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New dualities in convex quadrilaterals

Published online by Cambridge University Press:  22 June 2022

Mario Dalcín
Mario Dalcín*
Affiliation:
‘Artigas’ Secondary School Teachers Institute-CFE, Montevideo-Uruguay e-mail: [email protected]
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Extract

In [1] de Villiers points out the duality between sides and angles of quadrilaterals. The first objective of this article is make explicit two new dualities in the quadrilaterals. For this we will consider the diagonal segments: if diagonals AC and BD of a quadrilateral ABCD intersect at O, we call the diagonal segments OA, OB, OC, OD. According to [2, pp. 179-188], hierarchical classifications of the convex quadrilaterals are made taking as classification criteria the quantity and position of sides, angles and diagonal segments. In hierarchical classifications the more particular concepts form subsets of the more general concepts. Through classification according to the number and position of equal sides it is possible to define six families: four sides equal, at least three equal, two opposite pairs equal, two consecutive pairs equal, at least one opposite pair equal, at least one consecutive pair equal. In the families two opposite pairs equal and two consecutive pairs equal, the pairs may be equal to each other and then the four sides are equal. So in these two families the possibility DA = AB and AB = BC is excluded. Families analogous to the previous ones can be defined taking as a criterion of hierarchical classification the quantity and position of equal angles or the quantity and position of equal diagonal segments.

Type
Articles
Information
The Mathematical Gazette , Volume 106 , Issue 566 , July 2022 , pp. 269 - 280
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Copyright
© The Authors, 2022 Published by Cambridge University Press on behalf of The Mathematical Association

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References

de Villiers, M., An interesting duality in geometry, AMESA-2 Proceedings, Peninsula Technikon (1996), pp. 345350, available at http://mzone.mweb.co.za/residents/profmd/amesa96.pdf Google Scholar
Dalcín, M. and Molfino, V., Geometría euclidiana en la formación de profesores (5th edn.), Ediciones Palíndromo, Montevideo, Uruguay, (2020).Google Scholar
Polya, G., How to solve it (2nd edn.), Princeton University Press (1973).Google Scholar
de Villiers, M., An extended classification of quadrilaterals (1996), available at http://mysite.mweb.co.za/residents/profmd/quadclassify.pdf Google Scholar
Josefsson, M., Properties of tilted kites, International Journal of Geometry, 7 (2018), No. 1, pp. 87104.Google Scholar
Josefsson, M., Properties of bisect-diagonal quadrilaterals, Math. Gaz. 101 (July 2017) pp. 214226.Google Scholar
Tydd, M., Flying two kites: Part 1, AMESA KZN Mathematics Journal, 9 (2005) pp. 1418, available at http://dynamicmathematicslearning.com/matthew-tydd-two-kites.pdf Google Scholar
de Villiers, M., Definitions and some properties of quadrilaterals (2016), available at http://frink.machighway.com/~dynamicm/quad-defs-properties.html Google Scholar
de Villiers, M., A hierarchical classification of quadrilaterals (2016), available at http://dynamicmathematicslearning.com/quad-tree-new-web.html Google Scholar
Hang, K. H. and Wang, H., Solving problems in geometry. insights and strategies for Mathematical Olympiad and competitions, World Scientific (2017).Google Scholar
Josefsson, M., On the classification of convex quadrilaterals, Math. Gaz. 100 (March 2016) pp. 6885.CrossRefGoogle Scholar