lies on $C$ such that the length of the arc $A B$ is $(1 / 6)^{\text {th }}$ of the perimeter of $C$, then $\beta-\sqrt{3} \alpha$ is equal to
A circle C of radius 2 lies in the second quadrant and touches both the coordinate axes. Let r be the radius of a circle that has centre at the point $(2,5)$ and intersects the circle $C$ at exactly two points. If the set of all possible values of r is the interval $(\alpha, \beta)$, then $3 \beta-2 \alpha$ is equal to :
Let $C$ be the circle $x^2+(y-1)^2=2, E_1$ and $E_2$ be two ellipses whose centres lie at the origin and major axes lie on x -axis and y -axis respectively. Let the straight line $x+y=3$ touch the curves $C, E_1$ and $E_2$ at $P\left(x_1, y_1\right), Q\left(x_2, y_2\right)$ and $R\left(x_3, y_3\right)$ respectively. Given that $P$ is the mid point of the line segment $Q R$ and $P Q=\frac{2 \sqrt{2}}{3}$, the value of $9\left(x_1 y_1+x_2 y_2+x_3 y_3\right)$ is equal to _______.
Explanation:
Solving the line $x+y=3$, and the circle $x^2+$ $(y-1)^2=2$
Substitute $y=3-x$ :
$\begin{aligned} & x^2+(3-x-1)^2=2 \\ & \Rightarrow x^2-2 x+1=0 \\ & \Rightarrow x=1 \Rightarrow y=2 \end{aligned}$
So, $P=\left(x_1, y_1\right)=(1,2) \Rightarrow x_1 y_1=1 \cdot 2=2$
Use midpoint condition
Let $Q=\left(x_2, y_2\right), R=\left(x_3, y_3\right)$.
Since $P$ is the midpoint of QR:
$x_2+x_3=2 x_1=2, y_2+y_3=2 y_1=4
$So, we can write: $x_3=2-x_2, y_3=4-y_2$
Given,
$P Q=\frac{2 \sqrt{2}}{3} \Rightarrow P Q^2=\left(x_2-1\right)^2+\left(y_2-2\right)^2=\frac{8}{9}$
Let's denote: $x_2=a, y_2=b, x_3=2-a, y_3=4-b$
$\begin{aligned} & (a-1)^2+(b-2)^2=\frac{8}{9} \\ & \Rightarrow a^2-2 a+1+b^2-4 b+4=\frac{8}{9} \\ & \Rightarrow a^2+b^2-2 a-4 b+5=\frac{8}{9} \\ & \Rightarrow 9 a^2+9 b^2-18 a-36 b+37=0 \end{aligned}$
Hence, $a=\frac{5}{3}, b=\frac{4}{3}$
$\begin{aligned} & x_1 y_1+x_2 y_2+x_3 y_3=2+a b+(2-a)(4-b) \\ & 9\left(x_1 y_1+x_2 y_2+x_3 y_3\right)=9(10+2 a b-2 b-4 a) \\ & =90+18 a b-18 b-36 a=46 \end{aligned}$
The absolute difference between the squares of the radii of the two circles passing through the point $(-9,4)$ and touching the lines $x+y=3$ and $x-y=3$, is equal to ________ .
Explanation:
$\because x+y=3$ and $x-y=3$ are tangents
$\therefore \quad$ Both circle centre will lie on $x$-axis
$\therefore(x-a)^2+y^2=r^2$
Hence centre is $C(\alpha, 0)$
$\begin{aligned} &r=\sqrt{(\alpha+9)^2+16}\quad\text{.... (1)}\\ &\text { Also }\left|\frac{\alpha-3}{\sqrt{2}}\right|=r \quad\text{.... (2)}\\ &\begin{aligned} & \sqrt{(\alpha+9)^2+16}=\left|\frac{\alpha-3}{\sqrt{2}}\right| \\ & \Rightarrow \quad \alpha=-5 \text { or }-37 \\ & \mathrm{r}=\left|\frac{-5-3}{\sqrt{2}}\right| \text { or }\left|\frac{-37-3}{\sqrt{2}}\right| \\ & =4 \sqrt{2} \text { or } 20 \sqrt{2} \\ & \left|\mathrm{r}_1^2-\mathrm{r}_2^2\right|=|32-800|=768 \end{aligned} \end{aligned}$
Let the circle $C$ touch the line $x-y+1=0$, have the centre on the positive $x$-axis, and cut off a chord of length $\frac{4}{\sqrt{13}}$ along the line $-3 x+2 y=1$. Let H be the hyperbola $\frac{x^2}{\alpha^2}-\frac{y^2}{\beta^2}=1$, whose one of the foci is the centre of $C$ and the length of the transverse axis is the diameter of $C$. Then $2 \alpha^2+3 \beta^2$ is equal to ________.
