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Commandino's theorem

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The four medians of a tetrahedron are concurrent
Medians of a tetrahedron intersecting in a point S {\displaystyle S} (its centroid), such that
| A S | | S S B C D | = | B S | | S S A C D | = | C S | | S S A B D | = | D S | | S S A B C | = 3 1 {\displaystyle {\frac {|AS|}{|SS_{BCD}|}}={\frac {|BS|}{|SS_{ACD}|}}={\frac {|CS|}{|SS_{ABD}|}}={\frac {|DS|}{|SS_{ABC}|}}={\frac {3}{1}}}

Commandino's theorem, named after Federico Commandino (1509–1575), states that the four medians of a tetrahedron are concurrent at a point S, which divides them in a 3:1 ratio. In a tetrahedron a median is a line segment that connects a vertex with the centroid of the opposite face – that is, the centroid of the opposite triangle. The point S is also the centroid of the tetrahedron.

History

The theorem is attributed to Commandino, who stated, in his work De Centro Gravitatis Solidorum (The Center of Gravity of Solids, 1565), that the four medians of the tetrahedron are concurrent. However, according to the 19th century scholar Guillaume Libri, Francesco Maurolico (1494–1575) claimed to have found the result earlier. Libri nevertheless thought that it had been known even earlier to Leonardo da Vinci, who seemed to have used it in his work. Julian Coolidge shared that assessment but pointed out that he couldn't find any explicit description or mathematical treatment of the theorem in da Vinci's works. Other scholars have speculated that the result may have already been known to Greek mathematicians during antiquity.

Generalizations

Commandino's theorem has a direct analog for simplexes of any dimension:

Let Δ {\displaystyle \Delta } be a d {\displaystyle d} -simplex of some dimension d > 1 {\displaystyle d>1} in R n ( d , n N , n d ) {\displaystyle \mathbb {R} ^{n}\;(d,n\in \mathbb {N} ,n\geq d)} and let V 0 , V 1 , , V p {\displaystyle V_{0},V_{1},\ldots ,V_{p}} be its vertices. Furthermore, let 0 , 1 , , d {\displaystyle \ell _{0},\ell _{1},\ldots ,\ell _{d}} , be the medians of Δ {\displaystyle \Delta } , the lines joining each vertex V i {\displaystyle V_{i}} with the centroid of the opposite ( d 1 ) {\displaystyle (d-1)} -dimensional facet V 0 V i 1 V i + 1 V d {\displaystyle V_{0}\ldots V_{i-1}V_{i+1}\ldots V_{d}} . Then, these lines intersect each other in a point S {\displaystyle S} , in a ratio of d : 1 {\displaystyle d:1} .

Full generality

The former analog is easy to prove via the following, more general result, which is analogous to the way levers in physics work:

Let m {\displaystyle m} and k {\displaystyle k} be natural numbers, so that in an R {\displaystyle \mathbb {R} } -vector space V {\displaystyle {\mathcal {V}}} , m + k {\displaystyle m+k} pairwise different points X 1 , , X m , Y 1 , , Y k V {\displaystyle X_{1},\dots ,X_{m},Y_{1},\dots ,Y_{k}\in {\mathcal {V}}} are given.
Let S X {\displaystyle S_{X}} be the centroid of the points X i ( i = 1 , , m ) {\displaystyle X_{i}\;(i=1,\dots ,m)} , let S Y {\displaystyle S_{Y}} be the centroid of the points Y j ( j = 1 , , k ) {\displaystyle Y_{j}\;(j=1,\dots ,k)} , and let S {\displaystyle S} be the centroid of all of these m + k {\displaystyle m+k} points.
Then, one has
S = S X + k m + k ( S Y S X ) = m m + k S X + k m + k S Y . {\displaystyle S=S_{X}+{\frac {k}{m+k}}(S_{Y}-S_{X})={\frac {m}{m+k}}S_{X}+{\frac {k}{m+k}}S_{Y}.}
In particular, the centroid S {\displaystyle S} lies on the line S X S Y ¯ {\displaystyle {\overline {{S_{X}}{S_{Y}}}}} and divides it in a ratio of k : m {\displaystyle k:m} .

Reusch's theorem

The previous theorem has further interesting consequences other than the aforementioned generalization of Commandino's theorem. It can be used to prove the following theorem about the centroid of a tetrahedron, first described in the Mathematische Unterhaltungen by the German physicist Friedrich Eduard Reusch [de]:

One may find the centroid of a tetrahedron by taking the midpoints of two pairs of two of its opposite edges and connecting the corresponding midpoints through their respective midline. The intersection point of both midlines will be the centroid of the tetrahedron.

Since a tetrahedron has six edges in three opposite pairs, one obtains the following corollary:

In a tetrahedron, the three midlines corresponding to opposite edge midpoints are concurrent, and their intersection point is the centroid of the tetrahedron.

Varignon's theorem

A specific case of Reusch's theorem where all four vertices of a tetrahedron are coplanar and lie on a single plane, thereby degenerating into a quadrilateral, Varignon's theorem, named after Pierre Varignon, states the following:

Let a quadrilateral in R 2 {\displaystyle \mathbb {R} ^{2}} be given. Then the two midlines connecting opposite edge midpoints intersect in the centroid of the quadrilateral and are divided in half by it.

References

  1. Claudi Alsina, Roger B. Nelsen: A Mathematical Space Odyssey: Solid Geometry in the 21st Century. The Mathematical Association of America, 2015, ISBN 9780883853580, pp. 97–98
  2. Nathan Altshiller-Court: The Tetrahedron and Its Circumscribed Parallelepiped. The Mathematics Teacher, Vol. 26, No. 1 (JANUARY 1933), pp. 46–52 (JSTOR)
  3. Norman Schaumberger: Commandino's theorem. The Two-Year College Mathematics Journal, Vol. 13, No. 5 (Nov., 1982), p. 331 (JSTOR)
  4. Nathan Altshiller Court: Notes on the centroid. The Mathematics Teacher, Vol. 53, No. 1 (JANUARY 1960), pp. 34 (JSTOR)
  5. Howard Eves: Great Moments in Mathematics (before 1650). MAA, 1983, ISBN 9780883853108, p. 225
  6. Egbert Harzheim (1978). Einführung in die kombinatorische Topologie (in German). Darmstadt: Wissenschaftliche Buchgesellschaft. p. 33. ISBN 3-534-07016-X.
  7. Egbert Harzheim (1978), Einführung in die Kombinatorische Topologie (in German), Darmstadt, p. 31, ISBN 3-534-07016-X{{citation}}: CS1 maint: location missing publisher (link)
  8. ^ Friedrich Joseph Pythagoras Riecke (Hrsg.): Mathematische Unterhaltungen. Zweites Heft. 1973, S. 100, 128
  9. In den Mathematische Unterhaltungen (Zweites Heft, S. 128) wird auf die S. 36 von Reuschs Abhandlung Der Spitzbogen verwiesen.
  10. Coxeter, op. cit., S. 242
  11. DUDEN: Rechnen und Mathematik. 1985, S. 652

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