Power of a Point (original) (raw)

Last Updated : 23 Jul, 2025

In geometry, circles frequently appear in problems involving tangents, secants, and chords. The Power of a Point theorem helps analyze these relationships by assigning a numerical value that depends on the point’s distance from the circle’s center and the circle’s radius. This theorem establishes key connections between line segments interacting with the circle, making it a useful tool for solving geometry problems.

For any point in relation to a circle with center and radius, the power of the point is given by:

**Power(P) = OP 2 - **R 2

This value determines the point’s interaction with the circle. Based on its location, different segment relationships hold:

  1. **Point Outside the Circle: If a point is outside the circle, secants drawn from it satisfy a special product rule.
  2. **Point Inside the Circle: If a point is inside the circle, intersecting chords follow a product rule.
  3. **Point on the Circle: If the point lies on the circle, the power is zero.

Table of Content

**Secant-Secant Theorem (Point Outside the Circle)

When a point lies outside a circle, two secant lines can be drawn that intersect the circle at two points each. The Power of a Point theorem states that the product of the segment lengths of one secant is equal to the product of the segment lengths of the other secant.

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Point Outside the Circle

PA × PB = PC × PD

**Example: A point P is located outside a circle. Two secants are drawn from point P: one intersects the circle at points A and B, and the other at points C and D. Find PD.

**Solution:

Given that- PA = 6 , PB = 4 , PC = 3
PA × PB = PC × PD
6 × 4 = 3 × PD
PD × 3 = 24
PD = 24/3
PD = 8

**Chord-Chord Theorem (Point Inside the Circle)

The chord of a circle is defined as the line segment joining any two points on the circumference of the circle. It should be noted that the diameter is the longest chord of a circle that passes through the center of the circle.
When a point lies inside a circle, two chords that intersect follow a specific relationship.

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Point Inside the Circle

PA × PB = PC × PD

**Example: Two chords AB and CD intersect at point P inside a circle. Given PA = 2, PB = 6, and PC = 3, find PD.

**Solution:

Apply PA × PB = PC × PD:

2 × 6 = 3 × _PD
12 = 3 × PD
PD = 12/3 = 4.

**Tangent-Secant Theorem (Point Outside the Circle with a Tangent)

If a tangent and a secant are drawn from a point outside a circle, the square of the tangent’s length equals the product of the lengths of the secant’s segments.

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Point outside the circle with a tangent

PT2 = PA × PB

**Example: A tangent PT and PAB a secant are drawn from an external point P. If PT = 5, PA = 4, and PB is unknown, find PB.

**Solution:

Given that: PT = 5 , PA = 4
PT2 = PA × PB
52 = 4 × PB
PB = 25/4
PB = 6.25

Solved Question on the Power of a Point

**Question 1: A point P is located outside a circle with center O and radius 5. If the distance from P to the center O is 13, find the power of the point P.

**Solution:

The power of a point P with respect to a circle is given by the formula:
Power (P) = OP2 - R2
where OP = 13 and R = 5
Power (P) = 132 - 52
Power (P) = 169 - 25 = 144

**Question 2: A point P outside a circle is connected by two secants PAB and PCD that intersect the circle at points A, B, C, and D. If PA = 8, PB = 2, and PC = 5, find PD.
**Solution:

Given that- PA = 8 , PB = 2 , PC = 5 .
PA × PB = PC × PD
8 × 2 = 5 × PD
PD × 5 = 16
PD = 16/5
PD = 3.2

**Question 3: Two chords AB and CD intersect inside a circle at point P. Given that AP = 4, PB = 6, and CP = 3, find PD.
**Solution:

Given that- AP = 4 , PB = 6 , CP = 3.
AP × PB = CP × PD
4 × 6 = 3 × PD
PD × 3 = 24
PD = 24/3
PD = 8

**Question 4: A point P outside a circle has a tangent PT and a secant PAB where PA = 6 and PB = 12. Find the length of PT.
**Solution:

Given that - PA = 6 , PB = 12
PT2 = PA × PB
PT2 = 6 × 12
PT2= 72
PT = √72
PT = 6√2

**Related Reads:

Unsolved Question on the Power of a Point