Circle definitions, properties and core theorems

Geometry and measures • Properties and constructions

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Define radius and diameter.

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Radius: segment from centre to circle. Diameter: chord through the centre equal to twice the radius.

Key concepts

What you'll likely be quizzed about

Basic definitions

Centre: a point equidistant from all points on the circle. Radius: a line segment from the centre to any point on the circle. Diameter: a chord passing through the centre; length equals twice the radius. Chord: a line segment with endpoints on the circle. Circumference: the distance around the circle; proportional to the radius (C = 2πr). Arc: a continuous part of the circumference between two points. Sector: the region bounded by two radii and the connecting arc. Segment: the region bounded by a chord and the corresponding arc. Each definition limits which constructions and theorems apply; for example, diameters always pass through the centre while chords may not.

Radius and tangent relationship

A radius drawn to the point of contact with a tangent is perpendicular to the tangent. Cause: the tangent touches the circle at exactly one point. Effect: the radius at that point meets the tangent at a right angle. Consequence: a line claimed to be tangent can be tested by checking perpendicularity with the radius to the contact point; conversely, perpendicularity implies tangency at that point.

Perpendicular from centre to chord

If a radius or diameter is perpendicular to a chord, then it bisects the chord and the subtended arcs. Cause: two radii to the chord's endpoints form an isosceles triangle. Effect: perpendicular from the vertex (centre) splits the base (chord) into equal parts. Consequence: perpendicular bisector of a chord passes through the centre; this gives a method to locate the centre from a chord.

Equal chords and distances from centre

Equal chords subtend equal arcs and lie at equal distances from the centre. Cause: equal chords create equal isosceles triangles with radii. Effect: identical vertex angles and identical perpendicular distances from centre to each chord. Consequence: chord length comparisons lead to centre-to-chord distance comparisons and vice versa.

Angle in a semicircle (Thales' theorem)

An angle subtended by a diameter at any point on the circle is a right angle. Cause: endpoints of the angle join to form a triangle whose base is a diameter. Effect: two radii to the base endpoints produce an isosceles decomposition that forces the remaining angle to be 90°. Consequence: any triangle drawn with one side as the diameter is a right triangle.

Angle at the centre and at the circumference

An angle at the centre is twice any angle subtended by the same arc at the circumference. Cause: the central angle spans the whole arc while the inscribed angle spans the same arc from the circumference. Effect: central angle = 2 × inscribed angle subtending the same arc. Consequence: knowing a central angle gives an inscribed angle and vice versa; this supports solving angle-chasing problems.

Angles in the same segment

Angles in the same segment, subtended by the same chord, are equal. Cause: each inscribed angle intercepts the same arc and therefore uses the same fraction of the arc's measure. Effect: equal inscribed angles at different points on the same arc. Consequence: angle equality can identify parallel lines or deduce other angles inside the circle.

Tangent-chord theorem (angle between tangent and chord)

The angle between a tangent and a chord through the point of contact equals the angle in the opposite arc subtended by the chord. Cause: draw the radius to the point of contact and use the central–inscribed angle relationship. Effect: tangent-chord angle equals the inscribed angle on the far side of the chord. Consequence: tangents provide external angle information that links to interior inscribed angles.

Cyclic quadrilaterals

Opposite angles of a quadrilateral inscribed in a circle sum to 180°. Cause: each opposite angle subtends supplementary arcs that together cover the full circumference. Effect: angleA + angleC = 180° and angleB + angleD = 180°. Consequence: angle sums give a route for proofs involving four points on a circle and for solving unknown angles.

Proof strategies using circle theorems

Common proof steps: identify radii to construct isosceles triangles, use perpendiculars to bisect chords, apply central–inscribed angle relation, employ tangent perpendicularity. Cause: constructing radii and drawing auxiliary lines reveals known triangle types. Effect: angle chasing and congruence arguments produce short rigorous proofs. Consequence: complex results reduce to combinations of the basic theorems above.

Key notes

Important points to keep in mind

A diameter always passes through the centre and equals 2 × radius.

A line tangent at point P meets the radius to P at 90°.

Perpendicular from centre to chord bisects the chord and the corresponding arcs.

Central angle = 2 × inscribed angle when both subtend the same arc.

Angles in the same segment are equal, enabling rapid angle-chasing.

An angle on a semicircle is 90° (Thales' theorem).

Opposite angles in a cyclic quadrilateral sum to 180°.

Equal chords subtend equal arcs and have equal distances from the centre.

Constructing radii and perpendicular bisectors reduces many proofs to triangle congruence and angle sums.

Use the tangent–chord theorem to convert external tangent information into interior inscribed angles.