Explanation:
$\begin{aligned} &x-y+1=0\\ &\mathrm{p}=\mathrm{r}\\ &\left|\frac{\alpha-0+1}{\sqrt{2}}\right|=r \Rightarrow(\alpha+1)^2=2 r^2\quad\text{.... (1)} \end{aligned}$
$\begin{aligned} & \text { now }\left(\frac{-3 \alpha+0-1}{\sqrt{9+4}}\right)^2+\left(\frac{2}{\sqrt{13}}\right)^2=\mathrm{r}^2 \\ & \Rightarrow(3 \alpha+1)^2+4=13 \mathrm{r}^2 \ldots \ldots .(2) \\ & \text { (1) & }(2) \Rightarrow(3 \alpha+1)^2+4=13 \frac{(\alpha+1)^2}{2} \\ & \quad \Rightarrow 18 \alpha^2+12 \alpha+2+8=13 \alpha^2+26 \alpha+13 \\ & \Rightarrow 5 \alpha^2-14 \alpha-3=0 \\ & \Rightarrow 5 \alpha^2-15 \alpha+\alpha-3=0 \\ & \Rightarrow 5 \alpha^2-15 \alpha+\alpha-3=0 \\ & \Rightarrow \alpha=\frac{-1}{5}, 3 \end{aligned}$
$\begin{aligned} &\therefore \quad r=2 \sqrt{2}\\ &\text { How } \alpha \mathrm{e}=3 \text { and } 2 \alpha=4 \sqrt{2}\\ &\begin{aligned} & \alpha^2 \mathrm{e}^2=9 \Rightarrow \alpha=2 \sqrt{2} \Rightarrow \alpha^2=8 \\ & \alpha^2\left(1+\frac{\beta^2}{\alpha^2}\right)=9 \\ & \alpha^2+\beta^2=9 \\ & \therefore \beta^2=1 \\ & \therefore 2 \alpha^2+3 \beta^2=2(8)+3(1)=19 \end{aligned} \end{aligned}$
Let a circle passing through $(2,0)$ have its centre at the point $(\mathrm{h}, \mathrm{k})$. Let $(x_{\mathrm{c}}, y_{\mathrm{c}})$ be the point of intersection of the lines $3 x+5 y=1$ and $(2+\mathrm{c}) x+5 \mathrm{c}^2 y=1$. If $\mathrm{h}=\lim _\limits{\mathrm{c} \rightarrow 1} x_{\mathrm{c}}$ and $\mathrm{k}=\lim _\limits{\mathrm{c} \rightarrow 1} y_{\mathrm{c}}$, then the equation of the circle is :
If the image of the point $(-4,5)$ in the line $x+2 y=2$ lies on the circle $(x+4)^2+(y-3)^2=r^2$, then $r$ is equal to:
Let the circles $C_1:(x-\alpha)^2+(y-\beta)^2=r_1^2$ and $C_2:(x-8)^2+\left(y-\frac{15}{2}\right)^2=r_2^2$ touch each other externally at the point $(6,6)$. If the point $(6,6)$ divides the line segment joining the centres of the circles $C_1$ and $C_2$ internally in the ratio $2: 1$, then $(\alpha+\beta)+4\left(r_1^2+r_2^2\right)$ equals
If $\mathrm{P}(6,1)$ be the orthocentre of the triangle whose vertices are $\mathrm{A}(5,-2), \mathrm{B}(8,3)$ and $\mathrm{C}(\mathrm{h}, \mathrm{k})$, then the point $\mathrm{C}$ lies on the circle :
A circle is inscribed in an equilateral triangle of side of length 12. If the area and perimeter of any square inscribed in this circle are $m$ and $n$, respectively, then $m+n^2$ is equal to
Let the circle $C_1: x^2+y^2-2(x+y)+1=0$ and $\mathrm{C_2}$ be a circle having centre at $(-1,0)$ and radius 2 . If the line of the common chord of $\mathrm{C}_1$ and $\mathrm{C}_2$ intersects the $\mathrm{y}$-axis at the point $\mathrm{P}$, then the square of the distance of P from the centre of $\mathrm{C_1}$ is:
Let ABCD and AEFG be squares of side 4 and 2 units, respectively. The point E is on the line segment AB and the point F is on the diagonal AC. Then the radius r of the circle passing through the point F and touching the line segments BC and CD satisfies :
Let a circle C of radius 1 and closer to the origin be such that the lines passing through the point $(3,2)$ and parallel to the coordinate axes touch it. Then the shortest distance of the circle C from the point $(5,5)$ is :
Let $\mathrm{C}$ be a circle with radius $\sqrt{10}$ units and centre at the origin. Let the line $x+y=2$ intersects the circle $\mathrm{C}$ at the points $\mathrm{P}$ and $\mathrm{Q}$. Let $\mathrm{MN}$ be a chord of $\mathrm{C}$ of length 2 unit and slope $-1$. Then, a distance (in units) between the chord PQ and the chord $\mathrm{MN}$ is
A square is inscribed in the circle $x^2+y^2-10 x-6 y+30=0$. One side of this square is parallel to $y=x+3$. If $\left(x_i, y_i\right)$ are the vertices of the square, then $\Sigma\left(x_i^2+y_i^2\right)$ is equal to:
Let a variable line passing through the centre of the circle $x^2+y^2-16 x-4 y=0$, meet the positive co-ordinate axes at the points $A$ and $B$. Then the minimum value of $O A+O B$, where $O$ is the origin, is equal to
If one of the diameters of the circle $x^2+y^2-10 x+4 y+13=0$ is a chord of another circle $\mathrm{C}$, whose center is the point of intersection of the lines $2 x+3 y=12$ and $3 x-2 y=5$, then the radius of the circle $\mathrm{C}$ is :
If the circles $(x+1)^2+(y+2)^2=r^2$ and $x^2+y^2-4 x-4 y+4=0$ intersect at exactly two distinct points, then
Let the centre of a circle, passing through the points $(0,0),(1,0)$ and touching the circle $x^2+y^2=9$, be $(h, k)$. Then for all possible values of the coordinates of the centre $(h, k), 4\left(h^2+k^2\right)$ is equal to __________.
Explanation:
Circle will touch internally
$\begin{aligned} & C_1 C_2=\left|r_1-r_2\right| \\ & =\sqrt{h^2+k^2}=3-\sqrt{h^2+k^2} \\ & \Rightarrow 2 \sqrt{h^2+k^2}=3 \\ & \Rightarrow h^2+k^2=\frac{9}{4} \\ & \therefore 4\left(h^2+k^2\right)=9 \end{aligned}$
Consider two circles $C_1: x^2+y^2=25$ and $C_2:(x-\alpha)^2+y^2=16$, where $\alpha \in(5,9)$. Let the angle between the two radii (one to each circle) drawn from one of the intersection points of $C_1$ and $C_2$ be $\sin ^{-1}\left(\frac{\sqrt{63}}{8}\right)$. If the length of common chord of $C_1$ and $C_2$ is $\beta$, then the value of $(\alpha \beta)^2$ equals _______.
