Langley's Adventitious Angles

Last updated April 29, 2023

Langley's Adventitious Angles is a puzzle in which one must infer an angle in a geometric diagram from other given angles. It was posed by Edward Mann Langley in The Mathematical Gazette in 1922.^[1]^[2]

The problem

In its original form the problem was as follows:

ABC

is an isosceles triangle with

\angle {CBA}=\angle {ACB}=80^{\circ }.

CF

at

30^{\circ }

to

AC

cuts

AB

in

F.

BE

at

20^{\circ }

to

AB

cuts

AC

in

E.

Prove

\angle {BEF}=30^{\circ }.

^[1]^[2]^[3]

Solution

The problem of calculating angle $\angle {BEF}$ is a standard application of Hansen's resection. Such calculations can establish that $\angle {BEF}$ is within any desired precision of $30^{\circ }$ , but being of only finite precision, always leave doubt about the exact value.

A direct proof using classical geometry was developed by James Mercer in 1923.^[2] This solution involves drawing one additional line, and then making repeated use of the fact that the internal angles of a triangle add up to 180° to prove that several triangles drawn within the large triangle are all isosceles.

Draw

BG

at

20^{\circ }

to

BC

intersecting

AC

at

G

and draw

FG.

(See figure on the lower right.)

Since

\angle {BCG}=80^{\circ }

and

\angle {CBG}=20^{\circ }

then

\angle {BGC}=80^{\circ }

and triangle

BCG

is isosceles with

BC=BG.

Since

\angle {BCF}=50^{\circ }

and

\angle {CBF}=80^{\circ }

then

\angle {BFC}=50^{\circ }

and triangle

BCF

is isosceles with

BC=BF.

Since

\angle {FBG}=60^{\circ }

and

BF=BG

then triangle

BGF

is equilateral.

Since

\angle {BGE}=100^{\circ }

and

\angle {GBE}=40^{\circ }

then

\angle {GEB}=40^{\circ }

and triangle

BGE

is isosceles with

GB=GE.

Therefore all the red lines in the figure are equal.

Since

GE=GF

triangle

EFG

is isosceles with

\angle {GEF}=70^{\circ }.

Therefore

\angle {BEF}=30^{\circ }.

Many other solutions are possible. Cut the Knot list twelve different solutions and several alternative problems with the same 80-80-20 triangle but different internal angles.^[4]

Generalization

A quadrilateral such as BCEF is called an adventitious quadrangle when the angles between its diagonals and sides are all rational angles, angles that give rational numbers when measured in degrees or other units for which the whole circle is a rational number. Numerous adventitious quadrangles beyond the one appearing in Langley's puzzle have been constructed. They form several infinite families and an additional set of sporadic examples.^[5]

Classifying the adventitious quadrangles (which need not be convex) turns out to be equivalent to classifying all triple intersections of diagonals in regular polygons. This was solved by Gerrit Bol in 1936 (Beantwoording van prijsvraag # 17, Nieuw-Archief voor Wiskunde 18, pages 14–66). He in fact classified (though with a few errors) all multiple intersections of diagonals in regular polygons. His results (all done by hand) were confirmed with computer, and the errors corrected, by Bjorn Poonen and Michael Rubinstein in 1998.^[6] The article contains a history of the problem and a picture featuring the regular triacontagon and its diagonals.

In 2015, an anonymous Japanese woman using the pen name "aerile re" published the first known method (the method of 3 circumcenters) to construct a proof in elementary geometry for a special class of adventitious quadrangles problem.^[7]^[8]^[9] This work solves the first of the three unsolved problems listed by Rigby in his 1978 paper.^[5]

Related Research Articles

In mathematics, two quantities are in the golden ratio if their ratio is the same as the ratio of their sum to the larger of the two quantities. Expressed algebraically, for quantities $and with,$

In geometry a quadrilateral is a four-sided polygon, having four edges (sides) and four corners (vertices). The word is derived from the Latin words quadri, a variant of four, and latus, meaning "side". It is also called a tetragon, derived from greek "tetra" meaning "four" and "gon" meaning "corner" or "angle", in analogy to other polygons. Since "gon" means "angle", it is analogously called a quadrangle, or 4-angle. A quadrilateral with vertices $,, and is sometimes denoted as .$

A triangle is a polygon with three edges and three vertices. It is one of the basic shapes in geometry. A triangle with vertices A, B, and C is denoted $.$

<span class="mw-page-title-main">Similarity (geometry)</span> Same shape, up to a scaling

In Euclidean geometry, two objects are similar if they have the same shape, or if one has the same shape as the mirror image of the other. More precisely, one can be obtained from the other by uniformly scaling, possibly with additional translation, rotation and reflection. This means that either object can be rescaled, repositioned, and reflected, so as to coincide precisely with the other object. If two objects are similar, each is congruent to the result of a particular uniform scaling of the other.

