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The theorem of the gnomon states that certain
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''Gnomon'' is the name for the L-shaped figure consisting of the two overlapping parallelograms and . The parallelograms of equal area and are called ''complements'' (of the parallelograms on diagonal and ). Johannes Tropfke: ''Geschichte der Elementarmathematik Ebene Geometrie – Band 4: Ebene Geometrie''. Walter de Gruyter, 2011, , pp
134-135
(German)
The theorem of the gnomon can be used to construct a new parallelogram or rectangle of equal area to a given parallelogram or rectangle by the means of straightedge and compass constructions. This also allows the representation of a division of two numbers in geometrical terms, an important feature to reformulate geometrical problems in algebraic terms. More precisely, if two numbers are given as lengths of line segments one can construct a third line segment, the length of which matches the quotient of those two numbers (see diagram). Another application is to transfer the ratio of partition of one line segment to another line segment (of different length), thus dividing that other line segment in the same ratio as a given line segment and its partition (see diagram).
A similar statement can be made in three dimensions for
The theorem of gnomon is special case of a more general statement about nested parallelograms with a common diagonal. For a given parallelogram consider an arbitrary inner parallelogram having as a diagonal as well. Furthermore there are two uniquely determined parallelograms and the sides of which are parallel to the sides of the outer parallelogram and which share the vertex with the inner parallelogram. Now the difference of the areas of those two parallelograms is equal to area of the inner parallelogram, that is:
:
This statement yields the theorem of the gnomon if one looks at a degenerate inner parallelogram whose vertices are all on the diagonal . This means in particular for the parallelograms and , that their common point is on the diagonal and that the difference of their areas is zero, which is exactly what the theorem of the gnomon states.
35–36
/ref>George W. Evans: ''Some of Euclid's Algebra''. The Mathematics Teacher, Volume 20, no. 3 (March, 1927), pp. 127–141
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*William J. Hazard: ''Generalizations of the Theorem of Pythagoras and Euclid's Theorem of the Gnomon''. The American Mathematical Monthly, Vol. 36, No. 1 (January 1929), pp. 32–34
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*Paolo Vighi, Igino Aschieri: ''From Art to Mathematics in the Paintings of Theo van Doesburg''. In: Vittorio Capecchi, Massimo Buscema, Pierluigi Contucci, Bruno D'Amore (editors): ''Applications of Mathematics in Models, Artificial Neural Networks and Arts''. Springer, 2010, , pp. 601–610
and
in
The theorem of the gnomon states that certain parallelogram
In Euclidean geometry, a parallelogram is a simple (non- self-intersecting) quadrilateral with two pairs of parallel sides. The opposite or facing sides of a parallelogram are of equal length and the opposite angles of a parallelogram are of equa ...
s occurring in a gnomon
A gnomon (; ) is the part of a sundial that casts a shadow. The term is used for a variety of purposes in mathematics and other fields.
History
A painted stick dating from 2300 BC that was excavated at the astronomical site of Taosi is the ol ...
have area
Area is the quantity that expresses the extent of a region on the plane or on a curved surface. The area of a plane region or ''plane area'' refers to the area of a shape
A shape or figure is a graphics, graphical representation of an obje ...
s of equal size.
Theorem
In a parallelogram with a point on the diagonal , the parallel to through intersects the side in and the side in . Similarly the parallel to the side through intersects the side in and the side in . Then the theorem of the gnomon states that the parallelograms and have equal areas.Lorenz Halbeisen, Norbert Hungerbühler, Juan Läuchli: ''Mit harmonischen Verhältnissen zu Kegelschnitten: Perlen der klassischen Geometrie''. Springer 2016, , pp. 190-191William J. Hazard: ''Generalizations of the Theorem of Pythagoras and Euclid's Theorem of the Gnomon''. The American Mathematical Monthly, volume 36, no. 1 (Jan., 1929), pp. 32–34JSTOR
''Gnomon'' is the name for the L-shaped figure consisting of the two overlapping parallelograms and . The parallelograms of equal area and are called ''complements'' (of the parallelograms on diagonal and ). Johannes Tropfke: ''Geschichte der Elementarmathematik Ebene Geometrie – Band 4: Ebene Geometrie''. Walter de Gruyter, 2011, , pp
134-135
(German)
Proof
The proof of the theorem is straightforward if one considers the areas of the main parallelogram and the two inner parallelograms around its diagonal: * first, the difference between the main parallelogram and the two inner parallelograms is exactly equal to the combined area of the two complements; * second, all three of them are bisected by the diagonal. This yields: :Applications and extensions
The theorem of the gnomon can be used to construct a new parallelogram or rectangle of equal area to a given parallelogram or rectangle by the means of straightedge and compass constructions. This also allows the representation of a division of two numbers in geometrical terms, an important feature to reformulate geometrical problems in algebraic terms. More precisely, if two numbers are given as lengths of line segments one can construct a third line segment, the length of which matches the quotient of those two numbers (see diagram). Another application is to transfer the ratio of partition of one line segment to another line segment (of different length), thus dividing that other line segment in the same ratio as a given line segment and its partition (see diagram).
