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Properties of equal chords
Theorem: Equal chords of a circle (or of congruent circles) are equidistant from the centre (or centres).
Explanation:
 
Theorem 3.png
 
The theorem states that if the chords \(PQ\) and \(RS\) are equal, then the distance between the chords \(PQ\) and \(RS\) from the centre \(O\) are equal.
 
\(\text{Distance from }O\text{ to chord }PQ\) \(=\) \(\text {Distance from }O\text{ to chord}\) \(RS\)
 
Proof of the theorem:
 
Consider a circle with centre \(O\) and two equal chords \(PQ\) and \(RS\).
 
Join the endpoints \(Q\) and \(R\) of the chords \(PQ\) and \(RS\).
 
Draw a line \(OA\) perpendicular to \(RS\) and \(OB\) perpendicular to \(PQ\).
 
Theorem 3 exp.png
 
Two right triangles \(OAR\) and \(OBQ\) are obtained where \(\angle OAR = \angle OBQ = 90^{\circ}\) since \(OA \perp RS\) and \(OB \perp PQ\).
 
Here, \(OP\) and \(OQ\) are radius. So, they are equal.
 
According to the theorem, the perpendicular from the centre of the circle bisects the chord. So, \(RA = BQ\) since the chords are equal.
 
Therefore, by the RHS rule(In two right-angled triangles, if the length of the hypotenuse and one side of one triangle is equal to the length of the hypotenuse and corresponding side of the other triangle, then the two triangles are congruent), the triangles are congruent.
 
This implies that the sides \(OA = OB\).
 
Therefore, the chords \(PQ\) and \(RS\) are at equal distance from the centre \(O\).
Example:
Given, a circle with two equal and parallel chords. If one of the chords is at a distance of \(5\) \(cm\) from the centre, find the distance between the chords.
 
Solution:
 
Theorem 3 eg.png
 
Let \(O\) be the centre of the circle and \(AB\) and \(CD\) be the equal and parallel chords.
 
Given, one of the chords is at a distance of \(5\) \(cm\) from the centre.
 
Let the chord \(CD\) be at a distance of \(5\) \(cm\) from the centre.
 
By the theorem, the equal chords \(AB\) and \(CD\) of a circle are equidistant from the centre.
 
Thus, the distance between the chord \(AB\) and the centre \(O\) is \(5\) \(cm\).
 
Therefore, the distance between the two chords is given as follows:
 
\(=\) \(5\) \(cm\) \(+\) \(5\) \(cm\)
 
\(=\) \(10\) \(cm\)
Converse of  the theorem: The chords of a circle which are equidistant from the centre are equal.
Explanation:
 
Theorem 3.png
 
The theorem states that, if the distance between the chords \(PQ\) and \(RS\) from the centre \(O\) are equal, then the chords \(PQ\) and \(RS\) are equal (i.e.) \(PQ = RS\).
Example:
If two chords are connected by a line segment, and the centre of the circle passes through the mid-point of the line segment, then prove that the chords are equal.
 
Solution:
 
Given that, the centre of the circle passes through the mid-point of the line segment connecting the chords.
 
This implies that the chords are equidistant from the centre.
 
Therefore by the theorem, the chords are equal.
 
Hence, proved.