Angles in the same segment of a circle are equal
Angles in the same segment of a circle are equal. In this article, we will explain what this means, and prove that it is true.
Angles in the same segment
In this diagram, the chord RQ divides the circle into two segments (see parts of a circle). The larger segment (the major segment) is coloured magenta and the smaller one (the minor segment) is yellow.
The angle a at point P is called the angle in a segment (in this case it is the angle in the major segment).
Here is point S, at a different position on the circle:
The chord RQ hasn't changed, and S is still in the major segment, so S is in the same segment as P. So by the angles in a segment theorem, the angle at S is equal to the angle at P, which is a.
Angles not in the same segment
Here is another case:
In this case, the chord RQ remains unchanged, but the point T is now in the minor segment (yellow) so it is not in the same segment as P. We will call this angle b, and it will not generally be equal to a.
In fact, angles a and b are opposite angles in a cyclic quadrilateral, so they add up to 180°.
Proof
The proof for this theorem is similar to the proof that the angle at the centre of a circle is twice the angle at the circumference.
We construct three triangles like this, where point O is the centre of the circle:
Notice that OP, OQ and OR are all radii of the circle. There is a circle theorem that tells us that 2 radii form an isosceles triangle. We know that the two angles at the base of an isosceles triangle are equal.
This means that:
The two angles at the base of triangle PQO are equal, and we will call that angle x.
The two angles at the base of triangle PRO are equal, and we will call that angle y.
The two angles at the base of triangle QRO are equal, and we will call that angle z.
We can find the three angles of the triangle PQR, from the diagram:
Angle P is x + y.
Angle Q is x + z.
Angle R is y + z.
Since we know that the three angles in a triangle add up to 180°, this gives us:
This can be rearranged as:
We know that the angle at P (angle a) is equal to x + y. So we can replace 2x + 2y with 2a in the earlier equation, to get:
Which means:
Dividing both sides by two gives:
The angle z is determined by the triangle QRO. If we move the point P, it has no effect on points Q, R, or O. So moving point P does not change angle z.
Since angle a only depends on z it follows that moving point P will not change a, which proves the theorem.