A similar statement can be made in three dimensions for parallelepiped
In geometry, a parallelepiped is a three-dimensional figure formed by six parallelograms (the term ''rhomboid'' is also sometimes used with this meaning). By analogy, it relates to a parallelogram just as a cube relates to a square. In Euclidea ...
s. In this case you have a point on the space diagonal
In geometry, a space diagonal (also interior diagonal or body diagonal) of a polyhedron is a line connecting two vertices that are not on the same face. Space diagonals contrast with ''face diagonals'', which connect vertices on the same face (but ...
of a parallelepiped, and instead of two parallel lines you have three planes through , each parallel to the faces of the parallelepiped. The three planes partition the parallelepiped into eight smaller parallelepipeds; two of those surround the diagonal and meet at . Now each of those two parallepipeds around the diagonal has three of the remaining six parallelepipeds attached to it, and those three play the role of the complements and are of equal volume
Volume is a measure of occupied three-dimensional space. It is often quantified numerically using SI derived units (such as the cubic metre and litre) or by various imperial or US customary units (such as the gallon, quart, cubic inch). The de ...
(see diagram).
General theorem about nested parallelograms
The theorem of gnomon is special case of a more general statement about nested parallelograms with a common diagonal. For a given parallelogram consider an arbitrary inner parallelogram having as a diagonal as well. Furthermore there are two uniquely determined parallelograms and the sides of which are parallel to the sides of the outer parallelogram and which share the vertex with the inner parallelogram. Now the difference of the areas of those two parallelograms is equal to area of the inner parallelogram, that is:
:
This statement yields the theorem of the gnomon if one looks at a degenerate inner parallelogram whose vertices are all on the diagonal . This means in particular for the parallelograms and , that their common point is on the diagonal and that the difference of their areas is zero, which is exactly what the theorem of the gnomon states.
Historical aspects
The theorem of the gnomon was described as early as inEuclid's Elements
The ''Elements'' ( grc, Στοιχεῖα ''Stoikheîa'') is a mathematical treatise consisting of 13 books attributed to the ancient Greek mathematician Euclid in Alexandria, Ptolemaic Egypt 300 BC. It is a collection of definitions, postulat ...
(around 300 BC), and there it plays an important role in the derivation of other theorems. It is given as proposition 43 in Book I of the Elements, where it is phrased as a statement about parallelograms without using the term "gnomon". The latter is introduced by Euclid
Euclid (; grc-gre, Wikt:Εὐκλείδης, Εὐκλείδης; BC) was an ancient Greek mathematician active as a geometer and logician. Considered the "father of geometry", he is chiefly known for the ''Euclid's Elements, Elements'' trea ...
as the second definition of the second book of Elements. Further theorems for which the gnomon and its properties play an important role are proposition 6 in Book II, proposition 29 in Book VI and propositions 1 to 4 in Book XIII.Paolo Vighi, Igino Aschieri: ''From Art to Mathematics in the Paintings of Theo van Doesburg''. In: Vittorio Capecchi, Massimo Buscema, Pierluigi Contucci, Bruno D'Amore (editors): ''Applications of Mathematics in Models, Artificial Neural Networks and Arts''. Springer, 2010, , pp. 601–610, in particular pp. 603–606Roger Herz-Fischler: ''A Mathematical History of the Golden Number''. Dover, 2013, , p35–36
/ref>George W. Evans: ''Some of Euclid's Algebra''. The Mathematics Teacher, Volume 20, no. 3 (March, 1927), pp. 127–141
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References
*Lorenz Halbeisen, Norbert Hungerbühler, Juan Läuchli: ''Mit harmonischen Verhältnissen zu Kegelschnitten: Perlen der klassischen Geometrie''. Springer 2016, , pp. 190–191 (German) *George W. Evans: ''Some of Euclid's Algebra''. The Mathematics Teacher, Vol. 20, No. 3 (March 1927), pp. 127–141JSTOR
*William J. Hazard: ''Generalizations of the Theorem of Pythagoras and Euclid's Theorem of the Gnomon''. The American Mathematical Monthly, Vol. 36, No. 1 (January 1929), pp. 32–34
JSTOR
*Paolo Vighi, Igino Aschieri: ''From Art to Mathematics in the Paintings of Theo van Doesburg''. In: Vittorio Capecchi, Massimo Buscema, Pierluigi Contucci, Bruno D'Amore (editors): ''Applications of Mathematics in Models, Artificial Neural Networks and Arts''. Springer, 2010, , pp. 601–610
Notes
External links
and
in
Euclid's Elements
The ''Elements'' ( grc, Στοιχεῖα ''Stoikheîa'') is a mathematical treatise consisting of 13 books attributed to the ancient Greek mathematician Euclid in Alexandria, Ptolemaic Egypt 300 BC. It is a collection of definitions, postulat ...
{{Ancient Greek mathematics
Euclidean geometry
Theorems about quadrilaterals