Explanation:
$\begin{gathered} C_1: x^2+y^2=25, C_2:(x-\alpha)^2+y^2=16 \\ 5<\alpha<9 \end{gathered}$
$\begin{aligned} & \theta=\sin ^{-1}\left(\frac{\sqrt{63}}{8}\right) \\ & \sin \theta=\frac{\sqrt{63}}{8} \end{aligned}$
Area of $\triangle \mathrm{OAP}=\frac{1}{2} \times \alpha\left(\frac{\beta}{2}\right)=\frac{1}{2} \times 5 \times 4 \sin \theta$
$\begin{aligned} \Rightarrow \quad & \alpha \beta=40 \times \frac{\sqrt{63}}{8} \\ & \alpha \beta=5 \times \sqrt{63} \\ & (\alpha \beta)^2=25 \times 63=1575 \end{aligned}$
Equations of two diameters of a circle are $2 x-3 y=5$ and $3 x-4 y=7$. The line joining the points $\left(-\frac{22}{7},-4\right)$ and $\left(-\frac{1}{7}, 3\right)$ intersects the circle at only one point $P(\alpha, \beta)$. Then, $17 \beta-\alpha$ is equal to _________.
Explanation:
Centre of circle is $(1,-1)$
Equation of $A B$ is $7 x-3 y+10=0 \ldots$ (i)
Equation of $\mathrm{CP}$ is $3 x+7 y+4=0 \ldots$ (ii)
Solving (i) and (ii)
$\alpha=\frac{-41}{29}, \beta=\frac{1}{29} \quad \therefore 17 \beta-\alpha=2$
Consider a circle $(x-\alpha)^2+(y-\beta)^2=50$, where $\alpha, \beta>0$. If the circle touches the line $y+x=0$ at the point $P$, whose distance from the origin is $4 \sqrt{2}$, then $(\alpha+\beta)^2$ is equal to __________.
Explanation:
$\begin{aligned} & S:(x-\alpha)^2+(y-\beta)^2=50 \\ & C P=r \\ & \left|\frac{\alpha+\beta}{\sqrt{2}}\right|=5 \sqrt{2} \\ & \Rightarrow(\alpha+\beta)^2=100 \end{aligned}$
$x^{2}+y^{2}-18 x-15 y+131=0$
and $x^{2}+y^{2}-6 x-6 y-7=0$, is :
Let the centre of a circle C be $(\alpha, \beta)$ and its radius $r < 8$. Let $3 x+4 y=24$ and $3 x-4 y=32$ be two tangents and $4 x+3 y=1$ be a normal to C. Then $(\alpha-\beta+r)$ is equal to :
Let A be the point $(1,2)$ and B be any point on the curve $x^{2}+y^{2}=16$. If the centre of the locus of the point P, which divides the line segment $\mathrm{AB}$ in the ratio $3: 2$ is the point C$(\alpha, \beta)$, then the length of the line segment $\mathrm{AC}$ is :
A line segment AB of length $\lambda$ moves such that the points A and B remain on the periphery of a circle of radius $\lambda$. Then the locus of the point, that divides the line segment AB in the ratio 2 : 3, is a circle of radius :
Let O be the origin and OP and OQ be the tangents to the circle $x^2+y^2-6x+4y+8=0$ at the points P and Q on it. If the circumcircle of the triangle OPQ passes through the point $\left( {\alpha ,{1 \over 2}} \right)$, then a value of $\alpha$ is :
If the tangents at the points $\mathrm{P}$ and $\mathrm{Q}$ on the circle $x^{2}+y^{2}-2 x+y=5$ meet at the point $R\left(\frac{9}{4}, 2\right)$, then the area of the triangle $\mathrm{PQR}$ is :
Let a circle $C_{1}$ be obtained on rolling the circle $x^{2}+y^{2}-4 x-6 y+11=0$ upwards 4 units on the tangent $\mathrm{T}$ to it at the point $(3,2)$. Let $C_{2}$ be the image of $C_{1}$ in $\mathrm{T}$. Let $A$ and $B$ be the centers of circles $C_{1}$ and $C_{2}$ respectively, and $M$ and $N$ be respectively the feet of perpendiculars drawn from $A$ and $B$ on the $x$-axis. Then the area of the trapezium AMNB is :
Let $y=x+2,4y=3x+6$ and $3y=4x+1$ be three tangent lines to the circle $(x-h)^2+(y-k)^2=r^2$. Then $h+k$ is equal to :
Let the tangents at the points $A(4,-11)$ and $B(8,-5)$ on the circle $x^{2}+y^{2}-3 x+10 y-15=0$, intersect at the point $C$. Then the radius of the circle, whose centre is $C$ and the line joining $A$ and $B$ is its tangent, is equal to :
The points of intersection of the line $ax + by = 0,(a \ne b)$ and the circle ${x^2} + {y^2} - 2x = 0$ are $A(\alpha ,0)$ and $B(1,\beta )$. The image of the circle with AB as a diameter in the line $x + y + 2 = 0$ is :
The locus of the mid points of the chords of the circle ${C_1}:{(x - 4)^2} + {(y - 5)^2} = 4$ which subtend an angle ${\theta _i}$ at the centre of the circle $C_1$, is a circle of radius $r_i$. If ${\theta _1} = {\pi \over 3},{\theta _3} = {{2\pi } \over 3}$ and $r_1^2 = r_2^2 + r_3^2$, then ${\theta _2}$ is equal to :
Two circles in the first quadrant of radii $r_{1}$ and $r_{2}$ touch the coordinate axes. Each of them cuts off an intercept of 2 units with the line $x+y=2$. Then $r_{1}^{2}+r_{2}^{2}-r_{1} r_{2}$ is equal to ___________.
