Stewart's theorem

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Short description: Geometric relation between a triangle's side lengths and cevian length

In geometry, Stewart's theorem yields a relation between the lengths of the sides and the length of a cevian in a triangle. Its name is in honour of the Scottish mathematician Matthew Stewart, who published the theorem in 1746.[1]

Statement

Diagram of Stewart's theorem

Let a, b, c be the lengths of the sides of a triangle. Let d be the length of a cevian to the side of length a. If the cevian divides the side of length a into two segments of length m and n, with m adjacent to c and n adjacent to b, then Stewart's theorem states that [math]\displaystyle{ b^2m + c^2n = a(d^2 + mn). }[/math]

A common mnemonic used by students to memorize this equation (after rearranging the terms) is: [math]\displaystyle{ \underset{\text{A }man\text{ and his }dad}{man\ +\ dad} = \!\!\!\!\!\! \underset{\text{put a }bomb\text{ in the }sink.}{bmb\ +\ cnc} }[/math]

The theorem may be written more symmetrically using signed lengths of segments. That is, take the length AB to be positive or negative according to whether A is to the left or right of B in some fixed orientation of the line. In this formulation, the theorem states that if A, B, C are collinear points, and P is any point, then

[math]\displaystyle{ \left(\overline{PA}^2\cdot \overline{BC}\right) + \left(\overline{PB}^2\cdot \overline{CA}\right) + \left(\overline{PC}^2\cdot \overline{AB}\right) + \left(\overline{AB}\cdot \overline{BC}\cdot \overline{CA}\right) =0. }[/math][2]

In the special case that the cevian is the median (that is, it divides the opposite side into two segments of equal length), the result is known as Apollonius' theorem.

Proof

The theorem can be proved as an application of the law of cosines.[3]

Let θ be the angle between m and d and θ' the angle between n and d. Then θ' is the supplement of θ, and so cos θ' = −cos θ. Applying the law of cosines in the two small triangles using angles θ and θ' produces [math]\displaystyle{ \begin{align} c^2 &= m^2 + d^2 - 2dm\cos\theta, \\ b^2 &= n^2 + d^2 - 2dn\cos\theta' \\ &= n^2 + d^2 + 2dn\cos\theta. \end{align} }[/math]

Multiplying the first equation by n and the third equation by m and adding them eliminates cos θ. One obtains [math]\displaystyle{ \begin{align} b^2m + c^2n &= nm^2 + n^2m + (m+n)d^2 \\ &= (m+n)(mn + d^2) \\ &= a(mn + d^2), \\ \end{align} }[/math] which is the required equation.

Alternatively, the theorem can be proved by drawing a perpendicular from the vertex of the triangle to the base and using the Pythagorean theorem to write the distances b, c, d in terms of the altitude. The left and right hand sides of the equation then reduce algebraically to the same expression.[2]

History

According to (Hutton Gregory), Stewart published the result in 1746 when he was a candidate to replace Colin Maclaurin as Professor of Mathematics at the University of Edinburgh. (Coxeter Greitzer) state that the result was probably known to Archimedes around 300 B.C.E. They go on to say (mistakenly) that the first known proof was provided by R. Simson in 1751. (Hutton Gregory) state that the result is used by Simson in 1748 and by Simpson in 1752, and its first appearance in Europe given by Lazare Carnot in 1803.

See also

Notes

  1. Stewart, Matthew (1746), Some General Theorems of Considerable Use in the Higher Parts of Mathematics, Edinburgh: Sands, Murray and Cochran  "Proposition II"
  2. 2.0 2.1 Russell 1905, p. 3
  3. Proof of Stewart's Theorem at PlanetMath.org.

References

Further reading

  • I.S Amarasinghe, Solutions to the Problem 43.3: Stewart's Theorem (A New Proof for the Stewart's Theorem using Ptolemy's Theorem), Mathematical Spectrum, Vol 43(03), pp. 138 – 139, 2011.
  • Ostermann, Alexander; Wanner, Gerhard (2012), Geometry by Its History, Springer, p. 112, ISBN 978-3-642-29162-3 

External links



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