Click on the image below to play around with a visualization of circles and tangents/normals to it:

- Circle centered at origin is given by x2+y2=r2.

- Chord :A line segment with end points on the circle.

- Diameter: A chord passing through the centre. Diameter = 2 X Radius.

- Parametric form: For a circle centered at C(h,k), any point P on the circle can be written as (h+rcosθ,h+rsinθ), where θ is the angle that PC makes with the positive x axis. For a circle centered at origin, (rcosθ, rsinθ) is the parametric form.

- In general, if centre is (h,k) and radius is r, the equation can be written as (x-h)2+(y-k)2=r2

- The general equation of a circle is written as x2+y2+2gx+2fy+c =0 with (-g,-f) as the centre, and radius=g2+f2-c

- If the circle touches x axis, then its centre is of the form (h,±r)If it touches the y axis, then the centre is of the form (±r,k).

- A circle is the locus of a point that moves in a plane such that its distance from a fixed point in that plane, called the centre, is always constant. The constant distance is called the radius.

- The equation ax2+2hxy+by2+2gx+2fy+c=0 denotes an ellipse when abc+2fgh-af2-bg2-ch2≠0 and h=0.

**Tangents to a Circle - Pairs of Tangent from an External Point, Chord of Contact, Normal**

- T, S, S1: If x2+y2+2gx+2fy+c=0 is the equation of the circle, then S= x2+y2+2gx+2fy+c, S1= x12+y12+2gx1+2fy1+c (putting some point (x1,y1) in the equation) and T=xx1+yy1+g(x+x1)+f(y+y1).
- A pair of tangents from an external point P(x1,y1) is SS1=T2
- The
**chord of contact **wrt an external point P(x1,y1) is T=0. - A chord with mid point (x1,y1) is T=S1
**Tangent: ** Tangent
is a line touching the circle at exactly one point. The perpendicular
drawn to the tangent from the centre of the circle is equal to the
radius.**Equation of tangent** is given by T=0 where (x1,y1) is the point of contact.- Length of Tangent drawn from (x1,y1) is √S1
- For x2+y2=a2
- y = mx ± a[1 +m²]

- Normal: The normal is a line perpendicular to the tangent at the point of contact. It always passes through the centre of the circle.

- Conditions for Two circles with centres C1(x1, y1) and C2(x2, y2) and radii r1, r2 respectively, touch each other. (i) Internally: If |C1 C2| = |r2 – r1| (ii) Externally: If |C1 C2| = |r2 – r1|

**Common Tangents - Direct and Transverse**

(i) The direct common tangents to two circles meet on the line of centres and divide it externally in the ratio of the radii.

(ii) The transverse common tangents also meet on the line of centres and divide it internally in the ratio of the radii.

- When one circle lies completely inside the other without touching, there is no common tangent.
- When two circles touch each other internally 1 common tangent can be drawn to the circles.
- When two circles intersect in two real and distinct points, 2 common tangents can be drawn to the circles.
- When two circles touch each other externally, 3 common tangents can be drawn to the circles.
- When two circles neither touch nor intersect and one lies outside the other, then 4 common tangents can be drawn.

**Radial Axis of Two Circles**

If
S1 = 0 and S2 = 0 are two given circles, then S1 – S2 = 0 gives the
equation of a line related to both of them. This line can give various
results in varying conditions of relative positioning of two circles.

(i) Radical Axis of the two circles.

Radical axis of the two circles is defined as the line from each point
of which, tangents of equal length are drawn to the two circles.

(ii)
If the circles touch each other then the above equation gives the
common tangent at the point where the circles touch each other. It is
also the Radical axis of the two circles.

(iii)
If the two circles intersect then above equation gives the equation of
the common chord. Here also the common chord is also the Radical axis of
the two circles.

**Family of Circles**

(i) If S is x2 + y2 + 2gx + 2fy + c=0 and S’ is x2 + y2 + 2g’x + 2f’y + c=0 are two intersecting circles, then S + λS’ = 0, λ ≠ –1, is the equation of a family of circles passing through the points of intersection of S = 0 and S’ = 0.

(ii) If S as x2 + y2 +
2gx + 2fy + c = 0 is a circle which is intersected by the straight line
L as ax + by + c = 0 in two real and distinct points, then S + λL = 0
is the equation of a family of circles passing through the points of
intersection of S = 0 and L = 0.

