Brahmagupta's formula

In Euclidean geometry, Brahmagupta's formula finds the area of any cyclic quadrilateral (one that can be inscribed in a circle) given the lengths of the sides.

Formula

Brahmagupta's formula gives the area $K$ of a cyclic quadrilateral whose sides have lengths $a$ , $b$ , $c$ , $d$ as

K=\sqrt{(s-a)(s-b)(s-c)(s-d)}

where $s$ , the semiperimeter, is defined to be

s=\frac{a+b+c+d}{2}.

This formula generalizes Heron's formula for the area of a triangle. A triangle may be regarded as a quadrilateral with one side of length zero. From this perspective, as $d$ approaches zero, a cyclic quadrilateral converges into a cyclic triangle (all triangles are cyclic), and Brahmagupta's formula simplifies to Heron's formula.

If the semiperimeter is not used, Brahmagupta's formula is

K=\frac{1}{4}\sqrt{(-a+b+c+d)(a-b+c+d)(a+b-c+d)(a+b+c-d)}.

Another equivalent version is

K=\frac{\sqrt{(a^2+b^2+c^2+d^2)^2+8abcd-2(a^4+b^4+c^4+d^4)}}{4}\cdot

Proof

Diagram for reference

Trigonometric proof

Here the notations in the figure to the right are used. The area $K$ of the cyclic quadrilateral equals the sum of the areas of $△ ADB$ and $△ BDC$ :

= \frac{1}{2}pq\sin A + \frac{1}{2}rs\sin C.

But since $ABCD$ is a cyclic quadrilateral, $∠ DAB = 180° - ∠ DCB$ . Hence $sin A = sin C$ . Therefore,

K = \frac{1}{2}pq\sin A + \frac{1}{2}rs\sin A

K^2 = \frac{1}{4} (pq + rs)^2 \sin^2 A

4K^2 = (pq + rs)^2 (1 - \cos^2 A) = (pq + rs)^2 - (pq + rs)^2 \cos^2 A.\,

Solving for common side $DB$ , in $△ ADB$ and $△ BDC$ , the law of cosines gives

p^2 + q^2 - 2pq\cos A = r^2 + s^2 - 2rs\cos C. \,

Substituting $cos C = -cos A$ (since angles $A$ and $C$ are supplementary) and rearranging, we have

2 (pq + rs) \cos A = p^2 + q^2 - r^2 - s^2. \,

Substituting this in the equation for the area,

4K^2 = (pq + rs)^2 - \frac{1}{4}(p^2 + q^2 - r^2 - s^2)^2

16K^2 = 4(pq + rs)^2 - (p^2 + q^2 - r^2 - s^2)^2.

The right-hand side is of the form $a 2 - b 2 = (a - b)(a + b)$ and hence can be written as

[2(pq + rs) - p^2 - q^2 + r^2 +s^2][2(pq + rs) + p^2 + q^2 -r^2 - s^2] \,

which, upon rearranging the terms in the square brackets, yields

= [ (r+s)^2 - (p-q)^2 ][ (p+q)^2 - (r-s)^2 ] \,

= (q+r+s-p)(p+r+s-q)(p+q+s-r)(p+q+r-s). \,

Introducing the semiperimeter $S = <templatestyles src="Sfrac/styles.css" />p + q + r + s/2$ ,

16K^2 = 16(S-p)(S-q)(S-r)(S-s). \,

Taking the square root, we get

K = \sqrt{(S-p)(S-q)(S-r)(S-s)}.

Non-trigonometric proof

An alternative, non-trigonometric proof utilizes two applications of Heron's triangle area formula on similar triangles.^[1]

Extension to non-cyclic quadrilaterals

In the case of non-cyclic quadrilaterals, Brahmagupta's formula can be extended by considering the measures of two opposite angles of the quadrilateral:

K=\sqrt{(s-a)(s-b)(s-c)(s-d)-abcd\cos^2\theta}

where $θ$ is half the sum of any two opposite angles. (The choice of which pair of opposite angles is irrelevant: if the other two angles are taken, half their sum is $180° - θ$ . Since $cos(180° - θ) = -cos θ$ , we have $cos 2 (180° - θ) = cos 2 θ$ .) This more general formula is known as Bretschneider's formula.

It is a property of cyclic quadrilaterals (and ultimately of inscribed angles) that opposite angles of a quadrilateral sum to 180°. Consequently, in the case of an inscribed quadrilateral, $θ$ is 90°, whence the term

abcd\cos^2\theta=abcd\cos^2 \left(90^\circ\right)=abcd\cdot0=0, \,

giving the basic form of Brahmagupta's formula. It follows from the latter equation that the area of a cyclic quadrilateral is the maximum possible area for any quadrilateral with the given side lengths.

A related formula, which was proved by Coolidge, also gives the area of a general convex quadrilateral. It is^[2]

K=\sqrt{(s-a)(s-b)(s-c)(s-d)-\textstyle{1\over4}(ac+bd+pq)(ac+bd-pq)}\,

where $p$ and $q$ are the lengths of the diagonals of the quadrilateral. In a cyclic quadrilateral, $pq = ac + bd$ according to Ptolemy's theorem, and the formula of Coolidge reduces to Brahmagupta's formula.

Related theorems

Heron's formula for the area of a triangle is the special case obtained by taking $d = 0$ .
The relationship between the general and extended form of Brahmagupta's formula is similar to how the law of cosines extends the Pythagorean theorem.

References

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External links

Weisstein, Eric W., "Brahmagupta's Formula", MathWorld.

This article incorporates material from proof of Brahmagupta's formula on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License.

↑ Hess, Albrecht, "A highway from Heron to Brahmagupta", Forum Geometricorum 12 (2012), 191–192.
↑ J. L. Coolidge, "A Historically Interesting Formula for the Area of a Quadrilateral", American Mathematical Monthly, 46 (1939) pp. 345-347.

[1] Hess, Albrecht, "A highway from Heron to Brahmagupta", Forum Geometricorum 12 (2012), 191–192.

[2] J. L. Coolidge, "A Historically Interesting Formula for the Area of a Quadrilateral", American Mathematical Monthly, 46 (1939) pp. 345-347.

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Brahmagupta's formula

Contents

Formula

Proof

Trigonometric proof

Non-trigonometric proof

Extension to non-cyclic quadrilaterals

Related theorems

References

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