In geometry, a hexagon is a six-sided polygon. The total of the internal angles of any simple (non-self-intersecting) hexagon is 720°.

<span class="mw-page-title-main">Kite (geometry)</span> Quadrilateral symmetric across a diagonal

In Euclidean geometry, a kite is a quadrilateral with reflection symmetry across a diagonal. Because of this symmetry, a kite has two equal angles and two pairs of adjacent equal-length sides. Kites are also known as deltoids, but the word deltoid may also refer to a deltoid curve, an unrelated geometric object sometimes studied in connection with quadrilaterals. A kite may also be called a dart, particularly if it is not convex.

<span class="mw-page-title-main">Altitude (triangle)</span> Perpendicular line segment from a triangles side to opposite vertex

In geometry, an altitude of a triangle is a line segment through a vertex and perpendicular to a line containing the base. This line containing the opposite side is called the extended base of the altitude. The intersection of the extended base and the altitude is called the foot of the altitude. The length of the altitude, often simply called "the altitude", is the distance between the extended base and the vertex. The process of drawing the altitude from the vertex to the foot is known as dropping the altitude at that vertex. It is a special case of orthogonal projection.

<span class="mw-page-title-main">Equilateral triangle</span> Shape with three equal sides

In geometry, an equilateral triangle is a triangle in which all three sides have the same length. In the familiar Euclidean geometry, an equilateral triangle is also equiangular; that is, all three internal angles are also congruent to each other and are each 60°. It is also a regular polygon, so it is also referred to as a regular triangle.

In Euclidean geometry, a cyclic quadrilateral or inscribed quadrilateral is a quadrilateral whose vertices all lie on a single circle. This circle is called the circumcircle or circumscribed circle, and the vertices are said to be concyclic. The center of the circle and its radius are called the circumcenter and the circumradius respectively. Other names for these quadrilaterals are concyclic quadrilateral and chordal quadrilateral, the latter since the sides of the quadrilateral are chords of the circumcircle. Usually the quadrilateral is assumed to be convex, but there are also crossed cyclic quadrilaterals. The formulas and properties given below are valid in the convex case.

<span class="mw-page-title-main">Euler line</span> Line constructed from a triangle

In geometry, the Euler line, named after Leonhard Euler, is a line determined from any triangle that is not equilateral. It is a central line of the triangle, and it passes through several important points determined from the triangle, including the orthocenter, the circumcenter, the centroid, the Exeter point and the center of the nine-point circle of the triangle.

In geometry, Thales's theorem states that if $A$ , $B$ , and $C$ are distinct points on a circle where the line $AC$ is a diameter, the angle $∠ ABC$ is a right angle. Thales's theorem is a special case of the inscribed angle theorem and is mentioned and proved as part of the 31st proposition in the third book of Euclid's Elements. It is generally attributed to Thales of Miletus, but it is sometimes attributed to Pythagoras.

<span class="mw-page-title-main">Isosceles triangle</span> Triangle with at least two sides congruent

In geometry, an isosceles triangle is a triangle that has two sides of equal length. Sometimes it is specified as having exactly two sides of equal length, and sometimes as having at least two sides of equal length, the latter version thus including the equilateral triangle as a special case. Examples of isosceles triangles include the isosceles right triangle, the golden triangle, and the faces of bipyramids and certain Catalan solids.

<span class="mw-page-title-main">Incenter</span> Center of the inscribed circle of a triangle

In geometry, the incenter of a triangle is a triangle center, a point defined for any triangle in a way that is independent of the triangle's placement or scale. The incenter may be equivalently defined as the point where the internal angle bisectors of the triangle cross, as the point equidistant from the triangle's sides, as the junction point of the medial axis and innermost point of the grassfire transform of the triangle, and as the center point of the inscribed circle of the triangle.

In geometry, a decagon is a ten-sided polygon or 10-gon. The total sum of the interior angles of a simple decagon is 1440°.

<span class="mw-page-title-main">Midpoint</span> Point on a line segment which is equidistant from both endpoints

In geometry, the midpoint is the middle point of a line segment. It is equidistant from both endpoints, and it is the centroid both of the segment and of the endpoints. It bisects the segment.