(iii) The equation of the family of circles which touch the line y – y1 = m (x – x1) at (y1, x1) for any values of m is (x – x1)2 + (y – y1)2 + λ[(y – y1) – m(x – x1)] = 0.

.**Parametric Equation of a Circle:**

**x = a + r * cos A**

**y = b + r * sin A**

**Where 0 <= A <= (2*PI) radians**

#### Here are some of the problems solved in this tutorial :

**Q:** If the equation of the two diameters of a circle are x-y=5 and 2x+y=4 and the radius is 5, find the equation of the circle.

**Q:**Find all the common tangents to the circles x2 + y2 – 2x – 6y + 9 = 0 and x2 + y2 – 6x – 2y + 1 = 0.

**Q:**Find all the common tangents to the circles x2 + y2 – 2x – 6y + 9 = 0 and x2 + y2 – 6x – 2y + 1 = 0.

**Q:**Find
the equation of the circle which passes through two points of the x
axis which are at a distance of 4 from the origin and whose radius is 5.

**Q:**A
circle of radius 5 units touches the coordinate axes in the first
quadrant. If the circle makes one complete roll on x axis along the
positive direction, find its equation in new position.

**Q:**Find the equation of circle whose radius is 5 and which touches the circle x2+y2-2x-4y-20=0 externally at the point (5,5).

**Q:**A
circle of radius 2 lies n the first quadrant touching both axes. Find
the equation of the circle centred at (6,5) and touching the above
circle externally.

**Q:**Find the equation of the circle which touches the coordinate axes and whose centre lies on the line x-2y=3.

**Q:**If the point (2,k) lies outside the circles x2+y2+x-2y-14=0 and x2+y2=13, then what are the values that k can take?

**Q:**Find the equation of the incircle formed by the coordinate axes and the line 4x+3y=6.

**Q:**Find the equation of circle which touches the lines 4x-3y+10=0 and 4x-3y-30=0 and whose centre lies on the line 2x+y=0.

**Q:**Let S be any circle with centre (0,√2). Prove that at most 2 rational points can be there on S.

**Q:**The
straight line x/a + y/b =1 cuts the coordinate axes at A and B
respectively. Find the equation of the circle passing through A, B, and
O(0,0).

**Q:**Show that the points (9,1), (7,9), (-2,12), (6,10) are concyclic.

**Q:**On
the line joining (1,0) and (3,0) an equilateral triangle is drawn,
having its vertex in the first quadrant. Find the equation to the
circles described on its sides as diameter.

**Q:**Find the area of equilateral triangle inscribed in x2+y2+2gx+2fy+c=0.

**Q:**Write the equation of normal to x2 + y2 = 25 at (3, 4)?

**Q:**Find a circle passing through the intersection of x2 + y2 - 4 = 0 and x2 + y2 - 6x + 5 = 0 which passes through the point (2, 1)?

**Q:**Find the equation of the circle described on the common chord of the circles x2 + y2 – 4x – 5 = 0 and x2 + y2 + 8y+ 7 = 0 as diameter

**Q:**Find the co-ordinates of the point from which tangents are drawn to the circle x2 + y2– 6x – 4y + 3= 0 such that the mid-point of its chord of contact is (1, 1).

**Q:**When do two circles intersect orthogonally?

**Q:**Find all the common tangents to the circles x2 + y2 – 2x – 6y + 9 = 0 and x2 + y2 – 6x – 2y + 1 = 0.

**Equation of a Circle:**

**The circle is a locus of points, equidistant from a given point.**

**
****(x-a)**^{2} + (y-b)^{2} = r^{2}

Where (a,b) is the center of the circle and r is the radius of the circle.

**Complete Tutorial with Solved Examples :**

**MCQ Quiz #1 on Circles. **

**Answers will be e-mailed to the id which you fill up.**#### MCQ Quiz: Circles- 1

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**MCQ Quiz #2 on Circles. **

Answers will be e-mailed to the id which you fill up.

#### MCQ Quiz: Circles 2

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**MCQ Quiz #3 on Circles. **

Answers will be e-mailed to the id which you fill up.

#### MCQ Quiz: Circles-3

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