Circumference The ratio of a circle's circumference to its diameter is (pi), an
irrational constant approximately equal to 3.141592654. The ratio of a circle's circumference to its radius is . Thus the circumference
C is related to the radius
r and diameter
d by: C = 2\pi r = \pi d.
Area enclosed As proved by
Archimedes, in his
Measurement of a Circle, the
area enclosed by a circle is equal to that of a triangle whose base has the length of the circle's circumference and whose height equals the circle's radius, which comes to multiplied by the radius squared: \mathrm{Area} = \pi r^2. Equivalently, denoting diameter by
d, \mathrm{Area} = \frac{\pi d^2}{4} \approx 0.7854 d^2, that is, approximately 79% of the
circumscribing square (whose side is of length
d). The circle is the plane curve enclosing the maximum area for a given arc length. This relates the circle to a problem in the calculus of variations, namely the
isoperimetric inequality.
Radian If a circle of radius is centred at the
vertex of an
angle, and that angle intercepts an
arc of the circle with an
arc length of , then the
radian measure of the angle is the ratio of the arc length to the radius: \theta = \frac{s}{r}. The circular arc is said to
subtend the angle, known as the
central angle, at the centre of the circle. One radian is the measure of the central angle subtended by a circular arc whose length is equal to its radius. The angle subtended by a complete circle at its centre is a
complete angle, which measures radians, 360
degrees, or one
turn. Using radians, the formula for the arc length of a circular arc of radius and subtending a central angle of measure is s = \theta r, and the formula for the area of a
circular sector of radius and with central angle of measure is A = \frac{1}{2} \theta r^2. In the special case , these formulae yield the circumference of a complete circle and area of a complete disc, respectively.
Equations Cartesian coordinates Equation of a circle In an
x–
y Cartesian coordinate system, the circle with centre
coordinates (
a,
b) and radius
r is the set of all points (
x,
y) such that (x - a)^2 + (y - b)^2 = r^2. This
equation, known as the
equation of the circle, follows from the
Pythagorean theorem applied to any point on the circle: as shown in the adjacent diagram, the radius is the hypotenuse of a right-angled triangle whose other sides are of length |
x −
a| and |
y −
b|. If the circle is centred at the origin (0, 0), then the equation simplifies to x^2 + y^2 = r^2.
One coordinate as a function of the other The circle of radius with center at in the – plane can be broken into two semicircles each of which is the
graph of a function, and , respectively: \begin{align} y_+(x) = y_0 + \sqrt{ r^2 - (x - x_0)^2}, \\[5mu] y_-(x) = y_0 - \sqrt{ r^2 - (x - x_0)^2}, \end{align} for values of ranging from to .
Parametric form The equation can be written in
parametric form using the
trigonometric functions sine and cosine as \begin{align} x &= a + r\,\cos t, \\ y &= b + r\,\sin t, \end{align} where
t is a
parametric variable in the range 0 to 2, interpreted geometrically as the
angle that the ray from (
a,
b) to (
x,
y) makes with the positive
x axis. An alternative parametrisation of the circle is \begin{align} x &= a + r \frac{1 - t^2}{1 + t^2}, \\ y &= b + r \frac{2t}{1 + t^2}. \end{align} In this parameterisation, the ratio of
t to
r can be interpreted geometrically as the
stereographic projection of the line passing through the centre parallel to the
x axis (see
Tangent half-angle substitution). However, this parameterisation works only if
t is made to range not only through all reals but also to a point at infinity; otherwise, the leftmost point of the circle would be omitted.
3-point form The equation of the circle determined by three points (x_1, y_1), (x_2, y_2), (x_3, y_3) not on a line is obtained by a conversion of the
3-point form of a circle equation: \frac{({\color{green}x} - x_1)({\color{green}x} - x_2) + ({\color{red}y} - y_1)({\color{red}y} - y_2)} {({\color{red}y} - y_1)({\color{green}x} - x_2) - ({\color{red}y} - y_2)({\color{green}x} - x_1)} = \frac{(x_3 - x_1)(x_3 - x_2) + (y_3 - y_1)(y_3 - y_2)} {(y_3 - y_1)(x_3 - x_2) - (y_3 - y_2)(x_3 - x_1)}.
Homogeneous form In
homogeneous coordinates, each
conic section with the equation of a circle has the form x^2 + y^2 - 2axz - 2byz + cz^2 = 0. It can be proven that a conic section is a circle exactly when it contains (when extended to the
complex projective plane) the points
I(1:
i: 0) and
J(1: −
i: 0). These points are called the
circular points at infinity.
Polar coordinates In
polar coordinates, the equation of a circle is r^2 - 2 r r_0 \cos(\theta - \phi) + r_0^2 = a^2, where
a is the radius of the circle, (r, \theta) are the polar coordinates of a generic point on the circle, and (r_0, \phi) are the polar coordinates of the centre of the circle (i.e.,
r0 is the distance from the origin to the centre of the circle, and
φ is the anticlockwise angle from the positive
x axis to the line connecting the origin to the centre of the circle). For a circle centred on the origin, i.e. , this reduces to . When , or when the origin lies on the circle, the equation becomes r = 2 a\cos(\theta - \phi). In the general case, the equation can be solved for
r, giving r = r_0 \cos(\theta - \phi) \pm \sqrt{a^2 - r_0^2 \sin^2(\theta - \phi)}. Without the ± sign, the equation would in some cases describe only half a circle.
Complex plane In the
complex plane, a circle with a centre at
c and radius
r has the equation |z - c| = r. In parametric form, this can be written as z = re^{it} + c. The slightly generalised equation pz\overline{z} + gz + \overline{gz} = q for real
p,
q and complex
g is sometimes called a
generalised circle. This becomes the above equation for a circle with p = 1,\ g = -\overline{c},\ q = r^2 - |c|^2, since |z - c|^2 = z\overline{z} - \overline{c}z - c\overline{z} + c\overline{c}. Not all generalised circles are actually circles: a generalised circle is either a (true) circle or a
line.
Tangent lines The
tangent line through a point
P on the circle is perpendicular to the diameter passing through
P. If and the circle has centre (
a,
b) and radius
r, then the tangent line is perpendicular to the line from (
a,
b) to (
x1,
y1), so it has the form . Evaluating at (
x1,
y1) determines the value of
c, and the result is that the equation of the tangent is (x_1 - a)x + (y_1 - b)y = (x_1 - a)x_1 + (y_1 - b)y_1, or (x_1 - a)(x - a) + (y_1 - b)(y - b) = r^2. If , then the slope of this line is \frac{dy}{dx} = -\frac{x_1 - a}{y_1 - b}. This can also be found using
implicit differentiation. When the centre of the circle is at the origin, then the equation of the tangent line becomes x_1 x + y_1 y = r^2, and its slope is \frac{dy}{dx} = -\frac{x_1}{y_1}. ==Properties==