In Euclidean geometry, a square is a regular quadrilateral, which means that it has four equal sides and four equal angles. It can also be defined as a rectangle with two equal-length adjacent sides. It is the only regular polygon whose internal angle, central angle, and external angle are all equal (90°), and whose diagonals are all equal in length. A square with vertices ABCD would be denoted $ABCD .$

In geometry, the circumscribed circle or circumcircle of a polygon is a circle that passes through all the vertices of the polygon. The center of this circle is called the circumcenter and its radius is called the circumradius.

In geometry, given a triangle $ABC$ and a point $P$ on its circumcircle, the three closest points to $P$ on lines $AB$ , $AC$ , and $BC$ are collinear. The line through these points is the Simson line of $P$ , named for Robert Simson. The concept was first published, however, by William Wallace in 1799.

In Euclidean geometry, the trillium theorem – is a statement about properties of inscribed and circumscribed circles and their relations.

In geometry, the Newton–Gauss line is the line joining the midpoints of the three diagonals of a complete quadrilateral.

References

1 2 Langley, E. M. (1922), "Problem 644", The Mathematical Gazette , 11: 173.
1 2 3 Darling, David (2004), The Universal Book of Mathematics: From Abracadabra to Zeno's Paradoxes, John Wiley & Sons, p. 180, ISBN 9780471270478 .
↑ Tripp, Colin (1975), "Adventitious angles", The Mathematical Gazette , 59 (408): 98–106, doi:10.2307/3616644, JSTOR 3616644 .
↑ Bogomolny, Alexander, "The 80-80-20 Triangle", www.cut-the-knot.org, retrieved 2018-06-03
1 2 Rigby, J. F. (1978), "Adventitious quadrangles: a geometrical approach", The Mathematical Gazette , 62 (421): 183–191, doi:10.2307/3616687, JSTOR 3616687, MR 0513855 .
↑ Poonen, Bjorn; Rubinstein, Michael (1998), "The number of intersection points made by the diagonals of a regular polygon" (PDF), SIAM Journal on Discrete Mathematics, 11 (1): 135–156, doi:10.1137/S0895480195281246, S2CID 8673508 .
↑ Saito, Hiroshi (2016), "The adventitious quadrangles was solved completely by the elementary solution", Gendaisūgaku (現代数学) (in Japanese), 49 (590): 66–73, ISSN 2187-6495 .
↑ aerile_re (2015-10-27), The last challenge from Geometry the Great (in Japanese), archived from the original on 2016-04-16.
↑ Saito, Hiroshi (2016-12-11), Introducing "3 circumcenter method" - English translation of the article from Gendaisūgaku (現代数学).

External links

Angular Angst, MathPages

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[MG-1] 1 2 Langley, E. M. (1922), "Problem 644", The Mathematical Gazette , 11: 173.

[Darling-2] 1 2 3 Darling, David (2004), The Universal Book of Mathematics: From Abracadabra to Zeno's Paradoxes, John Wiley & Sons, p. 180, ISBN 9780471270478 .

[3] Tripp, Colin (1975), "Adventitious angles", The Mathematical Gazette , 59 (408): 98–106, doi:10.2307/3616644, JSTOR 3616644 .

[4] Bogomolny, Alexander, "The 80-80-20 Triangle", www.cut-the-knot.org, retrieved 2018-06-03

[:0-5] 1 2 Rigby, J. F. (1978), "Adventitious quadrangles: a geometrical approach", The Mathematical Gazette , 62 (421): 183–191, doi:10.2307/3616687, JSTOR 3616687, MR 0513855 .

[6] Poonen, Bjorn; Rubinstein, Michael (1998), "The number of intersection points made by the diagonals of a regular polygon" (PDF), SIAM Journal on Discrete Mathematics, 11 (1): 135–156, doi:10.1137/S0895480195281246, S2CID 8673508 .

[7] Saito, Hiroshi (2016), "The adventitious quadrangles was solved completely by the elementary solution", Gendaisūgaku (現代数学) (in Japanese), 49 (590): 66–73, ISSN 2187-6495 .

[8] rile_re (2015-10-27), The last challenge from Geometry the Great (in Japanese), archived from the original on 2016-04-16.

[9] Saito, Hiroshi (2016-12-11), Introducing "3 circumcenter method" - English translation of the article from Gendaisūgaku (現代数学).

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

Langley's Adventitious Angles

Contents

The problem

Solution

Generalization

Related Research Articles

References

External links