Explanation:
Where $\mathrm{d}=$ perpendicular distance of centre from line $x+y=2$
$ \begin{aligned} & \Rightarrow 2 \sqrt{a^2-\left(\frac{a+a-2}{\sqrt{2}}\right)^2}=2 \\\\ & \Rightarrow a^2-\frac{(2 a-2)^2}{2}=1 \Rightarrow 2 a^2-4 a^2+8 a-4=2 \\\\ & \Rightarrow 2 a^2-8 a+6=0 \Rightarrow a^2-4 a+3=0 \\\\ & \therefore r_1+r_2=4 \text { and } r_1 r_2=3 \\\\ & \therefore r_1^2+r_2^2-r_1 r_2=\left(r_1+r_2\right)^2-3 r_1 r_2 \\\\ & =16-9=7 \end{aligned} $
Consider a circle $C_{1}: x^{2}+y^{2}-4 x-2 y=\alpha-5$. Let its mirror image in the line $y=2 x+1$ be another circle $C_{2}: 5 x^{2}+5 y^{2}-10 f x-10 g y+36=0$. Let $r$ be the radius of $C_{2}$. Then $\alpha+r$ is equal to _________.
Explanation:
$ \begin{aligned} & C_1: x^2+y^2-4 x-2 y=\alpha-5 \\\\ & C_1:(x-2)^2+(y-1)^5-5=\alpha-5 \\\\ & C_1:(x-2)^2+(y-1)^2=(\sqrt{\alpha})^2 \end{aligned} $
So, centre and radius of $C_1$ are $(2,1)$ and $\sqrt{\alpha}$ respectively
Now, image of $(2,1)$ along the line $y=2 x+1$ is,
$ \frac{x-2}{2}=\frac{y-1}{-1}=\frac{-2(4-1+1)}{2^2+(-1)^2} $
$ \begin{aligned} & \Rightarrow \frac{x-2}{2}=\frac{y-1}{-1}=\frac{-8}{5} \\\\ & \Rightarrow x=\frac{-6}{5} \text { and } y=\frac{13}{5} \end{aligned} $
Now, $\left(\frac{-6}{5}, \frac{13}{5}\right)$ will be the centre of $C_2$
$ \therefore f=\frac{6}{5} \text { and } g=\frac{-13}{5} $
Now, radius of $\mathrm{C}_2=r=\sqrt{f^2+g^2-\frac{36}{5}}$
$ \begin{aligned} & \Rightarrow r=\sqrt{\frac{36}{25}+\frac{169}{25}-\frac{36}{5}}=1 \\\\ & \because r=1 \text { so, } \alpha=1 \\\\ & \therefore \alpha+r=1+1=2 \end{aligned} $
Concept :
Image of a point $\left(x_1, y_1\right)$ w.r.t. $a x+b y+c=0$ is $(x, y)$, then
$ \frac{x-x_1}{a}=\frac{y-y_1}{b}=\frac{-2\left(a x_1+b y_1+c\right)}{\left(a^2+b^2\right)} $